identifying the role of rgmc in an animal model of
TRANSCRIPT
Identifying the role of RGMc in an animal model of Multiple Sclerosis
By
Robin J. Vigouroux
A thesis submitted in conformity with the requirements for the degree of Master of Science
Department of Physiology
University of Toronto
© Copyright by Robin J. Vigouroux 2015
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The liver protein Hemojuvelin plays a critical role in an animal model of Multiple Sclerosis
Robin J. Vigouroux Master of Science
Department of Physiology University of Toronto
2015
Abstract The Repulsive Guidance Molecule a (RGMa) has recently been implicated in the development of Multiple sclerosis (MS). We report for the first time that the third
member of the RGM family, RGMc, is downregulated in the sera of mice induced with
Experimental Autoimmune Encephalomyelitis (EAE), a well-characterized animal model
of MS. Treatment with soluble RGMc (sRGMc) significantly delayed the onset of EAE
and reduced the clinical severity of disease. Furthermore, RGMc knockout animals
developed a stronger disease progression than wild-type controls. In vitro binding studies
outlined a mechanism by which soluble RGMa and RGMc competed for interaction with
their shared receptor, Neogenin. Finally, we demonstrated that administration of soluble
RGMc halted leukocyte infiltration by interfering with the RGMa-mediated RhoA
permeabilisation of the Blood-Brain Barrier (BBB). Overall, we show that RGMc
treatment alleviated the clinical severity of EAE by enhancing BBB integrity and
preventing leukocyte infiltration.
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Acknowledgments First and foremost, I would like to thank my supervisor Dr. Monnier, your knowledge, ambition, and passion for research is truly inspiring. Thank you for giving me the opportunity to carry out this exciting research project in your laboratory and for your advice throughout my graduate studies. Thank you to my
committee: Dr. Jeffrey Henderson, Dr. Lyanne Schlichter, and Dr. Joan Wither for your
time and advice in making this project a smooth as possible. In addition I would like to
thank my examination committee members: Dr. James Eubanks, Dr. Valerie Wallace, Dr.
Joan Wither and Dr. Lu-Yang Wang for their invaluable feedback and time.
I would next like to thank two special individuals: Dr. Nardos Tassew and Yuriy
Baglaenko. Nardos, thank you for your support and guidance since my first day in the
laboratory, which has helped shape not only my approach towards research but also my
approach towards life. Yuriy, thank you for the uncountable hours you have spent with
me on this project and most importantly for being you. I will undoubtedly miss our “early
mornings/late nights” on this project. I admire your perception to science, which has
unquestionably affected how I perceive it.
This manuscript would not have been completed without the help of both Yuriy
and Nardos but also the incredible comments provided by both Eric Gracey and Vasilis
Moisiadis, who took time out their extremely busy schedule to give me feedback and
advice. Thank you to Sherry Yang, you were by far the greatest summer student I have
had the pleasure of working with. Thank you to my laboratory colleagues, my days would
seem much longer and darker without you.
Lastly, I would like to thank my parents, Pascal and Véronique. You have always
given me the opportunity to expand my horizons and provided me with the support I
needed. My brother, Thomas, my role model, thank you for reminding me to follow my
passion. My partner, Marla Charlette, words cannot describe the help you have brought to
me during my graduate studies. Although I am sure many more memories are to come.
This project was supported by the CIHR Biotherapeutic Training Program.
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Table of Contents Abstract .................................................................................................................................................. ii Acknowledgments ............................................................................................................................ iii List of Figures ...................................................................................................................................... vi List of Tables .................................................................................................................................... viii List of Abbreviations: ....................................................................................................................... ix
Chapter 1: Introduction .......................................................................................................... 1 1.1 Multiple Sclerosis ........................................................................................................................ 2 1.1.1 Epidemiology and Quality of Life ................................................................................................. 2 1.1.2 Pathogenesis of Multiple Sclerosis ............................................................................................... 4 1.1.3 Multiple Sclerosis and the Iron Hypothesis ............................................................................. 5 1.1.4 Pathophysiology of Multiple Sclerosis ....................................................................................... 7 1.1.5 Treatment of Multiple Slerosis ...................................................................................................... 9 1.2 Experimental Autoimmune Encephalomyelitis (EAE), an Animal Model to Study the Pathophysiology of MS ........................................................................................................... 12 1.2.1 The Experimental Autoimmune Encephalomyelitis Model ............................................ 12 1.2.2 The Established Role of T cells in EAE .................................................................................... 13 1.2.3 An Emerging Role for B cells in EAE ........................................................................................ 14 1.3 The Blood Brain Barrier ........................................................................................................ 15 1.3.1 The Anatomical Composition of the Blood-Brain Barrier ............................................... 15 1.3.2 Immune Extravasation Through The Blood-Brain Barrier ............................................. 15 1.3.3 The Role of Astrocytes In Maintaining The Blood-Brain Barrier Integrity .............. 16 1.4 Repulsive Guidance Molecules ............................................................................................ 18 1.4.1 RGMs and Neogenin ........................................................................................................................ 19 1.4.2 RGMs and Bone Morphogenetic Protein signaling ............................................................. 21 1.4.3 RGMa ..................................................................................................................................................... 22 1.4.4 RGMb ..................................................................................................................................................... 23 1.4.5 RGMc ..................................................................................................................................................... 24 1.4.6 Repulsive Guidance Molecules and Multiple Sclerosis ..................................................... 27 1.5 Hypothesis and aims ............................................................................................................... 29
Chapter 2: Materials and Methods ................................................................................... 30 2.1 Construction of Expression Plasmids ................................................................................ 31 2.1.2 Cloning of sRGMc in the Psectag2B Vector ............................................................................ 31 2.2 Expression and Purification of Recombinant Proteins ............................................... 32 2.2.1 Culturing of Cell-lines ..................................................................................................................... 32 2.2.2 Determining Expression of sRGMc ........................................................................................... 33 2.2.3 Establishment of a Soluble RGMc and Soluble RGMa Stable Cell-line ........................ 33 2.2.4 Protein Purification ......................................................................................................................... 33 2.2.5. Protein Concentration Measurements ................................................................................... 34 2.3 Western Blot Analysis ............................................................................................................. 34 2.4 In Vitro Competition Assay .................................................................................................... 36 2.5 Enzyme-Linked Immunosorbant Assay (ELISA) ............................................................ 37 2.6. Animal Subjects ........................................................................................................................ 38 2.6.1. Statement of Ethics ......................................................................................................................... 38 2.6.2. Experimental Autoimmune Encephalomyelitis Mouse Model ..................................... 38 2.6.3 EAE Body Condition Score ........................................................................................................... 40 2.6.4 sRGMa and sRGMc Treatment Administration .................................................................... 41
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2.7 Flow Cytometry and Cytokine Staining ............................................................................ 41 2.7.1 Cell Preparation ................................................................................................................................ 41 2.7.2. Flow Cytometry and Intracellular Cytokine Staining ....................................................... 41 2.7.3 MOG-Specific Cytokine Expression and Proliferation ....................................................... 43 2.8 Immuno-Histochemistry ........................................................................................................ 44 2.9 Histological Staining ................................................................................................................ 45 2.10 Blood Brain Barrier Permeability Assays ..................................................................... 46 2.10.1. In Vitro BBB Permeability ......................................................................................................... 46 2.10.2 In Vivo BBB Permeability ........................................................................................................... 46 2.11 Microscopy ............................................................................................................................... 47 2.12 Statistical Analysis ................................................................................................................. 47
Chapter 3: Results ................................................................................................................. 48 Aim I: RGMc expression is modulated in the sera of EAE-induced mice ...................... 49 3.1 RGMc is down regulated in the EAE model. ..................................................................... 49 3.2 RGMc over-expression ameliorates clinical severity of EAE-induced mice ........ 51 3.3 RGMc is crucial both pre- and post-symptomatically. ................................................. 53 Aim II: A relationship exists between RGMa and RGMc ..................................................... 55 3.4 sRGMa is up-regulated in our EAE model and is crucial in the development of the disease .......................................................................................................................................... 55 Aim III: RGMc modulates the molecular activation of the adaptive immune system ................................................................................................................................................................ 58 3.5 RGMc treatment does not affect T-cell priming and activation ............................... 58 sRGMc Has No impact on Naïve Immune Cells ............................................................................... 58 sRGMc Treatment Does Not Modulate Activated Immune Cells ............................................. 62 3.6 RGMc affects the infiltration of leukocytes in the CNS ................................................ 65 3.7 sRGMc decreases BBB EC permeability ............................................................................ 68
Chapter 4: Discussion ........................................................................................................... 73 4.1 Soluble RGMa and RGMc are Differentially Regulated in EAE. ................................. 74 4.2 sRGMc and the immune system ........................................................................................... 75 4.2 sRGMc Increases Blood-Brain EC Barrier Stability ...................................................... 76 Axon Guidance Molecules and the Blood-Brain Barrier ............................................................. 76 The Small GTPase Rho and the Blood-Brain Barrier .................................................................... 76 Cross-talk Between the Sonic Hedgehog and Neogenin pathways in Blood-Brain Barrier Permeability .................................................................................................................................. 77 4.3 Working model .......................................................................................................................... 79 4.4 Future Directions ..................................................................................................................... 81 How does RGMa mediate BBB permeabilization? ......................................................................... 81 What is the role of sRGMc on Iron in EAE? ....................................................................................... 81 Does the interplay between sHh and Neogenin play a crucial role in the development of EAE? .................................................................................................................................................................. 82
Chapter 5: Conclusion .......................................................................................................... 83 Chapter 6: Appendix ............................................................................................................. 84 Chapter 7: Bibliography ...................................................................................................... 90
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List of Figures Figure 1-1 Representation of clinical progression of MS……………..………………………………3 Figure 1-2 A schematic representing the organizational layers of the neurovascular unit……………………………………………………………...………………………………………...17 Figure 1-3 The structure of RGM proteins…………………………………………………...……………19 Figure 1-4 Neogenin binds RGMa, RGMb and RGMc at various sites…………..………………20 Figure 1-5 BMP signaling can be mediated through a Smad-dependent and a Smad-independent pathway…………………………………….………………………………….……22 Figure 2-1 A representation of the sRGMc pSecTag2B plasmid………………………………....32 Figure 2-1 Generation of the experimental autoimmune encephalomyelitis (EAE) model……………………………………………………………………………………..……………...39 Figure 2-2 Representation of the body condition score (BCS) index………………..….……..40 Figure 3-1 RGMc levels are decreased during the course of EAE………………….……....……50 Figure 3-2 sRGMc decreases clinical severity of EAE-induced mice…………….……….…….52 Figure 3-3 RGMc plays a role both pre- and post-symptomatically…………….……….……..54 Figure 3-4 sRGMa is up-regulated in EAE and is able to compete with sRGMc for binding to Neogenin……………………….…………………………………………………………….……..57 Figure 3-5 sRGMc has no effect on naïve immune cell populations……………………..……..59 Figure 3-6 sRGMc treatment has no effect on naïve antigen-presenting cells.…………....60 Figure 3-7 sRGMc treatment has no effect on the adhesion protperties of naïve T and B cells……………………………………………………………………………………………………….61 Figure 3-8 sRGMc has no effect on activated immune cells……………………………..…………63 Figure 3-9 sRGMc has no effect on antigen-specific immune cells…………..………………….64 Figure 3-10 sRGMc treatment reduces both the number of cellular Infiltrates and the extent of de-myelination of EAE induced mice...........................................................66 Figure 3-11 sRGMc reduces the amount of immune infiltrates in the spinal cord of EAE-induced mice…………………………………..…………………………………...………….67 Figure 3-12 sRGMa induces blood-brain EC barrier permeability……………………………..…69 Figure 3-13 Neogenin expression in endothelial cells in the mouse spinal cord…………...71 Figure 3-14 sRGMc reduces BBB permeability……………………………………………..…………….72
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Figure 4-1 Neogenin and the Blood-Brain Barrier………………….………………………..………..80 Figure 6-1 sRGMc treatment does not modulate the cytokine secretion of MOG pulsed splenocytes……………………..……………………………………………………………..………85 Figure 6-2 sRGMc treatment reduces cellular infiltrates in the retinas of EAE-induced animals………………………………………...………………………………………………………..86 Figure 6-3 sRGMc treatment reduces CD3+ infiltrates in the spinal cord of EAE-induced mice………………………………………………………………………………...………………….....87 Figure 6-4 sRGMc treatment reduces B220+ infiltrates in the spinal cord of EAE-induced mice………………………………………………………………………………...…………………….88 Figure 6-5 sRGMc treatment reduces CD11b+ infiltrates in the spinal cord of EAE-induced mice…………………………………………...……………………….…………………….89
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List of Tables
Table 1-1 List of novel agents in clinical trials for the treatment of MS as well as current medications approved for the treatment of CIS, RRMS, PPMS, and SPMS………………………………………………………………………...……………………………11
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List of Abbreviations: 4Ig 4 Immunoglobulin-like domain
AP
Alkaline Phosphatase
BCS Body Condition Score
BBB
Blood-Brain Barrier
BM Basement Membrane
BMP Bone Morphogenetic Protein
BSA Bovine Serum Albumin
CCL2
Chemokine Ligand 2
CD Cluster of Differentiation
CIS Clinically Isolated Syndrome
CNS Central Nervous System
CSF Cerebrospinal Fluid
C-terminal Carboxy-terminal
DAPI 4′,6-diamidino-2-phenylindole
DCC Deleted in Colorectal Cancer
DMEM Dulbecco's Modified Eagle Medium
DNA Deoxyribonucleic acid
DRAGON Repulsive Guidance molecule B
EAE
Experimental Autoimmune Encephalomyelitis
EC Endothelial Cell
ELISA Enzyme-linked immunosorbent assay
EBV Epstein-Barr Virus
x
ERK Extracellular-Signal-Regulated Kinase
FBS Fetal Bovine Serum
FNIII Fibronectin type III domain
GA Glatiramer Acetate
GPI Glycosylphosphatidylinisotol
GWAS Genome-Wide Association Study
HEK 293 Human Embryonic Kidney type 293�
ICAM Intracellular Adhesion Molecule
IFN-γ Interferon-Gamma
IgG Immunoglobulin
IL
Inter-Leukin
IP Intra-Peritoneal
IV Intra-Venous
LN Lymph Node
JH
Juvenile Hemochromatosis
MBP
Myelin Basic Protein
MHC Major Histocompatibility Complex
MMP Matrix Metalloproteinase
MOG Myelin Oligodendrocyte Glycoprotein
MRI Magnetic Resonance Imaging
MS Multiple Sclerosis
MT-2 Matriptase-2
N-terminal Amine-terminal
OCC Occludin
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P38-MAPK p38-Mitogen Associated Protein Kinase
PBS Phosphate Buffered Saline
PBST Phosphate Buffered Saline with Tween or TritonX-100
PCR Polymerase Chain Reaction
PEI Polyethylenimine
PFA Paraformaldehyde
PFN3 Phosphate Buffered Saline / Fetal Bovine Serum / Azide
PI3K Phosphatidylinositol-4,5-Biphosphate 3-Kinase
PPMS Primary Progressive Multiple Sclerosis
PNPP P-Nitrophenol Phosphate
RGM Repulsive Guidance Molecule
RGMa Repulsive Guidance Molecule A
RGMb Repulsive Guidance Molecule B / DRAGON
RGMc Repulsive Guidance Molecule C / Hemojuvelin / HFE2
RGD Arginine, Glycine, Aspartic acid
ROCK Rho Kinase
RRMS Relapse-Remitting Multiple Sclerosis
SDS Sodium Dodecyl Sulfate
SDS-PAGE Sodium Dodecyl Sulfate – Polyacrylamide Gel Electrophoresis
SEM Standard Error of the Mean
siRNA Short-Interfering RNA
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SPMS Secondary Progressive Multiple Sclerosis
sRGMa Soluble Repulsive Guidance Molecule A
sRGMc Soluble Repulsive Guidance Molecule C
Th-1 / -17 T helper cell -1 / -17
TJ Tight Junction
T-reg T regulatory cell
WT Wild-type
μg Microgram
μl Microliter
μm Micrometer�
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Chapter 1: Introduction
Nearly one hundred and fifty years have passed since the initial description of “La
Sclérose en plaques” (Multiple Sclerosis) by Charcot, Carswell, and Cruveilhier, yet the
nature of this disease continues to puzzle scientists and physicians (1). This is
demonstrated by the large investment in Multiple Sclerosis (MS) research; the MS
society of Canada spent over 10 million dollars in 2013 and the National Institute of
Health is projecting a budget of 115 million dollars in 2014 (2).
The etiology of MS has been heavily debated for years. Whilst there is little
argument about the pathology and clinical presentation of MS, the question of cause
remains unanswered. The following section will provide a brief overview of the proposed
pathogenesis of MS as well as current treatments for this disease. As with most poorly
understood diseases, researchers depend upon appropriate animal models to both
elucidate the pathogenesis and establish therapeutic targets for MS. Several animal
models currently exist to study precise mechanisms of MS. We will discuss the
application of the experimental autoimmune encephalomyelitis (EAE) model of MS (a
well characterized model) for investigating the pathophysiology of this disease and the
downstream implications for developing therapeutic interventions.
Nascent evidence suggests that the Repulsive Guidance Molecule a (RGMa) and
its receptor, Neogenin, are key players in multiple cellular events in MS. Later sections of
this manuscript will focus on the origin and current biological understanding of RGMs.
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1.1 Multiple Sclerosis 1.1.1 Epidemiology and Quality of Life
MS is a chronic immune-mediated disease of the central nervous system (CNS)
with pathological hallmarks of the disease being inflammation, demyelination, neuronal
loss and gliosis (3). MS is the most common neurological disease amongst young adults,
with over 2.3 million people diagnosed (4). As with several other immune-mediated
diseases, such as type I diabetes, MS follows a sex-bias with a female to male ratio of 3:1
(5). Due to the long duration of disability and diagnosis typically occurring in the third
and fourth decades of life, MS has a profound social and economic impact. According to
the MS Society of Canada, up to 80% of Canadians living with MS will face early
unemployment (6). This places a long-term burden on both health care services and
unemployment insurances.
Clinically, MS can manifest in multiple forms based on the frequency and
duration of neurological deficits, Figure 1-1. The typical phenotype of MS arises with an
isolated neurological deficit which completely subsides, termed Clinically Isolated
Syndrome (CIS) (7). Approximately 85% of patients will go on to develop relapse-
remitting MS (RRMS), typified by neurological deficits for a brief period which subside
completely and spontaneously. Interestingly, ~30% of CIS patients will develop an
atypical form of MS with no relapsing neurological deficits for up to 15 years following
the initial episode. Many of RRMS patients will develop progressive and irreversible
neurological decline, termed Secondary Progressive MS (SPMS) (8). MS may also
present atypically in 5% of patients who have gradual neurological defects that do not
subside with time. This is termed Primary Progressive MS (PPMS). Intriguingly, this
clinical progression of MS does not follow a sex-bias and has a later age of onset, closely
associated with the age of onset of SPMS (9). Lastly, MS can also arise as a pediatric MS,
with 2-5% of patients being diagnosed under the age of eighteen (10).
Physicians assess the development of MS using a variety of tools. This task can
be difficult due to the heterogeneity of symptoms, which range from sensory, cognitive,
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and motor impairments to psychological deficits (11). In addition, symptoms may arise in
isolation or in combination and vary between individuals. As a result of the diverse
symptoms and the varied onset of MS, the diagnostic criteria for MS have evolved
continuously over the years. Currently, the revised McDonald criteria have come to be
dominant in clinical practice. These build upon a comprehensive view of MS
pathophysiology, and include: the presence of oligoclonal immunoglobulin G (IgG) in the
cerebrospinal fluid (CSF) indicative of CNS inflammation, the occurrence of blood-brain
barrier (BBB) lesions on Magnetic Resonance Imaging (MRI) scans, as well as decreased
visual-evoked potentials (indicative of optic nerve damage) (7, 12-14). Recent findings
have identified possible biomarkers for the diagnosis of MS, namely the presence of
neuro-filament heavy chains in the CSF of MS patients, which correlate with relapse rates
and extent of disability (15).
Figure 1-1 Representation of clinical progression of MS. Adapted from (16).
a
b c
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1.1.2 Pathogenesis of Multiple Sclerosis The heterogeneity displayed in the pathology and clinical progression of MS
patients has led to numerous hypotheses for the pathogenic roots of this disease.
Traditionally thought of as an autoimmune disease; MS was proposed to follow an
“outside-in” model. Where peripheral immune activation to specific myelin antigens
leads to infiltration of immune cells into the CNS and subsequent myelin damage.
However, more recent studies have proposed an “inside-out model”. This model
postulates that a neurodegenerative disease triggers the activation of immune cells within
the CNS that lead to bystander activation of peripheral immune cells and damage of
myelin (16). No consensus has been drawn as to which model is correct, as such it
remains unknown whether neuro-degeneration precedes the autoimmune attack in MS or
vice versa.
In order to solve this debate, scientists and physicians have focused on
environmental risk factors that might contribute to the pathogenesis of MS (for review)
(17-20). One striking environmental factor was that lower exposure to sunlight increases
the risk of developing MS. Epidemiologically this manifests as an increased incidence in
regions at greater distances from the equator. The dominant theory for this observation is
that Vitamin D3, an immunosuppressive, sunlight-derived vitamin, is inversely correlated
to the incidence of MS (21-23). Another key environmental trigger correlated with MS is
the occurrence of infections, which supports a “molecular mimicry” hypothesis. This
hypothesis proposes that infections by bacterial and viral organisms, which share
molecular similarities to myelin antigens, may cause an adjuvant-like effect and cause
aberrant autoimmune reaction in the host resulting in CNS damage. The Epstein-Barr
virus (EBV) is such a pathogen that has been linked to MS. This link was strengthened
when the discovery was made that a large portion of MS patients possessed antibodies
against EBV (24).
The role of genetics in the development of MS has also been extensively studied
(25). Initial evidence for a genetic inheritance of MS came from studies of twins. These
data indicate that monozygotic twins have a six-fold higher risk of developing MS than
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do dizygotic twins (26). Moreover, genome-wide association studies (GWAS) have
strengthened the argument that the immune system plays a major role in the development
of MS. These studies have identified DRB1, a gene locus encoding the Major
Histocompatibility Complex (MHC) class II, as having the strongest association with the
risk of MS (27). Minor risk alleles are found in other immune related genes such as those
encoding for interleukins (IL) IL-12A and IL-22RA (28). Recently, it was identified that
epigenetics may also play a role as MS is more frequently inherited from fathers than
mothers (for review) (29).
Despite the role that genetics may play in the development of MS, the majority of
polymorphisms identified in MS do not correlate with disease severity or progression.
Therefore, the complexity of this disease must stem from a conjunction of environmental
triggers in individuals with genetic pre-dispositions.
1.1.3 Multiple Sclerosis and the Iron Hypothesis Iron is crucial for many biological processes in tissues for the proper functioning
of the electron transport chain. In the CNS, iron plays multiple roles ranging from
neurotransmitter release (30) to myelin synthesis (31). Iron homeostasis is essential and
occurs through dietary iron absorption in the duodenum, iron recycling from senescent
erythrocytes in macrophages and storage in the liver (32).
Elevated iron levels have long been recognized in MS patients. Yet, the precise
role of iron in the development of MS remains largely unknown. Studies have observed
abnormal T2-hypointensity in MRI scans of the brains from MS patients which suggests
an increase in iron deposition (33). The localization of iron accumulation may shed light
on its functional role in MS. Although initially characterized by deposition in deep gray
matter regions of MS patients, new technical imaging techniques (Magnetic Field
Correlation, R2 Relaxometry, Susceptibility Weighted Imaging) have also identified iron
deposition in perivascular regions on the periphery of white matter plaques associated
with the site of a lesion (34). The molecular mechanisms by which iron may mediate the
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development of MS are poorly studied. Whilst most studies hypothesize the role of
reactive oxygen or nitrogen species in iron-mediated degeneration (35), one group has
observed that excess iron resulted in the increased secretion of pro-inflammatory
cytokines, such as Tumor Necrosis Factor α (TNF- α) (36). Furthermore, Gemmati and
colleagues identified polymorphisms in several key iron-regulatory molecules that were
highly correlative of MS incidence. Two genes FPN1: a gene encoding for an iron
exporter protein, HEPC: a gene encoding a 25-amino acid enzyme called hepcidin that is
crucial in iron regulation, were found to increase the incidence of MS by more than 4-
fold and 2.5-fold respectively (37). Furthermore, animal studies have identified that
reducing levels of iron resulted by either dietary restriction (38), iron-chelation therapy
(39, 40), or blocking peptides (41), resulted in reduced disease severity. It is important to
note that MS patients undergoing treatment show decreased levels of iron as compared to
patients receiving placebo, thus implying a possible role for iron in mediating disease
progression (42).
There is still wide speculation surrounding the role of iron in MS. There are gaps
in our understanding of whether iron deposition is the result of neuro-degeneration or
whether it contributes to the development of the disease.
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1.1.4 Pathophysiology of Multiple Sclerosis The Immune Cascade
The identification of the MHC II risk allele in MS patients alluded to a central
role played by cluster of differentiation (CD4+) T cells in the development of MS.
Analyses of blood and CSF from MS patients further suggested that the disease
implicated the recruitment of auto-reactive CD4+ T lymphocytes from the periphery to
the CNS, where they tethered, rolled, and adhered to endothelial cells lining the blood
vessels (43). The subsequent infiltration of these cells to the parenchyma is associated
with breakdown of the BBB; this has been demonstrated in MS patients using
gadolinium-enhanced MRI scans (44). The initial infiltration of CD4+ effector cells of the
T helper 17 (Th17) or Th1 subtypes lead to the secretion of pro-inflammatory cytokines,
such as IL-17α and IFN-γ respectively (45). These cytokines are cytotoxic and stimulate
the recruitment of other immune cells, such as CD8+ effector T cells, which are able to
further secrete cytotoxic cytokines or antigen-presenting cells, such as CD11c+ cells
which further prime and activate effector T cells within the CNS. This immune cascade
combines with the activation of CNS resident microglia, which can release cytotoxic
cytokines and reactive oxygen or nitrogen species to damage the network of supporting
oligodendrocytes. In addition to this aberrant immune activation, MS patients display a
decreased ability to negatively regulate effector T cells, further impacting this immune
activation (46, 47). Axonal damage occurs early in demyelinating lesions which correlate
highly with infiltration of immune cells (48).
The Neurodegenerative Cascade
Following the initial immune-induced injury, oligodendrocyte progenitors
mediate endogenous re-myelination of injured areas. These progenitors can receive cues
to proliferate from Semaphorin 3A and 3F, leading to re-myelination of injured axons
(shadow plaques) (49). However, subsequent waves of de-myelination as observed
through RRMS, exhaust the oligodendrocyte progenitor pool and eventually lead to the
clinical shift into the secondary progressive phase of the disease, which is associated with
diffuse neuro-degeneration (50). This phase of the disease has been shown to be
correlated with the infiltration of B cells into the CNS parenchyma, followed by the
8
formation of ectopic lymphoid follicles leading to further de-myelination. Axonal
damage may also occur as a result of Wallerian degeneration due to axonal severing (51).
In addition to immune attack, several recent studies have observed a re-distribution of ion
channels along the length of the axonal processes that lead to enhanced intra-axonal
calcium ion accumulation and consequent degeneration (52, 53). Mitochondrial damage
has also been shown to occur at this stage of the disease. Studies have observed that an
impaired NADH dehydrogenase activity and increased complex IV activity occurs in MS
lesions but not in normal-appearing white matter (54).
The Clinical Patterns
The complexity of MS is highlighted by the heterogeneity of pathological patterns
that occur in MS patients. These pathological hallmarks are subdivided in four distinct
patterns. The initial pathological damage is predominantly regulated by the infiltration of
T and B cells at the site of plaque formation (patterns I and II). Typically these
pathological patterns coincide with the novel occurrence of plaques. Subsequently, there
is a shift towards decreased cellular infiltration and increased neuro-degeneration
represented by sites of hypoxic insult leading to neuronal death and apoptosis (patterns
III and IV). MS was originally thought to target white matter tissue, however extensive
gray matter lesions have been identified in the early phases of MS progression. In the
progressive stages of the disease, BBB breakdown does occur, but to a lesser extent in
comparison to RRMS. Furthermore, immune cell infiltrates are present in areas that
maintain BBB permeability (55). This suggests that in progressive stages, immune
activation takes place within the CNS independently of peripheral infiltration. At this
stage of the disease, patients suffer from extensive brain atrophy and dilatation of
ventricles.
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1.1.5 Treatment of Multiple Sclerosis Early Treatments
Development of therapeutics is often dependent on our understanding of the
underlying pathophysiology of the disease. The development of first-line disease
modifying agents, such as injectable Interferon-β and Glatiramer Acetate (GA), has
provided the first treatments to reduce relapse rates and slow disease progression amongst
RRMS patients (56, 57). Both Interferon-β 1a and 1b subtypes have been shown to have
anti-viral, anti-proliferative and immune-modulatory mechanisms of action (58). The
subsequent discovery of GA, a co-polymer composed of four amino acids, significantly
reduced relapse rates amongst RRMS patients. Mechanistically, GA is proposed to act
through competing with immune cells for binding to myelin basic protein, present on the
myelin sheath of axons. Both Interferon-β and GA were shown to possess similar
efficacies, reducing relapse rate by 30% and reducing the progression of the disease (59).
New Drug Discoveries
In recent years, the targets and mechanisms of MS therapeutics have become
more elaborate; scientists are developing agents that are able to block immune cell
activation, proliferation, adhesion, and cytokine production. The recently FDA-approved
oral agent Fingolimod acts as a Sphingosine-1-Phosphate receptor antagonist. The
presence of this receptor on the surface of immune cells aids in their egress out of
secondary lymphoid organs, such as lymph nodes (60). Another clever treatment under
development inhibits the ability of immune cells to infiltrate into tissue. The development
of monoclonal antibodies that block the function of integrins on the surface of immune
cells, such as the α4β1-blocker Nataluzimab, hinders the ability of these cells to adhere to
endothelial cells lining the choroid plexus of the brain.
Several agents have been tested for their efficacy in treating both SPMS and
PPMS; however, most of these agents have provided disappointing outcomes. There are
currently only 3 agents that are approved by the FDA for the treatment of PPMS and
SPMS, but they are relatively ineffective at interfering with the progression of disability
(see reviews) (59, 61, 62). Recently, the controversial use of hematopoietic stem cell
10
transplantation has been studied in a series of phase II clinical trials that have shown
some benefits in SPMS and PPMS patients (63). Combinational treatments are currently
being tested for possible synergistic effects, such as the use of GA together with
Natalizumab, as well as the development of neuro-protective agents which may prove to
halt the neurodegenerative onset of PPMS and SPMS (60, 61).
The Drawbacks
Whilst these agents provide symptomatic relief in MS patients, there are major
drawbacks to their use. Prolonged use of these treatments can result in a tolerogenic
effect that hinders the efficacy of treatments (64). More troublesome, though, are the
complications associated with the administration of these agents. For example, the
increased incidence of progressive multifocal leuko-encephalopathy (a CNS-specific
infection) in MS patients treated with Natalizumab, or the increased incidence of cardio-
myopathies in MS patients treated with Fingolimod (60).
Overall, the therapeutic landscape for the treatment of MS is developing rapidly,
yet therapeutic interventions still result in mild success amongst patients. Current
therapeutic targets for MS are effective in reducing relapse rates and disability observed
in the early stages of MS. However, most current treatments show significant health costs
on individuals taking these drugs. Furthermore, there are currently very few therapies
offered for MS patients who are in the progressive of the disease.
11
Table 1-1 List of novel agents in clinical trials for the treatment of MS as well as current medications approved for the treatment of CIS, RRMS, PPMS, and SPMS.
Drug name MS type Mode of action Status References
Injectable Drugs
Interferon β (IFN-β1a)
RRMS, SPMS, CIS
Anti-proliferation, immune-modulatory Approved (56, 65)
Interferon β (IFN-β1b)
RRMS, SPMS Anti-proliferation, immune-modulatory Approved (66)
Glatiramer Acetate
RRMS, CIS Antagonist of MPB binding, cytokine modulation, reduced production of ROS and RNS, increased production of BDNF.
Approved (57, 67)
Mitoxantrone RRMS, SPMS, PPMS
Antineoplastic cytotoxic agent, disrupts DNA synthesis, anti-proliferation, and immonu-modulatory
Approved (68)
Oral Drugs
BG-12 RRMS Mode of action not characterized. Approved (69)
Teriflunomide RRMS, CIS Inhibits mitochondrial de novo pyrimidine synthesis Approved (70)
Laquinimod RRMS Acts on VLA-4 responsiveness to chemokine ligand 21. Phase III (71)
Fingolimod RRMS S1PR modulator on lymphocytes and cells Phase III (72, 73)
Monoclonal antibodies
Natalizumab RRMS Inhibits migration of immune cells through BBB endothelial cells. Approved (74, 75)
Alemtuzumab RRMS Targets CD52 on leukocytes. Phase III (76)
Ocreluzimab RRMS Targets CD20 on leukocytes Phase III (77)
Daclizumab RRMS, SPMS Targets CD25 on leukocytes. Phase II (78)
12
1.2 Experimental Autoimmune Encephalomyelitis (EAE), an Animal
Model to Study the Pathophysiology of MS
The development of animal models is an essential tool to better understand the
molecular events occurring in MS. Due to the heterogeneity of this disease in clinical
presentation, disease progression, and pathological features, no single animal model can
fully recapitulate the disease. Thus numerous animal models have been developed for the
investigation of RRMS (SJL/J or C57BL/6 mice), SPMS (Biozzi ABH and NOD mice),
as well as de-myelinating disease (using Cuprizone, Theiler’s murine encephalomyelitis
virus, or dyphteria toxin) (79). However, the most well characterized animal model for
the study of MS is the experimental autoimmune encephalomyelitis (EAE) model.
1.2.1 The Experimental Autoimmune Encephalomyelitis Model
Developed in 1925, the EAE model represents a wide variety of MS animal
models (80). EAE may be induced in mice by active immunization using a myelin
antigen such as myelin oligodendrocyte glycoprotein (MOG) or myelin basic protein
(MBP). The model can also be induced by adoptively transferring immune cells from
MOG-immunized animals to naïve animals. The typical disease onset occurs within 10-
12 days after induction and can follow a variety of progressions depending on the strain
of mouse, dosage of agents, and mode of induction (active or passive) of the disease. No
attempt at summarizing these models will be made as a recently published review
provides an in depth analysis (81). In our model, C57BL/6 mice are induced by active
immunization with MOG(35-55)aa to induce a chronic-progressive form of MS with high
incidence and without the occurrence of remission. The disease progression is
characterized by an ascending paralysis, beginning at the tail and finishing at the
forelimbs. The animal can be scored behaviorally using a well-established body condition
score (BCS), as shown in Figure 2-2.
13
1.2.2 The Established Role of T cells in EAE
In EAE, invading immune cells most prominently target the spinal cord
replicating the pathological patterns I and II of MS (81). The adoptive transfer of CD4+ T
cells from immunized mice into naïve mice confirmed that EAE was also a CD4+ T cell-
mediated disease (82). Initially, IFN-γ producing Th1 effector cells were believed to
mediate the disease, as adoptive transfers of Th1 cells induced EAE in mice. However,
the discovery that the induction of EAE was in fact dependent on a novel cytokine, IL-23,
led to the identification of a novel CD4+ T cell subtype, the IL-17 producing Th17 cells
(83-85). Thus, both Th1 and Th17 CD4+ T cell subsets can mediate EAE. Importantly,
both IFN-γ and IL-17 secreting cells were shown to be enriched in the CSF of MS
patients (45, 86). In EAE, both subtypes of T cells have been shown to promote
differential immune cell recruitments, with Th1 promoting monocytic inflammation and
Th17 promoting neutrophilic infiltrates (87). In addition, novel studies identified that
atypical forms of EAE may arise from a shift in the expression of these pro-inflammatory
cytokines. Higher expression of IL-17 is associated with more prevalent brain lesions
whereas it may be protective in the spinal cord (88). Interestingly, these studies raise the
possibility that T cell subsets may mediate differential functions depending on their tissue
localization.
In a normally functioning immune system, immune cells react and proliferate
upon recognition of a specific antigen. However, this response can be dampened by
another subset of T cells referred to as regulatory T cells (Treg). This T cell pool rapidly
expands and peaks at the recovery phase in the CNS of EAE-induced mice. The role of
these cells was identified using adoptive transfer of Tregs into EAE-induced mice,
resulting in a decreased clinical severity (89, 90). These cells can regulate immune cells
by releasing anti-inflammatory cytokines, such as Transforming Growth Factor-β, and
dampen the immune response. In addition, Tregs can function in an autocrine fashion by
using regulatory receptors to inhibit T cell activation, either by inducing pro-death signals
or by producing immune regulatory cytokines. The most well studied receptor is the
cytotoxic T-lymphocyte antigen-4 which is normally rapidly up-regulated in activated T
cells and regulates T cell function by outcompeting co-stimulatory molecule CD28 (91).
Programmed death-1 is another receptor able to modulate T-cell activation by inhibiting
14
phosphoinositide 3’ kinase (pI3K)-dependent proliferation (92). Importantly, the
appropriate signaling of Tregs was shown to be dysfunctional in the CNS of MS patients
(93).
In addition to the well-established role of CD4+ T-cells in the development of
EAE, studies have also identified other subsets of T cells that play a crucial role in EAE.
Adoptive transfers of CD8+ T cells induce an atypical form of EAE with lesions localized
to white matter of the cerebellum. In addition, this model induces widescale
oligodendrocyte death resembling patterns III and IV of MS patients (94). Recent
findings highlight the occurrence of multiple subsets of CD8+ T cells present in both EAE
and MS. Initial studies using CD8-/- knockout mice have shown increased severity of the
disease and more frequent relapses, indicating a possible regulatory role of CD8+ T cells
in EAE (95, 96). Furthermore, CD8+/CD28-/- T cells have been shown to induce
immunosuppressive phenotypes in EAE by interrupting co-stimulatory molecule
expression on the surface of CD4+ T cells (97).
1.2.3 An Emerging Role for B cells in EAE
Although T cells have been shown to mediate disease, a body of evidence
suggests that B cells are involved in the pathophysiology of EAE. MS patients possess
higher IgG levels in the CSF compared to age-matched controls, suggesting the presence
of antibody-releasing cells within the CSF. Studies have found that B cells enhance EAE
severity by promoting differentiation of Th1 and Th17 cells. Prior to EAE onset, a
regulatory subset of B cells, able to regulate immune response, exist. This may provide a
novel biomarker from which the shift of B cells from regulatory to pathogenic may
correlate with MS onset (98). This finding prompted scientist to develop blocking
antibodies against B cells. Rituximab (for review, see section 1.1.3), acts by binding a B
cell-specific surface receptor (CD20), depleting the B cell pool and ameliorating relapse
rates in MS patients (79).
Overall, EAE models have helped us gain great insight into the pathogenesis and
pathophysiology of MS whilst providing us with numerous therapeutics that have
successfully been translated to the clinic.
15
1.3 The Blood Brain Barrier 1.3.1 The Anatomical Composition of the Blood-Brain Barrier
The circulatory system is vast and complex, providing tissues with nutrients,
hormones and regulating pH. Covering the entire inner surface of blood vessels is the
endothelium, which forms a barrier to regulate vascular permeability. The CNS possesses
a unique endothelial barrier: the BBB. This structure is unique amongst the rest of the
circulatory system, and is made up of multicellular compartments regulating the passage
of contents from the peripheral circulation into the CNS; together these compartments are
referred to as the neurovascular unit. This unit is composed of a primary physical barrier
lining the wall of blood vessels, made of endothelial cells (EC), separated by a basement
membrane (BM) from the second juxtaposed layer of cellular control, the pericytes,
which tightly cover the ECs. Astrocytes regulate a third layer through cellular extensions,
termed astrocytic end-feet. In addition to these cells, the neurovascular unit contains
immune cells unique to the CNS, microglia, as well as the functional units of the CNS,
neurons (Figure 1-2) (99).
The specialized ECs lining the blood vessels of the BBB lack fenestrations, have
low pinocytic activity and possess a continuous expression of tight junction (TJ) proteins
(100). The maintenance of cross talk between the multicellular components of the
neurovascular unit is crucial for CNS homeostasis in response to either toxins or
inappropriate immune infiltration. Under normal conditions, ECs lining the BBB express
very low levels of leukocyte adhesion molecules, thus limiting the influx of peripheral
immune cells (101).
1.3.2 Immune Extravasation Through The Blood-Brain Barrier
In MS, loss of BBB integrity occurs early in the disease progression (102).
Breakdown of the BBB primes tissue for the recruitment of leukocytes and subsequent
neuronal damage. While the BBB normally sequesters immune cells outside of the CNS,
it can also promote the penetration of immune cells to localized regions of inflammation
within the CNS. Early in MS, ECs can enhance leukocyte infiltration by up-regulating
16
both E- and P-selectin proteins on their membranes (103). Furthermore, ECs can secrete
leukocytes attractants such as chemokine ligand 2 (CCL2) (104). Following activation by
inflammatory cytokines, ECs can express adhesion molecules, such as intracellular
adhesion molecule -1 (ICAM-1) and vascular adhesion molecule-1, which enhance the
extravasation of leukocytes through ECs (99). Once they pass through EC junctions,
leukocytes must cross the EC BM. The composition of the EC BM has been shown to
affect leukocyte pooling, for example, a higher expression of laminin 411 and a lower
expression of laminin 511 proteins lead to enhanced leukocyte pooling in EC BM (105).
The final step for infiltration of leukocytes into the parenchyma depends on their
infiltration through astrocytic end-feet. At this stage, leukocytes secrete pro-inflammatory
cytokines, promoting the secretion of matrix metalloprotease – 9 (MMP-9), which
degrades the astrocyte BM and dystroglycan expressed on astrocytic end-feet, resulting in
leukocyte infiltration into the glia limitans (106).
1.3.3 The Role of Astrocytes In Maintaining The Blood-Brain Barrier Integrity
Astrocytes perform a variety of support functions in the CNS, from nutrient distribution
to immune regulation and regulation of BBB integrity. Astrocytic end-feet are highly
polarized structures that express a series of receptors necessary for BBB maintenance.
For example, aquaporin-4, which regulates the influx of water in the CNS, is functionally
lost when astrocyte lose polarity. The result of reduced aquaporin-4 function leads to the
development of edema and increased BBB permeability; both of these phenotypes occur
in EAE-induced mice (107). Studies have recently discovered soluble factors that are
secreted by astrocytes, such as angiotensin-II, which regulate BBB integrity. Using in
vitro co-cultures of ECs and astrocytes, the release of angiotensin-II was shown to
promote an increase in TJ protein formation in ECs, thus strengthening the veracity of the
BBB (108, 109). During the progressive course of MS, astrocytes may, in fact, mediate
anti-inflammatory roles. Recent findings identified that activation of the Hedgehog (Hh)
receptor, Patched-1 (Ptch-1), as well as its downstream transcription factor Gli-1 in
human primary cultures, led to a more robust BBB (i.e. a decrease in CCL2 secretion and
down-regulation of ICAM-1) (110).
17
Figure 1-2 A schematic representing the organizational layers of the neurovascular unit (108).
18
1.4 Repulsive Guidance Molecules A crucial step for the development of the CNS is the appropriate guidance of
axonal tracts towards their target site. These directional cues can be mediated through
either attractive or repulsive molecules. The first discovered guidance cue, Netrin-1, was
shown to attract extending axons towards their correct site of projection (111). Shortly
thereafter, a repulsive molecule was identified in the chick visual system. This molecule
was termed Repulsive Guidance Molecule a (RGMa) as its expression in the chicken
optic tectum led to the repulsion of invading temporal axons from the retina (112).
Since the discovery of these two molecules, three members of the RGM family
have been characterized in mammals: RGMa, RGMb (DRAGON), and RGMc
(Hemojuvelin, HFE2) (113). These proteins share ~40% identity in primary amino acid
sequences and all three express an N-terminal signal peptide sequence followed by an
arginine-aspargine-aspartic acid (RGD) motif. Other key structures include the presence
of a partial von Willebrand type D domain and a carboxy-terminal GPI anchor (113)
(Figu). Both RGMa and RGMc can undergo autocatalytic cleavage generating a
membrane-bound isoform that can further undergo post-translational cleavage to secrete
soluble fragments (114, 115). These proteins demonstrate complex biological activities,
including cell adhesion, axonal outgrowth, axonal guidance, immune regulation, and
systemic iron regulation. All of these functions are mediated through the trans-membrane
receptor Neogenin, which is broadly expressed in the body. RGM’s have also been
shown to enhance Bone Morphogenetic Proteins (BMPs) signaling indirectly by acting as
co-receptors that can activate both the Smad-dependent and -independent pathways.
19
Figure 1-3 The structure of RGM proteins. All RGM proteins share ~40% primary amino acid sequence. All members posses an N-terminal signal sequence targeting the proteins to the membrane where they are anchored using a GPI-anchor sequence on the most C-terminal portion. All RGMs possess a von Willebrand factor domain whereas both RGMa and RGMc possess an auto-catalytic RGD motif able to generate a single-chain and a two-chain membrane-bound protein. RGMb is only expressed as a single-chain membrane-bound protein. Single-chain isoforms can be cleaved from the membrane to generate soluble protein fragments (asterisks).
1.4.1 RGMs and Neogenin
Neogenin is a type-I transmembrane protein that is homologous to the well-
known tumor suppressor receptor, Deleted in Colorectal Cancer (DCC). Both of these
receptors possess an extracellular domain containing four immunoglobulin (4Ig) domains
and six-fibronectin type III (FNIII) domains. The intracellular regions differ between the
two receptors except for 3 conserved regions termed P1, P2, and P3. Unlike DCC,
Neogenin is expressed broadly outside of the CNS in tissues including: lung, heart, gut,
kidney, liver, skeletal muscle, and bone (116). The well-known Netrin-1 ligand, known to
bind DCC at the FNIII(4-5) domains was also shown to bind to Neogenin at the same
location (117), and promote attraction of supraoptic axons in the Xenopus forebrain (118).
Neogenin was also shown to bind RGM proteins, with the RGMa-Neogenin interaction
20
first identified through its chemo-repulsive effect in temporal retinal axons of the chick
anterior optic tectum (119). As portrayed in Figure 1-4, the binding site of RGMa on
Neogenin resides within the FNIII(3-4) domain (114), whereas the binding sites for RGMb
and RGMc are located on the FNIII(5-6) domains (120, 121). Furthermore, functions of
both RGMb and RGMc are mediated through Neogenin signaling (32, 122).
Figure 1-4 Neogenin binds RGMa, RGMb and RGMc at various sites. RGMa was shown to bind the Fibronectin type-III(3-4) domain of Neogenin (114), whereas the binding sites for RGMb and RGMc are located on the Fibronectin type-III(5-6) domains (120, 121).
21
1.4.2 RGMs and Bone Morphogenetic Protein signaling
The BMPs, originally purified in the 1980’s, currently consist of 20 members
belonging to the transforming growth factor -β superfamily of ligands (123). BMPs have
been shown to regulate a number of biological processes, for example, cell fate
specification, cell proliferation, cell migration and cell death (124). There are two types
of BMP receptors, type-I and type-II; BMP ligands bind preferentially to type-I BMP
receptors (125). There are currently four type-I BMP receptors subtypes: ALK3, ALK6,
ALK1, and ALK2 and three type-II BMP receptors subtypes: BMPRII, ACTRIIA, and
ACTRIIB (126, 127). BMP receptors signal through Smad proteins, which upon
activation associate with the receptor and are phosphorylated (receptor-regulated Smads).
Smad proteins form complexes with common-mediator Smads and translocate to the
nucleus to regulate gene transcription, as shown in Figure 1-5. Inhibitory Smads are able
to target the receptor and prevent the phosphorylation of receptor-regulated Smads,
thereby interrupting Smad signaling. Activated BMP receptors can also transduce signals
through a non-canonical pathway utilizing p38 mitogen-acitvated protein kinase (MAPK),
and the extracellular-signal-regulated kinases (ERK1/2). All three RGM proteins bind
BMPs and enhance BMP signaling (128).
22
Figure 1-5 BMP signaling can be mediated through a Smad-dependent and a Smad-independent pathway. A) Upon BMP ligand binding both BMP type-I and BMP type-II receptors dimerize to phosphorylate each other, B) BMP signaling through the canonical pathway is driven by the phosphorylation of Regulatory-Smads which then form a complex with Common-mediator Smads. This complex translocates to the nucleus mediating gene transcription. Alternatively, BMP ligands can activate non-canonical BMP signaling through the activation of downstream p38MAK or ERK1/2. 1.4.3 RGMa
RGMa, the first member of the RGM family, is expressed throughout the body:
CNS, heart, liver, lung, kidney, and gut (113). Surprisingly, silencing the expression of
RGMa is embryonically fatal in only 50% of mice due to failure of neural tube closure
(129). The RGMa protein is post-translationally processed by two pro-protein
convertases, Furin and SKI-1, to generate several soluble and membrane-bound
fragments. The uncleaved full-length protein possesses no biological activity, whereas the
cleaved fragments, both membrane-bound and soluble, inhibit neurite outgrowth through
Neogenin (114). Thus, the processing of RGMa is essential for its biological activity. The
molecular mechanism by which RGMa mediates this repulsive cue has been heavily
studied. To date, RGMa was shown to bind the transmembrane receptor Neogenin, and
activate downstream cytoskeletal remodeling proteins, such as RhoA, Rac1, and CDC42.
Rac1 and CDC42 were shown to act as positive regulators of neurite extension. On the
other hand, RhoA was shown to negatively regulate actin cytoskeleton and mediate
23
growth cone collapse, which is efficiently inhbited using C3-Transferase. RhoA activates
a downstream effector, Rho Kinase which is effectively inhibited using the RhoK
inhibitor Y-27632 (130-132).
The RGMa-Neogenin signaling pathway has been observed to participate in
various biological functions: axon tract formation (133, 134), neural tube closure (135),
neuronal differentiation (136), cell survival (137), cell migration (138), regeneration
(139), and immune activation (140-142). RGMa was also shown to function as a BMP
co-receptor in vitro where it enhanced the BMP canonical signaling pathway (143, 144)
1.4.4 RGMb
The second member of the RGM family, RGMb, is currently the least
characterized; intriguingly RGMb and RGMa share a non-overlapping expression pattern
(145). RGMb is expressed in the CNS, bone, heart, lung, liver, kidney, testis, ovary,
uterus, epididymis and pituitary (146). Whereas knockout of RGMa resulted in high fetal
mortality, RGMb knockout mice die within 2-3 weeks following birth (147). RGMb was
the first member of the RGMs found to act as a co-receptor of BMP ligands (BMP-2/-4)
it activates the downstream Smad-dependent signaling pathway (148).
Early in vitro studies on post-natal rat cerebellar granule neurons showed that
RGMb-treated neurons exhibited shorter neurite length in comparison to non-treated
neurons. Using RhoA pull-down assays, Liu et al. (2009) were able to identify that
RGMb-treated neurons activated the downstream RhoA/Rho-kinase signaling pathway.
Furthermore, RGMb expression was up regulated at the site of injury following spinal
cord injury, indicating a possible inhibitory nature of RGMb in vivo (149). However,
recent observations have identified that RGMb may actually promote neurite outgrowth.
Dorsal root ganglion cells isolated from RGMb knockout mice developed shorter neurites
compared to their wildtype controls. Additionally, RGMb deficient mice showed a
decreased regenerative ability following sciatic nerve injury, which was rescued using the
BMP antagonist Noggin. Thus, RGMb can mediate axonal outgrowth as well as
peripheral nerve regeneration by activating the BMP Smad-dependent pathway (122).
24
Interestingly, RGMb was shown to decrease the expression of IL-6 on
macrophages through the non-canonical BMP pathway by activating the p38 MAPK and
ERK1/2 pathway (147). The recent finding that RGMb could act as a co-receptor to the
programmed-death ligand-2, which able to negatively regulate T cell expansion, further
supported the role of RGMb in immune regulation (150).
1.4.5 RGMc
The discovery of RGMc, also known as Hemojuvelin, was completed by mapping
the gene locus associated with an autosomal recessive disease, juvenile hemochromatosis
(JH) (32). JH presents as an early onset of iron overload typically in the first and second
decade of life, and is caused by the lack of function of a liver-derived enzyme, hepcidin.
Hepcidin regulates iron homeostasis by binding and degrading ferroportin, an iron efflux
exporter (151). Studies identified that RGMc knockout mice develop iron overload and a
decreased hepcidin expression, which is similar to observations in JH (152).
The RGMc protein undergoes complex post-translational processing. The
presence of an autocatalytic sequence results in two cell membrane proteins: i) a single-
chain 50 KDa; and 2) a two-chain 30 KDa protein linked to a 20 KDa protein by di-
sulfide bonds (Figu). The single-chain protein can be further processed by a pro-protein
convertase, Furin, to release a 50 KDa fragment (153). Furthermore, single-chain RGMc
can be cleaved by a serine-protease Matriptase-2 (MT2) to release a 36 KDa fragment
(32).
In hepatocytes, single-chain membrane-bound RGMc acts as a co-receptor for
BMP-6 and induces hepcidin expression (154, 155). Interestingly, only the two-chain
RGMc was shown to bind to Neogenin, whereas the single-chain did not (120, 156).
However, Neogenin knockout animals experience iron overload, low levels of hepcidin,
and reduced BMP signaling (157). These data suggest that Neogenin plays a crucial role
in RGMc-mediated iron regulation.
25
However, the mechanism by which Neogenin regulates iron is poorly understood.
In some studies, Neogenin increased RGMc cleavage at the membrane (32), while in
other studies it reduced the cleavage (157). Moreover, Neogenin was shown to have
variable effects on BMP signaling, in some cases increasing, having no effect or reducing
signaling (152). Soluble fragments of RGMc (sRGMc) play crucial roles in iron
regulation. Whereas membrane-bound RGMc promotes hepcidin expression, sRGMc
inhibits hepcidin expression by competing with BMP receptors for BMP ligands (158).
Although the presence of sRGMc in the sera is well-established, its origin is not
known (152). In the liver, the serine protease MT2 (encoded by the TMPRSS6 gene)
cleaves RGMc upon association of RGMc with Neogenin and MT2. Subsequently, the
complex internalized and trafficked to the Golgi for modification, recycling to the
membrane and a final cleavage by MT2 to sRGMc (32). However, when MT2 is knocked
out sRGMc levels are unchanged, suggesting that the role of MT2 in vivo is not necessary
and that other pathways exist for the creation of sRGMc (159). In fact, the ubiquitously
expressed protein Furin can also cleave RGMc. Cleavage of RGMc by Furin generates a
50 KDa fragment, and is co-ordinated by the hypoxia-inducible factor 1α (160).
Interestingly, the Furin-generated fragment appears to be a more potent inhibitor of BMP
signaling than is the MT2-generated fragment (161). Thus, sRGMc may fill roles other
than iron-regulation. RGMc processing appears to differ between varying tissues.
Skeletal muscle RGMc has been proposed to act as a reservoir for soluble RGMc,
however, skeletal muscle-specific knockout of RGMc does not affect iron regulation as
would be expected (162). Conversely, liver-specific knockout of RGMc does result in
systemic iron overload. Thus, in vivo liver-specific RGMc likely possesses most
importance for iron regulation.
RGMc has been proposed to regulate systemic iron levels through the formation
of a super protein complex. In the circulation, iron-bound transferrin can bind transferrin
receptors (transferrin 2) on the membrane of hepatocytes. This binding dissociates the
iron regulating protein, HFE, which can associate with RGMc to activate the Smad-
dependent signaling pathway inducing the expression of hepcidin (163).
26
Inflammation is associated with iron deregulation. Iron redistribution of reticulo-
endothelial macrophages and reduced intestinal iron absorption are believed to be the
main mechanisms for this iron dysregualtion. During inflammation, IL-6 activates Janus
kinase, to induce hepcidin expression through the phosphorylation of STAT3, which in
turn decreases intestinal iron absorption. Bacterial lipopolysaccharide (LPS; an
inflammatory bacterial agent) induces hepcidin expression and reduces the expression of
RGMc, BMP-2, BMP-4 and BMP-6 in the liver. Furthermore, in vitro studies in a human
hepatoma cell line demonstrated that TNF-α decreased RGMc levels independently of IL-
6 (164-166). Further studies have outlined that induced hepcidin expression following
inflammation is independent of BMP-Smad signaling (167). To date little is known about
the physiological roles of sRGMc. And the source of serum sRGMc remains unknown.
27
1.4.6 Repulsive Guidance Molecules and Multiple Sclerosis
As previously discussed, RGMa serves a pivotal role in the proper development
of the CNS, yet the role of RGMa outside of this complex system has been largely
understudied. Reports of increased RGMa expression on activated macrophages
following spinal cord injury raised a potential route by which RGMa may mediate its
chemo-repulsive signal on regenerating axonal fibers following injury (139, 168). Indeed,
in vitro co-cultures of mouse cortical neurons with macrophages supplemented with LPS,
strongly inhibited neurite outgrowth and led to neurite growth cone collapse (168). This
RGMa effect was shown to be mediated through its interaction with Neogenin since
down-regulation of Neogenin, using short-interfering RNA, decreased the chemo-
repulsive effect of activated macrophages (168). Thus, RGMa is expressed in the surface
of macrophages at the site of injury and is able to repulse regenerating fibers.
Interestingly, a recent discovery linked RGMa to murine EAE, shifting our
understanding of the physiological role of RGMa (169). This study was extended by
genotyping polymorphisms in the RGMa locus of MS patients which revealed to be
highly correlative and followed a female bias, as observed in clinical onsets of the disease.
RGMa polymorphisms correlated with elevated TNF-α and IFN-γ in the CSF and the
peripheral blood mononuclear cells (PBMCs) of MS patients (169). In addition, soluble
fragments of RGMa were found in the cerebrospinal fluid of RRMS patients which
decreased in patients undergoing intrathecal corticosteroid triamcinolone acetonide
(TCA) treatment (170). These exciting studies have shed light on a novel function of
RGMa in immune modulation.
More recently, possible mechanisms by which RGMa may mediate its immune
modulatory effect have been proposed. In vitro studies observed that following LPS
administration, both the full-length and the auto-catalytically cleaved forms of RGMa
were up regulated on the surface of bone marrow-derived dendritic cells, whereas its
receptor, Neogenin, was expressed on the surface of CD4+ T cells (142). Western blot
analysis identified a small GTPase, Rap1, which upon RGMa expression becomes
elevated leading to an increase in T cell adhesion (observed via increased ICAM-1
expression) (142). This finding highlights a possible role for the RGMa-Neogenin
28
signaling pathway in immune cell priming and activation. Muramatsu et al. (2011) were
able to show that using an RGMa-specific antibody decreased the clinical severity in both
active and passive EAE-induced mice. Overall, the RGMa antibody-treated animals
showed a significant reduction in cellular infiltration in spinal cord tissue as well as,
reduced white matter demyelination at day 21 following induction of EAE. These
observations were further confirmed in PBMCs of RRMS patients, where inhibition of
RGMa using an RGMa-specific antibody attenuated T cell proliferation and cytokine
production (142, 171).
RGMa has been further implicated in immune regulation through its ability to
transiently (for 8 hours) hinder leukocyte extravasation in an in vivo model of Zymosan-
A-induced peritonitis (141). RGMa expressed in cytokeratin-positive epithelial cells in
addition to polymorphonuclear leukocytes that expressed both RGMa and Neogenin
(141). In vitro analysis using a parracellular flux assay, indicated that RGMa reduced
formyl-methionyl-leucyl-phenylalanine induced PBMC migration through a lung
epithelial cell monolayer (141). The RGMa/Neogenin signaling pathway was further
implicated in acute inflammation by Konig and colleagues. They reported that Neogenin
knockout animals lost the ability to develop immune response following an acute
peritonitis model (140).
Taken together, the expression of RGMa on peripheral immune cells can
modulate immune activation through dendritic cell-T cell signaling, or by inhibiting the
infiltration of immune cells through epithelial cells. The potential of RGMa signaling in
MS goes far beyond immune modulation, as discussed previously. Inhibition of RGMa
signaling promotes axonal regeneration in several spinal cord injury models as well as
optic nerve injury models (139). Despite the recent focus on RGMa and its role as an
immune modulator, the physiologic mechanism by which RGMa mediates its actions on
the immune system is still poorly understood.
29
1.5 Hypothesis and aims
The recent elucidation that RGMa, and its interaction with Neogenin, plays a
crucial role in immune-activation and priming has uncovered a novel therapeutic target
for the treatment of MS. Yet, these studies fail to identify the role of soluble RGMa in the
development of MS. Likewise, RGMc is also processed and co-exists with soluble RGMa
in the serum. Both soluble proteins were shown to mediate their signal through their
interaction with Neogenin. Thus, we believe that the regulation between levels of soluble
RGMa as well as soluble RGMc is crucial for the development of autoimmune diseases,
such as MS. Together this thesis aims to examine the role of RGMc in the development
of autoimmune diseases in the context of a mouse animal model of MS, EAE.
In this study we hypothesize that:
Soluble RGMc is a key player in the development of experimental autoimmune encephalomyelitis and is crucial in immune-regulation in the CNS.
Our hypothesis will be tested with the following aims:
I: RGMc expression is modulated in the sera of EAE-induced mice
1. Examine the expression of soluble RGMa (sRGMa) and RGMc (sRGMc) in the
sera of mice at days 0, 5, 10, 18, and 30 post-EAE induction.
2. Examine whether supplement of RGMc ameliorates the clinical score in EAE-
induced mice
II: A relationship exists between RGMa and RGMc in the development of EAE
1. Observe the binding properties of sRGMa and sRGMc to Neogenin in vitro
2. Analyze the clinical severity of EAE-induced mice treated with sRGMc in
conjunction with sRGMa
III: RGMc modulates the molecular activation of the adaptive immune system
1. Survey the population distribution of immune cells and the activation of antigen-
specific immune cells in EAE-induced mice treated with sRGMc or vehicle
2. Examine the role of sRGMc on the migration of immune cells into the CNS
30
Chapter 2: Materials and Methods
31
2.1 Construction of Expression Plasmids To examine the role of soluble RGMc in the serum, a construct was engineered and
cloned. Membrane-bound full-length RGMc (mus musculus) was available and used as a
starting material for further cloning.
2.1.2 Cloning of sRGMc in the Psectag2B Vector
To replicate endogenous soluble RGMc, present in serum, the GPI anchor sequence of
RGMc was removed, generating a truncated form of RGMc (sRGMc). The resulting
protein is targeted to the membrane using the Psectag2B signaling sequence and is
released out of the cell, into the medium, as a soluble protein. sRGMC was generated
using the following primers:
Forward primer: 5’ cttggtacccatcatcatcatcatcatcagtgcaagatcctccgctg 3’
Reverse primer: 5’ gcgtctagacactcgagcgtcgagctgcccagctgtctgtc 3’
A Polymerase Chain Reaction (PCR) was performed, using TAQ polymerase, to generate
an RGMc DNA fragment of 1175 base pairs in length containing a KpnI restriction site
(5’ end) and an EcorI site (3’end) (New England Biolabs). The PCR product was then
purified and ligated into a T-vector which was subsequently digested, with the above
mentioned restriction enzymes, and inserted into a pSecTag2B expression vector
(Invitrogen). This construct was subsequently sent for sequencing to ensure the protein
was in the correct frame. The pSecTag 2B vector contains a T7 promoter binding site and
an Igk lead signal peptide for the specific targeting of the inserted sRGMc sequence to
the cellular membrane, see Figure 2-1.
32
Figure 2-1 A representation of the sRGMc pSecTag2B plasmid. The sRGMc construct was generated using the pSecTag2B expression plasmid, containing a T7 promoter and an Igk lead sequence, allowing for the overexpression of sRGMc to the cellular membrane of cells. The construct was generated with an N-terminal and a C-terminal His-tag sequence and a Myc-tag sequence on the C-terminal end. These tags allowed for the specific identification of the secreted protein as well as a method for specific purification of sRGMc.
2.2 Expression and Purification of Recombinant Proteins 2.2.1 Culturing of Cell-lines
Human Embryonic Kidney cells (HEK293) and murine Brain-derived Endothelial cells
(b.end3) were cultured in a humid environment at 37°C and 5% CO2. Cells were
maintained in Dulbecco’s Modified Eagle Medium (Sigma-Aldrich or ATCC) containing
10% fetal bovine serum (FBS) (Gibco) and 1% penicillin/streptomycin (p/s) antibiotics
(Gibco). For cell passaging, a 5-minute trypsinization step (0.25% Trypsin-EDTA,
Gibco) was done in order to disrupt adhesion of cells on the plates.
33
2.2.2 Determining Expression of sRGMc
The sRGMc pSecTag2b plasmid was transiently transfected into the HEK 293 cell line
using the transfection reagent, polyethylenimine (PEI, Polysciences Inc.). Cells were
transfected with 9μg of DNA at 95% cell confluency and were incubated for 6 hrs at
37°C and 5% CO2. The media was removed and cells were washed using Dulbecco-
Phosphate Buffered Saline (D-PBS, Sigma-Aldrich), medium with reduced serum (OPTI-
MEM, Gibco) was then added to the cells and incubated at 37°C and 5% CO2 for 48 hrs.
Empty pSecTag2b-transfected cells served as a control. Following incubation, the
medium was harvested and centrifuged at 300 rcf for 5 minutes to dispense of cellular
debris. Supernatants were then extracted and sRGMc was visualized by SDS-PAGE, see
section 2.3.
2.2.3 Establishment of a Soluble RGMc and Soluble RGMa Stable Cell-line
95% confluent HEK 293 cells were grown in antibiotic-free media for 16 hrs prior to
transfection. HEK 293 cells were transfected with sRGMc and sRGMa (previously
generated from our laboratory) using Lipofectamine 2000 reagent (Invitrogen) according
to manufacturer instructions. Briefly, 24μg of DNA was added to 60μl of Lipofectamine
2000 reagent and seeded to each 10cm tissue culture plate. 24 hrs post-transfection, cells
were passaged in a 1:3 ratio and incubated at 37°C. 48 hrs post-transfection, selection
media (10% FBS, 1% p/s, 250μg/mL Zeocin) was added to the cells and maintained
under selection (every 2-3 days) until all transfected cells were selected. Each specific
colony was then picked and expanded. The expression of both sRGMc and sRGMa were
then assessed using western blot analysis, as described in section 2.3.
2.2.4 Protein Purification
Once the stable cell line expressing both, sRGMc as well as sRGMa, reached 95%
confluence, the media was replaced with OPTI-MEM to aid in the purification process.
After 48 hrs of incubation at 37°C and 5% CO2, the media was spun at 300 rcf, collected
and stored at 4°C. The pH of the media was analyzed (>8.0) and 500μl of nickel agarose
(Ni-A) beads (Qiagen) were then added to the media and shaken for 2 hrs at 4°C. The
beads were then washed using 10mL of Ni-A wash buffer (5mM imidazole, 500mM
NaCl in PBS) for 30 mins at 4°C. The beads were subsequently washed and eluted with
34
500μl of Ni-A Elution buffer (250mM imidazole, 500mM NaCl in PBS) using a gravity
column (BioBasic). Each elution was dialyzed (Spectra/Por cellulose dialysis membrane
Spectrum Laboratories, Inc) with two changes of 1X PBS (137mM NaCl; 10mM
Phosphate buffer; 2.7mM KCl, pH 7.4). The proteins were aliquoted and stored at -20°C.
Protein purity was verified on a SDS-gel developed with a coomassie brilliant blue stain
(Bio-Rad), see section 2.3.
2.2.5. Protein Concentration Measurements
Protein concentrations of individual samples were determined using the protein Bradford
assay (Thermoscientific) as described by the manufacturers. Protein concentrations were
analyzed from absorbance values at 595nm wavelength using a spectrophotometer
(BioTek EL311 AutoReader). The recorded values were normalized to a blank (re-
suspension buffer). Six standard protein concentrations were used to generate a standard
curve; sample concentrations were determined based on their absorbance values.
2.3 Western Blot Analysis Western blot analysis was used to verify the expression of proteins used in this study.
Samples were prepared from: mouse serum, cells, conditioned medium, and reduced-
serum medium. Samples were prepared for gel electrophoresis by adding a 6X loading
buffer (50mM Tris-HCl [pH 6.8], 2% SDS, 10% Glycerol, 1% Beta-mercaptoethanol,
12.5mM EDTA, and 0.02% Bromophenol Blue) and denaturing the proteins by heating
the samples at 95°C for 5 minutes. Equal volume of sample were next loaded and
resolved on a 0.75mm 4% stacking / 10% resolving acrylamide gel in Tris-glycine
running buffer (25mM Tris, 192mM Glycine, and 0.1% SDS) at a constant voltage of 200
V for 1 hr (PowerPacTM Basic Power Supply, Bio-Rad).
To verify protein purity, SDS-gels were washed in Milli-Q H2O and stained with
Coomassie brilliant blue (Sigma-Aldrich) for 30 mins at room temperature.
To verify proteins by Western blot, proteins were then transferred to a nitrocellulose
35
membrane (Bio-Rad) in transfer buffer (30.3g Tris + 144g glycine in water) either
overnight at 4°C using a constant voltage of 11 V, or 1 hr at 4°C using a constant voltage
of 80 V. After the transfer, the membrane was blocked for 1 hr at room temperature with
5% non-fat dry milk solution dissolved in PBS. The nitrocellulose membranes were then
incubated overnight at 4°C with primary antibody in blocking PBST solution (5% non-fat
dry milk, 0.1% Tween-20, PBS). The primary antibodies used are described in Table 2-1.
Antibody Cat. No. company
RGMa AF-2459 R&D
RGMc AF-3636 R&D
Transferrin Sc-30159 Santa Cruz
Neogenin Sc-15337 Santa Cruz
Following primary antibody incubation, the blots were washed three times in PBST (10
mins washes) and then incubated for 2 hrs with InfraRed (IR)-linked secondary
antibodies at room temperature. The secondary antibodies used were: IRDye 800CW,
[Donkey anti-Rabbit]; [Goat anti-Mouse], [Donkey anti-Goat], LI-COR BioSciences).
Lastly, following further washing in PBST, specific immunoreactivity was visualized
using an Odyssey infrared Imaging system (LI-COR BioSciences).
In order to observe the expression of endogenous RGMc in mouse serum – Mice were
induced with EAE, as described in section 2.6.2. Prior to induction and 18 days post-
induction, blood was extracted from the saphenous vein of mice and allowed to coagulate
for 2 hrs at room temperature. The blood samples were then centrifuged at 2000 rcf for
20 mins and subsequently stored at -80°C. A 0.75mm 4% stacking /12% SDS gel was run
as previously described. The transferred nitrocellulose membrane was blocked using 5%
bovine serum albumin (BSA) (BioShop) in PBS. Blots were scanned and visualized using
36
an Odyssey infrared imaging system. Protein levels were determined using densitometric
analysis. RGMc protein levels were then normalized to their corresponding Transferrin
protein levels (loading control).
To verify Neogenin expression in brain-derived endothelial cells – the membrane of
b.End3 cells were isolated as follows: cells were centrifuged at 300 rcf for 5 mins,
supernatants removed and pellets were re-suspended in homogenizing (HB) buffer
(10mM HEPES, 25mM KCl, 5mM MgCl2, pH 7.3). The homogenized solution was
mechanically lysed with 10 passes through a 271/2 / 301/2 - gage needles (BD BioSciences).
The solution was overlaid on a sucrose gradient (5-50%); separated by ultracentrifugation
at 28,000 rcf for 10 mins at 4° C. The membranes were then extracted using a 21G needle
and centrifuged at 17,200 rcf for 10 mins at 4°C. The supernatant was removed and the
membrane pellets were re-suspended to the appropriate concentration in PBS. The
membranes were then prepared for Western Blotting analysis, as previously described.
2.4 In Vitro Competition Assay Using a 96-well microtiter plate (Corning), wells were coated with 100μl (10 μg/mL) of
Poly-L-Lysine (Sigma-Aldrich) at 4°C overnight. Wells were then washed three times
with 100μl of PBST (+0.02% Tween-20). 50μl (2.5 μg/mL) His-tagged proteins (extra-
cellular-Neogenin or sRGMa or sRGMc) were then coated onto each well for 1 hr at
37°C and washed three times with 100μl PBST. Each well was then blocked with 300μl
of 3% BSA in PBST for 1 hr at 37°C. Following the blocking, 50μl (1.0 μg/mL) Alkaline
Phosphatase (AP)-tagged proteins (extracellular-Neogenin or RGMa or RGMc) in 1%
BSA + PBST were added to each well and incubated at 37°C for 1 hr. Each well was
washed thoroughly three times with 100μl PBST and equilibritated using AP developing
buffer (100mM NaHC03, 1mM MgCl2). The reaction was developed away from light
using AP developing buffer supplemented with, p-nitrophenyl phosphate (pNPP, Sigma-
Aldrich). The pNPP reaction results in a fluorometric signal once bound to the AP-tag
fused with the protein of interest. The reaction was stopped, following color development,
37
with the addition of 50μl (0.1M) NaOH. The absorbance of each reaction was measured
using a microplate autoreader (BioTek EL311 AutoReader) at 405nm wavelength.
2.5 Enzyme-Linked Immunosorbant Assay (ELISA) A quantitative sandwich ELISA was used for the detection of sRGMa and sRGMc in the
sera of mice induced with EAE. Mice were induced with EAE, as described in section
2.6.2. Sera from mice at 5, 10, 18 and 30 days post-induction of EAE were isolated by
saphenous vein bleeding. Blood was collected in Microvette® CB300 capillary tubes
(Starstedt), spun down at 2000 rcf for 10 mins and stored at -80°C (n=3 animals). ELISA
on both sRGMa and sRGMc protein levels present in the sera of mice were analyzed
using the ELISA kits for sRGMa (MRGMA0, R&D) and sRGMc (MRGMC0, R&D) as
described by the manufacturer. In brief, a standard was created using recombinant
sRGMa/sRGMc. Sera was diluted four fold using calibrator diluent RD5-18 (R&D). 50μl
of either standard, control or samples were added to capture antibody pre-coated plates
and incubated for 2 hrs at room temperature on a microplate shaker at 500 rpm. The wells
were then washed four times using 400μl of ELISA wash buffer (R&D). 100μl of mouse
RGMa or RGMc biotin-conjugated detection antibody was added to each well and
incubated for 2 hrs at room temperature on a horizontal shaker and subsequently washed
as before. 100μl of substrate solution (blue) was added in each well and incubated at
room temperature for 30 mins away from light prior to stopping color reaction with 100μl
stop solution (R&D), at which point the reaction turned yellow. The signal for each well
was recorded using a microplate reader at 450nm after which the unknowns were
interpolated from the standard curve.
38
2.6. Animal Subjects
2.6.1. Statement of Ethics
All animal experimentation was conducted in accordance with the guidelines of the
Canadian Council of Animal Care, and approved by the Toronto General and Western
Hospital animal care committee (Protocol 2988.1-3).
2.6.2. Experimental Autoimmune Encephalomyelitis Mouse Model
Six to eight week-old female C57BL/6 mice (Harlan laboratories) or 129S-Hfe2tm1Nca/J
(stock. No. 017788, Jackson Laboratories) and their wildtype control 129S1/SvImJ (stock.
No. 002448, Jackson Laboratories) were actively immunized by subcutaneous (s.c.)
injection of 50μg myelin oligodendrocyte glycoprotein (MOG) amino acids 35-55
(Sheldon Biotech, Montreal, QC) in incomplete Freund’s adjuvant (Sigma) supplemented
with 1mg of mycobacterium tuberculosis (CFA) (Difco, Detroit, MI). 400ng of pertussis
toxin (List Biologicals) was administered intraperitoneally (i.p.) on days 0 and 2 post-
immunization (Figure 2-2).
39
Figure 2-2 Generation of the experimental autoimmune encephalomyelitis (EAE) model. As seen on the timeline, an initial injection of MOG (35-55) aa, in an emulsion with CFA, is injected s.c. in the hind flank of mice. Subsequently mice are injected with an i.p. injection of pertussis toxin at day 0 and day 2-post-induction of EAE. The typical initial symptoms arise at days 10-12 following induction. This model leads to an acute ascending paralysis (tail > forelimb), which typically progresses and eventually plateau’s by day 20-22 post induction.
40
2.6.3 EAE Body Condition Score
We assessed clinical signs of EAE on the basis of the following scale: 0, no paralysis; 1,
loss of tail-tone reflex; 2, loss of righting reflex; 3, complete hind limb paralysis; 4,
forelimb weakness; 5, moribund or dead.
Intermediate scores (.5) were given for animals which did not meet the upper scale of
paralysis. A mean cumulative score was obtained from two reading per day at 12-hr
intervals.
Figure 2-3 Representation of the body condition score (BCS) index. Adapted from (172)
41
2.6.4 sRGMa and sRGMc Treatment Administration
To investigate the role of sRGMc mice were induced with EAE as described and were
treated with either: sRGMc, sRGMa, or vehicle (PBS).
In order to evaluate the role of sRGMc as a therapeutic target in EAE-induced mice,
20mM of purified sRGMC was administered either intra-venously (i.v.) at days 3, 6 and 9
or intra-peritoneally every three days for the duration of the disease.
To elucidate the physiological interaction between sRGMc and sRGMa in the EAE
model, a combination of sRGMc (20mM) in conjunction with 2 volumes of sRGMa
(40mM) was administered to mice induced with EAE using intra-peritoneal injections
every three days until time of sacrifice.
2.7 Flow Cytometry and Cytokine Staining
2.7.1 Cell Preparation
Mice were euthanized at day 10 post-induction of EAE. Freshly isolated spleens and
draining caudal lymph nodes (LN) were pressed using a syringe plunger through a 70μm
cell strainers and washed twice using 2mL of 2% FBS in complete RPMI-1640 medium
(Invitrogen) supplemented with 2-β Mercaptoethanol, L-glutamine, p/s, and non-essential
amino acids. Single-cell suspensions were lysed with 7mL of red blood cell (RBC) lysing
buffer (Life Technologies) and centrifuged at 700 rcf for 5 mins. After washing three
times with 2% RPMI-1640 medium, cells were counted and cultured as described below
or proceeding to cell surface staining.
2.7.2. Flow Cytometry and Intracellular Cytokine Staining
The expression of cell-surface markers and cytokine expression on splenocytes and LN
cells were characterized by flow cytometry. For analysis of naïve cells, 5x105 RBC
depleted splenocytes and LN cells were plated in 96-well V-bottom plates (Starstedt) and
blocked with 50μl of 1% mouse IgG in 2%FBS PBS supplemented with azide (PFN3) for
20 mins at 4°C. Cells were then stained with the following primary conjugated antibodies
for 30 mins on ice:
42
Antibody Clone Company
CD5 53-7.3 BioLegend
CD3 145-2C11 BioLegend
CD4 GK1.5 BioLegend
CD8 53-6.7 BioLegend
CD19 6D5 BioLegend
CD11b M1/70 BioLegend
CD11c N418 BioLegend
CD80 16-10A1 BioLegend
CD86 GL-1 BioLegend
CD44 IM7 BioLegend
MHC II M5/114.15.12 BioLegend
CD62L MEL-14 BioLegend
ICAM-1 (CD54) 3E2 BioLegend
IL-17A TC11-18H10.41 BioLegend
IFN-γ XMG1.2 BioLegend
All antibodies were re-suspended in PFN3. When required, cells were washed twice with
100μl of PFN3 and stained with secondary SA-APC, SA-APC-Cy7, SA-PeCy7, or SA-
Percp-Cy5.5 for 30 mins on ice. Cells were then washed twice with PFN3 and
resuspended in a PFN3 solution containing propidium iodide (PI) before proceeding to
FACS acquisitation.
For examination of intracellular cytokine production, 0.5x106 RBC depleted splenocytes
and LN cells were plated in 96-well flat bottom plates (BD Biosciences) in 10% FBS in
complete RPMI-1640 in the presence of 0.5μg/mL phorbol 12-myrisate 13-acetate
(PMA), 0.5μg/mL Ionomycin, and Golgistop (BD Biosciences) for 4 hrs. Cells were
subsequently washed in PBS and stained with Near-Infrared Live Dead (Life
Technologies) as described in the manufacturer’s protocol. Cells were then washed twice
in PFN3 and stained for cell surface markers as described previously. Cells were then
43
fixed with 100μl of Cytofix/Cytoperm solution as described in the manufacturer’s
protocol. For intracellular staning, cells were then stained with anti-IL-17A, and anti-
IFN-γ for 30 mins on ice, washed twice, and resuspended in PFN3 before proceeding to
FACS acquisition.
Nonspecific background staining was determined by using fluorochrome-matched isotype
antibodies and fluorescence minus one controls. Samples were acquired in a BD LSRII or
FACS CantoII cytometer (BD Biosciences). For each experiment, at least 100,000 live
events were acquired and analyzed using Flowjo software (Tree Star Inc.).
2.7.3 MOG-Specific Cytokine Expression and Proliferation
Mice were sacrificed on day 10 post-induction and single cells suspension of splenocytes
were harvested as described in section 2.7.1. 1x106 cells were cultured in 10% FBS
RPMI-1640 in the presence of 0μg/mL, 30μg/mL, or 100μg/mL of MOG peptide for 15
hrs. Cells were then treated with GolgiStop (BD Biosciences) and incubated an additional
3 hrs. Cells were subsequently stained as previously described.
For cytokine analysis by ELISA, 2 x 106 splenocytes were resuspended in 1mL of 10%
FBS RPMI-1640 medium and incubated in 24 well plates (BD Biosciences) in the
absence or presence of MOG (0, 30 μg/mL respectively) for 72 hours at 37°C, 5% CO2.
Plates were centrifuged at 1800rpm for 5minutes and the media was then harvested and
stored at -80C until analysis. Cytokine secretion of IL-17a, IL-6, TNF-α, and IFN-γ were
assessed using the BD cytometric Bead Array (CBA) (BD Biosciences) according to the
manufacturer guidelines.
Measuring the levels of CFSE incorporated into cellular membranes, using flow
cytometry, assessed proliferation of splenocytes. Splenocytes were harvested from mice
as described in 2.7.1 and stained with CFSE (Life Technologies) as described in the
manufacturers protocol. Briefly, 1x106 cells were re-suspended in warm PBS/0.1% BSA
and stained with CFSE solution at a final concentration of 5μM and incubated at 37°C for
10 mins. The staining was quenched using 5 volumes of ice-cold culture media and
incubated for 5 mins on ice. The cell solution was centrifuged at 700 rcf for 5 mins,
44
washed twice using culture medium, and re-suspended in 10% FBS complete RPMI-1640.
Cells were then cultured in presence of 0μg/mL or 30μg/mL of MOG (35-55) peptide for 72
hrs at 37°C, 5% CO2. Following incubation, cells were harvested, washed, and stained
with anti-CD3, -CD4, -CD5, as previously described. Proliferation was analyzed by flow
cytometry following staining in the presence of PI.
2.8 Immuno-Histochemistry Mice were induced with EAE and sacrificed two weeks following induction. Mice were
trans-cardially perfused with 20mL of PBS followed by 20mL of 4% paraformaldehyde
in PBS (PFA) (Electron Microscopy Sciences). Spinal cords were isolated and post-fixed
with 4% PFA overnight at 4◦C, washed three times with PBS and soaked in 30% sucrose
in PBS for 48 hrs. Tissues were then embedded in Optimal Cutting Temperature (OCT)
compound. Frozen sections of spinal cords were cut at 10-30μm with a cryostat, mounted
on gelatinized slides and dried for 2 hrs prior to being stored at -80°C. Sections were then
re-hydrated in PBS for 5 mins and permeabilized with PBST (0.3% Triton X-100 in PBS)
for 5 mins. The tissues were then blocked (PBS, 0.3% Triton X-100, 3% FBS) for 1 hr at
room temperature and then were incubated with primary antibodies overnight at 4°C in a
humidified chamber. The following primary antibodies were used:
45
Antibody Clone/cat no. Company
CD3 145-2C11 BioLegend
CD11b M1/70 BioLegend
B220 RA3-6B2 BioLegend
DAPI MMS-435P Sigma
Fibrinogen D9542 Innovative Research
2.9 Histological Staining A Luxol Fast Blue and Haematoxylin-Eosin (LHE) staining was carried out on EAE-
induced mice. At day 18 post-EAE induction mice were trans-cardially perfused and
30μm spinal cord cryosections were stained. The slides were washed in PBS for 3 mins,
followed by a 30 secs wash in 50% ethanol (EtOH) and an overnight incubation in Luxol
Fast Blue (LFB) at 60ºC. The sections underwent a series of washes in 95% EtOH for 5
mins and distilled water for 5 mins prior to de-staining with LiCO2 for 10 mins.
Following a 30 secs wash in 70% EtOH and a 5 mins wash in MilliQ H2O, sections were
immersed in Harris Hematoxylin (Sigma-Aldrich) for 20 mins. A 10 mins wash in warm
tap H2O was used for differentiation of the hematoxylin stain. Samples were dehydrated
in 95% EtOH and immersed in alcoholic eosin Y (Sigma-Aldrich) for 15 secs. This was
followed by dehydration in two changes of: 95% EtOH for 5 mins, 100% EtOH for 5
mins and xylene for 5 mins. Slides were mounted with Permount (Fisher Scientific) and
air-dried overnight at room temperature.
Cellular infiltration was quantified using an inflammatory index: 0, no inflammation; 1,
cellular infiltration only in the perivascular areas and meninges; 2, mild cellular
infiltration in the parenchyma (<10 cells); 3, moderate cellular infiltration in the
parenchyma (10-49 cells); 4, moderate cellular infiltration in the parenchyma (50-99
46
cells); and 5, severe cellular infiltration in parenchyma (>100 cells).
LFB staining was quantified using relative staining intensity using Image J software. All
intensities were normalized to a sham mouse spinal cord.
2.10 Blood Brain Barrier Permeability Assays
2.10.1. In Vitro BBB Permeability
b.End3-endothelial cells (ECs) were used to generate an in vitro model of the human
endothelial cell barrier lining the choroid plexus. b.end3-ECs were plated on
polyethylene-coated 0.4 µm pore size Boyden chambers (Corning) at a density of 2x105
cells per well in DMEM, and were allowed to grow for 72 hrs to reach confluency at
which point the confluency of the cells were verified using crystal violet staining. After
72hrs, cells were serum starved for 6 hrs and pre-treated for 4hr with RGMa modulators
(sRGMc 10μg/mL; C3 Transferase 10 μg/mL; Y27632 10 μM). RGMa was then added to
the wells for 18hrs. The transwells were then transferred to a new plate containing 500μl
of HBSS and 200μl 4-KDa Dextran-FITC (25mg/mL)(Sigma-Aldrich) was added to the
upper chambers. Tracer diffusion across the EC monolayer was assessed in 30 mins
intervals for a period of 1.5 hrs. The FITC signal, representing the amount of
extravasation through the monolayer, was analyzed with a microplate reader with a
485nm excitation and a 535nm emission.
2.10.2 In Vivo BBB Permeability
To establish the role of RGMc on BBB permeability, 6-8 week old C57Bl/6 female mice
(Harlan Laboratories) were induced with EAE and treated with sRGMc or vehicle, as
described in sections 2.6.2 (n=6 animals per group). Animals were subsequently
anesthetized 18 days post induction and trans-cardially perfused; spinal cords were cryo-
sectioned at 10μm thickness and stored at -80ºC. The sections were stained for:
Fibrinogen (Innovative Research); CD31 (Invitrogen); and DAPI (Sigma-Aldrich). The
area (number of pixels) and fluorescent intensity (mean pixel intensity) of the
extravasation markers were measured using CellSens (Olympus). The relative extent of
fluorescent extravasation and BBB disruption was then calculated by multiplying the area
with the fluorescent intensity.
47
2.11 Microscopy
All images were obtained using a BX61 confocal microscope (Olympus). CellSens
software was used for quantification of cell area and pixel intensity.
2.12 Statistical Analysis
Data were analyzed using GraphPad Prism software. Student’s t-tests and two-way
ANOVA were used for direct comparisons between two groups. For comparisons
between multiple groups, one-way ANOVA with Bonferroni post-hoc correction for
multiple comparisons was utilized. Significance was set at p<0.05 (*); p<0.01 (**);
p<0.001 (***). For every figure, mean and standard error of the mean (SEM) are
presented.
48
Chapter 3: Results
49
Aim I: RGMc expression is modulated in the sera of EAE-induced mice 3.1 RGMc is down regulated in the EAE model.
To determine if levels of RGMc were modulated in EAE-induced animals, 3 mice
were induced (section 2.6.2) and sera was collected from the saphenous vein at days 5, 10,
18, and 30 post induction. The collected sera was compared to the sera of 3 control mice
and analyzed for its RGMc protein content using a commercially available RGMc ELISA
kit. A striking difference was observed in levels of RGMc, which were significantly
reduced by day 5 post-induction and remained decreased for the duration of the disease
course, reaching a 4-fold decrease at 30 days post induction (**p<0.001).
In order to confirm this finding, sera from 3 mice were analyzed by western blot
at day 18 post-induction and compared to control animals. The RGMc proteins levels
were normalized to transferrin signal intensity (loading control) and can be visualized in
Figure 3-1 (*p<0.05). Thus, we demonstrate for the first time a significant relationship
between early development of EAE and reduced levels of RGMc circulating in the serum.
50
Figure 3-1 RGMc levels are decreased in EAE. A) RGMc protein expression was analyzed using an RGMc ELISA kit on sera of EAE-induced mice at days 5, 10, 18, and 30 (n=3) B) 50ug of sera from EAE-induced mice was analyzed by Western blot showing decreased RGMc levels when compared to control animals. Quantification of RGMc levels is normalized to transferrin (n=3).
51
3.2 RGMc over-expression ameliorates clinical severity of EAE-induced mice
The observation that RGMc protein levels were significantly reduced following
induction of EAE led us to further investigate its role in the EAE model. In an effort to do
so, a construct was generated expressing soluble RGMc (sRGMc) in a PsecTag2B
expression plasmid. The plasmid containing a his-tag was used to characterize the
expression of sRGMc in HEK293 stable cell lines. A coomassie stain was also carried out
to identify the purity of the protein. sRGMc has a predicted molecular weight of ~ 50KDa
in non-reducing conditions and is illustrated in Figure 3-2.
Subsequently, mice were induced with EAE and were treated with repeated intra-
venous injections of sRGMc at days 3, 6, and 9 post induction. To ensure that over-
expression of sRGMc was efficient, sera from 3 RGMc-treated mice were collected and
compared to 3 vehicle-treated mice 24 hours post-treatment using an ELISA. Mice
treated with sRGMc i.v. displayed a 3-fold increase in sRGMc levels compared to
vehicle-treated animals. The mice were then observed and scored twice daily at 12 hr
intervals for 18 days. The treatment resulted in a significant decrease in clinical severity
of the disease (Figure 3-2, B) (***p<0.001). However, RGMc-treated animals developed
clinical symptoms by day 14 post induction, suggesting a transient effect of our treatment.
To address this limitation in our treatment, sRGMc was injected intra-peritoneally
every three days for the duration of the disease. The alternate administration route of
sRGMc, as seen in Figure 3-2 B, was shown to significantly abrogate disease severity,
decrease the incidence of EAE onset (Figure 3-2 C), and delay the onset of disease
(Figure 3-2 D).
Overall, over-expression of sRGMc in EAE-induced mice is beneficial in
reducing the incidence and the severity as well as delaying the onset of disease.
52
Figure 3-2 sRGMc decreases clinical severity of EAE-induced mice. A) Expression of sRGMc was analyzed by Western blot under non-reducing conditions. The purified protein was then analyzed by coomassie staining, B) sRGMc treatment both i.v. and i.p. (20mM, injected at days 3, 6, and 9 or every 3 days for the duration of disease course; arrowheads) reduces the clinical severity of EAE-induced mice (i.v. n=10; i.p. n=15), sRGMc reduces: C) the incidence of EAE (n=15), and delays the D) day of onset of EAE (n=15). E) sRGMc treatment is stable for 24 hrs post treatment and restores sRGMC levels to control levels, as observed by ELISA (n=3).
53
3.3 RGMc is crucial both pre- and post-symptomatically.
To specifically assess the role of RGMc in the development of EAE, we obtained
mice with a selective homozygous deletion of RGMc (129S-Hfe2tm1Nca/J). These mice
recapitulate symptoms of JH, with early onset iron overload as well as low hepcidin
levels. Female mice aged between 6-9 weeks were induced as described in section 2.6.2.
Deletion of RGMc was associated with a trend towards an increase in disease severity as
well as percentage of incidence (Figure 3-3). Thus, we provide evidence that genetic
neutralization of RGMc may result in an exacerbated disease phenotype marked by an
increased paralysis and a higher incidence of the disease.
54
Figure 3-3 RGMc KO show a possible susceptibility to EAE. A) Selective deletion of RGMc in EAE-induced mice results in an exacerbated clinical severity when compared to wild-type controls (n=10). No significant difference in B) the day of onset of EAE was observed in RGMc knockout animals when compared to their control (n=10), C) EAE incidence is observed in RGMc knockout animals when compared to their control (n=10).
55
Aim II: A relationship exists between RGMa and RGMc 3.4 sRGMa is up-regulated in our EAE model and is crucial in the development of the disease Nascent studies have demonstrated that ensuing the onset of EAE; membrane-
bound RGMa is up regulated on the surface of immune cells, which increased their
activation and subsequent extravasation to the CNS (140, 142). Recently, RGMa was
shown to undergo complex post-translational processing resulting in many biologically
active soluble fragments (114). Thus, we set out to analyze the levels of RGMa in the
sera of mice induced with EAE at days 5, 10, 18 and 30-post induction. Figure 3-4 A
shows the expression levels of soluble RGMa present in EAE induced-mice. We observe
a dramatic increase (5-fold) in levels of RGMa in the sera which maintains elevated for
the duration of the disease (**p<0.001). Thus, both sRGMa and sRGMc co-exist in the
sera and possess contrasting expression levels in EAE-induced mice.
To further analyze the role of sRGMc and sRGMa physiologically, we tested
whether the interaction of these proteins in the sera were crucial in the development of
EAE. Thus, mice were induced with EAE and treated with either: 1) sRGMc, 2) sRGMc
in conjunction with sRGMa, or 3) vehicle. A striking observation was made, whereby the
reduced clinical severity in sRGMc-treated mice was abolished when supplemented with
sRGMa (**p<0.001).
The observation that both proteins share contrasting expression levels during EAE,
and that they both share the same receptor to mediate their signaling (119, 156), led us to
investigate the possibility for these proteins to interfere with each others’ signaling.
Constructs over-expressing sRGMa, sRGMc and the extracellular domains of Neogenin
(Ec-Neogenin) were generated in a PsecTag2B vector. To evaluate the competition
between sRGMc and sRGMa, an in vitro competition assay was used. Briefly, sRGMc
was coated on a microtiter plate and blocked. Ec-Neogenin-AP tagged was co-incubated
with sRGMa or BSA and added to the RGMc-coated wells. Following several washes,
the wells were developed using AP developing buffer.
56
Figure 3-4 C demonstrates that pre-incubation of sRGMa with Ec-Neogenin-AP
resulted in a 3-fold reduction binding intensity of RGMc to Neogenin when compared to
BSA control. The reversal experiment showed a similar abrogation of binding intensity to
Neogenin. Overall, we show that sRGMa is able to interfere with sRGMc by interacting
on non-overlapping binding sites in Neogenin and vice-versa.
Here, we show for the first time that two molecules from the same protein family
are able to compete and regulate each other’s binding to their receptor. Furthermore, we
show that sRGMa is critical in the development of EAE.
57
Figure 3-4 sRGMa is up regulated in EAE and interferes with sRGMc for binding to Neogenin. A) sRGMa expression is increased in the sera of mice induced with EAE at days 5, 10, 18, and 30, as analyzed using an RGMa ELISA kit (n=3), B) The graph shows EAE scores of 6 week-old EAE-induced mice treated every three days with sRGMc (20mM), vehicle, or sRGMc (20mM) in conjunction with sRGMa (40mM)(n=10), C) Bar graph on the left shows: sRGMa-AP or sRGMc-AP were incubated on plates coated with Neogenin, Neogenin + sRGMa, or Neogenin + sRGMc to assess binding competition between sRGMa and sRGMc proteins to Neogenin (n=3, performed in triplicates). The reversal experiment was carried out and is shown in the bar graph on the right hand side.
58
Aim III: RGMc modulates the molecular activation of the adaptive immune system 3.5 RGMc treatment does not affect T-cell priming and activation i) sRGMc Has No impact on Naïve Immune Cells
Recent reports show that the RGMa-Neogenin signaling pathway is able to
modulate T cell priming and promote their activation by up-regulating small GTPases
such as Rap1. Activation of Rap1 increases the adhesion profile of T cells as well as their
infiltration within the CNS (142). The analysis that sRGMc was able to interefere with
the interaction between sRGMa and Neogenin in vitro prompted us to investigate its role
in modulating the immune system.
In order to assess whether sRGMc could affect the priming of immune cells, both
the distribution and activation of naïve immune cells of EAE-induced mice was analyzed.
Splenocytes from day 10 RGMc-treated mice were analyzed by flow cytometry and
compared to the vehicle-treated group. As portrayed in Figure 3-5 and 3-6, RGMc
treatment does not modulate the distribution of effector cells, as seen by the CD3+, CD8+,
and CD4+ T cells. Moreover, both the distributions and activation of dendritic cells
(CD11c+), and B cells (MHC II, CD80+/CD86+) were unaltered.
59
Figure 3-5 sRGMc has no effect on naïve immune cell populations. Mice induced with EAE were sacrificed 10 days post induction and splenocytes were harvested and stained as described. No difference was observed in the percentage of B cells, T cells, or MHC II on B cells in RGMc-treated versus vehicle-treated animals (n=15).
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Figure 3-6 sRGMc treatment has no effect on naïve antigen-presenting cells. Mice induced with EAE were sacrificed 10 days post induction and splenocytes were analyzed for the percentage of A) CD11c (dendritic cell), B) CD11b (myeloid cell). sRGMc does not impact the activation of B cells, as seen using co-activation markers C) CD80 on B cells, D) CD86 on B cells. (n=15).
The infiltration of leukocytes into the CNS is a key stage in the acute phase of
EAE. As a result, we wondered whether sRGMc could modulate the ability of T cells to
migrate into the CNS. To migrate into the parenchyma, immune cells must overexpress a
variety of cellular adhesion proteins. Thus, both naive splenocytes and lymph node cells
were analyzed for their expression of adhesion markers, namely ICAM-1 and CD62L. As
depicted in Figure 3-7, sRGMc does not modify the expression of adhesion markers on
the surface of CD4+ and CD8+ T cells as well as B cells.
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Figure 3-7 sRGMc treatment has no effect on the adhesion protperties of naïve T and B cells. Mice induced with EAE were sacrificed at 10 days post induction and splenocytes were analyzed for their A) levels of ICAM-1 expression on B cell, B) ICAM-1 expression on CD8+ T cells, C) ICAM-1 and CD62L expressino in CD4+T cells. (n=15).
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ii) sRGMc Treatment Does Not Modulate Activated Immune Cells Muramatsu and colleagues (2011) demonstrated that the expression of RGMa, on
the surface of bone marrow-derived dendritic cells, could prime and activate CD4+ T
cells through its interaction with Neogenin. Treatment with a polyclonal RGMa-antibody
could diminish this activation, as seen by a reduced secretion of IL-17 and IFN-γ (142).
Previously, we showed that sRGMc can also interfere with RGMa for its binding to
Neogenin. Consequently, we explored whether sRGMc treatment was able to modulate
the activation profile of immune cells. Mice were induced with EAE and treated with
sRGMc or vehicle. Splenocytes and draining lymph node cells were harvested and
stimulated with PMA and ionomycin and stained for IL-17 and IFN-γ. However, sRGMc
was unable to modulate the expression profile of IL-17 and IFN-γ secreted by CD4+ T
cells (Figure 3-8). In our EAE model, CD4+ T cells are specifically primed towards MOG (35-55)
peptide. Since the activation profile of immune cells is dependent on their antigen
recognition, we tested whether presenting sRGMc-treated immune cells with MOG (35-55)
peptide would modulate the activation potential splenocytes when compared to controls.
We immunized C57/BL6 mice with MOG(35-55), followed by treatment with either
sRGMc or vehicle and harvested splenocytes 10 days post induction. Splenocytes were
then re-stimulated with MOG(35-55) peptide for 18 hrs and analyzed their cytokine profile.
Again, no apparent effect was seen in RGMc-treated mice when compared to control
mice (Figure 3-9). These findings were confirmed using an ELISA on media collected
from splenocytes pulsed with MOG(35-55) for 3 days (Appendix A).
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Figure 3-8 sRGMc has no effect on activated immune cells. Mice were induced with EAE and sacrific ed 10 days post induction. A) splenocytes were harvested and stimulated using PMA and Ionomycin and analyzed for the expression of activated CD4+T cells secreting IL-17A or IFN-γ. (n=15). B) Draining lymph nodes (caudal, sciatic, lumbar) cells were also analyzed as described (n=15).
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Figure 3-9 sRGMc has no effect on antigen-specific immune cells. Mice were induced with EAE and splenocytes were harvested 10 days post induction A) CD4+T cell proliferation was measured using CFSE incorportion in splenocytes treated with 0 or 30ug/mL of MOG(35-55), B) Levels of IL-17 and IFN-γ in splenocytes pulsed with 0, 30, or 100μg/mL MOG(35-55) were analyzed. (n=15).
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3.6 RGMc affects the infiltration of leukocytes in the CNS
EAE is characterized by broad infiltration of immune cells within the CNS
followed by de-myelination, both of which contribute to the clinical severity of the
disease (80). We therefore explored whether sRGMc treatment was able to modulate the
extent of leukocyte present within the CNS of EAE-induced mice. Cervical spinal cord
sections were stained histologically using hemotoxylin and Eosin in combination with
luxol fast blue. Figure 3-5 depicts the spinal cord histology of both vehicle- or sRGMc-
treated animals. Strikingly, both the extent of cellular infiltrates and de-myelination of
sRGMc-treated animals were significantly reduced when compared to vehicle-treated
animals (**p<0.001). In addition to infiltrating within the spinal cord, immune cells have
been shown to infiltrate extensively in both the brain and the optic nerve of EAE-induced
mice. Moreover, in early phases of MS, patients present with inflammation of the optic
nerve, known as optic neuritis (173). We show preliminary data that treatment with
sRGMc reduced the extent of leukocyte infiltration in the retina of EAE-induced mice
(Appendix B).
To further typify the profile of cellular infiltrates within the spinal cord of EAE-
induced mice, spinal cords were stained for: 1) CD3: a pan T cell marker, B220: a pan B
cell marker, and CD11b: a pan myeloid cell marker. In order to analyze the extravasation
pattern of each cell type within the spinal cord of EAE-induced mice, spinal cords were
divided into 7 patterns of infiltration (Appendices C, D, and E). Figure 3-6 shows
representative images for the infiltration of CD3+, B220+, and Cd11b+ cell. As a whole,
RGMc-treated animals possessed a significantly decreased amount of cellular infiltrates
across all markers.
These data reflect that sRGMc treatment can reduce the extent of leukocyte
infiltration present within CNS of EAE-induced mice, correlated with a reduction of
CD3+, CD11b+, and B220+ cells present in the spinal cords. Furthermore, sRGMc
treatment is associated with a preserved myelination profile in contrast to vehicle-treated
animals.
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Figure 3-10 sRGMc treatment reduces the number of cellular infiltrates and the extent of de-myelination in EAE-induced mice. Mice induced with EAE were trans-cardially perfused 18 days post induction and stained with H&E in combination with Luxol fast blue. A) sRGMc-treated mice show less de-myelinating foci in cervical spinal cord sections of EAE-induced mice. sRGMc-treated mice possess: B) a greater mean pixel intensity of Luxol fast blue staining compared to vehicle-treated animals (normalized to a sham animal), and a C) decreased inflammatory index (n=6 per group).
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Figure 3-11 sRGMc reduces the amount of immune infiltrates in the spinal cord of EAE-induced mice. Day 18 EAE-induced mice treated with either sRGMc or vehicle were trans-cardially perfused with 1X PBS and 4% PFA in 1X PBS. A) Representative images of EAE-induced mice cervical spinal cords were cryo-sectioned and subsequently stained using CD3, CD11b, or B220 surface markers. B) A quantitative analysis of CD3+, CD11b+ and B220+ cells in 7 regions of the spinal cord sections (shown in Appendix C-E)(n=6 per group).
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3.7 sRGMc decreases BBB EC permeability RGMa signaling is dependent on its interaction with Neogenin by activating
downstream cytoskeletal remodeling proteins, such as RhoA (174). Of interest, RhoA
signaling has extensively been shown to modulate the integrity of the blood-brain EC
barrier (175). The BBB synchronizes the homeostasis of the CNS, regulating the passage
of leukocytes into the parenchyma. Moreover, BBB disruption is a key marker of both
EAE and MS, which leads to the subsequent infiltration of immune cells within the CNS
(102). Based on our previous observations, we speculated whether sRGMc could
interfere with sRGMa to restore BBB integrity. To test this exciting theory, a murine
brain-derived cell line (b.end3) was obtained to replicate an in vitro model of the blood-
brain EC barrier. Using both immunohistochemistry and western blot analysis of b.end3
cells, we show that Neogenin is strongly expressed on the surface of these cells, as shown
in Figure 3-12.
We next assessed the role of sRGMa on BBB permeability using a 4-KDa
Dextran conjugated to a FITC fluorochrome (Dextran-FITC). b.end3 cells were allowed
to form a monolayer on Boyden chambers (Figure 3-12 C) and were subsequently treated
with sRGMa , sRGMa blocking peptides for 4 hrs. Extravasation of Dextran-FITC was
assessed every 30 mins for a period of one hour and half. Treatment of sRGMa increased
the extravasation of Dextran-FITC when compared to vehicle-treated wells. Treatment
with either C3 Transferase (Rho inhibitor) or Y27632 (Rho Kinase inhibitor) reduced the
extravasation of Dextran-FITC (Figure 3-12). Because sRGMc reproduced the
RhoA/RhoK inhibitor effect, we conclude that sRGMc diminishes the RGMa-mediated
blood-brain EC barrier permeability, thus preventing infiltration of leukocytes in the CNS.
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Figure 3-12 sRGMc decreases BBB EC permeability by interfering with RGMa-mediated Rho activation. A) Neogenin expression was analyzed on the membrane of b.end3 cells using immunohistochemistical staining and by Western blot. Shown are changes in b.end3 cell permeability (B) crysal violet staining shows the b.end3 cell monolayer, C) a representative diagram of the boyden chamber set up, D) b.end3 cells were serum-starved for 6 hours followed by a 4hr pre-treatment of sRGMa modulators: C3 Transferase (10μg/mL) or Y27632 (10μM) or sRGMc (10μg/mL). Cells were finally treated with sRGMa (5μg/mL) for 18hours at which point a 4-KDa Dextran-FITC was seeded into the upper chamber and the extravasation was measured over a period of 60 minutes (n=3, performed in triplicates).
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To further confirm the role of sRGMc in maintaining blood-brain EC barrier
integrity, we tested these findings in vivo. First, we examined whether Neogenin was
expressed in endothelial cells lining the BBB of mice. A sham mouse spinal cord was
stained with: anti-CD31 to localize the presence of endothelial cells, DAPI to localize the
nuclei of cell, as well as Neogenin. As shown in Figure 3-13, Neogenin is widely
expressed in the spinal cord and co-localizes with CD31 staining. Thus, Neogenin is
expressed on the surface of endothelial cells in the mouse spinal cord.
We next went on to ask whether sRGMc treatment had an effect on the integrity
of the BBB following the induction of EAE. To this purpose, mice were induced with
EAE and trans-cardially perfused 18 days post induction. The spinal cords of RGMc-
treated and vehicle-treated mice were stained with three markers: 1) Fibrinogen: a small
plasma protein unable to cross the BBB under normal conditions 2) CD31 and 3) DAPI.
Figure 3-14 demonstrates the extent of extravasation of endogenous fibrinogen observed
in EAE-induced animals treated with vehicle. In sharp contrast, animals treated with
sRGMc showed a significant decrease in fibrinogen extravasation, indicative of a
preserved BBB integrity. The degree of extravasation was quantified by measuring the
relative pixel intensity of fibrinogen in EAE-induced animals normalized to a sham
animal (*p<0.05).
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Figure 3-13 Neogenin is expressed in endothelial cells in the mouse spinal cord. (A) Immunohistochemical staining for Neogenin expression was carried out in cervical spinal cord sections of naïve mice. Neogenin (red) is shown to strongly co-localize with endothelial cells as seen with CD31 staining (green).
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Figure 3-14 sRGMc reduces BBB permeability. (A) Immunohistochemical staining of cervical spinal cords of 18 days EAE-induced mice treated every 3 days with sRGMc or vehicle. The extent of Fibrinogen extravasation (red, arrowheads) accumulates around blood vessels (CD31, green, asterisks). Nuclei were stained using DAPI (blue). sRGMc-treated animals show a reduced extravasation of Fibrinogen when compared to vehicle-treated animals. Scale bars, 50μm. B) A quantitative analysis of perivascular extravasation of Fibrinogen by relative pixel intensity in sRGMc-treated and vehicle-treated animals (n=6).
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Chapter 4: Discussion
Emerging studies have demonstrated the role of RGMa in the development of MS
(169). Furthermore, its interaction with Neogenin was shown to increase the adhesion of
infiltrating leukocytes in the CNS of EAE mice (142). In this study we show for the first
time that sRGMa present in the serum is up regulated following the induction of EAE and
is able to increase the blood-brain EC barrier permeability, thereby increasing the
infiltration of leukocytes within the CNS. The third member of the RGM family, RGMc,
undergoes post-translational processing to generate soluble fragments present in the
serum. Our study identifies a previously uncharacterized function for the iron regulatory
protein RGMc, whereby its expression in the sera of EAE-induced mice is significantly
down regulated. Over-expression of sRGMc reduced the clinical severity in EAE-induced
mice. RGMc knockout animals develop a worse disease progression that their wild-type
control. Moreover, sRGMc treatment both diminished the extent of blood-borne proteins
and the amount of leukocytes extravasating in the CNS. Lastly, we show this effect is
mediated through the competition of these proteins for their receptor Neogenin on the
endothelium of the BBB. Together, our data supports an entirely novel molecular
mechanism between two members of the RGM family and their regulation in the
development of EAE.
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4.1 Soluble RGMa and RGMc are Differentially Regulated in EAE. Our findings show that following the induction of EAE, both RGMa and RGMc
levels are modulated prior to the onset of symptoms. In particular, sRGMc levels are
significantly reduced in the sera of EAE mice. We believe reduced sRGMc levels are
strongly associated with disease progression, as exogenous expression of sRGMc in these
EAE mice reverts the clinical severity. In agreement with this observation is the finding
that the axon guidance molecule Netrin-1 expression is significantly down regulated
during acute pulmonary inflammation and co-incides with the extensive influx of
leukocytes at the site of injury (176).
A complex physiological interplay exists between sRGMa and sRGMc. In support
of this argument is the finding that alleviation of EAE paralysis observed in sRGMc-
treated mice is completely abolished when co-injected with sRGMa. This interesting
observation pointed us to further analyze the relationship between these two molecules.
Using an in vitro competition assay we identified a novel molecular interplay between
these molecules whereby both proteins compete for the same receptor, Neogenin. From
the literature, we know that the binding site of RGMa (FNIII (3-4)) differs from that of
RGMc on Neogenin (FNIII (5-6)). Thus, we believe these molecules must regulate each
other’s binding through either negative allosteric modulation or by steric hindrance on
Neogenin. Interestingly, another axon guidance molecule was shown to replicate this
same effect. Recently, the axon guidance molecule Netrin-1 was also shown to bind the
RGM receptor Neogenin (117). The precise binding site of Netrin-1 was mapped on the
Neogenin FNIII (4-5) domains. Prior studies had identified that pre-incubation of PC12
neurites with Netrin-1 reduced the repulsive phenotype observed by RGMa (174, 177).
Hence, Netrin-1 is able to functionally inhibit RGMa-mediated axonal inhibition. It
remains unclear whether Netrin-1 mediates its effect by directly interfering with RGMa
binding to Neogenin or whether it can indirectly activate downstream positive signaling
(cdc42) and counteracting negative axonal cue (RhoA). Of importance, the binding
affinity of Netrin-1 toward Neogenin was found to be much lower than that of RGMa to
Neogenin (119). Thus, the binding affinity of both sRGMa and sRGMc on Neogenin
must be studied in order to better understand their binding profiles.
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4.2 sRGMc and the immune system
Cell migration is crucial for immune cells to attain their desired location. Thus,
the appropriate ligands must be secreted in order for these cells to target to the
appropriate sites. As with every system, the immune system must possess inhibitory cues
to prevent the migration of cells into inappropriate areas. Recently, the role of axon
guidance molecules in immune regulation have been outlined. The guidance cues
function very similarly to chemokine cues by re-modeling the actin cytoskeleton of
extending neurites. Thus it comes as no surprise that axon guidance molecules have
emerged as potential regulators of leukocyte migration. One particular axon guidance
molecule, the Slit family of secreted glycoproteins has been found to modulate the
immune cells. These studies along with a growing body of literature began to link the role
of axon guidance molecules with the immune system (176, 178, 179).
The Slit molecules consist of three isoforms (1-3), which bind to an
immunoglobulin receptor Roundabout (Robo). There are four Robo receptors (1-4) Robo-
1 is highly expressed on the surface of immune cells whereas Robo-4 is expressed on the
surface of endothelial cells (180). Upon binding to Robo-1, Slit-2 is able to activate
secondary messenger small guanosine trinucleotide phosphatase (GTPase), which can
further activate cytoskeletal remodeling proteins such as cdc42, Rac1, and RhoA (181).
Slit2 could inhibit lymphocyte and neutrophil trans-endothelial migration both in vitro
and in vivo (182-184). In contrast to these findings, our study failed to show an immune
regulatory effect of sRGMc treatment in EAE-induced animals.
Although sRGMc showed poor effect on immune cell activation and priming, it
remains to be investigated whether sRGMc can modulate the expression of chemokine
ligands expressed on the surface of endothelial cells and whether sRGMc can modulate
the expression of chemokine receptors expressed by infiltrating leukocytes.
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4.2 sRGMc Increases Blood-Brain EC Barrier Stability Axon Guidance Molecules and the Blood-Brain Barrier
Our data provide evidence for the first time of sRGMc in reducing BBB
permeability, as shown by a decrease in endogenous fibrinogen extravasation in EAE
mice. Recent studies in agreement with our observations have eluted to the role of the
axonal guidance molecule Netrin-1 in BBB permeability. Wen and colleagues (2014)
showed that over-expression of Netrin-1, using gene transfer in a mouse model of
traumatic brain injury led to a decrease in Evans Blue extravasation within the CNS (185,
186). Moreover, the group identified an increase in TJ levels in Netrin-1 treated animals.
However, the molecular mechanism for this phenotype has not yet been established.
In addition to mediating inhibitory chemotactic stimuli, the Slit-Robo family was
also shown to mediate endothelial cell integrity. For instance, by binding Robo-4 on the
surface of endothelial cells, Slit-2 is able to prevent BBB leakage associated with viral
sepsis (187, 188). It did so by down-regulating the expression of endothelial cell adhesion
molecules following inflammation and reduced the extent of both neutrophilic and
monocytic infiltrates (184, 189).
The Small GTPase Rho and the Blood-Brain Barrier
Here, we propose a model wherein sRGMa can increase BBB permeability by
activating the small GTPase RhoA. This small GTPase family is comprised of RhoA,
Rac1, and CDC42, provide a link between membrane receptors and cytoskeletal
remodeling via actin assembly and disassembly. Indeed, the repulsive function of RGMa
on projecting growth cones is mediated by the downstream activation of RhoA (139). In
addition, numerous axon guidance molecules have been shown to activate the Rho
signaling pathway to mediate their guidance cues (190). The direct downstream effector
of RhoA is Rho kinase (ROCK), which is a serine/threonine protein kinase.
77
An extensive body of research supports the role RhoA in BBB permeability (174,
191, 192). RhoA has been shown to modulate the expression of TJ on the surface of ECs
(175). TJ are localized at cell-cell sites on ECs of the BBB and serve as a para-cellular
barrier for the BBB. The molecular components of the TJ are comprised of two classes of
peripheral membrane proteins: the Claudins, and the Occludins. These proteins are
embedded to the actin cytoskeleton of the ECs by accessory Zonula-Occludens proteins
(Zo-1, and -2) (108). Together these proteins maintain the structural integrity of the BBB.
The expression pattern of both Claudin-5 as well as Occludin was shown to be mainly
restricted to the CNS, making these TJ proteins significantly interesting to study (193,
194).
TJ regulation is dynamically regulated by actin cytoskeletal re-arrangement.
Studies have shown that migration of leukocytes into the CNS is mediated through
monocyte-ECs contact resulted in RhoA activation and the subsequent claudin-
5/Occludin phosphorylation (175). Inhibition of both RhoA as well as ROCK ameliorates
BBB integrity, as shown by up regulation of TJ, decrease in monocytic infiltrates (by
90%), and decreased phosphorylation of claudin-5/Occludin (195). Phosphorylation of
Claudin-5/Occludin leads to the translocation of these proteins from the membrane of
ECs and results in loss of intercellular contacts (196, 197). Furthermore, activation of
RhoA in cells results in morphological retraction of brain-derived endothelial cells (198).
The phosphorylation site on these TJ proteins is crucial for their binding to accessory
proteins, such as the ZO (199).
Cross-talk Between the Sonic Hedgehog and Neogenin pathways in Blood-Brain Barrier Permeability The BBB is a multicellular vascular structure where the astrocyte-endothelial cell
integration is known to regulate the BBB permeability. Astrocytes can produce factors
which can modulate the ECs lining the BBB (99). One of these released factors is the
Sonic Hedgehog (sHh). Alvarez et al. showed that astrocyte can secrete sHh and
modulate BBB integrity through its binding to the Smoothened (Smo) and Patched-1
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(ptch-1) receptors expressed on the surface of ECs. Moreover, activation of Smo can
increase the activation of downstream transcription factor Gli-1, also expressed in ECs. In
this study, stimulation of the sHh pathway from astrocytes led to an up regulation of TJs
within ECs promoting integrity of the BBB. Furthermore, blocking this pathway
generated a widespread permeability phenotype with extensive blood-borne protein
leakage within the CNS as well as an increased clinical severity of EAE (110).
Recent reports have shown that the morphogen sHh, can regulate the expression
of Neogenin in both mice and humans (200, 201). During limb development, Neogenin
has been shown to act as a negative regulator to the sHh pathway (202). Hong and
colleagues suggest that Neogenin could serve in parallel to ptch-1 by negatively
regulating sHh function. Thus, a possible mechanism in which sHh-mediated BBB
integrity can be inhibited by RGMa signaling through Neogenin would be interesting to
investigate.
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4.3 Working model The findings portrayed in this document along with the literature extend a
working model through which Neogenin can mediate BBB integrity. We believe
Neogenin is a crucial receptor in the regulation of BBB permeability through various
ways:
1. Muramatsu and colleagues have identified the role of membrane-bound RGMa in
bone marrow-derived dendritic cells in priming CD4+ T cells. This model
describes that interaction between RGMa and Neogenin activates a downstream
GTPase Rap1. Upon activation, Rap1 can mediate the expression of Leukocyte
function-associated antigen-1 (LFA-1) which promotes leukocyte migration
within the CNS (142).
2. Our findings uncover a novel role of Neogenin in BBB integrity, whereby soluble
RGMa can interact with Neogenin to activate downstream secondary messenger
RhoA. This activation leads to the phosphorylation of TJs (Claudin-5 and
Occludin) mediated by Rho Kinase. Upon phosphorylation, TJs are unable to bind
the Zonula-Occludens and translocate away from the paracellular membrane of
endothelial cells. This results in gap formation in the endothelium of the BBB and
the subsequent infiltration of leukocytes.
3. A third mechanism may also be at play. In this mechanism, parallel activation of
Neogenin by sRGMa can inhibit the activation of Gli-1 and reduce the expression
of TJs in ECs. This reduced expression of TJs creates gaps in the endothelium and
leads to the subsequent infiltration of leukocytes within the CNS.
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Figure 4-1 Neogenin and the Blood-Brain Barrier. Our working model whereby Neogenin modulates the integrity of the BBB in various ways: 1) Interaction between RGMa on dendritic cells and Neogenin on the surface of CD4+ T cells increases Rap1 activation and LFA-1 expression. This increased LFA-1 expression increases the adhesion profile of circulating CD4+ T cells on the endothelium of the BBB, enhancing their ability to transmigrate into the CNS. 2) The interaction between sRGMa and Neogenin expressed on the endothelium of the BBB increases the activation of secondary messenger RhoA. This increased RhoA activation leads to the phosphorylation of TJ by RhoK and the subsequent translocation of TJ away from the paracellular sites creating gaps into which circulating leukocytes can migrate though. 3) Neogenin acts in parallel to Ptch-1 by inhibiting Smo activity. This Smo inhibition reduces the Gli-1 mediated expression of TJ, reducing the integrity of the BBB.
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4.4 Future Directions
In light of our recent studies, we support a model through which increasing levels of
sRGMa present in the serum in EAE leads to the de-stabilization of the BBB endothelium,
accentuating the infiltration of leukocytes within the CNS. To further strengthen this
theory, the following experiment must be addressed.
How does RGMa mediate BBB permeabilization? Whilst our studies have begun to elucidate the molecular mechanism mediating BBB
permeability, further experiments must be done to identify the direct interplay between
sRGMa and RhoA-mediated TJ phosphorylation. Thus, it would be crucial to carry out an
activation assay of the downstream effector RhoA in b.end3 cells treated with sRGMa, or
sRGMa antagonists (C3-transferase, Y27632, sRGMc). Furthermore, activation of
Neogenin through sRGMa should result in an increased expression of phosphorylated
Claudin-5 and Occludin-1.
What is the role of sRGMc on Iron in EAE? In both EAE and MS, higher levels of iron are observed than in aged-matched controls
(39). Furthermore, polymorphisms associated with iron regulatory pathways such as
HEPC have been associated with an increased risk for MS (37). In addition, the
understanding behind the accumulation of iron in both EAE and MS are poorly
understood. In this study, our focus remained on the competition between sRGMc with
sRGMa. However, RGMc plays a critical role in the regulation of iron upstream of
hepcidin (165). The first crucial experiment will be to identify where is the source of
soluble RGMc affecting the BBB. In an attempt to address this question we have
obtained liver specific RGMc conditional knockout animals (albumin-cre promoter)(162).
Using this exciting approach we will test whether liver-specific RGMc knockout renders
animals more susceptible to EAE. We further propose the following, wherein the tight
regulation observed in our findings between both RGMa and RGMc provide the
physiological model for the interplay between iron regulation and immune quiescence
present in MS. The up regulation of RGMa results in the aberrant immune responses
leading to autoimmunity whereas the reduced RGMc levels may be the cause of the iron
82
overload observed in MS. Additionally, the iron overload observed in MS has been
linked to the generation of reactive oxygen and nitrogen species (43). Therefore, our
treatment may provide a neuro-protective mechanism by regulating iron levels and
diminishing oxidative burst.
Does the interplay between sHh and Neogenin play a crucial role in the development of EAE? The astrocyte-endothelial cell interaction was recently shown to mediate BBB integrity
by secreting sonic Hedghehog and activating downstream Gli-1 transcription factor. The
activation of this transcription factor was shown to increase the expression of tight
junctions towards paracellular endothelial membranes (110). Of particular interest to our
study, recent studies identified Neogenin as a negative regulator of sHh signaling during
limb development (202). In their study, Hong et al showed that Neogenin could act in
parallel to patched-1 and inhibit the activation of Gli-1. In MS, BBB occurs early in the
disease. We propose the following model, in early stages of MS, increase in sRGMa
levels within the CNS can activate Neogenin present on the surface of endothelial cells.
This Neogenin activation could inhibit the sHh-mediated expression of tight junctions
and decrease the expression of TJs on ECs leading to the extensive influx of leukocytes
within the CNS.
83
Chapter 5: Conclusion Our work is the first to identify the role of RGMc in the development of EAE.
Our initial observation that soluble RGM fragments possess contrasting expression
patterns during the course of EAE provided us with enough information to investigate the
role of exogenous sRGMc in the development of EAE. sRGMc-treated animals
developed a delayed onset, a decreased percentage of incidence, and a diminished clinical
severity of the disease course. Moreover, RGMc knockout animals developed a more
severe disease progression than wild-type animals. Our in vitro competition assay
uncovered a molecular mechanism whereby sRGMc was shown to compete with sRGMa
for the binding to Neogenin. We were able to confirm this observation in vivo by treating
RGMC-treated animals in conjunction with sRGMa and observing a worsening disease
phenotype. Our findings, along with previous studies on EAE prompted us to investigate
a role for RGMc in the infiltration of leukocytes within the CNS. We further went to
characterize that RGMc strengthened the integrity of the BBB in EAE.
Prior to our studies the role of RGMc was exclusively believed to regulate iron
expression. Our findings provide evidence for the role of this protein in mediating RGMa
signaling. The finding that sRGMc is able to protect and stabilize the BBB may provide
wider implications than MS as several disorders exhibit a breach of the BBB, such as
stroke (203). We hope that this exciting discovery will propel the RGMc field forward
and place this crucial molecule in the foresight for EAE research and for the development
of MS therapeutics.
84
Chapter 6: Appendix
85
A
Figure 6-1 sRGMc treatment does not modulate the cytokine secretion of MOG pulsed splenocytes. Day 10 EAE-induced mice were sacrificed and their splenocytes were pulsed with MOG for 96 hrs. The cytokine secretion was analyzed using an ELISA.
IL17
RGM
c
Vehicl
e0
500
1000
1500
2000
con
cen
tra
tion
(pg
/mL
)
TNF-α
RGM
c
Vehicl
e0
50
100
150
200
250
con
cen
tra
tion
(pg
/mL
)
IFN-γ
RGM
c
Vehicl
e0
1000
2000
3000
4000
con
cen
tratio
n (p
g/m
L)
IL-6 - Day 17
RGM
c
Vehicl
e0
100
200
300
400
con
cen
tra
tion
(pg
/mL
)
86
B
Figure 6-2 sRGMc treatment reduces cellular infiltrates in the retinas of EAE-induced animals. Representative confocal images of EAE-induced mice retinal whole-mounts stained with cholera toxin
87
subunit-β. RGMc treatment (200mM, injected every 3 days for 18 days) reduces the extent of cellular infiltration (arrowheads) when compared to vehicle-treated animals.
C
Figure 6-3 sRGMc treatment reduces CD3+ infiltrates in the spinal cord of EAE-induced mice. Spinal cords were stained for CD3+ cells and subdivided into 7 patterns of infiltration.
88
D
89
Figure 6-4 sRGMc treatment reduces B220+ infiltrates in the spinal cord of EAE-induced mice. Spinal cords were stained for B220+ cells and subdivided into 7 patterns of infiltration.
E
90
Figure 6-5 sRGMc treatment reduces CD11b+ infiltrates in the spinal cord of EAE-induced mice. Spinal cords were stained for CD11b+ cells and subdivided into 7 patterns of infiltration.
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