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UNIVERSITY OF CALGARY

The role of pannexin1 channels in seizure activity in vivo and in vitro

by

Jordan Robinson

A THESIS

SUBMITTED TO THE FACULTY OF GRADUATE STUDIES

IN PARTIAL FULFILMENT OF THE REQUIREMENTS FOR THE

DEGREE OF MASTER OF SCIENCE

DEPARTMENT OF NEUROSCIENCE

CALGARY, ALBERTA

APRIL 2012

©Jordan Robinson, 2012

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ABSTRACT

Pannexin1 (Panx1) is a large-pore channel present in the post-synaptic site that has been

implicated in an in vitro model of seizure-like burst firing. However, the precise contribution of

Panx1 to seizure activity remains controversial, with many inconsistent findings. Furthermore,

the contribution of Panx1 to the development of ictogenic nervous tissue (‘epileptogenesis’) has

not been investigated. The present experiments pursue three lines of research in an attempt to

further characterize the role of Panx1 in seizure and epileptogenesis.

The contributions of Panx1 to susceptibility to seizure, seizure severity and seizure

duration were studied in vivo using both the pilocarpine model of seizure and status epilepticus,

and the electrical kindling model of seizure and epileptogenesis. Further, the effect of Panx1

block on the process of epileptogenesis itself in the electrical kindling model was examined.

Finally, the role of Panx1 in local excitability and short-term potentiation following

epileptogenesis were studied using acute hippocampal slices obtained from kindled and sham

kindled rats.

A single early central infusion of Panx1 blocker was sufficient to chronically attenuate

epileptogenesis. Furthermore, Panx1 block acutely decreased seizure severity and afterdischarge

threshold in fully kindled animals in the electrical kindling model. Panx1 block was also found

to acutely decrease seizure severity and increase seizure latency, but not seizure duration in the

pilocarpine model.

Finally, Panx1 block was also found to increase paired-pulse facilitation but not

differentially between kindled and non-kindled tissue.

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Acknowledgements

Supervisor:

Dr. G. Campbell Teskey

Co-Supervisory:

Dr. Roger J. Thompson

Supervisory Committee:

Dr. Quentin J. Pittman

Dr. Michael A. Colicos

Examining Committee:

Dr. Quentin J. Pittman

Dr. Michael A. Colicos

. Dr. Andrea B. Protzner

Members of the Teskey Lab:

Ryan McCarthy

Kathleen Scullion

Andrew Brown

Bonita Ma

Members of the Thompson Lab:

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Nick Weilinger

Peter Tang

Valentyna Maslieieva

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TABLE OF CONTENTS

Abstract 2

Acknowledgements 3

Table of Contents 5

List of Abbreviations 6

Chapter 1 – General Introduction 9

Introduction to Seizures and Epilepsy 9

Introduction to Pannexin Channels 11

Pannexin Channels in Seizure and Epileptogenesis 17

Modelling Seizure and Epileptogenesis 20

Kindling: Phenomenon, Technique and Model 22

Mechanisms of Kindling 26

Pilocarpine Model 32

in vitro Modelling – The Acute Slice 33

Hypotheses and Specific Aims 37

Chapter 2 – Empirical Paper 40

Introduction 40

Methods 42

Results 50

Discussion 64

Conclusion 69

Chapter 3 – General Discussion 70

Chapter 4 – References 76

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List of Abbreviations

µA microamp

10panx Pannexin1 blocking mimetic peptide

A1R Adenosine-1 Receptor

aCSF Artificial Cerebrospinal Fluid

AD Afterdischarge

ADD Afterdischarge Duration

Ado Adenosine

ADT Afterdischarge Threshold

AMPA 2-amino-3-(5-methyl-3-oxo-1,2-oxazol-4-yl)propanoic acid

AMPAR 2-amino-3-(5-methyl-3-oxo-1,2-oxazol-4-yl)propanoic acid Receptor

ANOVA Analysis of Variance

ATP Adenosine Triphosphate

BDNF Brain Derived Neurotrophic Factor

CA1 cornu ammonis 1

CA3 cornu ammonis 3

cDNA Complementary DNA

CNS Central Nervous System

DG Dentate Gyrus

EEG electroencephalogram

EP Evoked Potential

fEPSP field Excitatory Postsynaptic Potential

GABA Gamma-amino-butyric Acid

GABAR Gamma-amino-butyric Acid Receptor

GFAP Glial Fibrillary Acidic Protein

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HIV Human Immunodeficiency Virus

I2nd Secondary inward current

IP3 Inositol Triphosphate

ISH in situ Hybridization

KA Kainic Acid

KIP Kindling-Induced Potentiation

KS Kolmogorov-Smirnov

LTD Long-Term Depression

LTP Long-Term Potentiation

M1R Muscarinic Receptor 1

mV millivolt

MW Mann-Whitney

NMDA N-methyl-D-aspartate

NMDAR N-methyl-D-aspartate Receptor

OGD Oxygen Glucose Deprivation

P2XN Purinergic Receptor P2X type N

Panx Pannexin

Panx1 Pannexin1

PBS Phosphate Buffered Saline

PDS Paroxysmal Depolarizing Shift

PFA Paraformaldehyde

pop. Spike population spike

PPR Paired pulse ratio

PS Population Spike

PSD95 Post-Synaptic Density protein 95

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S.C. Schaffer Collaterals

SE status epilepticus

SEM Standard Error of the Mean

SO stratum oriens

SP/s.p. stratum pyramidale

SR/s.r. stratum radiatum

SS Seizure Severity

STP Short-Term Plasticity

TAT Transactivator of Transcription

trkB tyrosine receptor kinase B

UTP Uridine-5’-triphosphate

vHPC Ventral Hippocampus

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CHAPTER 1 – GENERAL INTRODUCTION

Introduction to Seizures and Epilepsy

A Brief History of Seizures and Epilepsy

Epilepsy is a neurological disorder affecting the central nervous system, characterized by

abnormal electrical activity that may result in a behavioural seizure (Engel and Pedley, 2008).

The first known reference to epilepsy is in a Babylonian medical text dating to the first

millennium BCE (Wilson and Reynolds, 1990). This text is a part of a larger medical diagnostic

document known as ‘All Diseases’, and attempts to differentiate between types of seizure and

their respective causative demons of possession. Interestingly, the text makes note of many types

of seizure caused by demons which specifically possess children, the infirm, and those with

unresolved sins. This folkloric association was prescient not only of the tendency for epilepsy to

occur predominantly in vulnerable populations (Engel and Pedley, 2008), but of the stigma

against people living with epilepsy (which continues to be a global problem into the 21st century;

de Boer, 2010).

Epidemiology

In 2001, there were an estimated 175000 Canadians living with epilepsy (Tellez-Zentino

et al, 2004) and a total global prevalence of around 50 million people (Engel and Pedley, 2008).

Cases of epilepsy tend occur with a greater frequency in the developing world (Kotsopoulos et

al, 2002; Bell and Sander 2001). Although the cause of this increased incidence has not been

determined, it is possible that increased exposure to parasitic infection might be associated with

comorbid seizure disorders (Bell and Sander 2001). And though a diagnosis of epilepsy may

occur at any age, the incidence of epilepsy is highest in children under the age of 12 and second

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highest in seniors over the age of 60 (Kotsopoulos et al., 2002). Together, these two age groups

account for 50% of all emerging diagnoses of epilepsy (Bell and Sander 2001).

Despite the enormous burden epilepsy places on global health, it remains that the

majority of seizures occur in people who do not have epilepsy. An estimated 4% of Americans

will have a single unprovoked seizure before the age of 80 with only 30-40% of those people

going on to have a second unprovoked seizure, obtaining a diagnosis of epilepsy. Seizures are

not benign events (Herman, 2004). It is therefore evident that research into the mechanisms of

seizure and its translation into clinical medicine extend beyond an application to the treatment of

epilepsy alone.

Pathophysiology of Seizures and Epilepsy

A behavioural or clinical seizure is the result of pathological hyperexcitable and

hypersynchronous neuronal activity (Engel and Pedley 2008). A hypothetical generalized

framework for discussing the pathophysiological mechanisms of seizure activity proposes two

conditions which may predispose individuals to seizure. First, there must be a population of

intrinsically hyperexcitable neurons (Engel and Pedley 2008); for example, a neuronal

population which is able to produce intrinsic burst discharges (Najm et al, 2001). Second, there

must be an increase in excitatory synaptic activity, and/or a decrease in inhibitory synaptic

activity in recurrent collaterals, the local network, and/or the projection neurons (Engel and

Pedley 2008, McCormick and Contreras 2001, Najm et al 2001). This shift in the balance of

excitation and inhibition can occur as the result of a number of mechanisms including changes in

gene transcription, alterations of the synapse at the molecular level, changes in synaptic

morphology, changes in neurite morphology, and neurodegeneration (Pitkanen and Lukasiuk

2011, Engel and Pedley 2008, Pitkanen et al 2006, Chang and Lowenstein 2003).

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The involvement of ion channel mutations in heritable forms of seizure disorder

continues to be characterized (Escayg et al 2000, Sugawara et al 2001, Baulac et al 2001,

Holland et al 2008, Singh et al 2009, and Estacion et al 2010). Mutations in the genes for

voltage-gated sodium channel β1 (Wallace et al 1998), α1 (Escayg et al 2000), and α2 (Sugawara

et al 2001) subunits have been identified in heritable forms of seizure disorder, as well as a

mutation in the γ2 subunit of the inhibitory synaptic ligand-gated chloride ion channel GABAA

(Baulac et al 2001).

Introduction to Pannexin Channels

Pannexins are integral membrane proteins that form hexameric large pores of high

conductance (475-550 pS; Bao et al 2004, Locovei et al 2006) and high permeability (molecules

up to 1kDa). Panx1 is expressed in both neuronal and, controversially, glial cell populations

within the central nervous system (Iglesias et al, 2009, Huang et al, 2009; Figure 1), and is

localized at specific subcellular sites such as the postsynaptic density (Zoidl et al 2007; Figure

1). Until recently, the notion that glial cells express pannexin was controversial as it had only

been observed in expression systems (Huang et al, 2009) and not in vivo (Vogt et al, 2005).

However, Panx1 expression has since been reported to co-immunolabel with glial fibrillary

acidic protein (GFAP, a glial marker) in hippocampal CA1 astrocytes, suggesting glial Panx1

expression (Santiago et al 2011; Figure 1).

Pannexins are expressed broadly in most vertebrate tissues outside the CNS such as taste

buds (Romanov et al 2007, Romanov et al, 2008), the retina (Zoidl et al 2008), and erythrocytes

(Locovei et al 2006), as well as in thyroid, prostate, liver and kidney tissue (Bruzzone et al,

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2003). There are three known genes encoding three pannexin proteins, each with unique

functions and expression profiles (Bruzzone et al 2003, Baranova et al 2004). For example,

Panx3 may be uniquely transcribed in the skin (Bruzzone et al 2003). Pannexins are known to

have a variety of functions in diverse cell types and at particular subcellular locations. Within the

CNS, Panx1 is localizes to the principle output cells of a number of brain areas. For instance,

they have been observed in pyramidal cells of the cortex and hippocampus (Zoidl et al 2007,

Vogt et al 2005) and on Purkinje neurons within the cerebellum (Ray et al 2006). At the

subcellular level, pannexins localize to the post-synaptic density of both PV+ inhibitory

interneurons as well as GluR2+ pyramidal neurons in the hippocampal CA1 region as well as the

neocortex. (Zoidl et al 2007) implying a role for pannexins in neuronal synaptic and non-

synaptic communication in many major structures of the mammalian CNS (MacVicar and

Thompson, 2010; Figure 1).

The post-synaptic density is a specialized, protein-dense intracellular region attached to

the post-synaptic membrane. It is apposed to the pre-synaptic active zone, and permits synaptic

proteins (such as glutamate receptors and Panx1) to remain in close association with sites of

neurotransmitter release from the presynaptic terminal. Proteins are maintained at this subcellular

location with the aid of scaffold proteins which serve to functionally organize the machinery

necessary for postsynaptic signal transduction. PSD95 is one such scaffolding protein and a

member of the membrane-associated guanylate kinase (MAGUK) superfamily of proteins.

MAGUK proteins are defined in part by their inclusion of specific subdomains such as the PDZ

domain which interacts with NMDARs and anchoring them in the post-synaptic site (Cui 2007).

Also commonly found in MAGUK proteins such as PSD95 are the SH3 and guanylate kinase

domains. Although Panx1 co-immunolocalizes with PSD95 is the post-synaptic density (Zoidl et

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al, 2007), the scaffolding protein which maintains its presence in the post-synaptic density in

excitatory and inhibitory neurons in the hippocampus and neocortex, as well as the specific

common MAGUK domains which interact with Panx1 remains unidentified. However, Panx1

interaction with actin microfilaments via the Panx1 intracellular c-terminal tail was shown to be

important for trafficking to the plasma membrane and stable presence there (Bhalla-Gehi et al

2010).

Although Panx1 can be activated and opened with a number of modes including via

purinergic receptor stimulation, mechanical stimulation, increases in intracellular Ca2+,

membrane depolarization, and increases in extracellular potassium (Bao et al, 2004; Locovei,

Wang and Dahl, 2006; Reigada et al 2008; Chekeni et al, 2010), the precise biophysical and

biomolecular mechanism by which these stimuli induce Panx1 opening is not known.

Furthermore, opening can be prevented through the use of mimetic peptides (Wang et al, 2007),

and non-specific channel blockers such as probenecid, carbenoxolone, and fluefenamic acid

(Barbe, Monyer, and Bruzzone, 2006; Dando and Roper, 2009). The latter are thought to block

Panx1 function by physically blocking the pore formed by an open Panx1 channel. The former

are thought to block Panx1 opening by binding to a particular location (such as the first

extracellular loop in the case of the 10

panx mimetic peptide), thereby preventing conformational

changes in Panx1 required for channel opening from a closed state, although this mechanism has

not been verified.

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a

Figure 1. Panx1 expression in the CA1 region of the hippocampus. A) Panx1 colocalizes with

GFAP in astrocytes in the stratum radiatum (modified from Santiago et al 2011). B) Panx1

colocalizes with NeuN in pyramidal neurons in the stratum pyramidale (modified from Santiago

et al 2011). C) Panx1 colocalizes with PSD95, a postsynaptic scaffolding protein in pyramidal

neurons in CA1 of the hippocampus (modified from Zoidl et al 2007). D) Hypothesized

colocalization of Panx1, PSD95, and NMDAR.

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Discovery of Panx Channels

The Panx protein was first identified based on bioinformatic analysis by Panchin and

colleagues (2000) while attempting to clone murine cDNA based on the invertebrate gap

junction protein, innexin. It was known that gap junctions of vertebrates are composed of

connexin proteins, which had no homologous members within the invertebrate lineage. However,

invertebrates possess gap junctional proteins which have no sequence homology with vertebrate

connexins (Panchin et al, 2000). However, Panchin et al (2000) identified proteins homologous

to innexins in many taxonomic clades including vertebrates. This led them to hypothesize that

they had discovered a new putative gap junction protein in vertebrates. For this reason, they

proposed the name ‘pannexin’ (‘Panx’; from the Latin root words ‘pan’ and ‘nexus’ meaning

‘all’ and ‘bond’ respectively) to replace the previous name of ‘innexin’ (Panchin et al, 2000).

Presciently, they anticipated the relevance of Panx to psychiatric and neurological medicine,

noting that its location on the q21 band of human chromosome 11 has been associated with

schizophrenia (St Clair et al, 1990).

Early research on Panx attempted to characterize the transcriptional profile of Panx

through Northern blot analysis and in-situ hybridization (ISH) to gain insight into its functional

expression (Bruzzone et al, 2003). Panx1 and Panx2 subtypes were found to be coexpressed in

many tissues outside the CNS. The mRNA of the Panx1 and Panx2 genes appeared to localize

predominantly to the hippocampus, cortex, cerebellum, and olfactory bulbs of P15 rat pups, with

additional dense expression of Panx2 in the striatum and thalamus. mRNA for Panx2 appeared to

stain more densely in the cortex than did Panx1 at this age. Additionally, in the hippocampus,

while staining could be observed within the stratum radiatum, stratum pyrimidale, and stratum

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oriens mRNA seemed to preferentially localize to cells within the stratum pyramidale, perhaps

suggesting a unique role for Panx within the primary output cells of this structure.

The hypothesis that Panxs form gap-junctions was initially investigated in the oocyte

expression system (Bruzzone et al, 2003). Intercellular junctions (suggested to be true gap

junctions) were observed upon injection of Panx1 mRNA into Xenopus oocytes, as well as Panx1

and Panx2 mRNA coinjection. However, Panx2 mRNA injection alone did not result in the

formation intercellular junctions. The Panx1 and Panx2 coexpression system also exhibited

unique physiological characteristics compared to Panx1 or Panx2 alone, such as reduced outward

current during a depolarizing voltage step compared to Panx1 expression alone. Therefore, the

authors suggested that Panxs may form homomeric (Panx1 subunits only) or heteromeric (Panx1

+ Panx2 subunit-containing) hemichannels, which may be expressed in different cell types

and/or have unique functions (Bruzzone et al 2003, Bruzzone et al 2005). Furthermore, Lai and

colleagues (2006) reported Panx1-mediated dye coupling in C6 glioma cells, suggesting the

presence of Panx1 gap junctions. However, dye coupling has yet to be observed in Panx1

expressing cells in vivo and is likely a phenomenon of expression systems. One possibility for

the appearance of Panx1 intercellular channels in these systems is proposed to be loss of proper

post-translational modifications that would prevent Panx1 docking with an apposed hemichannel

from a neighbouring cell and forming an intercellular junction (MacVicar and Thompson, 2010).

The gap-junction hypothesis of pannexins is in dispute (Dahl and Locovei 2006,

MacVicar and Thompson 2010). The conceptual question seems to be whether pannexins

perform adaptively redundant functions to the connexins, or rather perform adaptively unique

functions that merely appear to be redundant at first glance. The frequent inability of pannexin

channels to form gap junctions when studied as well as the many alternative functions of Panx

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that have been recently elucidated seems to indicate that gap-junction formation is not likely to

occur in vivo. Perhaps the most striking piece of evidence in favour of the non-gap junction

hypothesis of Panx channels is the discovery of Panx expression on erythrocytes (Locovei et al

2006). Therefore Panx is evidently expressed in a cell type that moves freely at the individual

cell level, and does not form gap junctions for intercellular communication (Locovei et al, 2006).

This supports the notion that Panx channels perform a function unrelated to the formation of gap

junctions.

Panx channels possess unique structural components that distinguish them from

connexins. For instance, gap-junction-forming connexin-46 hemichannels are present in the

plasma membrane and are blocked by divalent cations (such as calcium and magnesium) until

they dock with an apposed connexin hemichannel in an adjacent cell (Ebihara et al 2003). Once

docked, the cation block is removed and intercellular communication is permitted. In contrast to

connexin hemichannels, Panx channels appear to be insensitive to extracellular divalent cations,

and open to the extracellular space in physiological ionic conditions (Bruzzone et al 2005),

although Panx1 channels were found to open in response to increases in extracellular potassium

(Santiago et al 2011). However, to strongly conclude that the primary function of Panx is not the

formation of gap junctions, another candidate function ought to be positively identified and

shown to have a more important physiological role.

Indeed, such candidate functions have been proposed and investigated. As previously

discussed, when opened, Panx channels are permeable to molecules up to 1 kDa (Harris et al

2007) and are therefore the candidate pore through which messenger molecules such as ATP and

IP3 are released (Iglesias et al 2009, Locovei et al 2006). Panx has been proposed as the large

pore for ATP release from cultured astrocytes (Iglesias et al, 2009). Some evidence also suggests

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that Panx1 may be coupled to purinergic receptors (P2X2 and P2X7; Pelegrin and Surprenant

2009, Locovei et al 2007) allowing the receptor to recruit Panx1 to function as a highly

permeable pore in response to an ATP or UTP ligand. However, some research has contradicted

this finding (Yan et al 2008). Panx1 has also been found to be opened by ischemic like

conditions (oxygen-glucose deprivation; OGD) and prior to membrane breakdown during

necrosis (Thompson et al, 2006).

Pannexin Channels in Seizure and Epileptogenesis

The finding that Panx1 channels increase both the frequency and amplitude of interictal

bursting modeled by acute hippocampal slices exposed to a bath solution lacking Mg2+

, is of

particular interest to a mechanistic understand of the contribution of Panx1 to seizure activity

(Thompson et al 2008; Figure 2). Low magnesium exposure causes prolonged activation of

NMDARs in neurons following binding by their endogenous ligands in the hippocampal slice.

This permits the activation of NMDARs without the requirement of other glutamatergic

receptors such as AMPARs or kainate receptors. Blocking Panx1 opening in this condition with

the mimetic peptide 10

panx (Pelegrin and Surprenant, 2007) decreased both the frequency of

interictal bursts as well as the amplitude of the burst spikes (Thompson et al 2008). The

contribution of Panx1 channels to interictal burst activity caused by NMDAR activation suggests

that Panx1 may have a role in normal synaptic physiology by amplifying synaptic responses

(Thompson et al 2008, MacVicar and Thompson 2010; Figure 2).

Interictal spikes are clinically diagnostic of epilepsy (Staley and Dudek 2006). It has been

hypothesized that the correlation between interictal spikes and seizure implies a direct role for

interictal spiking in epileptogenesis; that is, the process by which central nervous tissue becomes

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more prone to seizure over time (Staley and Dudek, 2006). Thus, the involvement of Panx1 in a

NMDAR mediated model of interictal bursting in vitro suggests a potential involvement of

Panx1 in the pathophysiology of seizure and epileptogenesis (Thompson et al 2008, MacVicar

and Thompson 2010).

Targeting Panx1 in vivo has revealed both pro- and anti-convulsant outcomes following

administration of the convulsants pilocarpine (Kim and Kang, 2011) or kainic acid (Santiago et

al, 2011), respectively. These paradoxical effects are achieved through unique underlying

mechanisms (Figure 2) Furthermore, although these in vivo studies have implicated Panx1 in

seizure susceptibility and severity (Kim and Kang, 2011; Santiago et al, 2012), the relationship

between Panx channel function and epileptogenesis has not been investigated. This is

particularly important in light of the activation of Panx1 by NMDA receptors and the

dependence of epileptogenesis on glutamate signalling (Thompson et al, 2008; Scimemi et al

2006).

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Figure 2. Four hypothesized mechanisms of Panx1 contribution to seizure activity and

excitability. 1) NMDAR stimulation induces Panx1 opening causing a secondary inward current

(I2nd; Thompson et al 2008). 2) Panx1 opening in response to decreased extracellular glucose

(not shown) releases ATP. ATP is hydrolyzed to adenosine (Ado). Adenosine binds to the A1

receptor (A1R) resulting in the opening of ATP-sensitive potassium channels, causing

hyperpolarization (Kawamura et al 2010). 3) P2X7R activation by IP3-induced intracellular

calcium release (not shown) opens Panx1 clearing IP3 and releasing more ATP to sustain its

P2X7R-induced opening, reducing excitability (not shown, Kim and Kang, 2011). 4) Increased

extracellular potassium due to status epilepticus opens Panx1 channels by an unknown

mechanism (Santiago et al, 2011).

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Modelling Seizure and Epileptogenesis

Models of disease do not perfectly reproduce every aspect of human disease. Rather,

particular characteristics or suites of characteristics of a disease are emulated. Therefore,

investigators attempt to craft research questions such that they make appropriate use of

techniques that are currently available to them (Pitkanen et al 2006). A researcher may choose a

particular model in order to 1) understand the fundamental mechanisms of a disorder, 2)

rationalize new diagnostic techniques, 3) evaluate the effectiveness of a novel therapy, or 4) to

test ways to prevent disease (Pitkanen et al 2006).

Two preparations which have proven useful in understanding the fundamental

physiological principles underlying seizure activity in the hippocampus include chronically

implanted hippocampal electrodes for in vivo electrophysiological studies such as the electrical

kindling technique (Figure 3, Figure 4) as well as acutely isolated hippocampal preparations for

in vitro electrophysiological studies (Pitkanen et al 2006, Figure 5)).

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Figure 3. Repeated kindling stimulation increases afterdischarge duration. A) Repeated

daily electrical stimulation of a brain site such as the ventral hippocampus in the limbic system

elicits (B) an electrographic afterdischarge. C) With repeated daily stimulation, afterdischarge

duration and seizure severity (not shown) increase (Adapted from Racine 1972b).

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Kindling: Phenomenon, Technique, Model

Electrical kindling is a model of seizure and epileptogenesis (McIntyre, 2006). The

kindling technique consists of the daily repeated stimulation of a particular brain area such as the

amygdala or hippocampal region (Goddard, 1969). This stimulation protocol initially elicits a

relatively limited seizure which manifests as highly synchronous EEG activity from a local

recording electrode which outlasts the initial stimulus (Racine, 1972a). This EEG activity is

therefore called an ‘afterdischarge’ (AD). As the kindling technique is applied over many

consecutive stimulation sessions the kindling phenomenon manifests, such that the AD duration

(ADD) and the seizure severity (SS) both increase (McIntyre, 2006; Racine 1972a,b; Figure 3).

It is this progressive alteration in the severity of the EEG and behavioural responses to

repeated electrical stimulation that characterizes kindling (McIntyre, 2006; Figure 3; Figure 4).

By monitoring these parameters either chronically throughout kindling (ADD or SS; Figure 4),

or acutely at various prescribed time points during the kindling process (ADT, ADD, SS), the

contribution of candidate mechanisms of seizure and epileptogenesis can be evaluated and

quantified (McIntyre et al, 2006). An electrically kindled limbic focus is a valid model of partial

seizures (Albright and Burnham, 1980), and has therefore been used to assess the effects of a

number of conventional anticonvulsants on seizure activity (Gilbert, Bharadia, and Teskey, 2001;

Gilbert and Teskey 2001; Gilbert, Corley and Teskey 2002, Serralta et al 2006, Gilbert and

Teskey 2007).

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Figure 4. Modified Racine scale of seizure severity (Racine 1972b). With repeated kindling

stimulation, rats progressively exhibit behavioural seizures comprising inclusively greater

seizure stages. Expressed seizures are progressive in that a stage 3 contains a stage 1 and 2, a

stage 4 contains a stage 3, 2, and 1, etc.

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Electrical kindling was discovered by Goddard and colleagues (1969) while they were

attempting to determine the effect of amygdala stimulation on conditioning in rats. By

happenstance, a short, high frequency train of stimulation was repeatedly delivered to the

amygdala in a number of rats, eventually inducing several behavioural seizures which outlasted

the initial stimulus in one rat. Subsequently, a series of experiments were undertaken by Goddard

and colleagues (1969) in order to determine i) the anatomical specificity of electrical kindling, ii)

its permanence, iii) the effect of alternative stimulus parameters and paradigms on kindling

outcomes, iv) the effect of minor and major electrode-tip lesions on kindling, and v) whether the

kindling stimulation-induced effects were ‘transferrable’ to a distal stimulation site (Goddard et

al 1969). Differences between strains, species and other anecdotal observations were also

included.

From these experiments, Goddard and colleagues (1969) concluded that kindling

stimulation results in a seizure threshold reduction at the site of stimulation allowing repeated

application of a subthreshold stimulus to eventually elicit a seizure at the stimulation site. With

repeated application, this stimulus goes on to elicit behavioural ‘tonic-clonic’ seizures which

become progressively more severe, and this progressive increase in severity of the behavioural

seizures was determined to be relatively permanent, relying on a trans-synaptic mechanism

resulting in a ‘complex reorganization of function’. The results from these experiments are

consistent with the hypothesis that seizures occur on a neural substrate that reads this activity and

actively responds to it with a rearrangement of its functional organization to increase

transsynaptic excitability.

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Together, Goddard and colleagues’ experiments in 1969 provided a foundation for other

researchers to assess the validity and usefulness of electrical stimulation-induced kindled

seizures as a model of seizure and epileptogenesis (Racine 1972a,b,c; Wada and Sato 1974). Not

long after Goddard and colleagues’ seminal publication (1969), the first instance of a

spontaneous seizure state resulting from the kindling technique was demonstrated in the Baboon

species Papio papio (Wada, Ozawa, and Mizoguchi, 1975). This was an important finding

because it demonstrated that a permanently increased susceptibility to seizure as seen in patients

with epilepsy could be induced using the kindling technique if applied long enough and in a

species with a neurology that is adequately labile (Wada, Ozawa, and Mizoguchi, 1975). As

well, it illustrated how a latent epilepsy-like state could be made manifest with the correct

epileptogenic insult in an otherwise normal subject. Further, Wada, Ozawa and Mizoguchi

(1975) confirmed Goddard and colleagues preliminary results from the Macaque in the Guinea

Baboon. These results support the hypothesis that the difference between a person living with

epilepsy and an otherwise normal person may only be a matter of degree of susceptibility to

seizure.

Goddard and colleagues work was prescient of the implications of the kindling model in

that their work has also contributed to our understanding of neuroplastic changes which occur as

a result of seizure (Teskey et al, 2002, Teskey et al, 2008). Somatotopic organization of the

motor cortex is altered when kindling stimulation is delivered to the amygdala (Teskey et al,

2002) or ventral hippocampus (Van Rooyen et al, 2006). People living with epilepsy may

experience a functional reorganization of motor cortex following seizures (Teskey et al, 2008).

Penfield and Rasmussen (1950) mapped the human precentral gyrus in an effort to determine the

seizure focus in patients with epilepsy, and found that the representation of the face was ‘right-

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side up’ (Teskey et al, 2008). However, Kaas and colleagues (1979) later found the sensory

representation of the face in cortex from both Old-World Monkeys and New-World Monkeys to

be upside-down. This finding was replicated in human populations by using functional MRI to

map the cortex of individuals who had no history of epilepsy, confirming that such subjects have

an upside-down representation of the face in the neocortex similar to our Simian cousins (Servos,

1999). Together these data support the hypothesis, among others, that seizures (spontaneous or

stimulation-induced) effect neuroplastic changes in cortical tissues distant from the focus or site

of kindling. They confirm Goddard and colleagues (1969) results, demonstrating a quantifiable

change in motor system function following daily repeated electrical stimulation or spontaneous

seizures throughout life. Further, these studies establish kindling as a practical technique which

can be used to both investigate the fundamental science of seizure activity, and to test therapies

with the potential to alleviate the suffering of those living with epilepsy.

Mechanisms of Kindling

The previous studies illustrate that the kindling phenomenon emerges as a result of the

application of the electrical kindling technique. Subsequent to the confirmation of this discovery,

interest in the mechanism of kindling emerged (Racine 1972a,b; Douglas and Goddard , 1975;

Racine 1986; Mody and Heinemann, 1987; Mody, Stanton, and Heinemann, 1988). Although no

single identifiable mechanism has proven sufficient to account for the kindling phenomenon,

suites of measurable electrophysiological, morphological, and molecular changes have been

investigated for their contribution and together may constitute a close approximation of the

necessary and sufficient conditions required for kindling to occur (Corcoran and Teskey, 2009).

28

Electrophysiological Mechanisms

The electrophysiological mechanisms that contribute to kindling may be grouped into

three categories: 1) kindling-induced potentiation (KIP) of excitatory drive, 2) the erosion of

inhibitory drive, and 3) the emergence of the kindling-induced burst response.

I. Kindling-induced Potentiation

Kindling-induced potentiation (KIP) is an enhancement of the excitatory post-synaptic

potential or population spike that can occur in a secondary site following an application of the

electrical kindling technique (Maru et al, 2002; Corcoran and Teskey, 2009). There is some

controversy as to whether KIP is necessary for the development of the kindling phenomenon

(Corcoran and Teskey, 2009) particularly in the hippocampus (Maru et al, 2002). However, KIP

has been identified in secondary sites when kindling outside of the limbic system (Racine et al,

1991). Thus, although inconsistently expressed, KIP remains a manifestation of AD-induced

plasticity and epileptogenesis.

Long-term potentiation (or LTP) is another phenomenon related to neural plasticity that

shares some striking conceptual similarities with KIP (Racine et al, 1991; Cain, 1989). LTP

consists of an increase in synaptic efficacy following the delivery of a high frequency train of

stimulation to synaptic afferents. It was first observed and described by Terje Lomo in 1966,

three years prior to Graham Goddard’s description of the kindling phenomenon. Lomo (1966)

recorded evoked potentials (EP) from granule cells in the dentate gyrus of the hippocampus of

cats before and after stimulation of the perforant pathway. An increase in EP amplitude from

granule cells of the dentate gyrus following the stimulus was observed. Both kindling and LTP

involve an increase in neural activity following a high frequency stimulus. Although there are

29

many important differences between the two phenomena (Cain, 1989), both appear to be

expression of the Hebb Rule.

The Hebb Rule was proposed by the eminent Neuroscientist Donald O. Hebb in 1949.

Hebb (1949) postulated that mechanisms might exist which would allow synaptic strength to

increase as a function of the temporal synchrony with which a presynaptic neuron fires onto its

postsynaptic partner. This hypothesis is often summarized as ‘neurons that fire together wire

together’. Since both LTP and kindling may be mediated by Hebb-like processes, the possibility

that similar processes underlie their function was the basis of early investigations into the

mechanisms of kindling (Cain, 1989).

It is clear that both KIP and LTP are useful models for researchers interested in

understanding the mechanisms of neural plasticity. However, there are important conceptual

differences between the two phenomena (Cain, 1989). Most notably, KIP requires the elicitation

of afterdischarge, and potentiates this activity with repeated induction (Racine, 1978), whereas

LTP does not require the elicitation of epileptiform activity, nor does it cause any such events

(Cain, 1989).

II. Disinhibition

The corollary of KIP of excitatory synaptic drive would be a converse erosion of synaptic

GABAergic inhibitory drive at secondary efferent sites (Corcoran and Teskey, 2009; Leung et al

2005). Indeed, blocking fast GABAergic neurotransmission can be a useful experimental tool in

revealing enhancement of excitatory synaptic drive (Esclapez et al, 1999). Similar to the

hypothesis predicting increased excitatory drive, the decrease in inhibitory drive does not appear

equally in all secondary sites following kindling (Schinnick-Gallagher et al, 1998, Leung, et al

30

2005). However, erosion of inhibition does appear to apply within the hippocampus and

amygdala (Schinnick-Gallagher et al 1998, Leung et al, 2005). Inconsistent GABAergic

disinhibition is also apparent in chronic temporal lobe epilepsy, with some sites demonstrating

robust and even enhanced GABAergic drive, while others show a decrease (Bernard et al, 2000;

Cossart et al, 2001; Esclapez et al, 1998).

III. Bursting

Neurons isolated from a seizure focus often exhibit an electrical ‘bursting’ response

(Westbrook, 2000). Bursting is a form of periodic neural activity that consists of a group of

action potentials which occur due to a neural event known as a ‘paroxysmal depolarizing shift’

(PDS; Johnston and Brown, 1984). The PDS is a depolarization of the neuronal membrane of

about 20-40 mV from the resting potential, lasting on the order of 50 to 200 ms (Johnston and

Brown, 1984; Westbrook, 2000; Wong et al, 1984). A train of action potentials known as a burst

is often produced at the peak of depolarization during a PDS (Westbrook, 2000). Bursting within

PDSs can be measured from single and populations of neurons both intracellularly and from field

potentials, respectively (Johnston and Brown, 1984). Intracellularly, the PDS is often

immediately followed by a hyperpolarization. The early depolarization component is caused

predominantly by AMPAR and NMDAR-mediated excitatory signals and is correlated with a

relatively high calcium ion conductance (Lothman, 1993a; Wong et al, 1984). The late

hyperpolarization phase which limits the duration of the early phase is often mediated by

GABAR inhibitory signals and is correlated with a relatively high potassium ion conductance

(Wong et al, 1984). Along with neurons isolated from a seizure focus, healthy neurons from

particular areas of the brain exhibit PDS under normal conditions, and a similar

31

excitatory/inhibitory response pairing can be observed in cortical neurons when evoked by an

excitatory stimulus (Lothman, 1993a; Westbrook, 2000).

PDS-induced burst discharging is not only a property of neurons at a seizure focus, as

well as a limited number of healthy neurons, but importantly, though perhaps not surprisingly, is

associated with kindled neurons (Johnston and Brown, 1984). Bursting can be observed

prominently in the amygdala, piriform cortex, the substantia nigra (Corcoran and Teskey, 2009).

Bursting is a neural correlate of the interictal discharge observable between seizures events on

the EEG of patients with epilepsy, as well as the electrical activity at the level of individual cells

that occurs during an AD and is therefore considered an important component in the mechanism

of kindling (Corcoran and Teskey, 2009). Increased PDS-induced bursting is thought to be

predominantly the result of changes at the network level rather than the level of individual

neurons (the exception being changes in the intrinsic properties of granule cells within the

dentate gyrus; Johnston and Brown, 1984). That is, kindling may induce changes in excitation

and inhibition as well as changes in network properties to permit larger populations to exhibit

PDSs with greater frequency and synchrony. This may result in an increase in the frequency of

interictal burst firing as well as a progressive increase in the duration and character of AD that is

seen in kindling.

Morphological Mechanisms

Kindling does not result in, and does not depend on any significant neural damage

(Corcoran and Teskey, 2009). Rather, changes in synaptic morphology have been proposed to

account for the electrophysiological and behavioural phenomena associated with kindling (Sutula

et al, 1989; Geinisman et al, 1992; Henry et al, 2008). Specifically, an increase in the number of

32

perforated synapses has been observed in the dentate gyrus following hippocampal kindling

(Geinisman et al, 1992), as well in layer V of the sensorimotor neocortex following kindling of

the corpus callosum (Henry et al, 2008) demonstrating the generalisability of the morphological

mechanisms of kindling from the hippocampus to the neocortex.

Molecular Mechanisms

Particular neurotransmitter systems seem to be uniquely involved in mediating the

kindling phenomenon. GABAergic tone, as previously mentioned, is variably decreased

following kindling as is the contribution of noradrenergic function (Giorgi et al, 2004). Indeed

data from numerous experimental lines indicate an anti-epileptic role for noradrenaline, such that

kindling rates are increased when the noradrenergic system is interfered with (Giorgi et al,

2004). On the other hand, excitatory (calcium-ion dependent glutamatergic) drive appears to be

augmented following kindling (Jarvie et al, 1990). As well, the trkB receptor and its ligand

‘brain-derived neurotrophic factor’ (BDNF) appear to be critical factors in kindling

epileptogenesis, such that when trkB receptor is knocked out epileptogenesis ceases (He et al,

2004). As BDNF is a neurotrophic molecule, this may implicate its downstream neurotrophic

effects on neuronal morphology and dendritic outgrowth, in kindling epileptogenesis (He et al,

2004).

These results concerning the mechanisms of kindled seizures and epileptogenesis

highlight its continued importance in therapeutic discovery, its insight into human epilepsy, and

the insight it offers into the fundamentals of neural function. Epilepsy research using the kindling

phenomenon as a model of epileptogenic neural plasticity is a prime example of the overlap

between basic and translational research.

33

Pilocarpine Model

The pilocarpine model of acute seizure, status epilepticus and epileptogenesis has

experienced increasing popularity in recent years (Cavalheiro et al, 2006). It shares some

characteristics with electrical kindling, in that pilocarpine induces epileptogenesis which results

in a chronic increased susceptibility to seizure following a latent period, and that it is generally

considered to model some aspects of human temporal lobe epilepsy (Curia et al, 2008). Indeed,

the pilocarpine model which consists of a single systemic injection of the muscarinic

acetylcholine receptor agonist (Cavalheiro et al, 2006) results in acute seizure activity which may

progress from motor arrest to fully generalized tonic-clonic convulsions, similar to the

epileptogenic progression seen across kindling sessions (Curia et al, 2008). If the experimental

subject survives the acute phase, it can be followed by recovery and a ‘latent’ period wherein no

behavioural seizures are observed, which in turn is followed by a ‘chronic’ phase characterized

by increasingly severe spontaneous behavioural seizures (Curia et al, 2008). Behavioural

seizures induced by pilocarpine are accompanied by AD at a limbic focus (Young et al, 2009),

and hippocampal sclerosis in the chronic phase (Curia et al, 2008) similar to known

characteristics of temporal lobe epilepsy and consistent with its use as a model of that syndrome

(Curia et al, 2008).

However, there exist important differences between the electrical kindling and

pilocarpine models. As opposed to kindling, the pilocarpine model causes seizure-induced

damage and subsequent network reorganization more quickly. Induced primarily by sustained

status epilepticus lasting several hours during the acute phase, histopathological changes such as

necrosis, atrophy and dendritic sprouting are observable in the olfactory cortex, amygdala,

thalamus, hippocampus, and neocortex following pilocarpine treatment (Curia et al, 2008). Thus,

34

as opposed to kindling, the pilocarpine model necessarily results in greater CNS damage causing

epileptogenesis.

Electrical kindling is known to result in a functional reorganization of afferents of the

seizure focus (Henry et al, 2006; Teskey et al, 2002). Kindling with primary stimulation sites in

the corpus callosum, the amygdala, and the hippocampus are all known to persistently alter the

functional organization of the sensorimotor neocortex following seizure propagation to this site

(Teskey et al, 2002; Van Rooyen et al, 2006). Similarly persistent changes in the sensorimotor

neocortex have been noted following administration of pilocarpine in Wistar rats, and transiently

following pilocarpine-induced SE in Long-Evans rats (Young et al, 2009). This strain difference

presents the possibility that genetic variability may account for differences in neuroplastic

functional reorganization following seizure. Furthermore, it highlights important similarities

between electrical kindling and pilocarpine as models of temporal lobe epilepsy and all of its

neuroplastic sequelae.

In vitro Modelling – The Acute Slice

At around the same time that Bliss and Lomo were first investigating the long-term

potentiation (LTP) model of neural plasticity (1973), the development of a technique to remove

and acutely analyse brain slices was being explored for the first time (Yamamoto and McIlwain,

1966). This reduced preparation allowed relatively easy experimentation with hitherto

inaccessible systems and circuits, all the while preserving much of the local circuitry intact

(Bernard, 2006). There are some advantages to studying electrophysiology in acute slices.

Although field potentials can be recorded in vivo as in early LTP studies (Lomo, 1966) these

extracellular recordings can be obtained with a greater degree of control and accuracy in the

35

acute slice setting (Bernard, 2006). Furthermore, slice techniques allow visual access to

individual neurons within local brain sites of interest and allows the precise positioning of

stimulating and recording electrodes necessary for intracellular recording techniques such as the

patch clamp (Hamill et al, 1981; Figure 5).

Despite these advantages, there are some inherent limitations to the technique. Care must

be taken to remove slices thin enough to allow tissue perfusion of oxygen and artificial

cerebrospinal fluid, but thick enough to preserve circuitry and function (Bernard, 2006).

Furthermore the tight spatiotemporal coupling of neural activity and cerebral blood flow

(Chaigneau et al, 2003) is completely lost in the slice technique. However, it is perhaps unfair to

criticise an experimental technique when its supposed advantages overlap with its disadvantages.

Acute slice preparations are inherently reductionist (Bernard, 2006). A technique is not

absolutely better or worse, rather it is more or less appropriate to the research question to which

it is applied. When a research question can best be answered by a reduced model, such as

questions concerning intrinsic properties of individual neurons, or concerning local excitability

of pools of neurons with stereotyped synapses, then it is appropriate to use such a model. Thus, if

extrahippocampal circuitry is critical to the type of seizure activity being studied, then the acute

slice may not be appropriate (Bernard, 2006). Nonetheless, interictal and ictal epileptiform

discharges can be studied and compared across experimental or therapeutic manipulations

(Anderson et al, 1986; Traynelis and Dingledine, 1988; Cohen et al, 2002; Thompson et al,

2008).

There are a number of ways to study epilepsy acutely in the hippocampal slice

preparation. In general however, the strategies can be lumped into one of two categories: 1) acute

slices prepared from normal (non-epileptic) animals which are manipulated in vitro to exhibit

36

epileptiform activity, or 2) acute slices obtained from patients with epilepsy, or from animals

with genetic epilepsies, seizure disorders, or rendered epileptic using experimental models of

seizure disorders such as have been described above (Bernard, 2006). Field potentials or

intracellular electrophysiology can be studied passively or in response to electrical or chemical

stimulation (Bernard, 2006; Figure 5).

Epileptiform activity can be elicited from acute slices using a number of techniques. A

method of naively kindling acute slices can be accomplished by delivering tetanic, high-

frequency stimulation to the Schafer collaterals in the stratum radiatum of CA1 in the

hippocampus (Rafiq et al, 1993). A model of electroencephalographic AD can be produced by

this stimulation-induced bursting (Bragin et al, 1997; Rafiq et al, 1993). Eliciting AD in acute

slices provides the opportunity to study local circuit synchronization; in particular the

involvement of mediators of excitatory signals such as NMDARs, as well as inhibitory mediators

such as GABAR (Stasheff et al, 1993; Bracci et al, 1999).

Removing magnesium ions from artificial cerebrospinal fluid (aCSF) allows NMDARs to

respond directly to glutamatergic stimulation, and eventually comes to elicit stable, spontaneous

interictal-like discharges from acute slice being studied (Mody et al, 1987). Low magnesium has

been reported from patients with epilepsy (Durlach, 1967) suggesting clinical implications for

this particular acute slice model. Ictal discharges can be observed with an in toto preparation of

the hippocampus exposed to magnesium ion-free aCSF (Quilichini et al, 2002). These

preparations are highly useful in testing anti-epileptic or anti-convulsant therapies as the

dependent variables (burst frequency and amplitude) are readily recordable before and after a

particular treatment (Bernard, 2006).

37

Figure 5. Stimulation protocol for eliciting evoked field potentials in acute hippocampal

slices. A) A wave form of known, brief duration (0.1msec) and variable amplitude is applied to

the (B) Schaffer collaterals via a glass stimulating electrode. C) The stimulation induces an

excitatory postsynaptic field potential recorded from the dendritic arbor of CA1 pyramidale

neurons in the stratum radiatum of CA1. D) The evoked potential recording is made up of the

field potential (measured as the slope of the rising phase in red), and the population spike

(measured as the potential difference between the PS trough and a line drawn between its

flanking peaks.

38

Bathing slices in aCSF containing high potassium ion concentration (~8.5mM) results in

the appearance of spontaneous epileptiform activity (Traynelis and Dingledine, 1988). This

increase in extracellular potassium is in the same order of magnitude as increases in potassium

ions experienced by hippocampal neurons during seizure activity in vivo (Fisher and Alger,

1984). This particular technique is useful in that it increases excitability among most neural

populations and networks (Fisher and Alger, 1984). Mixed models of epileptiform activity in

acute slices can be generated by combining techniques. For example, 0 Mg2+ aCSF can be made

isotonic with regular aCSF by compensating for the lack of magnesium ions by replacing them

with potassium ions, elevating the potassium ion concentration from 3.5mM to 5.0mM

(Thompson et al, 2008).

Acute slices may also be obtained from animals treated with in vivo models of seizure,

SE and epileptogenesis, such as the electrical kindling or pilocarpine models (Bernard, 2006).

Such slices could be treated with bath solutions described in the previous paragraphs and

differences could be observed (Figure 5).

Hypotheses and Specific Aims

My long-term goal is to understand how seizure-induced Panx1 activation contributes to

epileptogenesis, and how epileptogenesis, in turn, alters the contribution of Panx1 to seizure

activity. The specific objective of this thesis was to determine how Panx1 affects

epileptogenesis, and how the contribution of Panx1 to seizure activity is altered following

epileptogenesis. The central hypothesis was that Panx1 amplifies and intensifies seizure

activity, and that interfering with this activity would attenuate measures of seizure

susceptibility and severity. This was based in part upon previous studies which suggested that

39

Panx1 is recruited by epileptiform activity and amplifies such activity by increasing the

amplitude and frequency of neuronal firing through a mechanism that also mediates synaptic

plasticity (Thompson et al, 2008).

Epileptogenesis may refer to dynamic processes which alter patterns of neuronal

excitability, reorganizes connectivity, and induces critical structural changes which ultimately

result in increases in seizure susceptibility, severity or duration (Pitkanen and Lukasiuk, 2011).

The rationale for pursuing this hypothesis in the experiments that follow is that once it is known

how and to what extent Panx1 can influence the course of epileptogenesis, therapeutic strategies

based on interfering with Panx1-mediated mechanism can be pursued in order to improve the

quality of life of people living with epilepsy. Further, by understanding how Panx1 contributions

to measures of seizure activity are changed following epileptogenesis, and the population-level

changes in excitability that correlate with these changes, we will better be able to determine how

Panx1 contributes dynamically to the mechanisms underlying the generation and spread of

seizures in people already diagnosed with epilepsy.

I pursued these unexplored opportunities with the following novel aims:

Specific Aim 1. To determine the contribution of the Panx1 channel to the process of

epileptogenesis. Hypothesis: That the Panx1 channel mediates a seizure activity-dependent

mechanism that is important for epileptogenesis.

a) Determine the contribution of Panx1 channel-opening to kindling epileptogenesis by

blocking this activity with a specific peptide and recording the number of kindling

stimulation sessions required to for the animal to experience 3 stage 5 seizures as well as

the rate at which rats from each group reach this criterion.

40

Specific Aim 2. To determine the contribution of Panx1 channel to acute seizure activity

and local field potential excitability and following epileptogenesis. Hypothesis: That the

Panx1 channel-opening is mediated by seizure activity, and that this effect mediates a

mechanism that is important in increasing seizure susceptibility

a) Determine the differential contribution of Panx1 to acute seizure activity following

epileptogenesis by blocking Panx1 with a specific peptide prior to administration of

kindling stimulation-induced seizures in rats naïve to stimulation, in partially kindled rats

(having experienced a single stage 3 seizure), and in fully kindled rats (having

experienced 3 stage 5 seizures).

b) Determine the differential contribution of Panx1 to local field excitability and short-term

plasticity near the seizure focus in fully-kindled rats compared to age-matched controls

by stimulating acute hippocampal slices with a paired-pulse protocol at increasing

stimulation intensities and recording the amplitude and paired-pulse ratio of the slope of

the field excitatory postsynaptic potential as well as the resulting population spike.

c) Determine the contribution of the Panx1 channel to acute seizure activity in the seizure-

naïve state in vivo by blocking Panx1 with a specific peptide prior to administration of

the chemical convulsant Pilocarpine and recording the latency, duration and severity of

the resulting behavioural seizure.

41

CHAPTER 2 – EMPIRICAL PAPER

Introduction

Epileptogenesis is defined as the process by which neuronal excitability is progressively

altered, rendering nervous tissue more prone to seizure (Goddard, 1969; Pitkanen and Lukasiuk,

2011). This process occurs following any of a variety of events or insults (Pitkanen and

Lukusiak, 2011), even by seizure activity itself (Dudek and Shao, 2003). Researchers have

explored the molecular mechanisms of epileptogenic plasticity with the goal of preventing

epileptogenesis (Temkin, 2001; Pitkanen et al, 2005; Pitkanen et al, 2007; Bortel et al, 2010) .

However, the prophylactic prevention of epileptogenesis remains an elusive therapeutic target for

the 50 million people who suffer from epilepsy worldwide (Pitkanen and Lukasiuk, 2011).

Pannexin1 (Panx1) is a large pore high conductance (~500pS) ion channel that has been

implicated in experimental models of seizure activity both in vitro (Thompson et al, 2008) and in

vivo (Kim and Kang, 2011; Santiago et al, 2011). Panx1 block was shown to reduce the

amplitude and frequency of NMDAR-activation dependent epileptiform activity in vitro

(Thompson et al, 2008). Furthermore, Panx1 block differentially increases and decreases seizure

severity in vivo resulting from pilocarpine (Kim and Kang, 2011) and kainic acid (Santiago et al,

2011) administration, respectively, in murine models. Further, in addition to these conflicting

findings, the relationship between Panx1 function and epileptogenesis has not been investigated.

This is particularly important in light of the activation of Panx1 by NMDA receptors and the

dependence of epileptogenesis on glutamate signalling (Thompson et al, 2008; El-Hassar et al,

2007).

42

The slowly progressive nature of electrical kindling allows for a finely controlled study

of the process of epileptogenesis. In this model, repeated electrical stimulation of a central

nervous system structure elicits electrographic afterdischarges and behavioural seizures that

become progressively longer and more severe (Goddard, 1969; McIntyre, 2006; Racine, 1972b).

In rats, kindling stimulation initially elicits seizures having behavioural characteristics which are

similar to the characteristic motor symptoms associated with focal partial seizures in humans

(McIntyre, 1970; McIntyre, 1979). Following successive daily stimulation, the elicited

behavioural seizures become more similar to characteristic motor involvement and severity of

complex partial seizures with secondary generalization (McIntyre, 1970; McIntyre, 1979).

Furthermore, the kindling and pilocarpine models induce neuroplastic and subsequent functional

changes at efferent motor sites that are correlated with the severity of the stimulus induced by the

convulsants (Teskey et al, 2002; Young et al, 2009) These results suggest that electrical kindling

and the pilocarpine-induced seizures model the epileptogenesis of secondary generalization from

a primary seizure focus.

The present study explores the hypothesis that Panx1 contributes directly to the process

of epileptogenesis itself, as well as to seizure activity differentially following epileptogenesis.

These innovative results suggest that a single early treatment with Panx1 blocker is sufficient to

significantly retard kindling epileptogenesis, as well as to acutely reduce seizure susceptibility

and severity. Further, they indicate that Panx1 blockade affects seizure severity and seizure

susceptibility differentially following epileptogenesis via a mechanism that does not rely on

Panx1-mediated changes in the neuronal excitability of the seizure focus.

43

METHODS

Animals

Adult male Wistar (n= 32; 250-400 grams) and Long-Evans (n= 30, 235-320 grams) were

obtained from Charles River (St Constant, PQ, Canada). Wistar rats were housed in groups of

three in standard shoebox cages in a colony room that was maintained on a 12 hour light cycle,

with lights on at 7:00 am. Long-Evans rats were individually housed in the same conditions. All

experiments were conducted during the light phase. Rats received food and water ad libitum and

were handled and housed according to the Canadian Council for Animal Care (CCAC)

guidelines and approved by the local Health Sciences Animal Care Committee.

Electrical Kindling Experiments

Electrode and cannula implantation

Adult male Long-Evans rats were each chronically implanted on the right side with a

stimulating/recording electrode and an infusion cannula. Twisted bipolar stimulating/recording

electrodes were constructed from Teflon-coated stainless steel wires having a diameter of 178

µm. The uninsulated ends of exposed wire were attached to male gold amphenol pins and the

electrode tips at the opposing end were separated by at least 0.5mm. Rats were anaesthetized

using isoflurane (5% induction, 2% maintenance), then mounted into the stereotaxic frame. 2%

Lidocaine was administered subcutaneously beneath the incision site prior to making the 1.5 inch

incision. The stimulating/recording electrode was implanted in the ventral hippocampus

according to the stereotaxic coordinates of Paxinos and Watson (1982; 4.5 mm posterior to

bregma, 4.5mm lateral to midline, and 7.0mm ventral from brain surface). The cannula was

44

implanted into the right lateral ventricle (0.8mm posterior to bregma, 1.5 mm lateral to midline,

and 3.7 mm ventral from brain surface). 5 anchoring screws and 1 ground screw were placed in

the frontal, parietal and temporal bones, and the electrode and cannula were cemented to the

screws using dental acrylic. The free male amphenol pins were inserted into a nine-pin McIntyre

connector plug (Ginder Scientific, Ottawa, Ontario, Canada). Rats were allowed to recover from

surgery for a minimum of 7 days prior to afterdischarge determination.

The positioning of the electrode was confirmed by post-hoc visual inspection. For the

latter, rats were perfused with physiological phosphate-buffered saline (PBS) followed by 4%

w/v paraformaldehyde (PFA). Fixed brains were then excised and hand-sliced with a razor for

coarse visual inspection. The approximate location of the terminal end of the bipolar electrode

track was recorded.

Afterdischarge determination

On the first day of kindling, the afterdischarge (AD) threshold (ADT) was determined for

every subject. The ADT is defined as the minimum amount of current required to elicit an AD

which lasts longer than 4 seconds. Current was delivered through the ventral hippocampal

electrode and recordings were made from the same. Stimulation consisted of a one second train

of 60 Hz biphasic square wave pulses, each leading and lagging pulses both 1 ms in duration,

with the lagging pulse entrained to initiate 2 ms after the initiation of the leading pulse.

Afterdischarge threshold determination began at 50 μA , and was increased in 25 µA increments

delivered every minute until an AD which lasts longer than 4 seconds was observed. Kindling

stimulation eliciting an afterdischarge was delivered twice daily at a current intensity 100 μA

greater than the determined ADT with at least 4 hours separating each stimulation session. EEG

45

was recorded from the ventral hippocampal electrode to determine afterdischarge duration.

Seizure behaviour was scored according to a 5 point ordinal scale of motor seizure progression

(Racine, 1972b).

Kindling

Afterdischarge threshold was determined at three time points throughout the extent of

each rat’s kindling lifetime. The ADT was evaluated the day following their initial ADT

determination (‘Naive’), the day following their first stage 3 seizure (‘Partially Kindled’), and

the day following their third stage 5 seizure according to the Racine scale (‘Fully Kindled’,

Racine 1972b). On each day, prior to ADT determination, subjects received 5.0 uL

intracerebroventricular administration of 7.5 mg/mL 10

panx in 0.9% saline or 0.9% saline

vehicle. The treatment was injected using a 10 µL Hamilton syringe and microdrive system at a

rate of 1.0 μL/min for 5 minutes. Following the 5 minute injection time, the treatment infused for

3 additional minutes, then the injection cannula was removed, and the dummy cannula inserted

into the guide cannula. The rat was then placed in a faraday cage, and the ADT determined. The

seizure stage and ADD was also recorded.

Pilocarpine Experiments

10panx – selective inhibitor of Panx1 hemichannels

In order to assess the effect of the Panx1 channel block on acute seizure and status

epilepticus, the selective Panx1 pore blocker ‘10

panx’ was administered prior to delivery of the

chemical convulsant pilocarpine. TAT-10

panx panx is a mimetic peptide which binds to the first

46

extracellular loop of Panx1 selectively, thereby blocking the flux of permeant molecules

(Pelegrin and Surprenant 2007). Wistar rats were treated in pairs with 10

panx (7.5 mg/kg, Tocris

Bioscience) or saline vehicle. 10

panx was administered intraperitoneally (i.p.) in sterile 0.9%

saline 30 minutes prior to injection with pilocarpine (see below).

Pilocarpine-induced seizures and status epilepticus

All rats received atropine methyl-nitrate (10 mg/kg) injected intraperitoneal (i.p.) 30

minutes prior to pilocarpine or saline treatment in order to block the effects of pilocarpine on

peripheral muscarinic receptors. Pilocarpine (360 mg/kg) or physiological saline was

administered intraperitoneally. The dosages were selected based on previous reports (Hort et al.,

1999, 2000; Šroubek et al., 2001; Dykstra et al., 2007).

Following drug administration, seizure behaviour was video recorded for 60 minutes,

observed and scored during both the recording session and post hoc. The measured parameters

were 1) latency to behavioural seizure, 2) seizure duration, and 3) seizure severity. The seizure

severity scale consists of the following stages: Stage 1 – mouth and facial movements, Stage 2 –

head nodding, Stage 3 – unilateral forelimb clonus, Stage 4 – bilateral forelimb clonus and

rearing, Stage 5 – a stage 4 with falling episodes (Racine, 1972). Diazepam (10 mg/kg, i.p.) was

administered either after SE or 45 minutes following convulsant injection to attenuate seizure

activity and promote survival. All rats were also given 5 ml of 5% dextrose in physiological

saline to replace electrolytes and facilitate recovery until brain extraction could occur. Later that

same day, the rats were humanely euthanized with a 1 mL injection of Euthanyl, perfused with

phosphate-buffered saline followed by a 4% paraformaldehyde solution and their brains

extracted.

47

In Vitro Experiments

Acute Hippocampal Slices

To determine differences in the excitability of kindled compared to non-kindled

hippocampal foci, acutely isolated hippocampal slices were prepared from Long-Evans rats

(“Naive”, n=8), from Long-Evans rats (“Sham Controls”, n=5), and from rats that had exhibited

three stage 5 behavioural seizures as scored according to the Racine scale (‘Fully Kindled’,

Racine 1972b) male Long-Evans rats (n=5). Under isoflurane anesthesia, brains were removed

and placed in cold slicing solution consisting of (in mM) 215 NaCl, 2.5 KCl, 26 NaHCO3, 10

MgCl2, 1.6 NaH2PO4, 10 D-glucose, and 215 sucrose, that was bubbled with 5% CO2/95% O2.

Horizontal hippocampal slices (370 μm) were cut using a vibratome and maintained for 45 min

in a warm (37°C) recovery solution composed of artificial CSF (aCSF) (in mM): 120 NaCl, 26

NaHCO3, 3 KCl, 10 Glucose, 1.25 NaH2PO4, 1.3 MgSO4, and 2 CaCl2, and continuously

bubbled with 5% CO2/95% O2 to maintain a pH of 7.4. After a minimum of 45 minutes, slices

were transferred to a recording chamber that was continuously perfused with aCSF at 32°C.

Extracellular field potentials were recorded with glass micropipettes filled with aCSF (2–3 MΩ)

and signals were acquired using an Axopatch 200B amplifier (Molecular Devices; low-pass

filter, 10 kHz; high-pass filter, 1 Hz; acquisition frequency, 10 kHz; gain, 500×). Evoked field

EPSPs (fEPSPs) were elicited in the CA1 stratum radiatum region of the hippocampus by

electrically stimulating the Schaffer collaterals (CA3 collateral axonal projections to CA1) with a

monopolar glass pipette electrode filled with aCSF at 50% maximal stimulation (the point at

48

which the fEPSP slope did not increase further with increasing stimulation was taken as 100%

maximal stimulation).

Statistics

The alpha levelfor all statistical tests listed below is p<0.05.

Acute Electrical Kindling Experiments

The difference in ADT and ADD between naive, partially-kindled, and fully-kindled

Panx-blocked and control rats was analysed using two-tailed unpaired t-tests. However, when

analysing the ADTs of fully kindled rats, the data failed the Kolmogorov-Smirnov test for

normality likely due to a floor effect in the Panx1-blocked rats. The Mann-Whitney test, a non-

parametric test, was used in lieu of the t-test in this instance.

The difference in SS between Panx1-blocked and controls rats was also analysed using

two-tailed unpaired t-tests. Again, when analysing the SS of fully kindled rats, the data failed the

Kolmogorov-Smirnov test for normality likely due to a ceiling effect in control rats. The Mann-

Whitney test, a non-parametric test, was used in lieu of the t-test in this instance.

Pilocarpine Experiments

The difference in the severity of the first seizure between Panx1-blocked and control rats

was analysed using a two-tailed t-test. The difference in the severity of the most severe seizure

between Panx1-blocked and control rats was analysed using a one-tailed t-test.

The difference in seizure latency between Panx1-blocked and control rats was analysed

using a one-tailed t-test. As well, the difference in seizure duration of both the first observed

49

seizure and the cumulative total seizure duration during the one hour observation period between

Panx1-blocked and control rats was analysed using a two-tailed t-test.

In vitro Experiments

The differences in standardized fEPSP slope between kindled and sham-kindled slices

were determined across a range of stimulus intensities (100µA, 150µA, 200µA, 300µA, 500µA,

750µA, 1000µA) to derive a plot of input stimulus intensity versus output fEPSP slope. This

protocol was performed in normal aCSF, after the peptide Panx1 blocker 10

panx was washed on,

and again in normal aCSF to wash off the 10

panx. The input/output curve was analysed using a

6x3 ANOVA with follow up Tukey’s tests between all columns. A paired-pulse protocol was

used to elicit fEPSPs. The paired pulse ratio (PPR) was calculated as the quotient of the

standardized slope of the fEPSP resulting from the second stimulus over the first. PPRs were

analysed across the same range of stimulus intensities as the fEPSP slopes (discussed above).

The differences in standardized population spike amplitude between kindled and sham-

kindled slices were also determined across a range of stimulus intensities (100µA, 200µA,

300µA, 500µA, 750µA, 1000µA) to derive a plot of input stimulus intensity versus output

population spike amplitude. This protocol was performed in normal aCSF, after the peptide

Panx1 blocker 10

panx was washed on, and again in normal aCSF to wash off the peptide blocker.

The input/output curve was analysed using a 6x3 ANOVA with follow up Tukey’s tests between

all columns. A paired-pulse protocol was used to elicit population spikes. The paired pulse ratio

(PPR) was calculated as the quotient of the population spike amplitude resulting from the second

stimulus over that elicited by the first. Population spike amplitude and PPRs were analysed

across the same range of stimulus intensities as the fEPSP slopes (discussed above).

50

Epileptogenesis in Electrical Kindling

The difference in the number of days required to fully kindle rats treated with Panx

blocker as compared to control rats was analysed using a two-tailed unpaired t-tests. The

differences in kindling rates between these two groups were compared using survival analysis,

with the third stage 5 seizure elicited as the termination criterion. The subsequent significant

hazard ratio from this analysis was calculated as the ratio of the drop-out rate of control rats to

that of Panx blocker-treated rats.

51

RESULTS

A single central infusion of Panx1 blocker chronically attenuates epileptogenesis

Epileptogenesis was measured as the number of stimulation induced seizures required to

elicit three stage 5 seizures as scored according to the Racine scale (‘fully kindled’; Racine,

1972b), as well as the rate at which subjects became fully kindled. A single administration of

Panx1 blocker prior to assessing the afterdischarge threshold in naive rats significantly increased

the mean (+/- SEM) number of kindling sessions required for rats to have their third stage 5

seizure (58.71 +/- 15.06 kindling sessions) compared to vehicle treated controls (29.86 +/- 4.53

kindling sessions; t=1.835, df=12, p=0.0457; Figure 1a).

Furthermore, survival analysis indicates that rats receiving a single treatment with Panx1

blocker (median survival = 47 kindling sessions) become fully kindled at a significantly slower

rate than did vehicle-treated controls (median survival = 27 kindling sessions, median survival

ratio = 0.57; Mantel-Cox Test, χ2

= 3.865, df = 1, p=0.0495; Figure 1b). The rate at which

subjects became fully kindled (that is, the ‘hazard ratio’ for epileptogenesis to 3 stage 5 seizures)

was 3.74 times higher in vehicle controls compared to centrally Panx1 blocked rats.

52

Figure 1. A single central infusion of Panx1 blocking peptide (7.5mg/kg) has the chronic effect

of (A) increasing the number of kindling sessions required for the rat to exhibit three stage 5

seizures(‘fully kindled’), and (B) decreasing the rate at which rats become fully kindled

compared to vehicle control.

53

Acutely, Panx1 block has pro- and anti-convulsant effects in the electrical kindling model

In the electrical kindling model (Figure 2a), the afterdischarge threshold (ADT) was

determined following administration of the Panx1 blocker in naive rats, in partially kindled rats,

and in fully kindled rats (Figure 2b,c). Panx1 block did not significantly change the mean (+/-

SEM) ADT (t=0.048, df=15, p=0.9620) in naive rats (146.9 +/-32.88 µA) compared to vehicle-

treated controls (144.4 +/- 37.22 µA), nor in partially kindled rats (t=0.75, df=9, p=0.4742; 100.0

+/-17.68 µA) compared to vehicle-treated controls (125.0+/-26.61 µA). However, Panx1 block

significantly decreased the ADT (KS distance = 0.3588, p<0.05; U = 4.00, p=0.0409) in fully

kindled rats (62.50 +/- 12.50 µA) relative to vehicle-treated controls (115.6 +/20.01 µA).

The AD duration (ADD) was determined from the ADs elicited when determining the

ADT in naive, partially kindled and fully kindled rats (Figure 2d). Panx1 block did not

significantly change the mean (+/- SEM) ADD in naive rats (41.13 +/- 9.76 seconds) compared

to vehicle-treated controls (46.33 +/- 14.87 seconds; unpaired two-tailed t-test, t=0.285, df=15,

p=0.7797), in partially kindled rats (32.00 +/- 7.24 seconds) compared to vehicle controls (55.00

+/- 14.18 seconds; unpaired two-tailed t-test, t=1.354, df=9, p=0.2087), or in fully kindled rats

(65.75 +/- 10.23 seconds) compared to vehicle controls (68.88 +/- 10.58 seconds; t= 0.186,

df=10, p=0.8562).

The seizure severity (SS) was determined from the behavioural seizure concomitant with

the AD elicited when determining the ADT in naive, partially kindled and fully kindled rats, and

scored according to a five-point ordinal scale (Figure 2e). Panx1 block did not change the mean

(+/- SEM) SS in naive rats (stage 0.88 +/- 0.35) compared to vehicle-treated controls (0.56 +/-

0.34; two-tailed unpaired t-test, p=0.3356), or in partially kindled rats (stage 1.4 +/- 0.40)

compared to vehicle-treated controls (stage 1.6 +/- 0.48; U = 17.00, p=1.000). However, Panx1

54

block significantly decreased the SS in fully kindled rats (stage 5.0 +/- 0.0) compared to vehicle-

treated controls (stage 3.5 +/- 0.87; U = 8.00, p=0.0492).

55

Figure 2. Acute Panx1 block decreases seizure severity and afterdischarge threshold (ADT) but

only in fully kindled rats. A) With repeated daily stimulation of the ventral hippocampus, the

elicited AD becomes longer. B) Sample traces of ADs elicited while determining the ADT under

control conditions and under Panx1 block in fully kindled rats. C) Panx1 block significantly

decreases ADT but only in fully kindled rat. D) Panx1 block has no effect on AD duration

(ADD). E) Panx1 block significantly decreases behavioural seizure severity, but only in fully

kindled rats.

56

Acute Panx1 block is anti-convulsant in the pilocarpine model

In order to determine the contribution of Panx1 to acute behavioural seizure, a Panx1

blocker (10

panx) or 0.9% saline vehicle were administered to 24 adult male Long-Evans rats

followed by the convulsant pilocarpine. Pilocarpine injection induced seizures in fewer rats

treated with 10

panx (4 of 12 total) than in rats treated only with saline vehicle (8 of 12). Of the

rats that exhibited seizures, administration of the Panx1 blocker significantly increased the mean

(+/- SEM; t=2.220, df=10, p=0.0253) latency to the first seizure (1642 +/- 422.4 seconds, N=4)

induced by pilocarpine, compared to the mean seizure latency of vehicle treated controls (815 +/-

166.8 seconds, N=8; Figure 3a). Further, treatment with Panx1 blocker significantly decreased

the mean (+/- SEM; t=2.236, df=10, p=0.0492) severity of the first seizure observed (stage 3 +/-

0.58, N=4) compared to vehicle controls (stage 4.5 +/- 0.4, N=8), and significantly decreased the

mean severity (t=2.066, df=10, p=0.0392) of the most severe recorded seizure (stage 3.8 +/-

0.6), compared to vehicle controls (stage 4.8 +/- 0.16; Figure 3c).

The Panx1 blocker did not significantly change the mean duration (+/- SEM) of either the

first seizure (t=0.1060, df=10, p=0.9177) or the sum duration of all seizure bouts in the total 60

minutes of observation (t=0.1004, df=10, p=0.9220) in rats treated with 10

panx (317.8 +/- 294.1

seconds and 650.3 +/-321.6 seconds, respectively), compared to vehicle controls (286.8 +/- 149.1

seconds and 692.1 +/- 246.3 seconds, respectively; Figure 3b).

57

Figure 3. Panx1 significantly increases seizure latency and decreases seizure severity in the

pilocarpine model of seizure and status epilepticus. A) The latency to the first observed

behavioural seizure is increased under acute Panx1 block. B) The severity of both the first

seizure and the most severe recorded seizure of only those rats exhibiting behavioural seizure are

decreased under acute Panx1 block. C) Panx1 block does not change the duration of the first

seizure nor the sum duration of all observed seizure bouts.

58

Panx1 block alters short-term plasticity but not excitability at SC-CA1 synapses

Field potentials were evoked by paired-pulse stimulation of the Schaffer collaterals

across a range of stimulus intensities in hippocampal slices obtained from both kindled and

sham-kindled rats. The percent increase in fEPSP slope with increasing stimulus intensity was

used as a measure of evoked potential magnitude standardized across samples by allowing the

rising slope of the potential evoked at 1000uA to be 100%. These results were analyzed with a

6x2 ANOVA to compare kindled and sham-kindled rats across the range of stimulus intensities

(Figure 4), and using a 6x3 ANOVA in kindled and sham-kindled rats (Figure 5).

Kindling does not alter evoked field potentials

A two-way ANOVA was conducted to examine the effect of increasing stimulation

intensity and kindling on the amplitude of the evoked field excitatory postsynaptic potential

(fEPSP) measured as the percent change in fEPSP slope from baseline. No significant

interaction between the two factors was observed (F(5,48)=0.07794, p=0.9953). Neither was

there a significant effect of stimulation intensity (F(1,48)=1.072, p=0.3058) or kindling (F(5,

48)=1.029, p=0.4114) on the percent change in fEPSP slope (Figure 4a,b).

Kindling does not alter evoked fEPSP PPR

A two-way ANOVA was conducted to examine the effect of increasing stimulation

intensity and kindling on the paired-pulse ratio of the evoked fEPSP as calculated by the quotient

of the percent increase of the second fEPSP slope over that of the first. No significant interaction

between the two factors was observed (F(5,48)=1.060, p=0.9318). Neither was there a significant

effect of stimulation intensity (F(1,48)=0.6552, p=0.2442) or kindling (F(5, 48)=1.167,

p=0.4079) on the percent change in fEPSP PPR (Figure 4c).

59

Figure 4. Kindling does not significantly change the amplitude of the field excitatory

postsynaptic potential (fEPSP) standardized to the slope of the stimulus-evoked potential at 1000

uA compared to sham-kindled controls across a range of stimulation intensities(B).

Representative traces of evoked potentials elicited with 300 uA stimulation are shown in A. C)

Kindling does not significantly alter the PPR of the standardized fEPSP slope across a range of

stimulation amplitudes.

60

Panx1 block does not alter evoked field excit ability in kindled or sham-kindled slices

A two-way ANOVA was conducted to examine the effect of increasing stimulation and

Panx1 block on the percent change in fEPSP slope from baseline in sham-kindled rats. No

significant interaction between the two factors was observed (F(10,71)=0.04903, p=1.000).

Neither was there a significant effect of stimulation intensity (F(5,71)=1.124, p=0.338) or Panx1

block (F(2, 71)=1.234, p=0.3025) on the percent change in fEPSP slope (Figure 5a).

A two-way ANOVA was conducted to examine the effect of increasing stimulation and

Panx1 block on the percent change in fEPSP slope from baseline in kindled rats. No significant

interaction between the two factors was observed (F(10,64)=0.1094, p=0.9997). Neither was

there a significant effect of stimulation intensity (F(5,64)=1.791, p=0.5260) or Panx1 block

(F(2,64)=0.6490, p=0.1272) on the percent change in fEPSP slope (Figure 5b).

Panx1 block does not alter evoked fEPSP PPR in kindled or sham-kindled slices

A two-way ANOVA was conducted to examine the effect of increasing stimulation and

Panx1 block on the percent change in fEPSP slope PPR from baseline in sham-kindled rats. No

significant interaction between the two factors was observed (F(10,65)=0.9947, p=0.8838).

Neither was there a significant effect of stimulation intensity (F(5,65)=0.8164, p=0.3778) or

Panx1 block (F(2, 65)=0.3960, p=0.9608) on the PPR of the percent change in fEPSP slope

(Figure 5c).

A two-way ANOVA was conducted to examine the effect of increasing stimulation and

Panx1 block on the percent change in fEPSP slope PPR from baseline in kindled rats. No

significant interaction between the two factors was observed (F(10,64)=0.8887, p=0.4056).

Neither was there a significant effect of stimulation intensity (F(5,64)=0.6273, p=0.3351) or

61

Panx1 block (F(2,64)=0.0.8015, p=0.9090) on the PPR of the percent change in fEPSP slope

(Figure 5d).

62

Figure 5. Panx1 block does not significantly alter the slope of the standardized fEPSP compared

to normal aCSF in either slices obtained from (A) sham-kindled or (B) kindled rats across a

range of stimulus intensities. Panx1 block does not alter the PPR of the slope of the standardized

fEPSP in either slices obtained from (C) sham-kindled or (D) kindled rats across a range of

stimulus intensities.

63

Neither kindling nor Panx1 block alter population spike amplitude

A two-way ANOVA was conducted to examine the effect of kindling and Panx1 block on

population spike amplitude elicited by a 200µA stimulus. No significant interaction between the

two factors was observed (F(2, 21)=0.1299, p=0.8789). Neither was there a significant effect of

kindling (F(1, 20)=0.4356, p=0.6526) nor Panx1 block (F(2,20)=0.7285, p=0.4030) on

population spike amplitude (Figure 6a).

Panx1 block but not kindling alters the population spike amplitude PPR

A two-way ANOVA was conducted to examine the effect of kindling and Panx1 block on

population spike amplitude PPR elicited by two 200µA stimuli delivered consecutively with a 50

msec interval. No significant interaction between the two main effects was observed

(F(2,20)=0.1353, p=0.8743). Further, kindling did not significantly alter population spike PPR

(F(1,20)=1.740, p=0.0395). However, a significant main effect of Panx1 block was observed

(F(2,20)=3.814, p=0.2020). Although Bonferroni-corrected follow-up tests failed to determine a

difference in any of the three comparisons (aCSF vs aCSF+10

panx, aCSF vs aCSF wash, or

aCSF+10

panx vs aCSF wash), the largest difference was between aCSF + 10

panx and aCSF wash

in kindled slices (t=1.991, p>0.05; Figure 6b).

64

Figure 6. A) Representative traces demonstrating paired-pulse facilitation under Panx1 block. B)

Panx1 block does not significantly change the amplitude of the population spike elicited at a

stimulation intensity of 200uA compared to those elicited under normal aCSF in slices either

obtained from control (sham-kindled) nor kindled slices. C) A significant main effect of

treatment with Panx1 blocker (10

panx) on the paired-pulse ratio of the population spike elicited in

acute hippocampal slices obtained from both control (sham-kindled) and kindled rats

65

DISCUSSION

I have discovered entirely novel contributions of the Panx1 channel to both seizure and

epileptogenesis. Here, I report the pioneering finding that the contribution of Panx1 to seizure

activity is not only changed following epileptogenesis, but that Panx1 also contributes to the

process of epileptogenesis itself. Further, the current study confirms the anti-convulsant

properties of Panx1 block in the pilocarpine model of seizure and status epilepticus. Finally, a

role for Panx1 in the short term plasticity of synchronous firing at SC-CA1 synapses was

revealed, but cannot explain the increase in excitability observed following Panx1 block in

kindled animals. However, further studies are required to elucidate the underlying mechanisms

which explain the many reported contributions of Panx1 to excitability at the population level

within the focus. As well, understanding the mechanism whereby Panx1 interference results in a

persistent decrease in epileptogenesis could offer many ways to prevent the ‘kindling’ of

epileptic tissue from initially mild convulsant insults.

Previous studies have explored the molecular basis for the observed role of Panx1 in

seizure activity in a number of models. Panx1 contributes to an in vitro model of interictal

bursting dependent on NDMAR-potentiation by removal of Mg2+

from the aCSF bath solution

alleviating the NMDAR pore-block by that ion. When Panx1 was blocked in this model, the

frequency and amplitude of the burst firing was reduced but not eliminated. The frequency and

amplitude of burst firing partially increased again upon wash off of the Panx1 peptide blocker

(Thompson et al, 2008). These results are consistent with a model in which Panx1 partially

mediates synchrony and excitability at the population level. They are also consistent with the

possibility that Panx1-mediated effect may be the result of a contribution of Panx1 to synaptic

activity following NMDAR stimulation. NMDAR stimulation results in a secondary inward

66

current that is mediated by Panx1 (Thompson et al, 2008), and although both Panx1 and

NMDAR are expressed extrasynaptically, the co-expression of Panx1 with PSD95 (a post-

synaptic scaffolding protein associated with NMDAR; Zoidl et al 2007) is consistent with a

model where NMDAR and Panx1 are closely associated at that subcellular location. This line of

evidence and reasoning was the initial impetus for subsequent studies to investigate the

contribution of Panx1 to seizure activity in vivo, including the present studies (Kawamura et al,

2010, Kim and Kang 2011, Santiago et al 2011).

Panx1 plays a role in mediating a multi-step mechanism of autocrine regulation in

hyperexcitable neurons (Kawamura et al 2010). In a series of experiments the researchers

demonstrate that Panx1 mediates a mechanism of purinergic autoregulation of CA3 neuronal

excitability. In conditions where sufficient ATP is present in neurons, Panx1 mediates a release

of ATP in response to a reduction of extracellular glucose (such as high neuronal activity). ATP

is hydrolysed to adenosine, and adenosine activates A1 receptors on the neuron releasing ATP as

well as its neighbours. Through G-protein coupled action, the A1R opens ATP-sensitive K+

channels at the post-synaptic site, causing a local hyperpolarization of neurons, reducing their

firing rate (Kawamura et al 2010). This is a potential mechanism of anti-convulsive action of the

ketogenic diet, since one of the conditions under which a reduction in extracellular glucose might

not result in a decrease in intracellular ATP is when carbohydrates are replaced by a high-fat,

high-protein diet producing ketone bodies (Kawamura et al, 2010). However, this study did not

explicitly investigate a mechanism whereby low extracellular glucose might open Panx1

channels (Kawamura et al 2010).

Despite these results demonstrating a role for Panx1 in decreasing neuronal excitability,

Panx1-mediated augmentation of aberrant, ictal-like burst firing via a mechanism whereby it

67

induces a secondary depolarizing inward current remained uncontested on the population and

single cell level (Thompson et al, 2008). Thus, further studies investigated the involvement of

Panx1 in seizure activity in vivo (Kim and Kang, 2011; Santiago et al 2011). The P2X7 receptor

is a member of a family of ionotropic receptors which open in response to ATP-binding

(‘purinergic’, Locovei et al 2007, Pelegrin and Surprenant 2006). It also uniquely responds to

purinergic stimulation by gradually opening the Panx1 channel (Pelegrin and Surprenant, 2006).

Using pharmacological and genetics interventions in mice, Kim and Kang (2011) demonstrated

that P2X7R inhibition increase seizure susceptibility in the Pilocarpine model of seizure and

status epilepticus. Furthermore, the researchers demonstrated that Panx1 block increased

behavioural seizure severity and EEG afterdischarge power, but did not do so above and beyond

the increased severity seen with P2X7R inhibition (Kim and Kang 2011). They propose a

mechanism whereby muscarinic acetylcholine M1 receptor stimulation by pilocarpine releases

inositol triphosphate (IP3) into the cytoplasm where it binds to IP3 receptors on the endoplasmic

reticulum to increase intracellular calcium resulting in Panx1 opening. Panx1 opening may

permit the efflux of IP3, limiting the M1 receptor-mediated responses. Furthermore, ATP efflux

through Panx1 activates P2X7Rs which both desensitizes M1Rs to limit the duration of IP3

production, and maintain Panx1 opening for the efflux of IP3 from the cell (Kim and Kang,

2011).

The effect of Panx1 targeting with a non-specific blocker as well as genetic knockouts

have been studied in an additional model of seizure and status epilepticus using the chemical

convulsant kainic acid (KA, Santiago et al 2011). In this series of experiments, elevated

extracellular potassium, such as is known to occur during seizure, was found to open Panx1

channels. The novel finding that glia express Panx1 in vivo was confirmed by immunolabelling

68

of Panx1 and glial fibrillary acidic protein (GFAP; a glial marker) in astrocytes in hippocampal

CA1 (Santiago et al 2011). Panx1-mediated dye flux was shown to increase during status

epilepticus, confirming that Panx1 opens during prolonged seizure activity. Finally, Panx1 block

was found to decrease seizure severity but not latency to forelimb clonus following KA

administration. These results are consistent with a proconvulsant role of Panx1 channels as

hypothesized from the early in vitro work (Santiago et al 2011, Thompson et al 2008) However,

results presented in this chapter demonstrate an increase in the latency to behavioural seizure

which was not observed by Santiago and colleagues (2011) which may be attributable to the

different criteria used by the studies. Whereas, Santiago and colleagues (2011) used forelimb

clonus onset as a metric of behavioural seizure susceptibility, the method adopted in this chapter

uses motor arrest as a metric, a behaviour which commonly occurs prior to unilateral forelimb

clonus (Racine 1972b). Motor arrest may thus be a more sensitive measure of behavioural

seizure initiation than forelimb clonus.

Here we report for the first time, the novel finding that a single administration of Panx1-

blocker is sufficient to significantly and persistently reduce kindling epileptogenesis. This

finding is particularly important for two reasons: 1) clinically-relevant anti-epileptogenic

therapies are currently an unmet clinical need and 2) no previous studies have successfully

identified an anti-epileptogenic effect following a single dose of anti-convulsant (see review

Pitkanen and Lukasiuk, 2011). The notion that some types of seizure disorders are progressive in

nature (that ‘seizures beget seizures’; Gowers, 1881), has been confirmed both in animal models

of seizure and epileptogenesis as well as in human populations (see review Pitkanen and Sutula,

2003;Ben-Ari et al 2008). Symptomatically-progressive epilepsy is most common in patients

experiencing seizures of temporal-lobe origin (Hauser, 2008). In one study, nearly 50% of

69

patients receiving anti-convulsant therapies continued to experience uncontrolled seizures after 3

years of therapeutic intervention, a subset of these patients experiencing progressive,

epileptogenic features such as increased seizure frequency and cognitive decline (Collaborative

Group for the Study of Epilepsy, 1994). These results presented in this chapter suggest that a

therapeutic intervention targeting the complex process of epileptogenesis can persistently

attenuate the progressive nature of seizure disorders, and may have the potential to improve the

quality of life for those continuing to live with this condition.

The mechanism by which Panx1 could mediate such a robust response remains an

important target of understanding for future research. The discovery and more detailed

description of the precise mechanism by which Panx1 acts to alter the course of epileptogenic

neuroplasticity not only has the potential to offer many possible therapeutic targets in addition to

the one described here, but also to offer a more precise understanding of the process itself. It will

be interesting to determine if Panx1 block of kindling epileptogenesis generalizes to other

models involving status epilepticus and traumatic brain injury. If this effect is confirmed in

additional models of epileptogenesis, it is likely to increase not only the clinical relevance of

these findings, but also provide additional platforms for the investigation of the specific

mechanism facilitating this novel effect.

It is likely that Panx1 mediates some mechanism which reads increases in neuronal

activity such as occur during seizure activity and translates them into persistent reorganization of

circuitry at the synaptic or population levels (Pitkanen and Lukasiuk, 2011). Future studies will

also investigate the mechanism by which Panx1 comes to be functionally recruited at the focus

and efferent circuits to provide its anti -and pro-convulsant modes, respectively. From the results

of the current study, the notion that Panx1 block can decrease seizure severity in the naïve state

70

and that this effect is increased following epileptogenesis are now established. However, the

system-level mechanism by which Panx1 differentially contributes seizure spread is currently

unknown.

CONCLUSION

The present study reveals the important and entirely novel finding that a single

administration of Panx1 blocker is sufficient to significantly and persistently attenuate the course

of kindling epileptogenesis. Further, it provides the additional novel insights that Panx1 block

decreases seizure severity in the pilocarpine model of seizure and status epilepticus as well as in

the kindling model following epileptogenesis. Panx1 was also found to both decrease and

increase seizure susceptibility, in the pilocarpine model and the kindling model following

epileptogenesis, respectively. Finally, kindling did not cause a change in Panx1-dependent

excitability or short-term plasticity at CA3-CA1 synapses. However, a novel Panx1-mediated

decrease in short-term plasticity of the population spike was discovered in slices from both

kindled and sham kindled rats. Together these results argue for the importance of Panx1 in

epileptogenesis as well as in acute seizure activity and synaptic plasticity.

71

CHAPTER 3 - GENERAL DISCUSSION

A researcher often attempts to rationalize the best model with which to study a particular

disease process in order to improve his or her odds of finding a result that has value and may be

published. Although researchers may simply attempt to pick the model which is most likely to

reveal a positive results, more often an attempt is made to pick a model which can clearly

provide an answer to a research question which is important or interesting regardless of whether

or not the null hypothesis is rejected. This can help to mitigate the risk of engaging in research

into important unknowns.

Of the experiments discussed in Chapter 2, by far the greatest risk was in investigating

the effect of Panx1 block on kindling epileptogenesis. No previous studies had investigated this

phenomenon, which made the positive result difficult to predict. Furthermore, the labour-

intensive nature of electrical kindling requires a commitment of one to two months of twice daily

stimulation sessions lasting approximately 10 minutes per animal. The animals must also survive

an early surgery in order to place a chronically implanted electrode and cannula into the

hippocampus and ventricle, respectively. The dental acrylic headcap that is generated is then

stressed daily with torsion when connecting the headcap to the EEG lead, as well as when the

animal experiences a stage 5 seizure. The animal repeatedly falls due to the loss of postural

control, oftentimes stressing the headcap, which can lead to electrode displacement, or loss of the

headcap entirely.

Specific strategies have been developed to mitigate some of the aforementioned risks. For

example, the use of a headcap having 6 anchoring screws helps to limit further restrict the range

of motion of the implanted electrode and prevents headcap loss. Other times, risks are absorbed

by the researcher. Regardless, the opportunity to investigate epileptogenesis in this finely

72

controlled model far outweighed these risks, and indeed the attempt revealed the most important

and novel finding of the study.

Another relatively high risk experimental design was the isolation of acute hippocampal

slices from kindled rats in order to study the contribution of Panx1 to field excitability and short

term plasticity in order to investigate the population level mechanism responsible for the changes

in pro- and anti-convulsant properties of the seizure focus following epileptogenesis. A

successful in vitro experiment requires the functional intersection of many moving parts. Noise

in the recording chamber must be at an appropriate level for the kind of recording being

attempted. The isolated tissue must be sufficiently healthy, solutions must be filled and flow

rates maintained between different solutions. If the slice shifts in the recording chamber, the

position of the electrode changes and a new input/output curve must be defined prior to

determining the effect of treatment solution. Again, each of these potential pitfalls can be

mitigated by engaging in useful strategies. For example, electrical noise was mitigated by

running aCSF solution through the recording chamber each morning before slicing, recording the

electrical noise, and attempting to ground it out. The electrical noise could not always clearly be

identified and eliminated by the time the slices had recovered, and experiments sometimes had to

be performed in less than ideal conditions. However, the risk often resulted in reward, and

through persistence, technical skill was developed. Ultimately this work revealed the entirely

novel result that Panx1 block acutely increases short term plasticity of the population spike but

not the field excitatory postsynaptic potential.

OTHER WORK

73

In the course of completing the above experiments, many other experiments were

attempted which were not included in the body of the work presented in Chapter 2. While

investigating the anti-convulsant effect of Panx1 block in the electrical kindling model, a fusion

peptide of a HIV transactivator of transcription (TAT) transduction domain (Console et al,

2003), and 10

panx (the peptide blocker of Panx1) was used. The addition of the TAT transduction

domain was used in order to facilitate the rapid delivery of the peptide blocker to the ventral

hippocampus prior to determining the ADT in the naïve, partially kindled or fully kindled states.

However, this resulted in behavioural abnormalities in the rats receiving the intervention, such

that they became very lethargic and easily startled. Furthermore, upon recording EEG from the

ventral hippocampus following administration of the TAT fusion peptide, spontaneous highly

synchronous, high amplitude firing was observed which was indistinguishable from the

afterdischarge induced by kindling stimulation. This effect was not observed when the TAT

domain or the 10

panx peptide were delivered alone or together in the same solution but not

covalently bonded. A version of the TAT fusion peptide where TAT was covalently bonded to a

version of 10

panx where the amino acids were reordered into a functionless arrangement

(“scrambled”) also produced similar behaviours and the appearance of spontaneous

electrographic afterdischarge, but much less frequently and for a much shorter duration than the

original TAT-10

panx convulsant agent. Indeed, it appears that this therapeutic intervention was

causing spontaneous seizures, rather than preventing them. Subsequently, 10

panx alone was used

to block Panx1 channels in vivo in order to avoid this potential confound.

The effect of TAT-10

panx-induced afterdischarge was briefly investigated in vitro as well.

Acute hippocampal slices were obtained from young naïve rats by the same method described in

Chapter 2. However, in this case spontaneous field activity, rather than evoked responses, was

74

recorded following wash-on of aCSF containing the TAT-10

panx. Increases in the frequency and

amplitude of spiking were observed. However, this response was determined from an early build

of the equipment used for electrophysiological recordings and the fast wash-on and wash-off

times seemed to indicate this in vitro finding might merely have been an artifact

In addition to studies involving evoked potentials in acute hippocampal slices outlined in

Aim 2 in Chapter 2, these same slices from kindled and sham-kindled animals were also exposed

to aCSF containing 0 Mg2+ following the experiments conducted in normal aCSF in order to

determine the change in NMDAR-activation-induced excitability in kindled slices following

Panx1 block. Evoked potentials were recorded from these slices in the same manner as described

in the methods section in Chapter 2. However, this was again from an early build of the

electrophysiology rig, and the responses obtained were unreliable. Often the stimulation artifact

would change dramatically, making the search for a maximized evoked response extremely

difficult. Ultimately, the recordings were too few and too unreliable to warrant inclusion in

Chapter 2. However, future studies might include such experiments in an effort to reveal changes

in local field excitability of the focus following kindling epileptogenesis.

Finally, I recruited Nick Weilinger of the Thompson Lab to also take slices from kindled

and sham-kindled animals for the purpose of studying changes in excitability and synaptic

plasticity at the single cell level using whole-cell patch clamp recordings following

epileptogenesis. The Schaffer collaterals were stimulated with a paired pulse protocol and

evoked excitatory post-synaptic currents (EPSCs) were recorded as well as spontaneous mini

EPSCs, following Panx1 block. The preliminary results from these studies detected no changes

in the evoked response between kindled and sham-kindled slices while Panx1 is blocked, but an

increase in the frequency of miniature EPSCs. These results seem to indicate that Panx1 block in

75

kindled slices induces an increase in presynaptic vesicle release probability without altering

excitability at the single cell level.

FUTURE STUDIES

The line of research with the most therapeutic potential but which had least been

investigated prior to the studies presented in the previous chapter is that of the contribution of

Panx1 to epileptogenesis. If a single Panx1 blocker infusion is sufficient to attenuate

epileptogenesis in other models of seizure and epileptogenesis (such as those involving

epileptogenesis following physical trauma or stroke), then the mechanism by which Panx1

mediates this change would also provide many new potential therapeutic targets. The same is

true of the mechanisms by which elevated extracellular potassium, glucose, NMDAR stimulation

and P2X7R stimulation open Panx1. Ultimately the cost/benefit analysis for these potential

therapies will be weighed in the clinic, but increased understanding of these mechanisms can

only serve to reduce the suffering and improve the lives of people living with epilepsy.

Additionally, an account of why Panx1 block decreases afterdischarge threshold

following kindling remains unknown. Although the current study reports an attempt to isolate

tissue from the kindling-stimulation seizure focus, Panx1 did not appear to alter excitability or

short term-plasticity at the candidate CA3-CA1 synapses differentially between kindled and

sham-kindled rats. Others have explored excitability at DG-CA3 synapses (Kawamura et al

2010), as well as EC-DG synapses (Kim and Kang 2011). An investigation of excitability and

STP may yield results in these alternative sites. Furthermore, an investigation of long-term

potentiation induced by trains of stimulation may elicit firing behaviour that is different between

kindled and non-kindled hippocampal tissue. The purpose of pursuing these differences is to

76

more tightly localize the differences in excitability between kindled and non-kindled that may

provide unique insight into repeated-seizure-induced changes in neuronal excitability. These

hypothetical characteristic differences will shed light on ways to prevent or attenuate such

changes.

77

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