role of costimulation in immune response
TRANSCRIPT
Role of Costimulation in Immune Response
2003. 4. 9.
Yong-Hoon Chung, MD, PhD
Department of Microbiology Hanyang Univ College of Medicine
Central Tolerance vs Peripheral Tolerance
Costimulation of antigen and co-receptoractivated T cells
Antigen-receptor and co-receptor ligation are ofteninsufficient for proliferation and the expression of effector function
AntigenRecognition Y
FDC
B
APC
Th
SIGNAL 1:
B7.1/2
APC
IL-1, IL-12IFN-SIGNAL 1
Antigen recognition & co-receptor ligation
Co-stimulation of T helper cells byprofessional APC
Signal 1 & signal 2 are required for T cell clonal proliferationand differentiation to effector cells
Processing
SIGNAL 2Cognate T-professional APCco-stimulatory interaction
APC activationinduces B7 costimulatory
molecules on B cells
Th
CD28
Low affinity IL-2 Receptor- and chains
IL-2
IL-2R
Resting T cell
Mechanism of co-stimulation in T cells
1 2
IL-2
IL-2R
Signal 1 + 2
Increases IL-2 transcriptionand stabilises IL-2 mRNA
Signal 1
Induction of high affinityIL-2R
High affinity IL-2 Receptor- and chains
1
IL-2
IL-2R
Cross-linking of CD28by B7 co-stimulatesand induces CTLA-4
Costimulatory molecules also associatewith inhibitory receptors
CTLA-4 binds CD28 with a higher affinity than B7 moleculesto shut down the T cell response.
Cross-linking of CTLA-4by B7 inhibits co-stimulationand inhibits T cell activation
2- - -
CD28
B7
Activated T cell
-
CD28
2 2T cell
B7
Signal—
Co-stimulation in the induction of T cell anergy
T
Epithelial cellexpressingself antigen
SIGNAL 1 ONLY
T
Epithelial cellexpressingself antigen
ANTIGEN SPECIFICUNRESPONSIVENESS
Professional APCpresenting
foreign antigen
SIGNAL 1 AND 2
RESPONSE
T
CD28
B7
Fig. 1. PD-L¯PD-1 and other B7¯CD28 family members. The structures, interactions and functions of five of each of B7 ligand and CD28 family members are depicted schematically. aa indicates the number of amino acid residues of the cytoplasmic tail. Y represents a tyrosine residue.+ and - indicate costimulatory and coinhibitory signaling, respectively. Molecular weights are those of the glucosylated form. CD28, CTLA-4 & ICOS are homodimers. ind, inductive; M, monocyte; APC,antigen-presenting cell; EC, extracellular doman.
Table 1. The B7 family of costimulatory ligands
Fig. 2. Role of NKG2D engagement in human and mouse NK cells. (a) Ignorance: normal cells are spared from NK cell cytolytic activity, by signals (-) from MHC I specific inhibitory receptors(inh NKR, dark blue). Inhibitory NKR include CD158 (KIR-L) & CD85j(LIR1/ILT2) in humans, inhibitory Ly49 in mice & CD94¯NKG2A heterodimers in both species. In no stress, most cells don’t express ligands for NKG2D & same for ligands of NCR. Activating signals can be mediated, beside NCR, also by activating NKR; these are not shown but include activating CD158(KIR-S) in humans, Ly49D, Ly49H and Ly49P in mice and CD94¯NKG2C heterodimers in both species. (b) Tolerance: upon distress, cells may express only low levels of NKG2D ligands (NKG2D-L, light green), ligands of NCR (NCR-L, light red) & ligands for activating NKR(not shown). In these conditions, the inhibitory signal (-) initiated by engagement of inhibitory NKR overcomes activation signals (+). (c) Elimination: this can be mediated (i) via costimulation or (ii) after `primary recognition'. (i) Cellular distress inhibit MHC I expression & upregulation of NKG2D-L & also NCR-L(ligands of activating NKR). These modifications allow NK activation via NKG2D & NCR(NKR), which cooperate to overcome inhibitory signals mediated by NKR. (ii) Stressed cells expressing low levels of NCR-L (ligands of activating NKR), but hi levels of NKG2D-L, are eliminated by NK cells solely via NKG2D engagement.
0
Importance of ICOS–B7RP-1 costimulation in acute and chronic allograft rejectionÖzkaynak, E. et al. Nature Immunology 2, 591 - 596 (2001)
Figure 2. Blockade of ICOS–B7RP-1 costimulation inhibits acute allograft rejection. (a) The anti-ICOS mAb 12A8 did not deplete ICOS+ T cells, as shown by flow cytometric analysis of splenocytes 24 h after intraperitonal injection of mAb (200 g). Staining of splenocytes with a secondary (2°) antibody alone (mouse anti–rat IgG2b) detected anti-ICOS bound to CD3+ splenic T cells in treated, but not control, mice. Additional mAb increased T cell staining only marginally (upper right panel) and untreated mice had similar numbers of ICOS+ T cells (lower right panel) as animals receiving anti-ICOS therapy. (b) Northern analysis compared expression of ICOS and B7RP-1 RNA in control hearts versus cardiac allografts collected at day 7 after transplant from recipients treated with IgG or a blocking anti-ICOS (mAb 12A8). A murine GAPDH cDNA fragment was used as a control for loading (data are representative of three grafts per group). Beginning at the time of engraftment, wild-type (ICOS+/+) allograft recipients were treated daily for 14 days with (c) anti-ICOS or (d) ICOS-Ig fusion protein and monitored daily to determine the effects of therapy on allograft survival. Allograft survival in ICOS-/- recipients was also prolonged. Survival data are mean s.d. and are representative of six animals per group. *P<0.005 compared to other groups, as determined using Mann-Whitney U test
In vivo stimulation of CD137 broadens primary antiviral CD8+ T cell responses Halstead, E. S. et al. Nature Immunology 3, 536 - 541 (2002)
Figure 4. Effects of in vivo CD137 stimulation on the immunodominant NP(366–374) CD8+ T cell response in CD28-/- mice. Pulmonary lymphocytes were collected 10 days after intranasal infection with influenza virus and were stained with CD8 mAb and Db–NP(366–374) tetramers. (a) Representative flow cytometry plots are shown. Numbers indicate the percentages of CD8+ T cells that stained positive for the NP(366–374) tetramer. Pooled data from five independent experiments (n = 12 in each group) show cells that stained positive for CD8 and NP(366–374) tetramer as a measure of (b) total CD8+ T cells (c) total lymphocytes and (d) the absolute numbers of NP(366–374)-specific CD8+ T cells. (e) Representative experiment showing cytotoxicity of pulmonary lymphocytes against NP(366–374) peptide–loaded target cells.
Signaling through OX40 (CD134) breaks peripheral T-cell tolerancePratima Bansal-Pakala et al. Nature Medicine 7, 907 - 912 (2001)
Figure 2: OX40 signals, provided at the time of soluble antigen exposure, promote T-cell expansion and prevent induction of hypo-responsiveness. Recipients of V3/V11 CD4 T cells were tolerized with soluble peptide and treated with anti-OX40. a, Accumulation of V3/V11 CD4+ cells after 10 d in mice injected with PBS alone (bottom), or soluble peptide and either control IgG (middle) or anti-OX40 (top) given on day 2. Values represent means of 3 individual mice per group s.e.m. b, Accumulation of V3/V11 CD4+ cells after 17 d with mice challenged on day 10 with peptide in CFA. Mice initially injected with PBS (second bottom), or soluble peptide and either control IgG (second top) or anti-OX40 (top) given on day 2. Controls receiving PBS with no peptide/CFA challenge (bottom). Values represent means of 3 individual mice per group s.e.m. c and d, Proliferation (c) and IL-2 production (d) per V3/V11 CD4+ T cell after restimulation in vitro with peptide on day 17. Comparison between T cells from mice challenged on day 10, after initial injection with PBS alone () versus soluble peptide and either control IgG () or anti-OX40 (). IL-2 values are from pooled triplicate cultures. Similar results were seen in 2 separate experiments.
Inhibition of natural killer cells results in acceptance of cardiac allografts in CD28-/- mice Stefan Maier et al. Nature Medicine 7, 557 - 562 (2001)
Figure 5: Depletion of NK-receptor–bearing cells leads to prolonged survival of allogeneic cardiac grafts in CD28-/- recipients. a, Number of circulating DX5+CD3- NK cells in anti-NK1.1– or control-treated recipients. The percentage of NK cells was monitored in peripheral blood on day -4 (prior to antibody treatment) and on days 1 and 4 after treatment. b, Allograft survival in anti-NK1.1–treated H-2b, CD28-/- recipients (), anti-NK1.1–treated H-2b, CD28+/+ recipients () and control-treated H-2b, CD28-/- recipients () after transplantation of allogeneic (BALB/c, H-2d) cardiac grafts. c, Histological analysis of explanted allogeneic cardiac grafts after transplantation (as in Fig. 1b). Explantation of cardiac grafts was at day 5
Cellular Expression of costimulatory molecules
Constitutive
Early (activation)
Late (activation)
naïve T Cell
CD28 LFA-1 CD2
CD40L CD27
OX40 4-1BB ICOS LIGHT
APC
ICAM-1 LFA-3 CD40 B7RP-1
B7/1 B7/2 CD70 CD40
OX40 L 4-1BB L ICOS L HVEM
Positive/Negative Role of costimulatory molecules
Superfamily Positive Regulator Negative Regulator
Ig CD28 ICOS CD2
CTLA-4 PD-1
TNFR CD40 OX40 4-1BB LIGHT CD27 RANKL GITR
Fas DR4/5
Cytokine TNFR IL-2 IL-15 IL-12 IL-1
IL-4 IL-10