Requirement for Q226, but not multiple charged residues,in the class I MHC CD loop/D strand for TCR-activated CD8 accessory function

Activation of CD8+ cytotoxic T lymphocytes typically begins with recognition of class I MHC-peptide complexes by the TCR and CD8 as a coreceptor. In its coreceptor role, CD8 binds thesame class I-peptide antigen complex as the TCR, enhancing the strength of TCR-class I interaction. Subsequent to initial TCR engagement, CD8 acts as an accessory molecule by binding any properly conformed class I molecules on the target cell surface, leading to CD8-mediated adhesion and cosignaling functions. We expressed and isolated a number of mutant class I molecules in which one or moreacidic or polar residues in the class I alpha3 domain CD loop and D strand region, or alpha2 domain were altered. Using solid phase CTL adhesion and degranulation assays with isolated class I molecules, we demonstrate that multiple acidic residues in the alpha3 domain, although involved in CD8 coreceptor interaction, are not required for TCR-activated CD8 accessory interactions. Instead, we show that Q226, a polar group on the end of the CD loop, is required for TCR-activated CD8 accessory functions. These results indicate that CD8 coreceptor and accessory interactions differ substantially and suggest that TCR activation results in changes that alter the structural constraints for CD8 accessory interactions.     

Role of alpha3 domain of class I MHC molecules in the activation of high- and low-avidity CD8+ CTLs

CD8 can serve as a co-receptor or accessory molecule on the surface of CTL. As a co-receptor, CD8 can bind to the alpha3 domain of the same MHC class I molecules as the TCR to facilitate TCR signaling. To evaluate the role of the MHC class I molecule alpha3 domain in the activation of CD8(+) CTL, we have produced a soluble 227 mutant of H-2D(d), with a point mutation in the alpha3 domain (Glu227 --> Lys). 227 mutant class I-peptide complexes were not able to effectively activate H-2D(d)-restricted CD8 T cells in vitro, as measured by IFN-gamma production by an epitope-specific CD8(+) CTL line. However, the 227 mutant class I-peptide complexes in the presence of another MHC class I molecule (H-2K(b)) (that cannot present the peptide) with a normal alpha3 domain can induce the activation of CD8(+) CTL. Therefore, in order to activate CD8(+) CTL, the alpha3 domain of MHC class I does not have to be located on the same molecule with the alpha1 and alpha2 domains of MHC class I. A low-avidity CD8(+) CTL line was significantly less sensitive to stimulation by the 227 mutant class I-peptide complexes in the presence of the H-2K(b) molecule. Thus, low-avidity CTL may not be able to take advantage of the interaction between CD8 and the alpha3 domain of non-presenting class I MHC molecules, perhaps because of a shorter dwell time for the TCR-MHC interaction.     

CD8 binding to MHC class I molecules is influenced by T cell maturation and glycosylation.

CD8 serves both as an adhesion molecule for class I MHC molecules and as a coreceptor with the TCR for T cell activation. Here we study the developmental regulation of CD8-mediated binding to noncognate peptide/MHC ligands (i.e., those not bound by the TCR). We show that CD8's ability to bind soluble class I MHC tetramers and to mediate T cell adhesion under shear flow conditions diminishes as double-positive thymocytes mature into CD8(+) T cells. Furthermore, we provide evidence that this decreased CD8 binding results from increased T cell sialylation upon T cell maturation. These data suggest that CD8's ability to interact with class I MHC is not fixed and is developmentally regulated through the T cell's glycosylation state.     

Antigen recognition by the T cell receptor is enhanced by CD8 alpha-chain binding to the alpha 3 domain of MHC class I molecules, not by signaling via the cytoplasmic domain of CD8 alpha.

The binding specificities and function of mouse CD8 were studied using a CD4-CD8- allospecific T cell hybridoma, chimeric class I MHC molecules, and a CD8 alpha deletion mutant. By transfecting the mouse CD8 alpha gene into a IL-2 producing, H-2Kb specific hybridoma, IL-2 production was increased when L cells expressing Kb were used as stimulators. However, no increase in IL-2 was observed when a KbKbB7 hybrid molecule, composed of the alpha 1 and alpha 2 domains of H-2Kb, and the alpha 3 domain of HLA-B7, was used as a stimulator. Comparison between T cell hybridomas that expressed full-length CD8 alpha and a deletion mutant lacking part of the cytoplasmic domain revealed identical responsiveness for H-2Kb. The data suggest that the mouse CD8 alpha homodimer does not bind to the alpha 3 domain of HLA class I molecules and that CD8 alpha acts as a co-receptor with the TCR by binding the same MHC molecule for alloantigen recognition. Our data also provide evidence that CD8 alpha signal transduction through its cytoplasmic tail by association with p56lck is not an absolute requirement for antigen recognition by T cells.     

The isolated major histocompatibility complex class I alpha3 domain binds beta2m and CD8alphaalpha dimers

The MHC class I molecule plays a crucial role in cytotoxic lymphocyte function. The heavy chain of the MHC class I molecule can form many non-covalent interactions with other molecules on multiple domains and surfaces. We have generated an isolated alpha3 domain of a murine MHC class I molecule and evaluated the contribution of this domain to binding with the MHC class I light chain, beta2m, and CD8. The alpha3 domain binds beta2m at a thousand-fold higher concentration than the whole MHC, and binds CD8alphaalpha with a dependence on the alpha3 CD loop. Our results are relevant for models of MHC folding and CD8-MHC function. The study of individual domains of complex molecules is an important strategy for understanding their dynamic structure and function.     

Thymus leukemia antigen (TL)-specific cytotoxic T lymphocytes recognize the alpha1/alpha2 domain of TL free from antigenic peptides

The thymus leukemia antigens (TL) belong to the MHC class Ib family and can be recognized by CD8-dependent or -independent cytotoxic T lymphocytes (CTL) showing TL, but not H-2, restriction. We previously reported that the CTL epitope is TAP independent and in the present study we further characterize the recognition mechanism of CD8-dependent TL-specific TCRalphabeta CTL. We first prepared empty TL tetramers by way of peptide-independent folding with recombinant proteins produced in an Escherichia coli expression system, and showed that TL-specific CTL recognized TL without putative TL-associated peptide and/or post-translational modifications of TL by mammalian and insect cells. We next prepared transfectants expressing various chimeric TL molecules with mouse or human MHC class I as well as chimeric TL tetramers with recombinant proteins produced by insect cells, and demonstrated that chimeric TL whose alpha3 domain was replaced by that of H-2K(b), but not of HLA-A2, was sufficient for binding and activation of TL-specific CTL. These results indicate that TL-specific CTL recognize predominantly their alpha1/alpha2 domain as an epitope(s) and that the binding activity to the murine CD8 of the alpha3 domain of H-2K(b) is sufficient to induce their CTL activity, although it is known to be weaker than that of TL, but stronger than that of HLA. The results taken together indicate that CD8-dependent TL-specific TCRalphabeta CTL recognize an epitope(s) of the alpha1/alpha2 domain of TL free from antigenic molecules, and that CD8 plays an important role in stable interactions between TL and their corresponding TCR.     

Co-capping studies reveal CD8/TCR interactions after capping CD8β polypeptides and intracellular associations of CD8 with p56lck

CD8 is a T cell surface glycoprotein that participates in recognition of peptide/MHC class I molecules by binding to their α3 domains. In addition, the cytoplasmic domain of CD8 associates with the intracellular tyrosine kinase p56^lck (lck) promoting recruitment of lck to the TCR signaling complex. Recent data have suggested also that CD8 may interact with the TCR to promote energetically favorable conformations which increase its ligand binding. We have used the techniques of co-capping and confocal microscopy to ask whether we can detect an association between CD8 and the TCR independently of their binding to MHC class I molecules. We show that capping CD8 heterodimers with antibodies to the CD8β polypeptide is significantly more efficient than antibodies to the CD8α polypeptide at inducing co-localization of TCR molecules with CD8, suggesting that there may be preferred conformations of CD8 which stabilize interactions with the TCR. In addition, we show by microscopy that intracellular lck redistributes very efficiently to the area of a CD8 cap, suggesting that there is a stronger association between lck and CD8 than has been proposed from immunoprecipitation analyses.     

The CD8alphabeta co-receptor on double-positive thymocytes binds with differing affinities to the products of distinct class I MHC loci

The CD8 co-receptor is essential for TCR-dependent immune recognition and T cell development involving peptides bound to MHC class I (MHCI) molecules. The dominant interaction of CD8 alpha alpha and alpha beta co-receptors is with the alpha3 domain of an MHCI molecule. Whether this interaction is different for the products of various MHCI loci is currently unknown. Here we examine the interaction between H-2K(b) and H-2D(b), the two MHCI molecules in the C57BL / 6 mouse, and CD8 using H-2K(b) and H-2D(b) tetramers. The MHCI molecules bind to the CD8alpha beta co-receptor on double-positive thymocytes with different avidities (H-2K(b) > D(b)). The differences are linked to their respective alpha3 domains. Hence, an H-2D(b)K(b) tetramer comprising D(b)alpha1--alpha2 and K(b)alpha3 domains shows more binding than H-2D(b). We also quantitated the monomeric affinities of CD8alpha alpha and CD8alpha beta for H-2K(b) and H-2D(b). The H-2K(b) interaction with CD8alpha alpha and CD8alpha beta is stronger than that of H-2D(b). Given that T cell repertoire selection of DP thymocytes is a function of both TCR-pMHCI and CD8alpha beta-pMHCI avidities, these differences may explain the dominant role of H-2K(b) as compared to H-2D(b) in CD8 T cell development of C57BL / 6 mice. The influence of allelic and non-allelic alpha3 polymorphisms on thymic selection processes are discussed.     

Memory CD8 T cells require CD8 coreceptor engagement for calcium mobilization and proliferation, but not cytokine production

Memory T-cell responses are faster and more robust than those of their naive counterparts. The mechanisms by which memory T cells respond better to subsequent antigenic exposure remain unresolved. A portion of the more rapid response is undoubtedly the result of the increased frequency of antigen-specific cells. In addition, there are also differences in the cells themselves with respect to their requirements for costimulation and the apparent avidity of the T cells. We used major histocompatibility complex (MHC) class I tetramers to stimulate T cells to focus on the interaction of T-cell receptor (TCR)/MHC and CD8 in the absence of other molecules that are present on cell surfaces and so contribute to the activation of T cells by undefined mechanisms. Mutated MHC class I tetramers that are unable to engage CD8 were used to investigate the role of CD8 engagement in memory cell activation. Either wild-type tetramers or tetramers carrying the mutation were used to stimulate both memory and naive TCR transgenic T cells in vitro. Surprisingly, like naive cells, memory CD8(+) T cells required CD8 engagement for calcium mobilization and optimum proliferation. In contrast, the requirements for cytokine production differed. Unlike naive cells, memory cells were able to produce cytokine in the absence of CD8 engagement. This suggests both a CD8-dependent pathway for early events and a CD8-independent pathway for cytokine production in memory cells.     

T cell receptor and coreceptor CD8 alphaalpha bind peptide-MHC independently and with distinct kinetics

The T cell surface glycoprotein CD8 enhances T cell antigen recognition by binding to MHC class I molecules. We show that human CD8 alphaalpha binds to the MHC class I molecule HLA-A2 with an extremely low affinity (Kd approximately 0.2 mM at 37 degrees C) and with kinetics that are between 2 and 3 orders of magnitude faster than reported for T cell receptor/peptide-MHC interactions. Furthermore, CD8 alphaalpha had no detectable effect on a T cell receptor (TCR) binding to the same peptide-MHC class I complex. These binding properties provide an explanation as to why the CD8/MHC class I interaction is unable to initiate cell-cell adhesion and how it can enhance TCR recognition without interfering with its specificity.     

T cell activation and thymic tolerance induction require different adhesion intensities of the CD8 co-receptor.

Activation of mature lymphocytes requires in addition to the TCR contact with the corresponding antigen the binding of the CD8 or CD4 co-receptors to MHC class I or class II proteins respectively. To investigate the contribution of the CD8-class I interaction to the elimination of autoreactive T cells during negative selection in the thymus we generated two types of transgenic mice. One set expressed a modified Kb molecule which contained a human HLA-A2 alpha 3 domain, thereby missing the binding residues for the murine CD8 molecules. The second set of mice expressed an anti-Kb specific TCR. Both lines were crossed and in the resulting double transgenic mice the development of Kb-reactive T cells was followed with an anti-clonotypic antibody. Surprisingly, efficient clonal deletion in the thymus was still observed, although the reduced CD8-class I adhesion abrogated effector functions in vivo and in vitro. These results imply that even T cells with intermediate affinity for self are negatively selected in the thymus despite the fact that they are not able to react against self antigens in the periphery. Thus a safety window is created which decreases the risk of autoaggression.     

Interactions between CD8alphabeta and the TCRalphabeta/CD3-receptor complex

CD8+ T cells recognize antigenic peptides bound to major histocompatibility complex (MHC) class I molecules on normal antigen-presenting cells (APC), as well as on virus-infected cells or tumour cells (pMHC). At least two receptor types participate in recognition of these complexes: T-cell receptor (TCR) alphabeta heterodimers and CD8alphabeta molecules. The former molecules react with antigenic peptide and variable regions of MHC class I molecules, whereas the latter molecules react with constant alpha3 regions of MHC class I molecules. As the avidity of both receptor-MHC interactions is low, it is believed that TCRalphabeta and CD8alphabeta heterodimers collaborate in T-cell recognition. We have established a TCR/CD3-CD8 capture ELISA, which can measure the interaction of pMHC with CD8alphabeta molecules and with TCR/CD3 complexes. The major findings are: (1) TCR/CD3 complexes derived from in vitro activated T cells and captured by anti-CD3 MoAb, do bind specific pMHC and (2) CD8+ T cells express at least three forms of CD8alphabeta molecules: single CD8alphabeta, CD3-CD8 and TCR/CD3-CD8 complexes. Only the latter complexes are associated with CD3zeta homodimers, and the quantity of TCR/CD3-CD8 complexes relative to total CD8alphabeta molecules appears to increase and to be selected into sucrose-gradient microdomains as a function of TCRalphabeta-mediated T-cell activation.     

Human CD8 co-receptor is strictly involved in MHC-peptide tetramer-TCR binding and T cell activation.

Although there has been extensive analysis on the capacity of MHC-peptide tetramers to bind antigen-specific TCR, there have been comparatively few studies regarding the role of the CD4 and CD8 co-receptors in binding and activation by these multimeric molecules. Here, we start from the observation that different antibodies against human CD8 exert opposite effects on MHC-peptide tetramer binding to the TCR: tetramer staining was enhanced by OKT8 antibody, while it was blocked with SK1 antibody. We used these different anti-CD8 antibodies to modulate CD8 function during tetramer staining of Melan-A/MART1-specific CTL clones. We show that CD8 action could be variably modulated during all the phases of interaction, indicating that CD8 participates in both the initial association of the TCR with MHC-peptide tetramers and the stability of this interaction. While the blocking effect of anti-CD8 antibodies was mostly exerted during the initial binding of the TCR with MHC-peptide tetramers, the enhancing effect was exerted by augmenting the duration of this interaction. Blocking anti-CD8 antibodies were also capable of preventing tetramer-mediated T cell activation. The possibility of variably affecting MHC-peptide tetramer binding and T cell activation using anti-CD8 antibodies confirms the critical role exerted by the CD8 co-receptor in this interaction and supports the notion that TCR engagement by MHC-peptide ligands typically involves CD8.     

In vivo receptor-mediated delivery of a recombinant invasive bacterial toxoid to CD11c + CD8 alpha -CD11bhigh dendritic cells

The precise contribution of mouse dendritic cells (DC) CD8 alpha +CD11blow and CD8 alpha -CD11bhigh subsets to CTL priming is not fully defined. Here we show that CyaA, the adenylate cyclase toxin of Bordetella pertussis, an invasive bacterial toxin that binds cells through CD11b/CD18 can be exploited for the targeted delivery of an exogenous peptide to the CD8 alpha -CD11bhigh subset in vivo. Antigen (Ag) genetically inserted in the N-terminal domain of mutant CyaA devoid of catalytic activity, are targeted to CD8 alpha -CD11bhigh DC by the CD11b/CD18-dependent binding of CyaA to the cell surface. Ag is then presented by MHC class I molecules of CD8 alpha -CD11bhigh DC after a TAP-dependent, cytosolic processing. As a result, CTL are primed after a single injection, bypassing requirement for adjuvant, CD4+ T cell help and CD40 signaling. Beside the interest of the CyaA vector for vaccine development, these results show that Ag presentation focused on CD8 alpha -CD11bhigh DC in vivo is sufficient for eliciting a vigorous CTL response and that CD11b/CD18 could be a suitable surface molecule for targeting Ag to DC.     

The crystal structure of a TL/CD8alphaalpha complex at 2.1 A resolution: implications for modulation of T cell activation and memory

TL is a nonclassical MHC class I molecule that modulates T cell activation through relatively high-affinity interaction with CD8alphaalpha. To investigate how the TL/CD8alphaalpha interaction influences TCR signaling, we characterized the structure of the TL/CD8alphaalpha complex using X-ray crystallography. Unlike antigen-presenting molecules, the TL antigen-binding groove is occluded by specific conformational changes. This feature eliminates antigen presentation, severely hampers direct TCR recognition, and prevents TL from participating in the TCR activation complex. At the same time, the TL/CD8alphaalpha interaction is strengthened through subtle structure changes in the TL alpha3 domain. Thus, TL functions to sequester and redirect CD8alphaalpha away from the TCR, modifying lck-dependent signaling.     

Role of phosphoinositide 3-kinase in TCR-signaled regulation of CD8-mediated adhesion to class I MHC protein.

CD8 must be activated by signaling through the TCR in order to mediate CTL adhesion. Up-regulation of adhesion to class I protein is shown to be blocked by specific inhibitors of phosphoinositide 3-OH kinase (PI3-K), indicating a critical role for this enzyme in signaling for activation of CD8. A minimal TCR stimulus that activates CD8 does not result in a detectable increase in total cellular PI3-K activity, but an increase in PI3-K activity associated with p59(fyn) kinase can be detected. Genistein blocks this increase concomitantly with blocking the activation of adhesion, suggesting that activation of fyn-associated PI3-K is downstream of TCR-dependent activation of protein tyrosine kinase(s) in the signaling pathway that leads to up-regulation of CD8-dependent adhesion. Treatment of cells with phorbol ester also blocks the TCR-dependent increase in fyn-associated PI3-K and inhibits CD8-dependent adhesion. This suggests a feedback model for deactivation of CD8 adhesion to allow target cell release by CTL and recycling to kill additional targets. In contrast, phorbol ester treatment up-regulates integrin-mediated adhesions, suggesting complex cross-talk between the TCR and the different adhesion/cosignaling receptors during the binding and killing of antigen-bearing targets.     

Location of the epitope for an anti-CD8alpha antibody 53.6.7 which enhances CD8alpha-MHC class I interaction indicates antibody stabilization of a higher affinity CD8 conformation

MHC class I tetramers are widely used, usually in combination with an antibody to CD8, to detect antigen specific T cells. Some anti-CD8alpha antibodies block the interaction of murine MHC class I tetramers with CD8 T cells, while others such as 53.6.7, enhance. To understand the molecular basis for this effect, we mapped the epitope for the enhancing antibody 53.6.7 and three other blocking antibodies using a panel of murine CD8alpha (Lyt-2) mutants expressed on COS-7 transfectants. Mutations in residues that contact MHC class I affected binding of the blocking antibodies. In contrast, antibody 53.6.7 was affected by a mutation in the residue T81A located on the D-E loop. In the cocrystal of CD8alphaalpha with MHC class I, two different complexes (A and B) were observed, indicating the existence of different CD8 conformations. The T81 residue does not make contact with MHC class I in either complex, however, neighboring residues in the D-E loop make very different contacts in the two different complexes. The most likely explanation for antibody enhancement of tetramer bindings is that binding of 53.6.7 to CD8alphabeta stabilizes a conformation with a higher affinity for interaction with MHC class I and suggests that the CD8 binding site is flexible.     

A correlation between TCR Valpha docking on MHC and CD8 dependence: implications for T cell selection

T cell receptors (TCR) adopt a similar orientation when binding with major histocompatibility complex (MHC) molecules, yet the biological mechanism that generates this similar TCR orientation remains obscure. We show here the cocrystallographic structure of a mouse TCR bound to a human MHC molecule not seen by the TCR during thymic development. The orientation of this xenoreactive murine TCR atop human MHC deviates from the typical orientation more than any previously determined TCR/MHC structure. This unique orientation is solely due to the placement of the TCR Valpha domain on the MHC. In light of new information provided by this structure, we have reanalyzed the existing TCR/MHC cocrystal structures and discovered unique features of TCR Valpha domain position on class I MHC that correlate with CD8 dependence. Finally, we propose that the orientation seen in TCR recognition of MHC is a consequence of selection during T cell development.     

Restoring the association of the T cell receptor with CD8 reverses anergy in human tumor-infiltrating lymphocytes

For several days after antigenic stimulation, human cytolytic T lymphocyte (CTL) clones exhibit a decrease in their effector activity and in their binding to human leukocyte antigen (HLA)-peptide tetramers. We observed that, when in this state, CTLs lose the colocalization of the T cell receptor (TCR) and CD8. Effector function and TCR-CD8 colocalization were restored with galectin disaccharide ligands, suggesting that the binding of TCR to galectin plays a role in the distancing of TCR from CD8. These findings appear to be applicable in vivo, as TCR was observed to be distant from CD8 on human tumor-infiltrating lymphocytes, which were anergic. These lymphocytes recovered effector functions and TCR-CD8 colocalization after ex vivo treatment with galectin disaccharide ligands. The separation of TCR and CD8 molecules could be one major mechanism of anergy in tumors and other chronic stimulation conditions.     

The roles of CD4 and CD8 in T cell activation

CD4 and CD8 T cell surface molecules play a role in T cell recognition and activation by binding to their respective class II and class I major histocompatibility complex (MHC) ligands on an antigen presenting cell (APC). Though CD4 and CD8 are capable of binding to MHC molecules in the absence of the T cell receptor (TCR), increasing evidence suggests that they may primarily function by complexing with the TCR to form a 'co-receptor' for recognition of antigen-bound MHC. Using gene transfer studies we have demonstrated that CD4 and CD8 can augment antigen-induced IL-2 production through different mechanisms dependent on whether or not they can bind MHC independently of the TCR or complexed with the TCR. Under circumstances where CD4 and CD8 can bind to the same MHC ligand as the TCR, they potentiate antigen-induced IL-2 production maximally by a mechanism in large part dependent on their cytoplasmic tails. Enhancement of antigen-induced IL-2 production can also occur under circumstances where CD4 and CD8 bind on MHC ligand distinct from that recognized by the TCR. In this instance, the magnitude of this enhancement is not as great and appears (at least for CD8) to be independent of the cytoplasmic tail and the associated p56lck. The dependence of co-receptor function on the cytoplasmic tail of CD4 or CD8 may reflect the activity of the associated intracellular tyrosine kinase p56lck.(ABSTRACT TRUNCATED AT 250 WORDS)