The majority of postselection CD4+ single-positive thymocytes requires the thymus to produce long-lived, functional T cells.

We have previously isolated, and characterized in vitro, two subsets of CD4hi T cell receptor (TCR)hi single positive (SP) thymocytes: CD8- and CD8lo. In this report, we have analyzed phenotypic, functional, and developmental characteristics of these "late" CD4hi SP thymocyte subsets. The TCRhi phenotype and the elimination of T cells expressing TCR V beta segments reactive with endogenous mouse mammary tumor virus (MMTV) products suggested that both subsets had undergone positive and negative selection. CD8-4hi thymocytes were functional, as judged by their ability to: (a) induce lethal graft versus host disease (GVHD); (b) survive and expand in peripheral lymphoid organs; and (c) proliferate, rather than undergo apoptosis, in response to in vitro TCR cross-linking. By contrast, CD8lo4hi cells could not induce GVHD, were unable to expand (and perhaps even survive) in peripheral organs and underwent apoptosis upon TCR cross-linking. However, when reintroduced into the thymus, these cells matured into functional, long-lived CD8-4hi lymphocytes. These results document an obligatory requirement for the thymic microenvironment in the final maturation of the majority of CD4hi SP postselection thymocytes, and demonstrate the existence of a previously unrecognized control point in T cell development.

The final maturation of at least some single-positive CD4(hi) thymocytes does not require T cell receptor-major histocompatibility complex contact.

The majority ( approximately 70%) of postselection CD4(+) single-positive (SP) thymocytes are CD8(lo)CD4(hi). These cells express very low levels of CD8, undetectable by flow cytofluorimetric (FCM) analysis, but sufficiently high to allow purification by panning. Unlike the fully mature CD8(-)CD4(hi) thymocytes, which account for the remaining approximately 30% of the SP CD4(+) thymocytes, CD8(lo)CD4(hi) cells are functionally immature and short-lived unless they receive an unidentified maturation signal from the thymus. In this study, we tested the hypothesis that this signal is provided by a T cell receptor (TCR)-major histocompatibility complex (MHC) class II interaction. Using intrathymic transfer, we show that the immature CD8(lo)CD4(hi) cells could complete their intrathymic maturation and populate the peripheral lymphoid organs in the absence of MHC class II (and class I) molecules. Furthermore, in mice devoid of class II (and class I) molecules, the progeny of CD8(lo)CD4(hi) cells was long-lived and functionally reactive to allogeneic class II molecules, although their numbers in the spleen and the mesenteric lymph node were approximately 40-50% lower than those in class II(+) mice 5 mo after transfer. Control experiments demonstrated that the surviving cells did not originate from the contaminating mature thymocytes. These results demonstrate that the final maturation, proliferation, and peripheral survival (up to 5 mo) of at least some postselection CD4(+) SP cells do not require the TCR-MHC class II interaction. They also indicate that the TCR-MHC class II interaction(s) required for the intrathymic development of long-lived CD4(+) SP cells occurs before the CD4(hi) SP stage of development.

Immature thymocytes become sensitive to calcium-mediated apoptosis with the onset of CD8, CD4, and the T cell receptor expression: a role for bcl-2?

During intrathymic negative selection by clonal deletion, crosslinking of the T cell receptor (TCR) induces cell death by delivering an apoptotic signal(s) to the nucleus along a calcium-dependent pathway. We investigated the reactivity of early precursor-containing thymocytes to Ca(2+)-induced signals, and discovered a breakpoint in their sensitivity to calcium-mediated cell death (CMCD). CD25+CD8-4- TCR- (triple negative [TN]) thymocytes stimulated with a calcium ionophore maintain their viability and precursor activity. By contrast, their immediate progeny, CD25-CD8lo4loTCR alpha beta lo (triple low [TL]) cells react to calcium elevation by abrogation of precursor activity and apoptotic cell death. This developmental difference is specific for CMCD, since both CD25+TN and CD25-TL cells are susceptible to steroid-induced apoptosis. The presence of bcl-2 mRNA correlates directly to the resistance to CMCD-CD25+ TN cells express it and CD25-TL cells do not. These experiments show that thymocytes become sensitive to Ca(2+)-induced apoptosis as soon as they begin to express molecules that mediate thymic selection, and suggest that a concomitant downregulation of bcl-2 may mediate this phenomenon.

T cell receptor (TCR) recognition of MHC class I variants: intermolecular second-site reversion provides evidence for peptide/MHC conformational variation.

We investigated mechanistic differences in antigen presentation between murine MHC class I variants H-2K(b) and H-2K(bm)8. H-2K(bm)8 differs from H-2K(b) by four residues at the floor of the peptide-binding site, affecting its B pocket which interacts with the second (P2) residue of the peptide. The rest of the molecule, including the T cell receptor (TCR)-contacting residues, is identical to H-2K(b). Due to this variation, CTLs that recognize the ovalbumin 257-264 and HSV gB 498-505 peptides on H-2K(b) cannot recognize them on H-2K(bm)8. This could be due to impaired peptide binding or an altered peptide: K(bm)8 conformation. Peptide binding studies ruled out the first explanation. Molecular modeling indicated that the most obvious consequence of amino acid variation between peptide/H-2K(b) and peptide/H-2K(bm)8 complexes would be a loss of the conserved hydrogen bond network in the B pocket of the latter. This could cause conformational variation of bound peptides. Intermolecular second-site reversion was used to test this hypothesis: P2-substituted OVA and HSV peptides, engineered to restore the hydrogen bond network of the B pocket, were the only ones which restored CTL recognition. These results provide a molecular understanding of peptide/MHC conformational variation.

Massive upregulation of the Fas ligand in lpr and gld mice: implications for Fas regulation and the graft-versus-host disease-like wasting syndrome.

Fas-deficient lpr and gld mice develop lymphadenopathy due to the accumulation of T cells with an unusual double negative (DN) (CD4-CD8-) phenotype. Previous studies have shown that these abnormal cells are capable of inducing redirected lysis of certain Fc receptor-positive target cells. Since the Fas ligand (FasL) has recently been shown to be partly responsible for T cell-mediated cytotoxicity, lymph node cells from lpr and gld mice were examined for the expression of FasL mRNA. Northern blot analysis revealed that lymph node cells obtained from lpr and gld mice had a striking increase in the level of expression of FasL mRNA predominantly due to expression in the DN T cells. Furthermore, lpr, but not gld lymph node cells killed the B cell line, A20, in a Fas-dependent manner. These findings indicate that Fas mutations result in a massive up-regulation of FasL which, most likely, results from repetitive exposure to (self) antigen. This phenomenon could explain the lpr-induced wasting syndrome observed when lpr bone marrow-derived cells are adoptively transferred to wild-type recipients.

Heteroclitic immunization induces tumor immunity.

In tumor transplantation models in mice, cytotoxic T lymphocytes (CTLs) are typically the primary effector cells. CTLs recognize major histocompatibility complex (MHC) class I-associated peptides expressed by tumors, leading to tumor rejection. Peptides presented by cancer cells can originate from viral proteins, normal self-proteins regulated during differentiation, or altered proteins derived from genetic alterations. However, many tumor peptides recognized by CTLs are poor immunogens, unable to induce activation and differentiation of effector CTLs. We used MHC binding motifs and the knowledge of class I:peptide:TCR structure to design heteroclitic CTL vaccines that exploit the expression of poorly immunogenic tumor peptides. The in vivo potency of this approach was demonstrated using viral and self-(differentiation) antigens as models. First, a synthetic variant of a viral antigen was expressed as a tumor antigen, and heteroclitic immunization with peptides and DNA was used to protect against tumor challenge and elicit regression of 3-d tumors. Second, a peptide from a relevant self-antigen of the tyrosinase family expressed by melanoma cells was used to design a heteroclitic peptide vaccine that successfully induced tumor protection. These results establish the in vivo applicability of heteroclitic immunization against tumors, including immunity to poorly immunogenic self-proteins.

Priming for T-cell-mediated rejection of established tumors by cutaneous DNA immunization.

DNA immunization has been shown to elicit both antibody and CTL responses against antigens expressed by infectious organisms. Because CTL responses have been implicated in rejection of cancer, we investigated whether DNA immunization by particle bombardment using a gene gun could induce CTL responses that were capable of rejecting tumors in mice. DNA immunization by particle bombardment using genes encoding beta-galactosidase and ovalbumin primed mice to generate CTLs in two genetic backgrounds (DBA/2 and C57BL/6 strains, respectively). DNA immunization was more potent in inducing CTLs than immunization with an optimized regimen of ovalbumin peptide plus immune adjuvant. Immunity induced by DNA immunization protected mice against s.c. challenge with tumors expressing the beta-galactosidase antigen. Tumors were rejected even when DNA immunization was started 3 or 7 days after tumor challenge as tumors were becoming established. Tumor rejection required CD8(+) T cells, confirming a role for CTLs in vivo. These studies show that DNA immunization by particle bombardment can efficiently induce CTL responses that are capable of rejecting even established tumors.

Peptide presentation by class-I major histocompatibility complex molecules.

MHC class-I molecules express distinct peptide-binding pockets within their antigen-binding groove. These are critically involved in the binding of antigenic peptides. The amino acid composition of a pocket dictates the structure of a peptide which can be bound in it. This is evident as a consensus amino acid motif which has to exist within a peptide in order for it to bind to a particular MHC allele. Perturbation of a MHC pocket by amino acid substitution can result in the abolition of peptide binding. Less drastic mutations of the peptide-binding groove, particularly the ones away from the critical pocket, can subtly alter the conformation of bound peptide. Both types of substitution exert an influence on the TCR recognition of antigenic peptide. Peptides are also critically involved in the positive selection of the class-I-restricted TCR repertoire in the thymus. These self peptides act by mimicking their foreign antigens. This mimicking involves the binding of self peptides and foreign antigenic peptides to the same pockets of the MHC class-I-antigen binding groove. Consequently, MHC class-I polymorphism in the antigen binding groove controls the intrathymic positive selection and peripheral antigen presentation by the same mechanisms. The majority of positively selecting self peptides could well originate from the extracellular processing of circulating self proteins. Using the diverse, extracellularly generated self peptides and the different determinant density requirements for positive versus negative selection, the immune system can ensure the repertoire diversity, avoiding both the massive clonal deletion of the selected repertoire and the autoreactivity of its T cells.

Positive selection of the T-cell repertoire is affected by mutations in the peptide-binding site of MHC class I molecules.

H-2Kb mutant molecules (H-2Kbm) and the H-2Kb-restricted response to OVA and VSV N peptides were used to investigate the influence of polymorphism of structurally defined regions of the MHC class I molecules on intrathymic positive selection of the T-cell repertoire. We show that the positive selection of the T-cell repertoire in the thymus requires the self-peptide to be present in the MHC antigen-binding site. A correlation between the ability of four MHC molecules to present antigenic peptide and to positively select T cells specific for it was noted. The self-peptides involved in positive selection may therefore mimic the foreign peptide during intrathymic selection. A structural correlate of this mimicry may be a similar or identical binding requirement for the antigen-binding pocket(s)/residues of the MHC peptide-binding site.

Phenotypic and functional stages in the intrathymic development of alpha beta T cells.

The thymus is the main site of T-cell maturation. On arrival in the thymus, CD8-CD4- double-negative (DN) T-cell precursors undergo extensive gene rearrangement, phenotypic alteration and biochemical modification to yield the population of thymocytes that undergoes intrathymic selection. The selected mature thymocytes then go on to seed the periphery. In this article Janko Nikolic-Zugic discusses the labyrinthine development that constitutes alpha beta T-cell maturation and selection.

Functional and phenotypic delineation of two subsets of CD4 single positive cells in the thymus.

CD4 single positive thymocytes are the fraction of mature thymocytes that contains precursors of MHC class II restricted T cells. In the experiments presented here, we demonstrate phenotypic and functional heterogeneity amongst CD4 single positive thymocytes from adult mice. Approximately 70% of these cells adhere to anti-CD8 antibody-coated dishes and therefore express low levels of CD8 molecules. They are referred to here as CD8loCD4hi. The remaining 30% are CD8-CD4hi. The CD8loCD4hi subset also expresses 3-fold higher surface levels of heat-stable antigen (HSA) than CD8-CD4hi thymocytes. Both CD4hi subsets express high levels of the alpha beta TCR/CD3 complex on the cell surface, and can proliferate in response to allogeneic cells expressing MHC class II differences but not to cells expressing only class I disparate molecules. However, CD8-CD4hi thymocytes are self-sufficient in such a proliferative response, whereas CD8loCD4hi thymocytes require exogenous IL-2 for optimal proliferation. The results suggest that CD8loCD4hi thymocytes are not completely mature. Their phenotype suggests that they might be descendants from CD8hiCD4hi double positive thymocytes, and that they have begun to down-regulate gradually CD8 and HSA molecules. The relationship between the two CD4hi single positive subsets is discussed.

T cell-specific protein-DNA interactions occurring at the CD4 locus: identification of possible transcriptional control elements of the murine CD4 gene.

The cis-acting transcriptional control elements of the murine CD4 gene were investigated within 75 kb of chromatin associated with the CD4 locus. DNase I hypersensitive (DH) sites were identified in several T and non-T cell lines, and in freshly isolated thymocytes. A total of 22 DH sites were found, seven of which are present only in T cells expressing CD4 or CD8. The T cell-specific DH sites are located in four regions: (i) 5' of the first exon of CD4, (ii) in the first intron, (iii) near the second and third exons, and (iv) 3' of the CD4 gene. Some of these sites inversely correlate to the CD4 expression at defined stages of T cell development, suggesting a role for these sites in repression of this gene. The T cell-specific DH sites were subcloned and analyzed for protein-DNA interactions using the electrophoretic mobility shift assay. All T cell-specific DH sites analyzed appear to be a consequence of T cell-specific protein-DNA interactions. We have also identified the nuclear matrix attachment regions (MARs) and repetitive elements associated with the CD4 gene. Two nuclear MARs, separated by a region of highly repetitive DNA, are located 5' of the gene. Another region of highly repetitive DNA exists within the third intron. We discuss the implications of our results for the developmental regulation of CD4 expression.

Transcription factor activation during signal-induced apoptosis of immature CD4(+)CD8(+) thymocytes. A protective role of c-Fos.

Many signals that cause apoptotic cell death operate by inducing transcription and translation of other (presumably death effector) mediators, and it is well established that stimulus-induced apoptosis can often be blocked by inhibiting transcription and translation. Transcriptional regulation of apoptosis, however, is incompletely understood. To gain insight into nuclear events associated with signal-induced apoptosis during T cell development, we studied signal-induced apoptosis of ex vivo isolated immature CD8(+)4(+) double-positive (DP) thymocytes. Stimuli utilizing the T cell receptor (TCR) signaling pathway or its parts (an alphaCD3/TCR monoclonal antibody, a Ca2+ ionophore, or a protein kinase C-activating phorbol ester) or a stimulus that antagonizes TCR signaling and apoptosis in T cell hybridoma (forskolin, a cyclic AMP-signaling activator) resulted in massive apoptosis of DP thymocytes. At the same time, these stimuli induced qualitatively similar but quantitatively unique patterns of inducible transcription factors (TFs) NF-kappaB/RelA-p50, AP-1 (Fos-Jun), and NUR-77. We focused our attention on the role of AP-1 (Fos-Jun) complex, which was strongly induced by all of the above stimuli and thus was a candidate for a proapoptotic TF. However, we found that AP-1/c-Fos induction was vital in prolonging DP thymocyte life, as judged by increased spontaneous and induced death of DP cells in Fos-/- mice. In direct support of this hypothesis, experiments with antisense oligonucleotides demonstrated that c-Fos plays an essential role in protecting normal DP thymocytes from Ca2+- and cAMP-induced apoptosis but not from TCR-mediated death. Together, these results demonstrate a physiological role for c-Fos in maintaining longevity of DP thymocytes.

The effect of mutations in the MHC class I peptide binding groove on the cytotoxic T lymphocyte recognition of the Kb-restricted ovalbumin determinant.

The H-2Kb-restricted cytotoxic T lymphocyte (CTL) response directed against ovalbumin (OVA) is specific for a region contained within the sequence OVA253-276. In this study we have characterized this response by examining the class I-restricted presentation of OVA peptides by the naturally occurring Kb mutant (Kbm) glycoproteins Kbm1, Kbm3, Kbm5, Kbm8, Kbm10, Kbm11 and Kbm23. To facilitate this study we derived a series of somatic cell hybrid targets expressing the various Kbm class I molecules. Experiments using bulk OVA-specific CTL from C57BL/6 mice demonstrated that all the Kbm molecules except for Kbm1 and Kbm8 could present OVA peptides for effective T cell recognition. Clonal analysis revealed a more complex and relatively diverse pattern of CTL recognition of the Kbm/peptide combinations. This diversity is unlikely to result from the existence of multiple, independent Kb-restricted T cell determinants within OVA, since all CTL tested were specific for a single region between residues 259 and 273. Examination of the fine specificity of Kbm presentation identified individual changes at residues 77, 80 and 116 which affected T cell recognition. The results imply that these changes do not inhibit peptide binding since some clones could recognize peptide presented by a particular Kbm molecule, while other clones could not. All three residues reside within the peptide-binding cleft of the class I protein and are not expected to directly contact the T cell receptor. Although we did not formally demonstrate that OVA binding by Kbm vs. Kb is quantitatively identical, our results are best explained by postulating that the changes at residues 77, 80 and 116 indirectly affect T cell recognition by altering peptide conformation. Taken together our results suggest that changes within the class I binding site can profoundly modify peptide presentation without significantly inhibiting peptide-class I association.

Role of self-peptides in positively selecting the T-cell repertoire.

The fate of an immature thymocyte is determined by the specificity of its alpha beta T-cell receptor. Only cells expressing receptors that interact with sufficient affinity with major histocompatibility complex (MHC) molecules expressed on thymus epithelial cells are positively selected and go on to mature and seed the peripheral lymphoid organs. The H-2Kb class-I MHC molecule positively selects for the maturation of cytotoxic T lymphocytes that will respond in the periphery to H-2Kb cells presenting a foreign peptide. We have now analysed the ability of variant H-2Kb molecules to positively select T-cells that respond to H-2Kb with ovalbumin. Our results indicate that self-peptides, presented in the groove of the class-I molecule on thymus epithelial cells, are critically involved in positive selection of the T-cell repertoire. Furthermore, the ability of four different H-2Kb variants to select this response in the thymus correlates with their ability to present the ovalbumin peptide, indicating that a self-peptide mimic of the foreign peptide could be involved in positive selection.

Thymocytes expressing CD8 differentiate into CD4+ cells following intrathymic injection.

Based on the cell surface expression of CD4 and CD8 molecules, murine thymocytes can be divided into four populations: these include CD4-, CD8- double-negative and CD4+, CD8+ double-positive subpopulations, both of which consist largely of immature cells, and the single positive, CD4+ or CD8+, subsets that contain functional helper or killer cells, respectively. The double-negative subset contains precursors of the other three populations and can reconstitute the thymus following intravenous or intrathymic transfer into irradiated hosts. In an attempt to establish the sequence of CD4 and CD8 expression during intrathymic development, we investigated the differentiation potential of highly purified CD8+ thymocytes by using intravenous or intrathymic adoptive transfer. Unlike the double-negative thymocyte subset, CD8+ cells did not have the ability to home to the thymus following intravenous transfer. However, when CD8+ thymocytes were injected directly into the thymus, they increased in number and gave rise to CD4+, CD8+ double-positive and CD4+ single-positive progeny. Furthermore, the rate of appearance of CD4+ cells from injected CD8+ precursors was faster than from the double-negative subset. Cells expressing a high surface density of CD8 convert to double-positive and CD4+ progeny without increasing in number, whereas CD8+ cells expressing a low surface density of the marker expand greatly and give rise to differentiated progeny. The results suggest that CD8 expression is an intermediate step on the differentiation pathway of mature CD4+ T cells.

T cell receptor expression on immature thymocytes with in vivo and in vitro precursor potential.

Immature CD8-CD4- double-negative (DN) thymocytes differentiate intrathymically into CD8+CD4- and CD8-CD4+ thymocytes and migrate to the periphery. This differentiation proceeds through several intermediate phenotypic changes in the expression of CD8 and CD4. We have recently established the existence of a CD8loCD4lo cell population in murine thymus that can repopulate the irradiated thymus in vivo and differentiate rapidly in vitro to CD8+CD4+ double-positive (DP) cells. The CD8loCD4lo cells score as DN upon direct cytofluorometric analysis, yet are distinct from true DN cells by various criteria. Experimental evidence strongly suggests that they are descendants of true DN in the maturation pathway. In the experiments presented here, we further characterize this CD8loCD4lo thymocyte population. Northern blot and RNA protection analysis reveal that these cells transcribe full length mRNA for the T cell receptor (TcR)alpha chain, unlike the less mature interleukin 2 receptor-positive DN thymocytes. Surface expression of the TcR-associated CD3 molecule occurs on approximately 15% of these cells at low levels characteristic of immature cells. In the course of in vitro differentiation a vast majority (approximately 80%) of these cells convert to CD8+CD4+ and significant numbers of the brightly staining DP convertants (11%-34% on day 1 and 48%-68% on day 2) express immature levels of CD3. Our results indicate that CD8lo, CD4lo cells might be the first thymic subset to rearrange TcR alpha chain genes and express TcR alpha/beta heterodimer on the surface at levels characteristic of immature cells. Furthermore, the surface expression of TcR persists on the in vitro progeny of these thymocytes.

Biochemical and kinetic characterization of the glucocorticoid-induced apoptosis of immature CD4+CD8+ thymocytes.

We characterized kinetic and biochemical changes during glucocorticoid (GC)-induced apoptosis of immature CD8+CD4+ double-positive (DP) thymocytes. A GC analog dexamethasone (Dex) induced rapid apoptotic commitment and a transient up-regulation of the NF-kappaB/RelA-p50-binding activity in DP cells. This required an early activation of proteasome, as judged by the ability of a specific proteasomal inhibitor, lactacystine, to delay apoptosis and to suppress Dex-dependent NF-kappaB activation. Dex-induced apoptotic commitment was preceded by the rapid (3 h) cleavage of both a typical caspase substrate, poly(ADP-ribose) polymerase (PARP), and of nuclear transcription factors AP-1, NF-kappaB p50-p50 and NUR-77. By contrast, phorbol myristate acetate (PMA) and/or ionomycin-induced apoptosis had much slower kinetics, were preceded by an early increase of NF-kappaB/RelA-p50, AP-1 and NUR-77 activities, and were insensitive to proteasome inhibition. Both the transgenic Bcl-2 and zVAD-fmk, an inhibitor of caspases, affected all features of Dex-induced apoptosis in a similar fashion, by inhibiting cell death and PARP cleavage, and by stabilizing AP-1, NF-kappaB p50-p50 and NUR-77 levels. Furthermore, Bcl-2 prevented Dex-induced RelA-p50 activation. However, a higher gene dosage of the transgenic Bcl-2 was required for protection against Dex, compared to the PMA and/or ionomycin-induced apoptosis. These findings highlight the unique mechanistic features of GC-induced apoptosis.

MHC polymorphism can enrich the T cell repertoire of the species by shifts in intrathymic selection.

The murine class I molecule H-2Kb and its natural gene conversion variant, H-2Kbm8, which differs from H-2Kb solely at 4 aa at the bottom of the peptide-binding B pocket, are expressed in coisogenic mouse strains C57BL/6 (B6) and B6.C-H-2bm8 (bm8). These two strains provide an excellent opportunity to study the effects of Mhc class I polymorphism on the T cell repertoire. We recently discovered a gain in the antiviral CTL repertoire in bm8 mice as a consequence of the emergence of the Mhc class I allele H-2Kbm8. In this report we sought to determine the mechanism behind the generation of this increased CTL diversity. Our results demonstrate that repertoire diversification occurred by a gain in intrathymic positive selection. As previously shown, the emergence of the same Mhc allele also caused a loss in positive selection of T cell repertoire specific for another Ag, OVA-8. This indicates that a reciprocal loss-and-gain pattern of intrathymic selection exists between H-2Kb and H-2Kbm8. Therefore, in the thymus of an individual, a new Mhc allele can select new T cell specificities, while abandoning some T cell specificities selected by the wild-type allele. A byproduct of this repertoire shift is a net gain of T cell repertoire of the species, which is likely to improve its survival fitness.

The critical role of a solvent-exposed residue of an MHC class I-restricted peptide in MHC-peptide binding.

The immunodominant ovalbumin257-264 (OVA-8, SIINFEKL) and herpes simplex virus gB496-503 (HSV-8, SSIEFARL) peptides share 50% amino acid identity (residues P1, P3, P5 and P8) and bind with comparable efficacy to the murine MHC-encoded class I molecule H-2Kb. However, these two peptides bind differently to H-2Kbm8, a natural H-2Kb variant with a substitution in four amino acids on the floor of the peptide-binding site; HSV-8 binds with high and OVA-8 with a relatively low efficacy. To investigate which of the non-homologous peptide residues were responsible for this differential binding, we used substituted peptide variants and the class I thermodynamic stabilization assay. Variation at the solvent-exposed peptide residues P6 and P7 did not appreciably influence binding. By contrast, variation at the buried P2 and, surprisingly, at the solvent-exposed P4 residue was found to be important. Transplantation of the HSV-8 P2 or P4 residues onto the OVA-8 backbone created variant peptides O2S (P2I-->S) and O4E (P4N-->E) that bound considerably better to H-2Kbm8 than OVA-8. Furthermore, the double-substituted peptide, O2S4E, bound even better, revealing a cooperative effect of the two residues. The reciprocally substituted peptides H2I and H4N, generated by grafting the OVA-8 P2 and P4 residues onto the HSV-8 backbone respectively, bound to H-2Kbm8 slightly worse than HSV-8 but the double-substituted peptide H2I4N bound as poorly as OVA-8. Effects exerted by the P4 residue, which is solvent accessible and therefore available for the TCR contact, demonstrated that exposed peptide residues can, in certain situations, influence not only the TCR contact but also MHC-peptide binding.