Towards prediction of degenerate CTL epitope recognition.

The cellular immune system is characterized by flexibility with respect to epitope recognition at the level of peptide binding to HLA molecules and HLA-peptide complexes to T-cell receptors (TCRs). For epitopes recognized by cytotoxic T-lymphocytes (CTLs), amino acid substitutions at different positions have varying impact on recognition. By analyzing the frequencies of specific amino acid substitutions at each position in conjunction with HLA-peptide binding and immune-response data, we have developed new methods to predict cross-reactive recognition of epitope variants by CTLs. We derived position-specific substitution matrices (EPSSMs) through the analysis of known HLA ligands and achieved relatively accurate prediction of detrimental and tolerated amino acid substitutions. Initial analysis of amino acid substitutions in CTL epitopes with degenerate recognition showed strong position-specific preferences. This first systematic analysis further suggested that spatial constraint may be the major molecular factor determining the degenerate epitope recognition. As the data cumulates, we anticipate that eventually EPSSMs will be available for prediction of degenerate T-cell epitope recognition.

Comprehensive epitope analysis of cross-clade Gag-specific T-cell responses in individuals with early HIV-1 infection in the US epidemic.

To elucidate the mechanisms underlying cross-clade T-cell reactivity, we evaluated responses to Gag peptides based on clades A, B, C, and M-group sequences at the epitope level by IFN-gamma ELISpot assay in 25 subjects following primary clade B infection. T-cell reactivity to CON (consensus), COT (center of tree), and ANC (most recent common ancestor) B peptides was similar and a high level of cross-reactivity was noted to clade A, C, and M-group peptides. T-cell responses to 15 of the 16 epitopes reacted with at least 1 of the 2 heterologous peptides (A or C or both) and 7 epitopes were invariant across all 3 clades. The remaining 9 epitopes were associated with a total of 11 variant sequences, and with the exception of 1, all substitutions were outside the HLA anchor positions. We conclude that Gag-specific cross-clade T-cell responses producing IFN-gamma can be detected in primary HIV-1 infection. Cross-reactivity is attributable to the recognized epitopes being either invariant across clades or differing by single amino acid substitutions outside the HLA anchor sites. Semi-conservative and non-conservative substitutions that presumably involve the T-cell receptor contact sites have significant effects on T-cell recognition. Finally, further studies are needed to determine if the detection of cross-clade IFN-gamma T-cell responses indeed translates to cross-reactive antiviral activity.

Enhanced detection of human immunodeficiency virus type 1 (HIV-1) Nef-specific T cells recognizing multiple variants in early HIV-1 infection.

A human immunodeficiency virus (HIV)-preventive vaccine will likely need to induce broad immunity that can recognize antigens expressed within circulating strains. To understand the potentially relevant responses that T-cell based vaccines should elicit, we examined the ability of T cells from early infected persons to recognize a broad spectrum of potential T-cell epitopes (PTE) expressed by the products encoded by the HIV type 1 (HIV-1) nef gene, which is commonly included in candidate vaccines. T cells were evaluated for gamma interferon (IFN-gamma) secretion using two peptide panels: subtype B consensus (CON) peptides and a novel peptide panel providing 70% coverage of PTE in subtype B HIV-1 Nef. Eighteen of 23 subjects' T cells recognized HIV-1 Nef. In one subject, Nef-specific T cells were detected with the PTE but not with the CON peptides. The greatest frequency of responses spanned Nef amino acids 65 to 103 and 113 to 147, with multiple epitope variants being recognized. Detection of both the epitope domain number and the response magnitude was enhanced using the PTE peptides. On average, we detected 2.7 epitope domains with the PTE peptides versus 1.7 domains with the CON peptides (P = 0.0034). The average response magnitude was 2,169 spot-forming cells (SFC)/10(6) peripheral blood mononuclear cells (PBMC) with the PTE peptides versus 1,010 SFC/10(6) PBMC with CON peptides (P = 0.0046). During early HIV-1 infection, Nef-specific T cells capable of recognizing multiple variants are commonly induced, and these responses are readily detected with the PTE peptide panel. Our findings suggest that Nef responses induced by a given vaccine strain before HIV-1 exposure may be sufficiently broad to recognize most variants within subtype B HIV-1.