Of the nine peptides in this group, eight elicited IFNγ ELISpot responses in PBMCs from HIV-1-infected subjects possessing A2 alleles: ENV-1002 (AVLSIVNRV) [49], ENV-1005 (SLCLFSYHRL) [49], GAG-1013 (ELKSLYNTV) [68], NEF-1015 (WLEAQEEEEV) [69], POL-1008 (ELAENREIL) [70], POL-1010 (DIQKLVGKL) [70], VPR-1019 (ETYGDTWTGV) [71], and VPU-1020 (TMVDMGHLRL) [70]. And finally, eight of the selected HLA-A2 epitopes are still novel for HIV-1 at the time of submission. The following peptides were confirmed to be immunogenic in IFNγ ELISpot assays in PBMC cultures from our HIV-1 infected cohorts: ENV-1001 www.selleckchem.com/products/Adrucil(Fluorouracil).html (GIKPVVSTQL) in both Providence, RI and Bamako, Mali; TAT-1017 (RLEPWKHPG)
and VIF-1018 (KISSEVHIPL) in Providence; and REV-2001 (GVGSPQILV), REV-2002 (ILVESPTVL),
VIF-3006 (KVGSLQYLA), VIF-3007 (SLQYLALTA), and VPU-3009 (KIDRLIDRI) in Bamako. Epitope VPU-3009 did not elicit any positive IFNγ ELISpot responses and has yet to be described as an HIV-1 epitope in other publications even though it bound to HLA-A2 in vitro; PFI-2 mouse this may due to the size of the study cohort or to false positive selection by our immunoinformatics tools. A globally relevant vaccine for HIV-1 continues to remain elusive due to the dynamic and extraordinary diversity of the virus. Virus-specific cytotoxic T-cell responses have been shown to play a vital role in the control of primary and chronic HIV-1 infection [16], [20], [17], [72] and [73], and while T-cell epitopes continuously evolve under immune pressure, early work showed fitness costs limited viral escape from CTL [34]. These findings suggest that a vaccine capable of raising CTL to the most conserved epitopes would have the most success at slowing or halting the progression of disease. This supports our firm belief that critical highly conserved, high-affinity epitopes available for vaccine design lie in restricted regions of the HIV genome that are resistant
Dipeptidyl peptidase to selective pressure, where mutations are slow to evolve and exact a cost on virus replicative fitness. We have called these epitopes the “Achilles’ heel” epitopes of HIV [32]. Due to HIV viral evolution in response to pressure from HLA-restricted immune responses, many highly immunogenic T-cell epitopes may be disappearing from the HIV genome, while highly conserved regions of the genome may also evolve to escape human immune response [74] and [75]. In the work presented here, we have employed immunoinformatics methods to search available HIV sequences for both highly conserved and immunogenic HLA-A2 epitopes. Using this balanced strategy of selecting for both conservation and immunogenicity, 38 total putative A2 epitopes were chosen and then tested in assays with PBMCs from HIV-1 infected subjects in two geographically distinct areas (Providence, Rhode Island, and Bamako, Mali).