Positively charged amino acid substitutions at positions 11 and 25 within the loop of the third variable region (V3) of HIV-1 subtype B envelope have been shown to be associated with the syncytium-inducing (SI) phenotype of the virus. The present study was designed to examine SI and NSI-associated V3 mutations in HIV-1 subtypes other than B. HIV-1 RNA was isolated from 53 virus stocks and 26 homologous plasma samples from 53 recently infected individuals from Brazil, Rwanda, Thailand, and Uganda. The C2-V3 region of the viral envelope was converted to cDNA, amplified, and sequenced. Of 53 primary virus stock samples 49 were biologically phenotyped through measurement of the syncytium-inducing capacity in MT-2 cells (to differentiate between SI and NSI phenotypes). In addition, after passage of primary isolates through PHA stimulated donor PBMC, the replication capacity was determined in U937-2, CEM, MT-2, and Jurkat-tat cell lines (to differentiate rapid/high and slow/low phenotypes). According to the sequence analysis 9 (17.0%) of the viruses belonged to subtype A, 15 (28.3%) to subtype B, 1 (1.9%) to subtype C, 13 (24.5%) to subtype D, and 15 (28.3%) to subtype E. Sequence analysis of virus RNA, obtained from 26 homologous plasma samples, confirmed the homogeneity of sequence populations in plasma compared to primary virus isolates. Of the 49 viruses tested 12 had the SI phenotype, 5 were confirmed to be rapid/high, and 4 appeared to be slow/low pattern 3 replicating. Of 49, 29 had the NSI phenotype, 24 were confirmed to be slow/low pattern 1 or 2, and 3 appeared to be slow/low pattern 3 replicating. Analysis of mutations at V3 loop amino acid positions 11 and 25 revealed that 10/12 (83.3%) of the SI viruses had SI-associated V3 mutations and that 28/29 (96.6%) of the NSI viruses lacked these mutations. V3 loop heterogeneity, length polymorphism, and a high number of positively charged amino acid substitutions were most frequently found among subtype D variants. These results indicate that both the phenotypic distinction between SI and NSI viruses and the association of biological phenotype with V3 mutations is present among HIV-1 subtypes other than B.
Antiretroviral therapy including zidovudine may yield replicating viruses with a two amino-acid insertion in RT in combination with amino-acid changes at codons 67 and 215, which are highly resistant to lamivudine and stavudine on top of zidovudine and have unpredictable susceptibility to didanosine and zalcitabine despite lack of previously reported corresponding resistance-associated amino-acid changes. It is currently unknown what regimens can induce the emergence of this type of multidrug-resistant viruses. This will only be elucidated when resistance assays are capable of detecting these mutants.
The third variable domain (V3) of the envelope gene of human immunodeficiency virus type 1 contains a major neutralization epitope and determinants of syncytium-inducing (SI) capacity and replication rate (reviewed by J. P. Moore and P. L. Nara, AIDS Suppi. 2:S21-S33, 1991). Sequences were generated from DNA of samples taken 3 months apart over a period of 24 and 30 months from peripheral blood mononuclear cells (PBMC) of two individuals, both before and after cocultivation with uninfected donor PBMC. The isolated virus shifted from the non-syncytium-inducing (NSI) phenotype to the SI phenotype during the study period. This shift was associated with distinct changes in the V3 domain in both patients. The association of the phenotype shift with the V3 sequence changes was confirmed by construction of viruses with chimeric V3 loops. The shift from NSIto SI-associated V3 variants was also seen in the uncultured PBMC of both patients, but not until 3 and 9 months after the detection of SI virus in culture. In the samples of uncultured PBMC DNA, several subgroups of sequences were found, indicating that the process of evolution may not be gradual and that several distinct populations can coexist. The paucity of intermediate sequences indicated that strong selection pressure was exerted on this part of the envelope. The early emergence of disease-associated SI variants in cultured material indicates that virus culture may have relevance for the in vivo situation.
Control of viremia in natural human immunodeficiency virus type 1 (HIV-1) infection in humans isassociated with a virus-specific T-cell response. However, still much is unknown with regard to the extent of CD8 ؉ cytotoxic T-lymphocyte (CTL) responses required to successfully control HIV-1 infection and to what extent CTL epitope escape can account for rises in viral load and ultimate progression to disease. In this study, we chose to monitor through full-length genome sequence of replication-competent biological clones the modifications that occurred within predicted CTL epitopes and to identify whether the alterations resulted in epitope escape from CTL recognition. From an extensive analysis of 59 biological HIV-1 clones generated over a period of 4 years from a single individual in whom the viral load was observed to rise, we identified the locations in the genome of five CD8 ؉ CTL epitopes. Fixed mutations were identified within the p17, gp120, gp41, Nef, and reverse transcriptase genes. Using a gamma interferon ELIspot assay, we identified for four of the five epitopes with fixed mutations a complete loss of T-cell reactivity against the wild-type epitope and a partial loss of reactivity against the mutant epitope. These results demonstrate the sequential accumulation of CTL escape in a patient during disease progression, indicating that multiple combinations of T-cell epitopes are required to control viremia.
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