Characterisation of near-full length genome sequences of three South African human immunodeficiency virus type 1 subtype C isolates

Identification of a new 2-amino acid insertion in the integrase coding region of HIV-1 subtype G isolates

Amino acid insertions have been rarely found in the integrase (IN) coding region of Human immunodeficiency virus 1 (HIV-1), and have been considered as natural polymorphisms. It is still unclear the potential impact of these insertion mutations on the viral replication capacity and/or susceptibility to integrase strand transfer inhibitors (INSTIs). The objective of this study was to describe a previously unreported amino acid insertion in the IN coding region of HIV-1 isolates obtained from antiretroviral treatment-naïve infected individuals. Nucleotide sequences of HIV-1 isolates obtained from two infected individuals were analyzed for genotypic resistance to antiretroviral drugs. Phylogenetic inference was carried out for HIV-1 genetic variant identification. An unreported insertion of a threonine (T) and an asparagine (N) between codon 255 and 256 (S255N_TN) was identified in the IN C-terminal domain of HIV-1 subtype G isolates. No resistance-associated mutations to INSTIs were detected in the inserted sequences. Both individuals maintained undetectable HIV-1 RNA viral load, 24 months after undergoing antiretroviral treatment with an INSTI containing regimen. The results demonstrated the possibility of transmission of this insertion mutation and suggested that the codon 255 insert by itself may not affect susceptibility to INSTIs.

Genetic diversity and naturally polymorphisms in HIV type 1 integrase isolates from Maputo, Mozambique: implications for integrase inhibitors

HIV proviral DNA integration into the host chromosome is carried out by integrase becoming an important target antiretroviral therapy. Raltegravir was the first integrase inhibitor approved for use in HIV therapy and elvitegravir is in the late phase of clinical development; both show good results in monotherapy studies and may be used worldwide for rescue therapy. In this work we analyzed 57 integrase sequences obtained from samples from drug-naive and first line regime-failing patients from Maputo, Mozambique, to evaluate the presence of natural polymorphisms and resistance mutations associated with raltegravir and elvitegravir. No major mutations conferring resistance to integrase inhibitors were found and polymorphic accessory mutations were solely observed in low frequency among subtype C sequences-L74M (3.4%), T97A (1.8%), and E157Q (1.8%)-suggesting that this new antiretroviral drug class will be effective in Mozambique providing a good perspective to the introduction of this class of drugs in that country.

Natural polymorphisms of integrase among HIV type 1-infected South African patients

An HIV-1 subtype C specific assay was established for integrase genotyping from 51 integrase inhibitor-naive patient plasma samples and 22 antiretroviral drug-naive primary viral isolates from South Africa. Seventy-one of the 73 samples were classified as HIV-1 subtype C and two samples were unique AC and CG recombinants in integrase. Amino acid sequence analysis revealed there were no primary mutations (Y143R/C/H, Q148H/R/K, and N155H/S) associated with reduced susceptibility to the integrase inhibitors raltegravir and elvitegravir. However, one sample had the T97A mutation, three samples had the E157Q and V165I mutations, and the majority of samples contained the polymorphic mutation V72I. The expected finding of no major integrase mutations conferring resistance to integrase inhibitors suggests that this new antiretroviral drug class will be effective in our region where HIV-1 subtype C predominates. However, the impact of E157Q and other naturally occurring polymorphisms warrants further phenotypic investigation.

Documentation of subtype C HIV Type 1 strains in Argentina, Paraguay, and Uruguay

HIV subtypes B, F, and BF recombinants have been previously reported in South America. This report describes the presence of HIV-1 subtype C infection in the countries of Argentina, Uruguay, and Paraguay dating back to at least 1999. Surveillance for uncommon non-B/non-F subtype viruses circulating in South America has been conducted in samples obtained from nine countries. Peripheral blood mononuclear cells (PBMC), dried filter paper (FP), and fresh blood (FB) samples were collected from HIV-positive patients from Ecuador, Colombia, Venezuela, Peru, Chile, Bolivia, Argentina, Uruguay, and Paraguay. From a total of 2962 HIV seropositive samples examined during a 9-year period (1995-2003), only 11 (0.4%) were found to be infected with non-B/non-F HIV variants. Eight of these 11 strains were determined to be subtype C by heteroduplex mobility assay (HMA). Five of these 8 strains were further characterized by sequencing and phylogenetic analysis of the protease (Pro) and reverse transcriptase (RT) region of the genome and two were sequenced full length. One of the strains was found to be a unique BC recombinant. The spread of a third subtype of HIV, subtype C, should raise the question of its potential future role in the HIV epidemic in this region.

Cellular specificity of HIV-1 replication can be controlled by LTR sequences

Two well-established determinants of retroviral tropism are envelope sequences that regulate entry and LTR sequences that can regulate viral expression in a cell-specific manner. Studies with human immunodeficiency virus-1 (HIV-1) have demonstrated that tropism of this virus maps primarily to variable envelope sequences. Studies have demonstrated that T cell and macrophage-specific transcription factor binding motifs exist in the upstream region of the LTR U3; however, the ability of the core enhancer/promoter proximal elements (two NF-kappaB and three Sp1 sites) to function well in macrophages and T cells have led many to conclude that HIV LTR sequences are not primary determinants of HIV tropism. To determine if cellular specificity could be imparted to HIV by the core enhancer elements, the enhancer/promoter proximal region of the HIV LTR was substituted with motifs that control gene expression in a myeloid-specific manner. The enhancer region from equine infectious anemia virus (EIAV) when substituted for the HIV enhancer/promoter proximal region was found to drive expression in a macrophage-specific manner and was responsive to HIV Tat. The addition of a 5' methylation-dependent binding site (MDBP) and a promoter proximal Sp1 motif increased expression without altering cellular specificity. Spacing between the promoter proximal region and the TATA box was also found to influence LTR activity. Infectivity studies using chimeric LTRs within the context of a dual-tropic infectious molecular clone established that these LTRs directed HIV replication and production of infectious virions in macrophages but not primary T cells or T cell lines. This investigation demonstrates that cellular specificity can be imparted onto HIV-1 replication at the level of viral transcription and not entry.