Valentina García

Evaluation of genotypic tropism prediction tests compared with in vitro co-receptor usage in HIV-1 primary isolates of diverse subtypes

OBJECTIVES To evaluate the sensitivity and specificity of genotypic methods for predicting the co-receptor usage of subtypes B and non-B HIV-1 primary isolates, using as gold standard the infectivity of each primary isolate in GHOST cells stably expressing HIV-1 co-receptors. METHODS Primary isolates were obtained by co-culturing either patients peripheral blood mononuclear cells (PBMCs) or ultracentrifuged plasma with donor-activated PBMCs. In vitro co-receptor usage was determined by infecting GHOST cells. Tropism prediction, based on V3 sequences, was determined with simple rules and bioinformatic tools (Geno2pheno[coreceptor] and WebPSSM). RESULTS This study includes 102 HIV-1 primary isolates; 23 (22.5%) subtype B and 79 (77.5%) non-B genetic forms. V3 sequences were classified into six subtypes (A-G), although 32 (31.4%) were circulating recombinant forms and 21 (20.6%) were unique recombinant forms. Sixty-nine isolates were R5, 27 R5X4 and 6 X4. The highest levels of sensitivity and specificity for the detection of X4 strains among V3 sequences, between 91% and 100%, were obtained by using PSSM(x4r5), PSSM(si/nsi) and the 11/25 rule for sequences of subtypes A, B and G, but not for subtype F. Establishing the recommended cut-off for clinical settings of a 10% false positive rate for Geno2pheno, we obtained 93% specificity and 97% sensitivity. CONCLUSIONS Comparing genotypic assays for HIV-1 co-receptor use with a cell-culture phenotypic assay could provide more reliable results of sensitivity and specificity for the detection of X4 strains than comparing them with recombinant assays, considered as gold standard. In general, except for subtype F isolates, there is a good correlation for tropism prediction.

Identification of a new HIV type 1 circulating BF intersubtype recombinant form (CRF47_BF) in Spain.

We report the identification of a new HIV-1 circulating recombinant form (CRF47_BF) derived from subtypes B and F. It was initially identified in protease-reverse transcriptase sequences from nine individuals from three separate regions of Spain who acquired HIV-1 infection via sexual contact. All nine sequences formed a strongly supported phylogenetic cluster, branching apart from all known CRFs, and in bootscan analyses were BF mosaics with two coincident breakpoints. Two epidemiologically unlinked viruses were sequenced in near full-length genomes, which exhibited identical mosaic structures, with 16 intersubtype breakpoints in a genome predominantly of subtype B. Subtype F segments of the new CRF failed to cluster with any of the near full-length genome subtype F sequences available in public databases. Recent dates of HIV-1 diagnoses and short genetic distances suggest a recent origin of this CRF. This is the tenth reported CRF_BF, the first apparently having originated outside of South America.

Development of a Panel of Well-Characterized Human Immunodeficiency Virus Type 1 Isolates from Newly Diagnosed Patients Including Acute and Recent Infections

The aim of this study was the development of a panel constituted by well-defined HIV-1 strains of different genetic forms, with a particular focus on isolates from acute and recent infections. Fourteen HIV-1 isolates, including four from acute and five from recent infections, were expanded in peripheral blood mononuclear cells. SI phenotype, coreceptors use, and TCID(50)/ml were determined. V3 net charge was calculated. Near full-length genomes were amplified by RT-nested PCR in four overlapping segments. Phylogenetic analyses were performed with neighbor-joining trees and bootscanning. Analysis of cysteine residues, lengths of variable regions, and potential N-linked glycosylation sites in gp120 and gp41 was performed. Viral stocks were produced. Thirteen strains were NSI/R5 and one SI/R5,X4. TCID(50)/ml ranged between 10(4.6) and 10(6). V3 net charge was <+5 in 12 sequences and +5 in two sequences. Near full-length HIV-1 genomes analysis identified viruses of the following genetic forms: eight subtype B, three subtype C, two CRF02_AG, and one subtype G. Cysteine residues that form the V1,V2,V3, and V4 loops were highly conserved. The number of potential N-linked glycosylation sites in gp120 and gp41 ranged between 24-29 and 4-6, respectively. Seven potential N-linked glycosylation sites in gp120 and three in gp41 were conserved. V1, V2, V4, and V5 variable regions exhibited substantial length variation. In addition, an analysis of transmitted and natural resistance to current antiretroviral drugs in these strains was performed. It is worth mentioning that the 13S mutation in the V3 sequence, associated with resistance to maraviroc, was observed in a subtype B strain that harbored resistance mutations to nucleoside reverse transcriptase inhibitors and to T20. The availability of a panel including strains from acute and recent infections should be a valuable resource for optimizing and standardizing vaccine candidate assessment. Near full-length genome characterization may be necessary for evaluating clade-specific reactivities.

Improvement of HIV-1 coreceptor tropism prediction by employing selected nucleotide positions of the env gene in a Bayesian network classifier

OBJECTIVES This study aimed to develop a genotypic method to predict HIV-1 coreceptor usage by employing the nucleotide sequence of the env gene in a tree-augmented naive Bayes (TAN) classifier, and to evaluate its accuracy in prediction compared with other available tools. METHODS A wrapper data-mining strategy interleaved with a TAN algorithm was employed to evaluate the predictor value of every single-nucleotide position throughout the HIV-1 env gene. Based on these results, different nucleotide positions were selected to develop a TAN classifier, which was employed to predict the coreceptor tropism of all the full-length env gene sequences with information on coreceptor tropism currently available at the Los Alamos HIV Sequence Database. RESULTS Employing 26 nucleotide positions in the TAN classifier, an accuracy of 95.6%, a specificity (identification of CCR5-tropic viruses) of 99.4% and a sensitivity (identification of CXCR4/dual-tropic viruses) of 80.5% were achieved for the in silico cross-validation. Compared with the phenotypic determination of coreceptor usage, the TAN algorithm achieved more accurate predictions than WebPSSM and Geno2pheno [coreceptor] (P<0.05). CONCLUSIONS The use of the methodology presented in this work constitutes a robust strategy to identify genetic patterns throughout the HIV-1 env gene differently present in CCR5-tropic and CXCR4/dual-tropic viruses. Moreover, the TAN classifier can be used as a genotypic tool to predict the coreceptor usage of HIV-1 isolates reaching more accurate predictions than with other widely used genotypic tools. The use of this algorithm could improve the correct prescribing of CCR5 antagonist drugs to HIV-1-infected patients.

Identification of new splice sites used for generation of rev transcripts in human immunodeficiency virus type 1 subtype C primary isolates.

The HIV-1 primary transcript undergoes a complex splicing process by which more than 40 different spliced RNAs are generated. One of the factors contributing to HIV-1 splicing complexity is the multiplicity of 3′ splice sites (3ss) used for generation of rev RNAs, with two 3ss, A4a and A4b, being most commonly used, a third site, A4c, used less frequently, and two additional sites, A4d and A4e, reported in only two and one isolates, respectively. HIV-1 splicing has been analyzed mostly in subtype B isolates, and data on other group M clades are lacking. Here we examine splice site usage in three primary isolates of subtype C, the most prevalent clade in the HIV-1 pandemic, by using an in vitro infection assay of peripheral blood mononuclear cells. Viral spliced RNAs were identified by RT-PCR amplification using a fluorescently-labeled primer and software analyses and by cloning and sequencing the amplified products. The results revealed that splice site usage for generation of rev transcripts in subtype C differs from that reported for subtype B, with most rev RNAs using two previously unreported 3ss, one located 7 nucleotides upstream of 3ss A4a, designated A4f, preferentially used by two isolates, and another located 14 nucleotides upstream of 3ss A4c, designated A4g, preferentially used by the third isolate. A new 5′ splice site, designated D2a, was also identified in one virus. Usage of the newly identified splice sites is consistent with sequence features commonly found in subtype C viruses. These results show that splice site usage may differ between HIV-1 subtypes.

HIV type 1 intersubtype recombinants during the evolution of a dual infection with subtypes B and G.

ABSTRACT The aim of this study was to characterize the HIV-1 intersubtype recombinant forms generated during the follow-up of a dual natural infection with subtypes B and G. Near full-length sequences from plasma and peripheral blood mononuclear cell (PBMC) compartments were analyzed and the biological characteristics of their derived primary isolates studied. Different mutations were detected in V1, V2, and V3 sequences from primary isolates but not in sequences from plasma RNA or PBMC DNA. The HIV-1 near full-length sequence from the first collected plasma was of subtype G and the presence of subpopulations of subtypes B and G was observed with subtype-specific primers for protease and reverse transcriptase segments. Subsequent sequences from plasma, PBMCs, and primary isolates were obtained during a follow-up of 6 years; all of them were BG recombinants and showed identical intersubtype breakpoints between subtypes B and G in pol and nef. The env sequence from all primary isolates harbored a unique insert of subtype B. Specific primers for the V3 loop identified fluctuating subtype B and/or subtype G sequences either from plasma RNA or PBMC DNA.

Oligonucleotide Ligation Assay for Detection of Mutations Associated with Reverse Transcriptase and Protease Inhibitor Resistance in Non-B Subtypes and Recombinant Forms of Human Immunodeficiency Virus Type 1

ABSTRACT The oligonucleotide ligation assay is a genotypic assay for the detection of resistance-associated mutations to reverse transcriptase and protease inhibitors in human immunodeficiency virus type 1 subtype B. This assay has been modified and developed for non-B subtypes and recombinant strains and has been evaluated with sequencing, resulting in a more sensitive assay than sequencing for non-B subtypes.