Interaction with human immunodeficiency virus (HIV) type 2 predicts HIV type 1 genotype

In West Africa, India, and certain regions of Europe, both human immunodeficiency viruses types 1 and 2 (HIV-1 and HIV-2) are known to cocirculate. To investigate the HIV-1 subtypes involved in dual HIV-1 and HIV-2 infections, we sequenced the envelope C2-V3 region from 29 dually infected female commercial sex workers from Senegal. The majority of women (23 of 29) were infected by HIV-1 subtype A. Within the HIV-1 subtype A sequences, 14 of 23 (60.8%) clustered with the West African associated A/G recombinant form (IbNG), and 9 of 23 (39.2%) formed a separate cluster distinct from the A/G IbNG. In contrast, in HIV-1 singly infected individuals, non-IbNG subtype A was found in only 13 of 98 (13.3%). Therefore, the lack of protection and/or interaction with HIV-2 was associated with a distinct HIV-1 A genotype. These results suggest differences in the biological properties of HIV-1 genotypes and their in vivo interaction with HIV-2.     

Molecular characterization of human immunodeficiency virus (HIV)-1 and -2 in individuals from guinea-bissau with single or dual infections: predominance of a distinct HIV-1 subtype A/G recombinant in West Africa.

Guinea-Bissau in West Africa has the highest prevalence of human immunodeficiency virus (HIV)-2 infection in the world, but recently the HIV-1 prevalence increased rapidly with the subsequent appearance of HIV-1 and HIV-2 dual infections. Information about the genetic subtypes of HIV in the region is limited. Therefore, we characterized the env V3 region of HIV-1 and HIV-2 variants through direct DNA sequencing of peripheral blood mononuclear cell samples from 18 individuals with HIV-1 only and 9 individuals with dual infection. Phylogenetic analyses of these new sequences and database sequences from other West African countries showed that all HIV-1 and HIV-2 sequences from singly as well as dually infected individuals, except one, clustered among HIV-1 subtype A and HIV-2 subtype A, respectively. Importantly, a majority of the HIV-1 sequences from Guinea-Bissau and neighbouring countries were closely related with the isolates IbNG, DJ263, and DJ264, which share a common subtype A/G recombination pattern. Analysis of pol gene sequences from selected HIV-1 variants showed that "IbNG-like" viruses in Guinea-Bissau are also recombinant, indicating that the HIV-1 epidemic in Guinea-Bissau and neighbouring countries is dominated by an epidemic spread of a distinct subtype A/G recombinant, which is strikingly similar to the epidemic spread of a subtype A/E recombinant in Southeast Asia. Furthermore, the HIV-1 and HIV-2 variants carried by individuals with dual infection were intermixed with variants from singly infected individuals, indicating that variants involved in dual and single infections have common epidemiological histories.     

The AG recombinant IbNG and novel strains of group M HIV-1 are common in Cameroon.

The genetic diversity of group M HIV-1 is highest in west central Africa. Blood samples from four locations in Cameroon were collected to determine the molecular epidemiology of HIV-1. The C2-V5 region of envelope was sequenced from 39 of the 40 samples collected, and 7 samples were sequenced across the genome. All strains belonged to group M of HIV-1. The circulating recombinant form CRF02 AG (IbNG) was the most common strain (22/39, 56%). Two of these were confirmed by full genome analysis. Four samples (4/39, 10%) clustered with the sub-subtype F2 and one of these was confirmed by full genome sequencing. Recombinant forms, each different but containing subtype A, accounted for the next most common form (7/39, 18%). Among these recombinants, those combining subtypes A and G were the most common (4/7, 57%). Also found were 3 subtype A, 2 subtype G, and 1 subtype B strain. Many recombination break points were shared between IbNG and the other AG recombinants, though none of these other AG recombinants included IbNG as a parent. This suggests that there was an ancestral AG recombinant that gave rise to CRF02 AG (IbNG), the successful circulating recombinant form, and to others that were less successful and are now rare.     

Distribution of HIV-1 subtypes among HIV-seropositive patients in the interior of Côte d'Ivoire

Limited data exist on the distribution of HIV-1 subtypes in C?te d'Ivoire. The aim of this study is to describe the distribution of genetic subtypes of HIV-1 strains in six regions of C?te d'Ivoire. In 1997, we consecutively collected blood from 172 HIV-1-infected patients from six regional tuberculosis treatment centers. Peripheral blood mononuclear cells (PBMCs) from these people were analyzed by a restriction fragment-length polymorphism (RFLP) assay that involves a sequential endonuclease digestion of a 297-base pair polymerase chain reaction (PCR) fragment; plasma samples were tested by a V3-loop peptide enzyme immunoassay (PEIA). DNA sequencing of the protease or env genes was performed on all samples discordant in the two assays as well as a random sample of the concordant subtyped samples. Of 172 specimens, 3 were PCR-negative, and 169 were putatively classified as subtype A by RFLP. The 3 PCR-negative samples were unequivocally subtyped A by PEIA. Of the 169 RFLP subtype A samples, 159 (94%) were subtyped A by PEIA. Of the 10 discordant samples, PEIA testing classified 3 as subtype C, 2 as D, and 5 as F. Sequencing of the env gene classified these samples as 1 subtype A, 4 Ds, and 5 Gs. Thus, 163 (95%) of the specimens were subtype A, 3 subtype D, 4 subtype G, 1 A/D, and 1 A/G (IbNG) circulating recombinant forms (CRF). In conclusion, most HIV-1-infected tuberculosis patients throughout the interior of C?te d'Ivoire are infected with HIV-1 subtype A, which are very likely the A/G (IbNG) CRF. The uniform distribution of this subtype makes C?te d'Ivoire a potential site for vaccine trials.     

Analysis of a Local HIV-1 Epidemic in Portugal Highlights Established Transmission of Non-B and Non-G Subtypes

The existing data support Portugal as the western European country with the highest HIV-1 subtype diversity. However, detailed phylogenetic studies of Portuguese HIV-1 epidemics are still scarce. Thus, our main goal was to analyze the phylodynamics of a local HIV-1 infection in the Portuguese region of Minho. Molecular epidemiological analysis was applied to data from 289 HIV-1-infected individuals followed at the reference hospital of the province of Minho, Portugal, at which isolated viruses had been sequenced between 2000 and 2012. Viruses of the G (29.1%) and B (27.0%) subtypes were the most frequent, followed by recombinant forms (17.6%) and the C (14.5%), F1 (7.3%), and A1 (4.2%) subtypes. Multinomial logistic regression revealed that the odds of being infected with the A1 and F1 subtypes increased over the years compared with those with B, G, or C subtypes or recombinant viruses. As expected, polyphyletic patterns suggesting multiple and old introductions of the B and G subtypes were found. However, transmission clusters of non-B and non-G viruses among native individuals were also found, with the dates of the most recent common ancestor estimated to be in the early 2000s. Our study supports that the HIV-1 subtype diversity in the Portuguese region of Minho is high and has been increasing in a manner that is apparently driven by factors other than immigration and international travel. Infections with A1 and F1 viruses in the region of Minho are becoming established and are mainly found in sexually transmitted clusters, reinforcing the need for more efficacious control measures targeting this infection route.     

Genetic analysis of HIV-1 strains in rural eastern Cameroon indicates the evolution of second-generation recombinants to circulating recombinant forms

The HIV-1 genetic diversity in most parts of Cameroon is well described and shown to be very broad. However, little is known about the composition of the HIV-1 epidemic in the rural parts of eastern Cameroon. Therefore, we investigated 25 specimens from this region for their subtypes in gag, pol, and env gene fragments. Along with genetic material of subtypes A1, C, G, CRF01_AE, CRF02_AG, and CRF11_cpx, we also identified a large number (24%, 6/25) of distinct env sequences within the subtype A radiation. CRF02_AG was the predominant genetic form in all genes studied. Half of the specimens studied were considered "pure" based on concordant subtypes in the genes studied, whereas the other half were unique recombinant forms (URFs). Except for 1 URF, all were second-generation recombinants (SGRs), 90% of which contained genetic material of CRF02_AG in at least 1 gene. Notably, we identified individuals from 3 different villages infected with CRF01_AE(gag)CRF02_AG(pol)A(env) strains, which is indicative of the evolution of this URF to a circulating recombinant form (CRF). In addition, we identified a CRF02_AG(pol)C(env) recombinant infecting a man and a woman living in the same village, suggesting horizontal transmission of this recombinant. The current study emphasizes the power of HIV-1 recombination through the generation of SGRs and the evolution of URFs into CRFs. These findings suggest that, in a region where a predominant HIV-1 strain cocirculates among several subtypes, recombination could eventually decrease the proportion of this strain over time, such as CRF02_AG in Cameroon.     

Distribution of HIV-1 variants in the Democratic Republic of Congo suggests increase of subtype C in Kinshasa between 1997 and 2002

The Democratic Republic of Congo (DRC) is characterized by low and stable HIV prevalences and high HIV-1 genetic diversity and is most probably the epicenter of HIV-1 group M. Our major goal was to study the distribution of HIV-1 variants over a 5-year period against a background of political instability and civil war. A total of 288 HIV-1-positive samples collected in 2002 from sentinel population groups in an HIV serosurveillance study performed in 4 cities (Kinshasa [capital city], Mbuji-Mayi [south], Lubumbashi [southeast], and Kisangani [northeast]) were genetically characterized by sequencing and phylogenetic analysis of the V3-V5 env region. The results were compared with those obtained in 1997. Similarly, as in 1997, an extremely high genetic diversity of HIV-1 strains overall and a heterogeneous geographic distribution were seen in 2002. All subtypes and several circulating recombinant forms were present, high intrasubtype diversity was observed, and 5.6% of the samples could not be classified. In each geographic region of the DRC, the genetic diversity was significantly higher than in neighboring countries. Comparison of subtype distribution in similar population groups in Kinshasa in 1997 and 2002 revealed an overall increase of subtype C in Kinshasa from 2.1% to 9.7% and, more precisely, from 0% to 18.9% in female sex workers (P = 0.013). Genetic characterization of HIV-positive samples from sentinel surveys adds significant additional information on new trends in the HIV epidemic. These changes could have implications regarding the spread of HIV infection in the DRC as well on vaccine and/or treatment strategies.     

Screening of HIV-1 isolates by reverse heteroduplex mobility assay and identification of non-B subtypes in Italy

OBJECTIVE: The increasing prevalence of HIV-1 transmission through heterosexual contacts and the growing number of immigrants from non-Western countries, where non-B subtypes and recombinant forms are prevalent, suggest the possible emergence in Italy of a new epidemic wave of HIV-1 non-B subtypes as well as recombinant forms. METHODS: The distribution of HIV-1 subtypes has been evaluated in 63 seropositive individuals residing in Italy, most of whom were infected through a sexual route during the last 5 years. A modified heteroduplex mobility assay (HMA) strategy, reverse HMA (rHMA), has been developed in our laboratory, allowing rapid identification of divergent-from-B-subtype isolates, which have been subsequently characterized by detailed molecular and phylogenetic analyses. RESULTS: Five samples show, on rHMA, an electrophoretic pattern compatible with a non-B subtype classification. Their phylogenetic analysis, performed on both env and gag regions, confirms the rHMA subtyping prediction, given that 3 samples fall into the "A-family" subtype and 2 into the G subtype. The 5 non-B-subtype HIV-1 isolates have been identified among 23 variants (prevalence, 21.74%) isolated during the 2000 to 2001 period in heterosexuals. In parallel, B-subtype isolates show high levels of intrasubtype nucleotide divergence, compatible with a constant HIV-1 molecular diversification. CONCLUSION: The Italian HIV-1 epidemic is still mostly attributable to the B subtype, which shows an increasing nucleotide heterogeneity. Heterosexual transmission and the interracial blending, however, are slowly introducing novel HIV-1 subtypes, and the data indicate that rHMA represents a powerful tool for HIV-1 biomolecular screening in epidemics characterized by a mono-/dual-subtype predominance.     

Identification of subtype C human immunodeficiency virus type 1 by subtype-specific PCR and its use in the characterization of viruses circulating in the southern parts of India

Human immunodeficiency virus type 1 (HIV-1) subtype C viruses are associated with nearly half of worldwide HIV-1 infections and are most predominant in India and the southern and eastern parts of Africa. Earlier reports from India identified the preponderance of subtype C and a small proportion of subtype A viruses. Subsequent reports identifying multiple subtypes suggest new introductions and/or their detection due to extended screening. The southern parts of India constitute emerging areas of the epidemic, but it is not known whether HIV-1 infection in these areas is associated with subtype C viruses or is due to the potential new introduction of non-subtype C viruses. Here, we describe the development of a specific and sensitive PCR-based strategy to identify subtype C-viruses (C-PCR). The strategy is based on amplifying a region encompassing a long terminal repeat and gag in the first round, followed by two sets of nested primers; one amplifies multiple subtypes, while the other is specific to subtype C. The common HIV and subtype C-specific fragments are distinguishable by length differences in agarose gels and by the difference in the numbers of NF-kappaB sites encoded in the subtype C-specific fragment. We implemented this method to screen 256 HIV-1-infected individuals from 35 towns and cities in four states in the south and a city in the east. With the exception of single samples of subtypes A and B and a B/C recombinant, we found all to be infected with subtype C viruses, and the subtype assignments were confirmed in a subset by using heteroduplex mobility assays and phylogenetic analysis of sequences. We propose the use of C-PCR to facilitate rapid molecular epidemiologic characterization to aid vaccine and therapeutic strategies.     

Most env and gag subtype A HIV-1 viruses circulating in West and West Central Africa are similar to the prototype AG recombinant virus IBNG

The genetic subtype was identified in gag and env of 219 HIV-1-positive samples collected in different African countries, 44 from Senegal, 55 from Cameroon, 82 from Gabon, and 38 from Djibouti. In total, 20 (9.1%) samples had discordant subtypes between gag and env, 6 of 44 (13.9%) in Senegal, 4 of 55 (7.2%) in Cameroon, 1 of 38 (2.6%) in Djibouti, and 10 of 82 (12.1%) in Gabon. Subtypes A and G were predominantly involved in the recombination events. Phylogenetic tree analysis of gag showed that an important number of the A sequences form a distinct subcluster with the AG-IBNG prototype strain (a complex A/G mosaic virus): 27 of 32 (84.3%) in Senegal, 12 of 17 (70.6%) in Nigeria, 24 of 39 (61.5%) in Cameroon, and 38 of 70 (54.3%) in Gabon. Full-length genome analysis of 3 and additional sequences in pol for 10 such strains confirmed that they have a similar complex A/G mosaic genomic structure. These data suggest that in West Africa, most probably between 60% and 84% of the subtype A viruses are recombinant AG-IBNG viruses. This finding has potential implications on future vaccine, diagnostic, and treatment strategies. The actual and future role of these viruses in the global pandemic must be monitored in all new molecular epidemiologic studies, a discrimination between subtype A and AG-IBNG-like viruses is necessary.     

Genetic characterization of diverse HIV-1 strains in an immigrant population living in New York City

New York City (NYC) is one of the original foci of the HIV-1 epidemic and has a greater number of AIDS cases than any other city in the United States. NYC also hosts the highest number of immigrants among the nation's cities: more than 2 million among a total population of 8 million. Such a high rate of immigration could act as a potential source for introducing and disseminating novel HIV-1 strains into the United States. Our current study focuses on the genetic characterization of HIV-1 strains circulating in an immigrant population in NYC. Of the 505 HIV-1-positive specimens obtained, 196 were available for viral sequencing from the C2 to V3 region of env. Phylogenetic analysis using maximum-likelihood and neighbor-joining methods demonstrated that non-B subtypes and circulating recombinant forms (CRFs) accounted for 43.4% (85 of 196 cases), whereas the remaining 56.6% (111 of 196) cases had viral variants similar to the typical North American subtype B virus. Of those non-B subtypes and CRFs, subtype A and CRF02 dominated (63.5% combined); other subtypes, including C, D, F1, G, CRF01_AE, and CRF06_cpx, were also detected. Two HIV-1 sequences do not cluster with any known subtypes or CRFs. Furthermore, the distribution of non-B subtypes and CRFs was consistent with the countries of origin, suggesting that many of the study subjects were likely infected in their home country before they entered the United States. Subtype B viruses identified in the immigrant population showed no significant differences from the typical North American B subtype, however, indicating that a significant proportion of the immigrants must have been infected after they came to the United States. Public health officials and physicians should be aware of the growing genetic diversity of HIV-1 in this country, particularly in areas with sizable immigrant populations.     

High genetic diversity of HIV-1 strains in Chad,West Central Africa

The genetic diversity of HIV-1 strains in Chad was documented with a total of 107 samples from patients attending the general hospital in N'Djamena, the capital city of Chad. The genetic subtypes were identified in the V3-V5 env and p24 gag regions by sequence and phylogenetic tree analyses. Of the 107 strains, 78 had the same subtype/CRF designation between env and gag. Four subtypes and three CRFs were found to cocirculate: subtype A, 20.5%; subtype D, 18.7%; CRF02_AG, 13.1%; CRF11_cpx, 13.1%; subtype G, 3.7%; CRF01_AE, 2.8%; and subtype F1, 0.9%. The remaining 29 strains (27%) had discordant subtypes or CRF designations between env and gag; in 15 of these 29 strains, a CRF was involved in the recombination event, and 10 were subtype G in gag and subtype A in env, forming a separate subcluster within subtypes G and A. Subtype D strains represent almost 20% of the HIV-1 strains circulating in Chad and form a separate subcluster in gag and env. Nearly full-length genome sequencing for two such strains (99TCD-MN011 and 99TCD-MN012) revealed that they represent nonrecombinant subtype D variants. Compared with neighboring countries, the genetic subtype distribution of HIV-1 strains in Chad is unique for several reasons: lower prevalence of CRF02, high prevalence of CRF11 and subtype D, and absence of CRF06. These data clearly show that subtype distribution is very heterogeneous in Africa, probably the result of different founder effects.     

Temporal trends in the HIV-1 epidemic in Russia: predominance of subtype A

During the period 1996-1997, three highly homogeneous variants of HIV-1 were identified, circulating among injecting drug users (IDUs) in the former Soviet Union republics. One of these belonged to HIV-1 genetic subtype A (IDU-A), another belonged to HIV-1 genetic subtype B (IDU-B) and the third was a recombinant between the first two variants (CRF03_AB). However, since 1997, the HIV-1 epidemic has affected an increasing number of geographic regions in Russia. This study was undertaken to survey the prevailing genetic variants and to estimate the current proportions of these three HIV-1 genetic subtypes in Russia. Blood samples were taken in 1999-2003 from 1090 HIV-infected individuals and analysed by gag/env HMA. The IDU-A variant was found to be the majority variant (89.7-100%) in 44 of 45 regions of the Russian Federation studied. The IDU-A variant was also found to spreading rapidly through heterosexual transmission in 1999-2003 (30/34, 88%). CRF03_AB predominates in the Kaliningrad region only (28/29, 96.6%). The IDU-B variant is currently of minor importance in the IDU epidemic but other European subtype B variants predominate among men having sex with men (18/18, 100%). Sequence analysis of the env V3 encoding regions derived from HIV-1 infected individuals in Yekaterinburg (the main centre of the HIV-1 epidemic in Russia in 2002-2003) showed that the IDU-A variant is still highly homogeneous. The mean pairwise nucleotide distance (n = 9) was 2.89 +/- 1.14 (range 1.36-6.14). However, the mean genetic distance between each sequence within the samples collected from the Yekaterinburg IDU-A variant subset and the IDU-A consensus is 2.51 +/- 1.06 (range 1.36-4.66) and considerably higher than in South Russia in 1996 (0.79 +/- 0.51, range 0.38-1.90). The current HIV-1 epidemic in Russia is almost entirely caused by a highly homogeneous A-subtype strain, which will influence vaccine development strategies and must be taken into account in the quality control of molecular tests for the diagnosis of HIV-1.     

Differences in perinatal transmission among human immunodeficiency virus type 1 genotypes

OBJECTIVE: To determine whether genotypes from human immunodeficiency virus type 1 (HIV-1) subtypes A, C, or D or intersubtype recombinants have the same probability of being transmitted from mother to child. METHODS: We determined the HIV-1 genetic subtype and maternal risk factors of 51 matched transmitting and nontransmitting mothers from Tanzania. The HIV-1 gag (p24-p7) and env (C2-C5) nucleotide sequences were used for genotype classification, and matched logistic regression analysis was used to assess differences among genotypes. RESULTS: Mothers infected with HIV-1 subtype A (odds ratio, 3.8; 95% CI, 0.8-24.7%), HIV-1 subtype C (odds ratio, 5.1; 95% CI, 1.3-30.8%), or HIV-1 intersubtype recombinant viruses (odds ratio, 5.3; 95% CI, 1.2-33.4%) were more likely to transmit HIV-1 to their infants than mothers infected with HIV-1 subtype D. Lower CD4 cell counts at enrollment were associated with transmission, but CD4 cell counts within each genotype did not explain differences in transmission among HIV-1 genotypes. CONCLUSION: We have shown that HIV-1 genotypes might be associated with differential risk for vertical transmission. These findings provide the first evidence that HIV-1 genetic subtypes may play a role in rates of vertical transmission in an African setting.     

Genetic and neutralization properties of HIV-1 env clones from subtype B/BC/AE infections in China

BACKGROUND: As HIV vaccines move into preclinical and clinical trials in China, pseudovirion-based neutralization assays, especially those using env genes of Chinese origin, are widely required to evaluate the ability of HIV vaccines to induce neutralizing antibody (nAb) responses. MATERIALS AND METHODS: Functional gp160 genes from plasma samples from Chinese HIV-infected patients were cloned and sequenced and then used to establish a pseudovirus-based neutralization assay. The neutralization phenotypes of the Env-pseudotyped viruses were characterized with known nAbs (4E10, 2F5, IgG1b12, and 2G12) and 43 plasma samples from patients infected with different HIV subtypes. RESULTS: Overall, 27 functional gp160 genes (18 subtype BC, 3 subtype AE, and 6 subtype B) of HIV-1 were obtained, and their full-length nucleotide sequences were analyzed. The results confirmed the presence of significant genetic diversity among the clones. 4E10 neutralized all 27 Env-pseudotyped viruses, whereas IgG1b12 neutralized 44% of them. 2F5 neutralized 67% and 100% of subtype B and AE clones, respectively, but not subtype BC clones, whereas 2G12 neutralized 33% of subtype B viruses but not subtype BC and AE viruses. There were significant differences in the cross-neutralization activities when the neutralization phenotypes of the 27 Env-pseudotyped viruses were characterized using 43 HIV-positive plasma samples. CONCLUSIONS: These characterized functional HIV-1 env clones should be useful for standardizing neutralization assays in China.