HIV type 1 subtype surveillance in central Kenya

Human immunodeficiency virus 1 (HIV-1) infection is characterized by genetic diversity such that specific viral subtypes are predominant in specific geographic areas. To determine circulating subtypes of HIV-1 in different parts of central Kenya, a cross-sectional study was carried out on HIV-1-positive blood samples collected from consenting individuals in eight hospitals of Kenya's central province. Proviral DNA was extracted from peripheral blood mononuclear cells. Polymerase chain reaction and direct sequencing using primers generated from a highly conserved region of HIV-1 env gp41 were carried out. Ninety-six samples were successfully amplified and sequenced. Analysis of the sequences showed that a majority of them belonged to subtype A1 (67/96, 69.8%), followed by subtypes D (18, 18.7%) and C (11/96, 11.5%). Consistent with findings in other parts of Kenya, HIV-1 subtype A1 was the most dominant virus in circulation. Continued surveillance of circulating subtypes of HIV-1 in Kenya is important in determining the evolution of the HIV/AIDS epidemic in Kenya.     

HIV type 1 subtypes among STI patients in Nairobi: a genotypic study based on partial pol gene sequencing

Circulating strains of human immunodeficiency virus (HIV) exhibit an extraordinary degree of genetic diversity and have been classified on the basis of relationships into distinct lineages called groups, types, subtypes, and subsubtypes. Sexually transmitted infections (STIs) are known to be a risk factor for HIV infection. To establish HIV-1 subtype diversity among STI patients in Nairobi, 140 samples were collected and partial pol gene sequencing done. From the analysis it was established that subtype A1 was the major subtype (64%) followed by D (17%), C (9%), G (1%), and recombinants AD (4%), AC (3%), CRF02()AG (1%), and CRF16()A2D (1%). These results suggest that the HIV-1 epidemic may be evolving toward more virulent and complex subtypes through transmission of complex recombinants due to viral mixing. Any use of ARVs may therefore require initial testing for de novo resistance before commencement of treatment and/or management.     

Identification of env CRF-10 among HIV variants circulating in rural western Kenya

As part of a program to determine the genetic diversity of human immunodeficiency virus in rural Kenya, we carried out a molecular analysis of the C2-V3 region of HIV-infected blood samples obtained from 30 antenatal clinic attendees of seven health centers in western Kenya. Direct sequencing was carried out on the envelope C2-V3 region of proviral DNA. On phylogenetic analysis with reference strains, 20 were subtype Al, 2 were subtype D, 1 was subtype C, 1 was subtype G, 1 was CRF-10, 2A/D, 2A/C, and 2 were unclassified. The presence of CRF-10 and the great variety of subtypes and recombinants in such a limited sample size suggest that western Kenya may be a potential hotspot for HIV recombination in the country.     

HIV type 1 subtypes among blood donors in the Mbeya region of southwest Tanzania

HIV-1 is endemic in Tanzania where three different subtypes, A, C, and D, have been identified. Information on HIV-1 genetic diversity is crucial to define requirements for an effective vaccine, in regions where HIV-1 vaccine trials are planned. To define the subtype distribution of HIV-1 in the Mbeya region of southwest Tanzania, peripheral blood mononuclear cells (PBMC) and plasma were obtained from 36 discarded HIV seropositive blood units. Multiregion hybridization assay (MHA) was performed on both PBMC DNA and plasma RNA to determine the subtype distribution. Twenty virtually full-length HIV-1 sequences were amplified from the extracted DNA, sequenced, and phylogenetically analyzed. Subtype distribution determined by all three assays was comparable. More than 50% of the samples analyzed were subtype C, followed by a high proportion of subtype C-containing intersubtype recombinants. Based on this work, subtype C appears to be the prevalent subtype in southwest Tanzania, followed by a high proportion of intersubtype recombinants.     

陕西省HIV-1流行株膜蛋白基因 C2-V3区序列特征和亚型分析

目的了解陕西省HIV-1毒株的流行情况和亚型特征.方法用套式聚合酶链式反应(Nested-PCR)对6份采集于陕西省经确认为HIV-1感染者或艾滋病病人外周血淋巴细胞(PBMC)提取核酸,从6份样品中获得了HIV-1膜蛋白(ENV)基因的核酸片段进行扩增,并测定和分析了C2-V3及其邻区共312个核苷酸序列.结果 6份血样中,2份为HIV-1A亚型毒株感染(SHX7、SHX8);4份为HIV-1B'亚型(泰国B'亚型)毒株感染(SHX1、SHX5、SHX6、SHX9).SHX1、SHX5、SHX6、SHX9彼此间基因离散率为5.62%,SHX7与来自卢旺达的U08794之间的基因离散率仅为2.41%.结论陕西省目前存在HIV-1 A、B'两种亚型的毒株,HIV-1 B'亚型由邻近地区传入,HIV-1 A亚型为与非洲人接触传入.     

Genetic diversity and high proportion of intersubtype recombinants among HIV type 1-infected pregnant women in Kisumu, western Kenya

The high genetic diversity of HIV-1 continues to complicate effective vaccine development. To better understand the extent of genetic diversity, intersubtype recombinants and their relative contribution to the HIV epidemic in Kenya, we undertook a detailed molecular epidemiological investigation on HIV-1-infected women attending an antenatal clinic in Kisumu, Kenya. Analysis of gag-p24 region from 460 specimens indicated that 310 (67.4%) were A, 94 (20.4%) were D, 28 (6.1%) were C, 9 (2.0%) were A2, 8 (1.7%) were G, and 11 (2.4%) were unclassifiable. Analysis of the env -gp41 region revealed that 326 (70.9%) were A, 85 (18.5%) D, 26 (5.7%) C, 9 (2.0%) each of A2 and G, 4(0.9%) unclassifiable, and 1 (0.2%) CRF02_AG. Parallel analyses of the gag-p24 and env-gp41 regions indicated that 344 (74.8%) were concordant subtypes, while the remaining 116 (25.2%) were discordant subtypes. The most common discordant subtypes were D/A (40, 8.7%), A/D (27, 5.9%), C/A (11, 2.4%), and A/C (8, 1.7%). Further analysis of a 2.1-kb fragment spanning the gag-pol region from 38 selected specimens revealed that 19 were intersubtype recombinants and majority of them were unique recombinant forms. Distribution of concordant and discordant subtypes remained fairly stable over the 4-year period (1996-2000) studied. Comparison of amino acid sequences of gag-p24 and env-gp41 regions with the subtype A consensus sequence or Kenyan candidate vaccine antigen (HIVA) revealed minor variations in the immunodominant epitopes. These data provide further evidence of high genetic diversity, with subtype A as the predominant subtype and a high proportion of intersubtype recombinants in Kenya.     

Genetic diversification and recombination of HIV type 1 group M in Kinshasa, Democratic Republic of Congo

As the HIV-1 pandemic becomes increasingly complex, the genetic characterization of HIV strains bears important implications for vaccine research. To better understand the molecular evolution of HIV-1 viral diversity, we performed a comparative molecular analysis of HIV strains collected from high-risk persons in Kinshasa, Democratic Republic of Congo (DRC). Analysis of the gag-p24, env-C2V3 and -gp41 regions from 83 specimens collected in 1999-2000 revealed that 44 (53%) had concordant subtypes in the three regions (14 subsubtype A1, 10 subtype G, 8 subtype D, 5 subtype C, 2 each subsubtype F1 and CRF01_AE, and one each of subtypes H and J, and subsubtype A2, while the remaining 39 (47%) had mosaic genomes comprising multiple subtype combinations. Similar multisubtype patterns were also observed in 24 specimens collected in 1985. Sequence analysis of the gag-pol region (2.1 kb) from 21 discordant specimens in the gag-p24, env-C2V3 and -gp41 regions in 1985 and 1999-2000 further confirmed the complex recombinant patterns. Despite the remarkable similarity in overall subtype distribution, the intra- and intersubtype distances of major subtypes A1 and G increased significantly from 1985 to 1999-2000 (p=0.018 and p=0.0016, respectively). Given the complexity of HIV-1 viruses circulating in DRC, efforts should focus on the development of vaccines that result in cross-clade immunity.     

Forty-one near full-length HIV-1 sequences from Kenya reveal an epidemic of subtype A and A-containing recombinants

OBJECTIVE: To further define the genetic diversity of HIV-1 in Kenya using approaches that clearly distinguish subtypes from inter-subtype recombinants. DESIGN: Near full genome sequencing and analysis were used, including sensitive new tools for detection and mapping of recombinants. METHODS: Purified peripheral blood mononuclear cell DNA from 41 HIV-1 positive blood donations collected from six hospitals across southern Kenya was used to amplify near full-length genomes by nested PCR. These were sequenced on an ABI 3100 automated sequencer and analyzed phylogenetically. RESULTS: Among 41 near full-length genomes, 25 were non-recombinant (61%) and 16 were recombinant (39%). Of the 25 pure subtypes, 23 were subtype A, one was subtype C and one was subtype D. Most recombinants consisted of subtype A and either subtype C or subtype D; a few contained A2, a recently identified sub-subtype. Two A2/D recombinants had identical breakpoints and may represent a circulating recombinant form. A third A2/D recombinant had the same structure as a previously described Korean isolate, and these may constitute a second A2-containing circulating recombinant form. CONCLUSIONS: In Kenya, 93% of HIV-1 genomes were subtype A or A-containing recombinant strains. Almost 40% of all strains were recombinant. Vaccine candidates tested in Kenya should be based on subtype A strains, but the methods used for evaluation of breakthrough infections during future vaccine trials should be capable of identifying non-A subtypes, the A2 sub-subtype, and recombinants.     

The influence of the expanding HIV genetic diversity on molecular diagnosis in the Philippines

Since the discovery in the Philippines of the first AIDS case in 1984, several subtypes of HIV-1 have been discovered. From the persons diagnosed in the early 1980s only subtype B was found and thereafter other subtypes, C, D, E, and F were also identified although HIV was not particularly prevalent at that time. In this paper, we determine whether the rapid expansion of genetic diversity will influence molecular diagnosis by polymerase chain reaction (PCR). First, we determine HIV-1 subtype on env (V3) and gag (p24) gene as a means of rapid genetic diversity. Secondly, we tried to analyse and identify homologous regions of gag (p24) gene of HIV genome for diagnostic purposes of designing primers. Out of 46 samples analysed, six subtypes were classified based on gag and env gene subtyping namely: 33 subtype B/B (71.2%), nine subtype A/E and one each subtype C/C, A/B and G/A (2.2% each). As a result, occurrence of non-subtype B and inter-subtype recombinant contributed to expanding genetic diversity. Based on inter- and intra-subtype gag alignment, oligonucleotides (>10 bases in length) could be easily selected as a universal primer to produce the PCR product composed of more than 100bp. This indicates that the PCR technology can be safely used with limited length of primers for the diagnosis of HIV infection in this country.     

Global and regional distribution of HIV-1 genetic subtypes and recombinants in 2004

OBJECTIVE: To estimate the global and regional distribution of HIV-1 subtypes and recombinants in 2004. DESIGN: A study was conducted in which molecular epidemiological data on HIV-1 subtype distribution in individual countries were combined with country-specific estimates of the number of people living with HIV. METHODS: HIV-1 subtype data were collected for 23 874 HIV-1 samples from 70 countries, which together accounted for 89% of all people living with HIV worldwide in 2004. The proportions of HIV-1 infections due to various subtypes detected in each country were combined with the number of HIV infected people in the respective countries to generate regional and global HIV-1 subtype distribution estimates. RESULTS: Subtype C accounted for 50% of all infections worldwide in 2004. Subtypes A, B, D and G accounted for 12%, 10%, 3% and 6%, respectively. The subtypes F, H, J and K together accounted for 0.94% of infections. The circulating recombinant forms CRF01_AE and CRF02_AG each were responsible for 5% of cases, and CRF03_AB for 0.1%. Other recombinants accounted for the remaining 8% of infections. All recombinant forms taken together were responsible for 18% of infections worldwide. CONCLUSION: Combining data on HIV-1 subtype distribution in individual countries with country-specific estimates of the number of people living with HIV provided a good method to generate estimates of the global and regional HIV-1 genetic diversity in 2004. The results could serve as an important resource for HIV scientists, public health officials and HIV vaccine developers.     

Relationship between HIV-1 Env subtypes A and D and disease progression in a rural Ugandan cohort

OBJECTIVE: To investigate the role of HIV-1 envelope subtypes on disease progression in a rural cohort of Ugandan adults where two major HIV-1 subtypes (A and D) exist. METHODS: Participants of a clinical cohort seen between December 1995 and December 1998 had blood collected for HIV-1 subtyping. These included prevalent cases (people already infected with HIV at the start of the study in 1990) and incident cases (those who seroconverted between 1990 and December 1998). HIV-1 subtyping was carried out by heteroduplex mobility assay and DNA sequencing in the V3 env region. Disease progression was measured by the rate of CD4 lymphocyte count decline, clinical progression for the incident cases as time from seroconversion to AIDS or death, to first CD4 lymphocyte count < 200 x 10(6)/l and to the World Health Organization clinical stage 3. All analyses were adjusted for age and sex. RESULTS: One hundred and sixty-four individuals, including 47 prevalent and 117 incident cases, had V3 env subtype data of which 65 (40%) were subtyped as A and 99 as D. In the incident cases, 44 (38%) were subtyped as A and 73 as D. There was a suggestion that for most end-points A had a slower progression than D. The cumulative probability of remaining free from AIDS or death at 6 years post-seroconversion was 0.72 [95% confidence interval (CI), 0.50 to 0.85] for A and 0.58 (95% CI, 0.42 to 0.71) for D, and the adjusted hazard ratio of subtype D compared to A was estimated to be 1.39 (95% CI, 0.66 to 2.94; P = 0.39). The estimated difference in rates of decline in square root CD4 lymphocyte counts was -0.41 per year (95% CI, -0.98 to 0.15; P = 0.15). CONCLUSION: This study suggests that although subtype A may have a slower progression than D, HIV-1 envelope subtype is not a major factor in determining the progression of HIV-1 disease in a rural population in Uganda.     

出入境人群HIVenv基因部分序列特征和亚型研究

目的 对出入境人员中的艾滋病病毒(HIV)感染者进行病毒基因型测定，监测国内外流行的HIV毒株的状况及其变化。方法 用逆转录-聚合酶链反应(RT-PCR)或直接套式PCR方法扩增HIVenv基因C2-V3区及其邻近的基因片段，然后直接进行核苷酸序列测定，与国际标准亚型序列比较，确定基因型并进行系统分析。结果 2003年确认的19例HIV阳性样品中，15例扩增出目的基因片段并进行了序列测定，确定为B亚型4例，B’亚型2例，D亚型2例，CRF01-AE重组亚型1例，CRF02-AG重组亚型6例。这些不同亚型的HIV-1感染者来自包括中国在内的6个国家。HIV-1基因型的分布与我国国内有很大不同。结论 出入境人群中HIV-1基因型种类多且复杂，监测出入境人群HIV基因型及其变化对于发现和鉴定新型变异毒株十分重要。     

Molecular epidemiology of HIV type 1 infection in Portugal: high prevalence of non-B subtypes

In this study, we have investigated the diversity of current HIV-1 strains circulating in the metropolitan area of Lisbon, Portugal. A total of 217 HIV-1-positive blood samples, collected between October 1998 and December 2000, was genetically characterized in the gp120 C2V3C3 region (n = 205) or part of the gp41 N-terminal segment (n = 12) by heteroduplex mobility assay (HMA) and/or DNA sequencing. The HMA subtyping efficiency (number of samples unambiguously subtyped by HMA divided by the total number of samples subtyped) was 65.9% (143 of 217), with indeterminate migration patterns of subtype A and G strains contributing significantly to this value. On the overall, subtype B was the most prevalent (50.2%), followed by subtypes G (21.7%), A (17.5%), and F (5.5%), whereas subtypes C, D, H, and J accounted altogether for 5.1% of the infections. Non-B subtypes were responsible for 77.4 and 33.1% of the infections among African immigrants and Portuguese subjects, respectively. Angolan individuals (n = 25) were the only ones infected with all the HIV-1 subtypes documented, probably reflecting a high degree of viral genetic diversification in their country of origin. Phylogenetic analysis showed a predominance of IbNG-like viruses among subtype A sequences and two new major subclusters within subtype G (G(P) and G(P)'). The majority of the Portuguese G sequences described formed a well-defined subcluster (G(P)), supported by bootstrap values >90%, phylogenetically distant from clade G sequences in databases. gag (p24/p7) sequence analysis of these variants confirmed the maintenance of the subtype G subclusters. The multiple subclustering observed for the major clades A, B, D, and G, as well as the variety of subtypes found, indicate a high diversity of HIV-1 variants circulating in Portugal and suggest a need for continuous epidemiologic surveillance.     

Diversity of human immunodeficiency virus type 1 subtypes in Kagera and Kilimanjaro regions, Tanzania

A strategy to prevent the spread of HIV-1 worldwide is complicated by the high genetic diversity of the virus. To gain a better understanding of the HIV-1 genetic diversity in Tanzania, a molecular epidemiological investigation was conducted in Kagera and Kilimanjaro regions. While several studies have addressed HIV-1 subtypes in Tanzania, this is the first study to describe the virus subtypes circulating in Kagera. The Kagera region is the epicenter of the HIV-1 epidemic in Africa, and it was therefore of interest to compare the prevalence of HIV subtypes in this region and Kilimanjaro. Blood samples were obtained from 246 HIV-1-infected pregnant women attending antenatal clinics. Plasma HIV-1 RNA was extracted, amplified, and sequenced in the env C2V3 and/or pol regions from 209 samples. Based on the analysis of env C2V3 and pol sequences, 47.4% had concordant subtypes, 19.1% were discordant indicating recombination, and for 33.5% sequences were obtained for only one region. The distribution HIV-1 subtypes based on the phylogenetic analysis of paired env C2V3/ pol sequences in Kagera region was A/A (27.8%), C/C (29.6%), D/D (16.7%), and unique recombinant forms (25.9%), and in Kilimanjaro region was A/A (32.9%), C/C (25.9%), D/D (10.6%), CRF10_CD (1.2%), and unique recombinant forms (29.4%). The env C2V3 subsubtype A2 and env C2V3/pol CRF10_CD were also observed indicating that these recombinants are circulating in Tanzania. The high diversity of HIV-1 subtypes and the high prevalence of recombinants demonstrated in this study necessitate expanded and continuous monitoring of the epidemic in Tanzania. The trend may have implications for current national control strategies against the HIV-1 epidemic.     

Twenty years of prospective molecular epidemiology in Senegal: changes in HIV diversity

Over a 20-year period we have observed the dynamics of HIV-1 subtypes and HIV-2 infection in a prospective cohort of registered female sex workers (FSW) in Dakar, Senegal. Prevalence and incidence rates for HIV-1 and HIV-2 are described from 290 seroprevalent and 193 seroincident subjects who were among the 3,910 women enrolled between 1985 and 2004. We report a significant decrease of HIV-2 prevalence in the cohort, parallel to the introduction and rise of HIV-1 infection. In 328 HIV-1-infected women, a 385-bp C2-V3 fragment of the envelope gene was sequenced and classified into the following subtypes or recombinant forms: 239 (72%) were subtype A [of which 180 (55%) were CRF02_AG and 53 (16%) were A3], 10 (3%) were B, 12 (4%) were C, 11 (4%) were D, 18 (6%) were G, 24 (7%) were CRF06_cpx, and 7 (2%) were CRF09_cpx. We found an increasing proportion of CRF02_AG over many years, but recently subsubtype A3 has over-taken CRF02_AG, with the largest proportion of new infections. The predominance of existing HIV-1 subtypes did not preclude the emergence and increase of other closely related subtypes or recombinant forms. This 20-year prospective serological and sequence analysis of HIV viruses reveals a complex and changing HIV epidemic in Senegal.     

Identification and characterization of HIV type 1 subtypes present in the Kingdom of Saudi Arabia: high level of genetic diversity found

Saudi Arabia has a very low prevalence of HIV infections and nothing is known about HIV strains present in the population. Here specimens were collected from 62 HIV-1-infected patients at the King Faisal Specialist Hospital and Research Center, Jeddah, Saudi Arabia. Viral sequences were PCR amplified using primers for HIV-1 group M in gag p24, pol integrase, and env gp41 and genetic subtype was determined by phylogenetic analysis. HIV-1 viral sequences were amplified from 56 of the 62 specimens. Based on phylogenetic analysis of viral sequences, subtype C was the most common subtype present and accounted for 39.3% of the infections followed by subtype G (25%), subtype B (17.9%), subtype D (3.6%), and subtypes A and CRF02_AG (1.8% each). In addition, for six specimens subtype classifications were discordant between gag, pol, and/or env; these intersubtype recombinant viruses account for 10.7% of the infections and consisted of recombinants of subtypes A/CRF01, A/CRF02, A/G, B/G, and D/CRF02. The high HIV-1 strain diversity suggests that there have been multiple introductions of HIV-1 into Saudi Arabia from several sources. Within the study population, there were five husband/wife pairs. For each pair, the viral sequences obtained were closely related to each other showing that heterosexual transmission occurred.     

Among 46 near full length HIV type 1 genome sequences from Rakai District,Uganda, subtype D and AD recombinants predominate

The impact of HIV-1 genetic diversity on candidate vaccines is uncertain. To minimize genetic diversity in the evaluation of HIV-1 vaccines, vaccine products must be matched to the predominant subtype in a vaccine cohort. To that end, full genome sequencing was used to detect and characterize HIV-1 subtypes and recombinant strains from individuals in Rakai District, Uganda. DNA extracted from peripheral blood mononuclear cells (PMBC) was PCR amplified using primers in the long terminal repeats (LTRs) to generate nearly full length genomes. Amplicons were directly sequenced with dye terminators and automated sequencers. Sequences were phylogenetically analyzed and recombinants were detected and mapped with distance scan and bootscan. Among 46 sequences, 54% were subtype D, 15% were subtype A, and 30% were recombinant. All recombinants were individually unique, and most combined subtypes A and D. Subtype D comprised more than 70% of all the HIV-1 genomes in Rakai when both pure subtypes and recombinants were considered. Candidate vaccines based on HIV-1 subtype D would be appropriate for evaluation in Rakai District, Uganda.