Mateusz M. Urbanski

Preferential use of the VH5-51 gene segment by the human immune response to code for antibodies against the V3 domain of HIV-1.

Human anti-V3 monoclonal antibodies (mAbs) generated from HIV-1 infected individuals display diversity in the range of their cross-neutralization that may be related to their immunogenetic background. The study of the immunoglobulin (Ig) variable region gene usage of heavy chains have shown a preferential usage of the VH5-51 gene segment which was detected in 35% of 51 human anti-V3 mAbs. In contrast, human mAbs against other envelope regions of HIV-1 (anti-Env), including the CD4-binding domain, the CD4-induced epitope, and gp41 preferentially used the VH1-69 gene segment, and none of them used the VH5-51 gene. Furthermore, the usage of the VH4 family by anti-V3 mAbs was restricted to only one gene segment, VH4-59, while the VH3 gene family was used at a significantly lower frequency by all of the analyzed anti-HIV-1 mAbs. Multivariate analysis showed that usage of VH gene segments was significantly different between anti-V3 and anti-Env mAbs, and compared to antibodies from healthy subjects. In addition, the anti-V3 mAbs preferentially used the JH3 and D2-15 gene segments. The preferential usage of selected Ig gene segments and the characteristic pattern of Ig gene usage by anti-V3 mAbs can be related to the conserved structure of the V3 region.

Genetic and Biological Properties of HIV Type 1 Isolates Prevalent in Villagers of the Cameroon Equatorial Rain Forests and Grass Fields: Further Evidence of Broad HIV Type 1 Genetic Diversity

To understand the evolution of HIV-1, the genetic and biological characteristics of viruses that infect persons living in regions in which the virus has been evolving for several decades must be studied. Thus, we investigated teh genetic subtypes, coreceptor usage, and syncytium-inducing ability of viruses in 47 HIV-1-infected blood samples from individuals living in rural villages in the equatorial rain forest and grass field regions in Cameroon. Heteroduplex mobility analysis (HMA) of gag (part of p24 and p7) and env (C2V5) or sequence and phylogenetic analysis of gag (part of p24 and p7), pol (protease), and env (C2V5), revealed a broad HIV-1 group M genetic diversity. Subtype analysis revealed genetic evidence of seven subtypes (A, C, D, F, G, H, and J) and three circulating recombinant froms (CRFs) (CRF01_AE, CRF02_AG, and CRF11_cpx). Only 15 (32%) of the 47 samples analyzed revealed a concordant subtype in all three genes (gag, pol, and env), while discordant subtypes and CRFs were identified for the remaining 32 (68%) samples. Two patterns of HIV-1 diversity could be discerned in two provinces. While more concordant subtypes in gag, pol, and env genes were identified in villages of South province (10 of 13, 77%), the HIV-1 diversity in the West province was characterized by intersubtype recombinants (63%). Five new intersubtype recombinants were identified including Agag Jpol Genv, Ggag Upol Aenv, AGgag Jpol Aenv, Agag AGpol Henv, and Cgag AGpol AGenv. All of the 40 viruses tested used the R5 coreceptor, of which four also used the X4 coreceptor. Four viruses were able to induce syncytia in MT-2 cells, however, syncytium induction did not correlate with coreceptor usage. This study further reveals the complexity of HIV-1 infection in rural Cameron and points to the future of the global epidemic, which may be characterized by more genetically diverse viruses.

HIV type 1 group M clades infecting subjects from rural villages in equatorial rain forests of Cameroon.

Summary: Though the HIV‐1 subtypes infecting patients living in urban and semiurban areas in Cameroon have been reported, information on the subtypes infecting patients in rural villages is lacking. To begin to understand the diversity of the HIV‐1 group M subtypes infecting persons living in rural villages in the equatorial rain forest regions of Cameroon, 49 plasma samples from 14 rural villages in four provinces of Cameroon were analyzed using heteroduplex mobility analysis (HMA), DNA sequencing, and phylogenetic tree analysis on the basis of env C2V5, gag, or pol regions. Sixty‐one percent of the group M infections were clade A or CRF02_AG‐like as subtyped by env and gag. Of the remaining group M infections, 12% were either A or CRF02_AG‐like or CRF01_AE‐like in recombination with other clades; 25% were infections that were entirely non‐A or non‐CRF02_AG‐like; and 2% were CRF1l_cpx. The HIV‐1 group M clades identified included A, D, F (F2), G, and H. The CRF strains identified were CRF02_AG‐like, CRF01_AE‐like, and CRF11_cpx. Two new intersubtype recombinant infections, H/G and A/F2, were identified. This study suggests that the HIV‐1 diversity in rural villages in the equatorial rain forest of Cameroon is at least as broad as has been observed in major cities of Cameroon and that multiple HIV‐1 group M subtypes are infecting persons living in the countryside of Cameroon.

Predominance of infection with HIV-1 circulating recombinant form CRF02_AG in major Cameroonian cities and towns.

Our observations add to previous results on molecular epidemiology in different provinces in Cameroon demonstrating a high prevalence of CRF02_AG and subtype A accounting for 90% of circulating HIV-1 strains. The country-wide high prevalence of HIV-1 CRF02_AG in Cameroon compared with the relatively low prevalence of CRF02_AG in the Democratic Republic of Congo suggest an early founder effect of this AG recombinant in West Central Africa initiating major CRF02 epidemics. (excerpt)

High frequency of HIV-1 dual infections among HIV-positive individuals in Cameroon, West Central Africa.

Objectives:To determine the frequency of dual inter- and intra-subtype HIV-1 infection among a cohort of 64 longitudinally-studied, HIV-1-positive individuals in Yaoundé, Cameroon. Methods:Blood was collected every 3-6 months for up to 36 months and RNA was extracted from plasma. Gag fragment (HxB2 location 1577-2040) was amplified by nested RT-PCR, and mixed-time-point Heteroduplex Assays (HDAs) were performed. As heteroduplexes in this assay indicate ≥5% genetic discordance in the gag fragment, their presence reveals dual infection. Results were confirmed by phylogenetic analysis. Results:Heteroduplexes were generated by specimens of 10 subjects (15.6%). Kaplan-Meier nonparametric estimate of maintenance of single infection was calculated; the rate/year of a 2nd infection was found to be ~11%. Dual infection was identified in the final specimens of five subjects, after as much as 18 months follow-up, while for the remaining five subjects, dual infection was identified in interim specimens within an average of 10 months follow-up. Analysis of samples obtained after dual infection from each of these latter five subjects revealed two patterns: reversion to initial strain, or replacement of initial strain. Four subjects were dually-infected with HIV-1 strains of the same subtype, while 6 were infected with different subtypes. Conclusions:The high prevalence of recombinant HIV-1 strains in Cameroon may in part be explained by the high frequency of dual infection. In this genetically-diverse HIV-1 milieu, dual infections and the recombinant viruses they generate are strongly driving viral evolution, complicating vaccine strategies.

Infection with HIV type 1 group M non-B subtypes in individuals living in New York City

Objective: To document infection with HIV type 1 (HIV-1) group M non-B subtypes in individuals living in New York City. Design: From October 1999 through April 2003, HIV-1–seropositive individuals were selected from 3 clinics in New York City based on having risk factors for infection with HIV-1 non-B subtypes. Methods: HIV-1 RNA was extracted from plasma samples, and partial gag, pol, or env genes were amplified by PCR analysis. The infecting HIV-1 group M subtype was determined based on results of either heteroduplex mobility assay or sequencing and phylogenetic analysis. Results: Ninety-seven subjects were enrolled in the study. Of the 97 subjects, 91 (94%) were selected based on having emigrated from a non-European country, while 6 (6%) were native United States citizens. Subtypes were successfully determined in 53 (55%) of the 97 plasma samples tested. The subtypes in 2 plasma samples were unclassifiable. HIV-1 infections were classified as those due to the following group M subtypes: A (n = 4; 7%), B (n = 12; 22%), C (n = 8; 15%), F (n = 2; 4%), CRF01_AE–like (n = 7; 13%), CRF02_AG–like (n = 19; 34%), an intersubtype recombinant form Ggag/Aenv (n = 1; 2%), and unclassifiable viruses (n = 2; 4%). Conclusion: This study reveals infection with a broad variety of HIV-1 group M subtypes mostly in the immigrant population of New York City as well as how several non-B subtypes are being introduced into the United States.

Neutralization Patterns and Evolution of Sequential HIV Type 1 Envelope Sequences in HIV Type 1 Subtype B-Infected Drug-Naive Individuals

To design a vaccine that will remain potent against HIV-1, the immunogenic regions in the viral envelope that tend to change as well as those that remain constant over time must be identified. To determine the neutralization profiles of sequential viruses over time and study whether neutralization patterns correlate with sequence evolution, 12 broadly neutralizing plasmas from HIV-1 subtype B-infected individuals were tested for their ability to neutralize sequential primary HIV-1 subtype B viruses from four individuals. Three patterns of neutralization were observed, including a loss of neutralization sensitivity by viruses over time, an increase in neutralization sensitivity by sequential viruses, or a similarity in the sensitivity of sequential viruses to neutralization. Seven to 11 gp160 clones from each sequential virus sample were sequenced and analyzed to identify mutational patterns. Analysis of the envelope sequences of the sequential viruses revealed changes characteristic of the neutralization patterns. Viruses that evolved to become resistant to neutralizing antibodies also evolved with diverse sequences, with most of the changes being due to nonsynonymous mutations occurring in the V1/V2, as well as in the constant regions (C2, C3, C4), the most changes occurring in the C3. Viruses from the patient that evolved to become more sensitive to neutralization exhibited less sequence diversity with fewer nonsynonymous changes that occurred mainly in the V1/V2 region. The V3 region remained constant over time for all the viruses tested. This study demonstrates that as viruses evolve in their host, they either become sensitive or resistant to neutralization by antibodies in heterologous plasma and mutations in different envelope regions account for these changes in their neutralization profiles.

Utility of the Heteroduplex Assay (HDA) as a Simple and Cost-Effective Tool for the Identification of HIV Type 1 Dual Infections in Resource-Limited Settings

The predominance of unique recombinant forms (URFs) of HIV-1 in Cameroon suggests that dual infection, the concomitant or sequential infection with genetically distinct HIV-1 strains, occurs frequently in this region; yet, identifying dual infection among large HIV cohorts in local, resource-limited settings is uncommon, since this generally relies on labor-intensive and costly sequencing methods. Consequently, there is a need to develop an effective, cost-efficient method appropriate to the developing world to identify these infections. In the present study, the heteroduplex assay (HDA) was used to verify dual or single infection status, as shown by traditional sequence analysis, for 15 longitudinally sampled study subjects from Cameroon. Heteroduplex formation, indicative of a dual infection, was identified for all five study subjects shown by sequence analysis to be dually infected. Conversely, heteroduplex formation was not detectable for all 10 HDA reactions of the singly infected study subjects. These results suggest that the HDA is a simple yet powerful and inexpensive tool for the detection of both intersubtype and intrasubtype dual infections, and that the HDA harbors significant potential for reliable, high-throughput screening for dual infection. As these infections and the recombinants they generate facilitate leaps in HIV-1 evolution, and may present major challenges for treatment and vaccine design, this assay will be critical for monitoring the continuing pandemic in regions of the world where HIV-1 viral diversity is broad.

A heteroduplex assay for the rapid detection of dual Human Immunodeficiency Virus Type 1 infections

The predominance of circulating and unique recombinant forms (URFs) of Human Immunodeficiency Virus Type 1 (HIV-1) in Cameroon suggests that dual infection occurs frequently in this region. Despite the potential impact of these infections on the evolution of HIV diversity, relatively few have been detected. The failure to detect dual infections may be attributable to the laborious and costly sequence analysis involved in their identification. As such, there is a need for a cost-effective, more rapid method to efficiently distinguish this subset of HIV-positive individuals, particularly in regions where HIV diversity is broad. In the present study, the heteroduplex assay (HDA) was developed to detect dual HIV-1 infection. This assay was validated on sequential specimens obtained from 20 HIV+ study subjects, whose single or dual infection status was determined by standard sequence analysis. By mixing gag fragments amplified from the sequential specimens from each study subject in HDA reactions, it was shown that single and dual infection status correlated with the absence and presence, respectively, of heteroduplex bands upon gel electrophoresis. Therefore, this novel assay is capable of identifying dual infections with a sensitivity and specificity equivalent to that of sequence analysis. Given the impact of dual infection on viral recombination and diversity, this simple technique will be beneficial to understanding HIV-1 evolution within an individual, as well as at a population level, in West-Central Africa and globally.