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. 1996 Nov;70(11):8209–8212. doi: 10.1128/jvi.70.11.8209-8212.1996

Human immunodeficiency virus type 1 subtypes defined by env show high frequency of recombinant gag genes. The UNAIDS Network for HIV Isolation and Characterization.

M Cornelissen 1, G Kampinga 1, F Zorgdrager 1, J Goudsmit 1
PMCID: PMC190904  PMID: 8892955

Abstract

Genetic subtypes of human immunodeficiency virus type 1 can be distinguished on the basis of phylogenetic analysis of their envelope (env) gene. A significant proportion of human immunodeficiency virus type 1 strains was retrospectively shown to result from recombination events between viruses belonging genetically to distinct subtypes (D. L. Robertson, P. M. Sharp, F. E. McCutchan, and B. H. Hahn, Nature [London] 374:124-126, 1995). To establish the frequency of natural infections with recombinant viruses and to exclude tissue culture artifacts, we analyzed plasma samples from the UNAIDS sample collection. The collection includes samples from 53 individuals infected with subtype A (n = 9), subtype B (n = 15), subtype C (n = 1), subtype D (n = 13), and subtype E (n = 15) on the basis of V3 region analysis. Phylogenetic analysis of the gag gene fragment showed intersubtype recombinant genomes in 23 cases: 3 of 9 (33%) of subtype A, 2 of 15 (13%) of subtype B, 3 of 13 (23%) of subtype D, and all of subtype E. Of the 23 recombinant viruses, 19 had a gag gene from one subtype and env from another (B(env)/C(gag), A(env)/C(gag), D(env)/A(gag), and E(env)/A(gag)). Phylogenetic analysis clustered the A(gag) of subtype E viruses as an outgroup of subtype A, suggesting that these viruses may belong to a distinct A' cluster. The remaining four recombinant viruses (B(env)/B(p17)F(p24), A(env)/A(p17)D(p24), A(env)/A(p17)C(p24), and D(env)/ D(p17)A(p24)) had breakpoint crossover sites in the proximity of the p17-p24 protein processing site. We conclude that recombination in the gag gene is highly frequent among the major env subtypes and that selection of recombinants is apparently based on particularly beneficial combinations of gag and env gene products.

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Selected References

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