Beatrice H. Hahn scite author profile

Most simian–human immunodeficiency viruses (SHIVs) bearing envelope (Env) glycoproteins from primary HIV-1 strains fail to infect rhesus macaques (RMs). We hypothesized that inefficient Env binding to rhesus CD4 (rhCD4) limits virus entry and replication and could be enhanced by substituting naturally occurring simian immunodeficiency virus Env residues at position 375, which resides at a critical location in the CD4-binding pocket and is under strong positive evolutionary pressure across the broad spectrum of primate lentiviruses. SHIVs containing primary or transmitted/founder HIV-1 subtype A, B, C, or D Envs with genotypic variants at residue 375 were constructed and analyzed in vitro and in vivo. Bulky hydrophobic or basic amino acids substituted for serine-375 enhanced Env affinity for rhCD4, virus entry into cells bearing rhCD4, and virus replication in primary rhCD4 T cells without appreciably affecting antigenicity or antibody-mediated neutralization sensitivity. Twenty-four RMs inoculated with subtype A, B, C, or D SHIVs all became productively infected with different Env375 variants—S, M, Y, H, W, or F—that were differentially selected in different Env backbones. Notably, SHIVs replicated persistently at titers comparable to HIV-1 in humans and elicited autologous neutralizing antibody responses typical of HIV-1. Seven animals succumbed to AIDS. These findings identify Env–rhCD4 binding as a critical determinant for productive SHIV infection in RMs and validate a novel and generalizable strategy for constructing SHIVs with Env glycoproteins of interest, including those that in humans elicit broadly neutralizing antibodies or bind particular Ig germ-line B-cell receptors.

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Nuclear import and cell cycle arrest functions of the HIV-1 Vpr protein are encoded by two separate genes in HIV-2/SIV(SM).

Fletcher

et al. 1996

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The vpr genes of human and simian immunodeficiency viruses (HIV/SIV) encode proteins which are packaged in the virus particle. HIV‐1 Vpr has been shown to mediate the nuclear import of viral reverse transcription complexes in non‐dividing target cells (e.g. terminally differentiated macrophages), and to alter the cell cycle and proliferation status of the infected host cell. Members of the HIV‐2/SIV(SM) group encode, in addition to Vpr, a related protein called Vpx. Because these two proteins share considerable sequence similarity, it has been assumed that they also exhibit similar functions. Here, we report that the functions of Vpr and Vpx are distinct and non‐redundant, although both proteins are components of the HIV‐2/SIV(SM) virion and reverse transcription complex. Characterizing SIV(SM) proviruses defective in one or both genes, we found that Vpx is both necessary and sufficient for the nuclear import of the viral reverse transcription complex. In contrast, Vpr, but not Vpx, inhibited the progression of infected host cells from the G2 to the M phase of the cell cycle. Thus, two independent functions of the HIV‐1 Vpr protein are encoded by separate genes in HIV‐2/SIV(SM). This segregation is consistent with the conservation of these genes in HIV‐2/SIV(SM) evolution, and underscores the importance of both nuclear transport and cell cycle arrest functions in primate lentivirus biology.

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Mosaic genome structure of simian immunodeficiency virus from west African green monkeys.

et al. 1994

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Elucidation of the phylogenetic origins of simian and human immunodeficiency viruses (SIV and HIV) is fundamental to the understanding of HIV pathogenesis and the spread of AIDS worldwide. In this study, we molecularly characterized multiple SIVAGM isolates from four different African green monkey species (vervet, grivet, sabaeus and tantalus monkeys). Phylogenetic analysis of partial (1 kb) env sequences indicated that all SIVAGM strains cluster together, and that they fall into four distinct sequence sub‐groups according to their species of origin. However, alignment of long terminal repeat sequences revealed that SIVs from West African sabaeus monkeys contain a structural feature (a duplication of the transactivation response element) thus far only found in otherwise highly divergent lentiviruses infecting sooty mangabeys (SIVSM) and humans (HIV‐2). To determine whether there were additional similarities with the SIVSM/HIV‐2 group, a full‐length replication competent sabaeus provirus was cloned and sequenced. In phylogenetic trees derived from the central and 3′ coding regions, the sabaeus virus clustered with SIVAGM isolates from other African green monkey species. However, in trees derived from the 3′ half of gag and the adjacent 5′ region of pol, the sabaeus virus grouped with the SIVSM/HIV‐2 lineage. These results indicated that the sabaeus virus comprised a mosaic genome which must have resulted from recombination of divergent lentiviruses in the distant past. A second, independent sabaeus isolate exhibited similar phylogenetic relationships, suggesting that all West African green monkey viruses share this complex evolutionary history. Taken together, these results indicate that African green monkeys have been infected with SIVAGM for very long periods of time, and that recombination and cross‐species transmission in the wild have contributed to the genetic complexity of primate lentiviruses.

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IFI16 Targets the Transcription Factor Sp1 to Suppress HIV-1 Transcription and Latency Reactivation

Hotter

Bosso

Jønsson

et al. 2019

Cell Host & Microbe

105

149

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The heterosexual human immunodeficiency virus type 1 epidemic in Thailand is caused by an intersubtype (A/E) recombinant of African origin

Gao

Robertson

Morrison

et al. 1996

J Virol

334

149

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Since 1989, human immunodeficiency virus type 1 (HIV-1) has spread explosively through the heterosexual population in Thailand. This epidemic is caused primarily by viruses classified as "subtype E", which, on the basis of limited sequence comparisons, appear to represent hybrids of subtypes A (gag) and E (env). However, the true evolutionary origins of "subtype E" viruses are still obscure since no complete genomes have been analyzed, and only one full-length subtype A sequence has been available for phylogenetic comparison. In this study, we determined full-length proviral sequences for "subtype E" viruses from Thailand (93TH253) and the Central African Republic (90CR402) and for a subtype A virus from Uganda (92UG037). We also sequenced the long terminal repeat (LTR) regions from 16 virus strains representing clades A, C, E, F, and G. Detailed phylogenetic analyses of these sequences indicated that "subtype E" viruses do indeed represent A/E recombinants with multiple points of crossover along their genomes. The extracellular portion of env, parts of vif and vpr, as well as most of the LTR are of subtype E origin, whereas the remainder of the genome is of subtype A origin. The possibility that the discordant phylogenetic positions of "subtype E" viruses in gag-and env-derived trees are the result of unusual rates or patterns of evolution was also considered but was ruled out on the basis of two lines of evidence: (i) phylogenetic trees constructed for synonymous and nonsynonymous substitutions yielded the same discordant branching orders for "subtype E" gag and env gene sequences, thus excluding selection-driven evolution, and (ii) multiple crossovers in the viral genome are most consistent with the copy choice model of recombination and have been observed in other documented examples of HIV-1 intersubtype recombination. Thai and CAR "subtype E" viruses exhibited the same pattern of A/E mosaicism, indicating that the recombination event occurred in Africa prior to the spread of virus to Asia. Finally, all "subtype E" viruses were found to contain a distinctive two-nucleotide bulge in their transactivation response (TAR) elements. This feature was present only in viruses which also contained a subtype A 5 pol region (i.e., subtype A viruses or A/D and A/E recombinants), raising the possibility of a functional linkage between the TAR region and the polymerase. The implications of epidemic spread of a recombinant HIV-1 strain to viral natural history and vaccine development are discussed.

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Beatrice H. Hahn

Envelope residue 375 substitutions in simian–human immunodeficiency viruses enhance CD4 binding and replication in rhesus macaques

Nuclear import and cell cycle arrest functions of the HIV-1 Vpr protein are encoded by two separate genes in HIV-2/SIV(SM).

Mosaic genome structure of simian immunodeficiency virus from west African green monkeys.

IFI16 Targets the Transcription Factor Sp1 to Suppress HIV-1 Transcription and Latency Reactivation

The heterosexual human immunodeficiency virus type 1 epidemic in Thailand is caused by an intersubtype (A/E) recombinant of African origin

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