Human immunodeficiency virus type 1 genetic recombination is more frequent than that of Moloney murine leukemia virus despite similar template switching rates.

Retroviral recombinants result from template switching between copackaged viral genomes. Here, marker reassortment between coexpressed vectors was measured during single replication cycles, and human immunodeficiency virus type 1 (HIV-1) recombination was observed six- to sevenfold more frequently than murine leukemia virus (MLV) recombination. Template switching was also assayed by using transduction-type vectors in which donor and acceptor template regions were joined covalently. In this situation, where RNA copackaging could not vary, MLV and HIV-1 template switching rates were indistinguishable. These findings argue that MLV's lower intermolecular recombination frequency does not reflect enzymological differences. Instead, these data suggest that recombination rates differ because coexpressed MLV RNAs are less accessible to the recombination machinery than are coexpressed HIV RNAs. This hypothesis provides a plausible explanation for why most gammaretrovirus recombinants, although relatively rare, display evidence of multiple nonselected crossovers. By implying that recombinogenic template switching occurs roughly four times on average during the synthesis of every MLV or HIV-1 DNA, these results suggest that virtually all products of retroviral replication are biochemical recombinants.

Rev activity determines sensitivity of HIV-1-infected primary T cells to CTL killing.

The HIV Nef protein is thought to promote HIV immune evasion by downmodulating MHC-I and protecting infected cells from CTL killing. In addition, we demonstrated that Rev, an HIV regulatory protein needed for expression of the HIV late genes, can influence CTL killing. When Rev activity level was reduced by virtue of amino acid alterations in the Rev protein sequence, infected cells were more resistant to anti-Gag and anti-Env CTL killing. A screen of primary viral isolates revealed that viruses derived from asymptomatic, infected people had lower Rev activity, lower Gag levels, and greater resistance to anti-Gag CTL killing. Thus, rev alleles with low activity may have a selective advantage in infected people with effective immune responses.