CA Mutation N57A Has Distinct Strain-Specific HIV-1 Capsid Uncoating and Infectivity Phenotypes

The ability of human immunodeficiency virus type 1 (HIV-1) to transduce nondividing cells is key to infecting terminally differentiated macrophages, which can serve as a long-term reservoir of HIV-1 infection. The mutation N57A in the viral CA protein renders HIV-1 cell cycle dependent, allowing examination of HIV-1 infection of nondividing cells. Here, we show that the N57A mutation confers a postentry infectivity defect that significantly differs in magnitude between the common lab-adapted molecular clones HIV-1 (>10-fold) and HIV-1 (2- to 5-fold) in multiple human cell lines and primary CD4 T cells. Capsid permeabilization and reverse transcription are altered when N57A is incorporated into HIV-1 but not HIV-1 The N57A infectivity defect is significantly exacerbated in both virus strains in the presence of cyclosporine (CsA), indicating that N57A infectivity is dependent upon CA interacting with host factor cyclophilin A (CypA). Adaptation of N57A HIV-1 selected for a second CA mutation, G94D, which rescued the N57A infectivity defect in HIV-1 but not HIV-1 The rescue of N57A by G94D in HIV-1 is abrogated by CsA treatment in some cell types, demonstrating that this rescue is CypA dependent. An examination of over 40,000 HIV-1 CA sequences revealed that the four amino acids that differ between HIV-1 and HIV-1 CA are polymorphic, and the residues at these positions in the two strains are widely prevalent in clinical isolates. Overall, a few polymorphic amino acid differences between two closely related HIV-1 molecular clones affect the phenotype of capsid mutants in different cell types. The specific mechanisms by which HIV-1 infects nondividing cells are unclear. A mutation in the HIV-1 capsid protein abolishes the ability of the virus to infect nondividing cells, serving as a tool to examine cell cycle dependence of HIV-1 infection. We have shown that two widely used HIV-1 molecular clones exhibit significantly different N57A infectivity phenotypes due to fewer than a handful of CA amino acid differences and that these clones are both represented in HIV-infected individuals. As such minor differences in closely related HIV-1 strains may impart significant infectivity differences, careful consideration should be given to drawing conclusions from one particular HIV-1 clone. This study highlights the potential for significant variation in results with the use of multiple strains and possible unanticipated effects of natural polymorphisms.