Inefficient HIV-1 trans Infection of CD4+ T Cells by Macrophages from HIV-1 Nonprogressors Is Associated with Altered Membrane Cholesterol and DC-SIGN

Professional antigen-presenting cells (APC; myeloid dendritic cells [DC] and macrophages [M Phi]; B lymphocytes) mediate highly efficient HIV-1 infection of CD4(+) T cells, termed trans infection, that could contribute to HIV-1 pathogenesis. We have previously shown that lower cholesterol content in DC and B lymphocytes is associated with a lack of HIV-1 trans infection in HIV-1-infected non-progressors (NP). Here, we assessed whether HIV-1 trans infection mediated by another major APC, M Phi, is deficient in NP due to altered cholesterol metabolism. When comparing healthy HIV-1 seronegatives (SN), rapid progressors (PR), and NP, we found that monocyte-derived M Phi from NP did not mediate HIV-1 trans infection of autologous CD4(+) T cells, in contrast to efficient trans infection mediated by SN and PR M Phi. M Phi trans infection efficiency was directly associated with the number of DC-specific intercellular adhesion molecule-3-grabbing nonintegrin (DC-SIGN)-expressing M Phi. Significantly fewer NP M Phi expressed DC-SIGN. Unesterified (free) cholesterol in M Phi cell membranes and lipid rafting was significantly lower in NP than PR, as was virus internalization in early endosomes. Furthermore, simvastatin (SIMV) decreased the subpopulation of DC-SIGN(+) M Phi as well as cis and trans infection. Notably, SIMV decreased cell membrane cholesterol and led to lipid raft dissociation, effectively mimicking the incompetent APC trans infection environment characteristic of NP. Our data support that DC-SIGN and membrane cholesterol are central to M Phi trans infection, and a lack of these limits HIV-1 disease progression. Targeting the ability of M Phi to drive HIV-1 dissemination in trans could enhance HIV-1 therapeutic strategies. IMPORTANCE Despite the success of combination antiretroviral therapy, neither a vaccine nor a cure for HIV infection has been developed, demonstrating a need for novel prophylactic and therapeutic strategies. Here, we show that efficiency of M Phi-mediated HIV trans infection of CD4(+) T cells is a unique characteristic associated with control of disease progression, and it is impaired in HIV-infected NP. In vitro treatment of M Phi from healthy donors with SIMV lowers their cholesterol content, which results in a strongly reduced trans infection ability, similar to the levels of M Phi from NP. Taken together, our data support the hypothesis that M Phi-mediated HIV-1 trans infection plays a role in HIV infection and disease progression and demonstrate that the use of SIMV to decrease this mechanism of virus transfer should be considered for future HIV therapeutic development.