Rare HIV-1 transmitted/founder lineages identified by deep viral sequencing contribute to rapid shifts in dominant quasispecies during acute and early infection

In order to inform the rational design of HIV-1 preventive and cure interventions it is critical to understand the events occurring during acute HIV-1 infection (AHI). Using viral deep sequencing on six participants from the early capture acute infection RV217 cohort, we have studied HIV-1 evolution in plasma collected twice weekly during the first weeks following the advent of viremia. The analysis of infections established by multiple transmitted/founder (T/F) viruses revealed novel viral profiles that included: a) the low-level persistence of minor T/F variants, b) the rapid replacement of the major T/F by a minor T/F, and c) an initial expansion of the minor T/F followed by a quick collapse of the same minor T/F to low frequency. In most participants, cytotoxic T-lymphocyte (CTL) escape was first detected at the end of peak viremia downslope, proceeded at higher rates than previously measured in HIV-1 infection, and usually occurred through the exploration of multiple mutational pathways within an epitope. The rapid emergence of CTL escape variants suggests a strong and early CTL response. Minor T/F viral strains can contribute to rapid and varied profiles of HIV-1 quasispecies evolution during AHI. Overall, our results demonstrate that early, deep, and frequent sampling is needed to investigate viral/host interaction during AHI, which could help identify prerequisites for prevention and cure of HIV-1 infection.
Author summary The development of safe, effective, and scalable vaccines and cure strategies to control the HIV-1 pandemic is a major public health concern. The rational design of these preventive and treatment measures requires a profound knowledge of the interaction between HIV-1 and its host during the first weeks that follow viral infection (i.e., acute infection). Here we performed a systematic and in-depth study of individuals whose infection was detected before peak viremia and before the emergence of the first antibody responses. Plasma samples were collected twice weekly during acute infection and we performed next-generation sequencing of the viral swarms. In most participants, we first detected viral escape from the initial adaptive cellular immune responses at the end of peak viremia downslope. Viral escape proceeded at higher rates than previously measured in HIV-1 infection and usually through the exploration of multiple mutational pathways. The analysis of sequences from infections established by multiple viral lineages revealed dramatic shifts in the frequencies of the viruses that composed the HIV-1 population within each host. These results, using early, deep, and frequent sampling, support rapidly changing viral lineages likely in response to both adaptive cellular immunity and possibly other host responses during acute HIV-1 infection.