Penile acquisition of HIV accounts for most infections among men globally. Nevertheless, candidate HIV interventions for men advance to clinical trials without preclinical efficacy data, due primarily to a paucity of relevant animal models of penile HIV infection. Using our recently developed macaque model, we show that a single subcutaneous administration of broadly neutralizing antibody (bNAb) 10-1074 conferred durable protection against repeated penile exposures to simian-human immunodeficiency virus (SHIVSF162P3). Macaques co-administered bNAbs 10-1074 and 3BNC117, or 3BNC117 alone, also exhibited significant protection against repeated vaginal SHIVAD8-EO exposures. Regression modeling estimated that individual plasma bNAb concentrations of 5 mug ml(-1) correlated with >/=99.9% relative reduction in SHIV infection probability via penile (10-1074) or vaginal (10-1074 or 3BNC117) challenge routes. These results demonstrate that comparably large reductions in penile and vaginal SHIV infection risk among macaques were achieved at clinically relevant plasma bNAb concentrations and inform dose selection for the development of bNAbs as long-acting pre-exposure prophylaxis candidates for use by men and women.

BACKGROUND: Hormonal changes during menstrual cycling may affect susceptibility to HIV. METHODS: We determined the simian human immunodeficiency virus (SHIV) acquisition time point in 43 cycling pigtail macaques infected by repeated vaginal virus exposures initiated randomly in the cycle. RESULTS: SHIV infection was first detected in the follicular phase in 38 macaques (88%), and in the luteal phase in five macaques (12%), indicating a statistically significant timing difference. Assuming a 7-day eclipse phase, most infections occurred during or following a high-progesterone period associated with menstruation, vaginal epithelium thinning, and suppressed mucosal immunity. CONCLUSIONS: This raises questions whether other high-progesterone conditions (pregnancy, hormonal contraception) similarly affect HIV risk.

Infections following repeated, low-dose (RLD), mucosal S(H)IV exposures of macaques are used to model sexual HIV exposures for biomedical prevention testing. Different susceptibilities among animals can complicate study designs. In rhesus macaques, TRIM5 alleles Q, CypA, and TFP, are resistance factors for infection with some S(H)IV strains, but not for SIVmac239 due to its capsid properties. SIVmac239-derived SHIVSF162P3 has been demonstrated to reproducibly infect mucosally in vaginal and rectal RLD models. To further test the suitability of SHIVSF162P3 for RLD models, we studied the influence of TRIM5 genotype on susceptibility to rectal RLD infection and on plasma viremia by analyzing 43 male Indian rhesus macaques from control arms of completed studies. The median number of exposures required for infection was: 3 (Q/Q, n=4) (TRIM5 alleles, number of macaques, respectively); 4 (Q/CypA, n=7), 3 (TFP/Q, n=15); 3 (TFP/TFP, n=15); 2 (TFP/CypA, n=2); TRIM5CypA/CypA was not represented in our study. Median peak viremia (log10 viral copies/mL) in infected animals was: 7.4 (Q/Q, n=4); 7.2 (Q/CypA, n=6), 7.3 (TFP/Q, n=13); 7.1 (TFP/TFP, n=15); 6.5 (TFP/CypA; n=2). Neither susceptibility nor peak viremia were significantly different (log-rank test, Kruskal Wallis test, respectively). Rhesus macaques' susceptibility to RLD SHIVSF162P3 is independent of TRIM5 TFP, CypA, and Q alleles, with the limitation that the power to detect any impact of CypA/CypA and TFP/CypA genotypes was nonexistent or low, due to absence or infrequency, respectively. The finding that TRIM5 alleles do not restrict mucosal infection or ensuing replication rates suggests that SHIVSF162P3 is indeed suitable for RLD experimentation.

BACKGROUND: The impact of Pre-exposure Prophylaxis (PrEP) with anti-retrovirals on breakthrough HIV or SHIV infection is not fully documented. We addressed the hypothesis that SHIV(SF162P3) infection despite active PrEP results in altered early immune parameters compared to untreated infection. METHODS: Eleven rhesus macaques were infected during repeated, rectal, low-dose SHIV(SF162P3) exposures while receiving concurrent, oral PrEP (Truvada, n=2, or GS7340, n=4), or as untreated controls (n=5). We measured SHIV RNA, inflammatory cytokines, CD4 cells, and SHIV-specific and memory T cells until 20 weeks post peak viremia. RESULTS: SHIV infection during PrEP resulted in 100-fold lower peak viremia and lower IL-15, IL-18, and IL-1Ra levels compared to controls (p<0.05; Wilcoxon rank-sum test). Unlike controls, PrEP-treated macaques showed no significant CD4 reduction during acute infection, and developed more SHIV-specific central memory T cells relative to controls. Following in-vivo CD8(+) cell depletion, viremia rose to similar levels, indicating that CD8(+) cells were critical for viral control in both groups. CONCLUSIONS: PrEP with anti-retrovirals has beneficial effects on early SHIV infection even when infection is not prevented. While long-term immune control could not be examined in this SHIV infection model, our results suggest that PrEP results in improved early disease parameters in breakthrough infections.

Fluctuations in susceptibility to HIV or SHIV during the menstrual cycle are currently not fully documented. To address this, time point of infection was determined in 19 adult female pigtail macaques vaginally challenged during their undisturbed menstrual cycles with repeated, low-dose SHIVSF162P3 exposures. Eighteen macaques (95%) first displayed viremia in the follicular phase, as compared to 1 macaque (5%) in the luteal phase (p<0.0001). Due to a viral eclipse phase, we estimated a window of most frequent virus transmission between days 24-31 of the menstrual cycle, in the late luteal phase. Thus, susceptibility to vaginal SHIV infection is significantly elevated in the second half of the menstrual cycle when progesterone levels are high, and when local immunity may be low. Such susceptibility windows have been postulated before but not definitively documented. Our data support findings of higher susceptibility to HIV in women during progesterone-dominated periods including pregnancy and contraceptive use.

Pre-exposure prophylaxis (PrEP) with anti-viral drugs is currently in clinical trials for the prevention of HIV infection. Induction of adaptive immune responses to virus exposures during anti-viral drug administration, i.e., a "chemo-vaccination" effect, could contribute to PrEP efficacy. To study possible chemo-vaccination, we monitored humoral and cellular immune responses in nine rhesus macaques undergoing up to 14 weekly, low-dose SHIV(SF162P3) rectal exposures. Six macaques concurrently received PrEP with intermittent, oral Truvada; three were no-PrEP controls. PrEP protected 4 macaques from infection. Two of the four showed evidence of chemo-vaccination, because they developed anti-SHIV CD4(+) and CD8(+) T cells; SHIV-specific antibodies were not detected. Control macaques showed no anti-SHIV immune responses before infection. Chemo-vaccination-induced T cell responses were robust (up to 3,940 SFU/10(6) PBMCs), predominantly central memory cells, short-lived (≤22 weeks), and appeared intermittently and with changing specificities. The two chemo-vaccinated macaques were virus-challenged again after 28 weeks of rest, after T cell responses had waned. One macaque was not protected from infection. The other macaque concurrently received additional PrEP. It remained uninfected and T cell responses were boosted during the additional virus exposures. In summary, we document and characterize PrEP-induced T cell chemo-vaccination. Although not protective after subsiding in one macaque, chemo-vaccination-induced T cells warrant more comprehensive analysis during peak responses for their ability to prevent or to control infections after additional exposures. Our findings highlight the importance of monitoring these responses in clinical PrEP trials and suggest that a combination of vaccines and PrEP potentially might enhance efficacy.

Animal models for research on susceptibility to HIV are currently not available. Here we explore whether a macaque model of repeated low-dose rectal or vaginal virus challenges could be employed. We tested the hypothesis that susceptibility to Simian HIV is not merely stochastic in this model but rather is associated with identifiable host factors. Forty macaques required a median of 3.5 SHIVSF162P3 challenges for infection. We studied the association of their susceptibility with 13 predisposing plasma cytokines/chemokines (RANTES, Eotaxin, monocyte chemoattractant protein (MCP)-1, IL-7, MIP-1beta, TNF-alpha, MIP-1alpha, granulocyte colony-stimulating factor, IL-8, interferon-gamma, IL-17, IL-1beta, IL-6). Higher plasma RANTES, IL-8, and Eotaxin were associated with lower susceptibility, that is, higher resistance to infection. In a group of macaques with low IL-8 and RANTES, a median 3 exposures were required to infect; whereas, when either IL-8 or RANTES were high, a median 12 exposures were required. Thus, susceptibility was associated with identifiable discrete host factors and was not stochastic. In addition, the macaque model identified key human resistance factors (RANTES, Eotaxin), but also revealed a novel association with resistance (IL-8). Future direct evaluation of these or other factors in the animal model may be beneficial for developing new immunomodulation strategies for HIV prevention.

The macaque model of repeated SHIV exposures is increasingly used as a preclinical tool to evaluate biomedical HIV intervention strategies. It is unclear whether multiple virus exposures induce immune responses in macaques, as documented in uninfected individuals repeatedly exposed to HIV. We here address whether repeated, rectal SHIV(SF162P3) exposures lead to systemic T cell activation in 12 rhesus macaques, and whether this is associated with increased infection resistance. Eight macaques became systemically infected after 2-7 exposures, three macaques were less susceptible (infection after 10-12 exposures), and one macaque remained uninfected after 14 exposures. PBMCs were retrospectively monitored for increases in T cell activation by analyzing the proportion of CD8(+) T cells, recently activated or proliferated T cells (markers CD38, Ki67), a marker for cytotoxicity (granzyme B), or T cell-produced plasma cytokines (IFN-gamma, RANTES, IL-2). Repeated virus exposures did not induce sustained, potent, or diverse T cell responses prior to systemic infection. Some changes occurred in the analyzed parameters during repeated virus exposures, but similar T cell activities were also observed in five SHIV-unexposed control macaques. Thus, we found no evidence that delayed infection or resistance to infection was associated with systemic, long-lasting, protective T cell responses to repeated rectal virus exposures. Our results provide further insights into the repeat exposure macaque model. We find that this model can be used for testing biomedical prevention strategies without concern of eliciting a systemic vaccination effect.