Receptor usage dictates HIV-1 restriction by human TRIM5α in dendritic cell subsets.

The most prevalent route of HIV-1 infection is across mucosal tissues after sexual contact. Langerhans cells (LCs) belong to the subset of dendritic cells (DCs) that line the mucosal epithelia of vagina and foreskin and have the ability to sense and induce immunity to invading pathogens. Anatomical and functional characteristics make LCs one of the primary targets of HIV-1 infection. Notably, LCs form a protective barrier against HIV-1 infection and transmission. LCs restrict HIV-1 infection through the capture of HIV-1 by the C-type lectin receptor Langerin and subsequent internalization into Birbeck granules. However, the underlying molecular mechanism of HIV-1 restriction in LCs remains unknown. Here we show that human E3-ubiquitin ligase tri-partite-containing motif 5α (TRIM5α) potently restricts HIV-1 infection of LCs but not of subepithelial DC-SIGN+ DCs. HIV-1 restriction by TRIM5α was thus far considered to be reserved to non-human primate TRIM5α orthologues, but our data strongly suggest that human TRIM5α is a cell-specific restriction factor dependent on C-type lectin receptor function. Our findings highlight the importance of HIV-1 binding to Langerin for the routeing of HIV-1 into the human TRIM5α-mediated restriction pathway. TRIM5α mediates the assembly of an autophagy-activating scaffold to Langerin, which targets HIV-1 for autophagic degradation and prevents infection of LCs. By contrast, HIV-1 binding to DC-SIGN+ DCs leads to disassociation of TRIM5α from DC-SIGN, which abrogates TRIM5α restriction. Thus, our data strongly suggest that restriction by human TRIM5α is controlled by C-type-lectin-receptor-dependent uptake of HIV-1, dictating protection or infection of human DC subsets. Therapeutic interventions that incorporate C-type lectin receptors and autophagy-targeting strategies could thus provide cell-mediated resistance to HIV-1 in humans.

Mutations in CypA Binding Region of HIV-1 Capsid Affect Capsid Stability and Viral Replication in Primary Macrophages.

Mutations in the cyclophilin A (CypA) binding region in the HIV-1 capsid affect their dependency on the known HIV-1 cofactor CypA and allow escape from the HIV-1 restriction factor Trim5α in human and simian cells. Here we study the effect of these mutations in the CypA binding region of capsid on cofactor binding, capsid destabilization, and viral replication in primary cells. We showed that the viral capsid with mutations in the CypA binding region (CypA-BR) interacted efficiently with CypA, but had an increased stability upon infection as compared to the wild-type capsid. Interestingly, the wild-type virus was able to infect monocyte-derived macrophages (MDM) more efficiently as compared to the CypA-BR mutant variant. The lower infectivity of the CypA-BR mutant virus in MDM was associated with lower levels of reverse transcription products. Similar to the wild-type virus, the CypA-BR mutant variant was unable to induce a strong innate response in primary macrophages. These data demonstrate that mutations in the CypA binding site of the capsid resulted in higher capsid stability and hampered infectivity in macrophages.

Adaptation of HIV-1 to rhTrim5α-mediated restriction in vitro.

Recently, gene therapy with rhTrim5α, an innate restriction factor which blocks HIV-1 at a post entry step, have been shown to be applicable as treatment in vitro. However, HIV-1 might adapt to replicate in the presence of rhTrim5α due to its high mutation rate. Here we observed that two different HIV-1 isolates were able to replicate in cells expressing high levels of rhTrim5α. Escape mutations were found in the conserved regions of the viral genome, Gag and p51 RT subunit. Furthermore, the escape mutations, predominantly in the capsid and p51 RT, altered viral sensitivity to modified huTrim5α R332P and R335G variants, with only a minor effect on the replication capacity in primary PBMCs. Therefore, gene therapy with rhTrim5α might be suitable for HIV-1 treatment, however the virus will eventually escape the pressure by gaining mutations in the conserved regions of the viral genome without any severe fitness cost.

SAMHD1 degradation enhances active suppression of dendritic cell maturation by HIV-1.

A hallmark of HIV-1 infection is the lack of sterilizing immunity. Dendritic cells (DCs) are crucial in the induction of immunity, and lack of DC activation might underlie the absence of an effective anti-HIV-1 response. We have investigated how HIV-1 infection affects maturation of DCs. Our data show that even though DCs are productively infected by HIV-1, infection does not induce DC maturation. HIV-1 infection actively suppresses DC maturation, as HIV-1 infection inhibited TLR-induced maturation of DCs and thereby decreased the immune stimulatory capacity of DCs. Interfering with SAMHD1 restriction further increased infection of DCs, but did not lead to DC maturation. Notably, higher infection observed with SAMHD1 depletion correlated with a stronger suppression of maturation. Furthermore, blocking reverse transcription rescued TLR-induced maturation. These data strongly indicate that HIV-1 replication does not trigger immune activation in DCs, but that HIV-1 escapes immune surveillance by actively suppressing DC maturation independent of SAMHD1. Elucidation of the mechanism of suppression can lead to promising targets for therapy or vaccine design.

Viral evolution in HLA-B27-restricted CTL epitopes in human immunodeficiency virus type 1-infected individuals.

The HLA-B27 allele is over-represented among human immunodeficiency virus type 1-infected long-term non-progressors. In these patients, strong CTL responses targeting HLA-B27-restricted viral epitopes have been associated with long-term asymptomatic survival. Indeed, loss of control of viraemia in HLA-B27 patients has been associated with CTL escape at position 264 in the immunodominant KK10 epitope. This CTL escape mutation in the viral Gag protein has been associated with severe viral attenuation and may require the presence of compensatory mutations before emerging. Here, we studied sequence evolution within HLA-B27-restricted CTL epitopes in the viral Gag protein during the course of infection of seven HLA-B27-positive patients. Longitudinal gag sequences obtained at different time points around the time of AIDS diagnosis were obtained and analysed for the presence of mutations in epitopes restricted by HLA-B27, and for potential compensatory mutations. Sequence variations were observed in the HLA-B27-restricted CTL epitopes IK9 and DR11, and the immunodominant KK10 epitope. However, the presence of sequence variations in the HLA-B27-restricted CTL epitopes could not be associated with an increase in viraemia in the majority of the patients studied. Furthermore, we observed low genetic diversity in the gag region of the viral variants throughout the course of infection, which is indicative of low viral replication and corresponds to the low viral load observed in the HLA-B27-positive patients. These data indicated that control of viral replication can be maintained in HLA-B27-positive patients despite the emergence of viral mutations in HLA-B27-restricted epitopes.

Genetic variation in Trex1 affects HIV-1 disease progression.

OBJECTIVE: Three prime repair exonuclease 1 (TREX1) plays a pivotal role in HIV-1 infection. In-vitro studies have shown that TREX1 degrades excess HIV-1 DNA, thereby shielding HIV-1 from recognition by innate immune receptors and preventing a type 1 interferon response. To determine whether TREX1 plays a role in HIV-1 pathogenesis, we analyzed whether genetic variation in Trex1 is associated with the clinical course of HIV-1 infection. DESIGN/METHODS: Two tagging single nucleotide polymorphisms (SNPs) in Trex1 were genotyped in a cohort of 304 HIV-1-infected MSM and a cohort of 66 high-risk seronegative individuals. Kaplan-Meier and Cox regression survival analyses were used to analyze the effect of the SNPs on HIV-1 disease progression. In-vitro HIV-1 infection assays and Trex1 mRNA analysis were performed in peripheral blood mononuclear cells (PBMCs) obtained from donors that were genotyped for the tag SNP in Trex1. RESULTS: We observed that the minor allele of SNP rs3135941 in Trex1 is associated with faster HIV-1 disease progression. This association was independent of the CCR5-Δ32 genotype and human leukocyte antigen alleles that were previously found to be predictive of disease progression. In addition, we observed an increased HIV-1 replication in PBMC positive for the minor allele of SNP rs3135941. CONCLUSION: Our data emphasize the important role of TREX1 in HIV-1 pathogenesis. The association of SNP rs3135941 with accelerated disease progression that we observed might be explained by the increased HIV-1 replication observed in PBMC positive for the minor allele of the SNP.

A polymorphism at position 400 in the connection subdomain of HIV-1 reverse transcriptase affects sensitivity to NNRTIs and RNaseH activity.

Reverse transcriptase (RT) plays an essential role in HIV-1 replication, and inhibition of this enzyme is a key component of HIV-treatment. However, the use of RT inhibitors can lead to the emergence of drug-resistant variants. Until recently, most clinically relevant resistance mutations were found in the polymerase domain of RT. Lately, an increasing number of resistance mutations has been identified in the connection and RNaseH domain. To further explore the role of these domains we analyzed the complete RT sequence of HIV-1 subtype B patients failing therapy. Position A/T400 in the connection subdomain is polymorphic, but the proportion of T400 increases from 41% in naïve patients to 72% in patients failing therapy. Previous studies suggested a role for threonine in conferring resistance to nucleoside RT inhibitors. Here we report that T400 also mediates resistance to non-nucleoside RT inhibitors. The susceptibility to NVP and EFV was reduced 5-fold and 2-fold, respectively, in the wild-type subtype B NL4.3 background. We show that substitution A400T reduces the RNaseH activity. The changes in enzyme activity are remarkable given the distance to both the polymerase and RNaseH active sites. Molecular dynamics simulations were performed, which provide a novel atomistic mechanism for the reduction in RNaseH activity induced by T400. Substitution A400T was found to change the conformation of the RNaseH primer grip region. Formation of an additional hydrogen bond between residue T400 and E396 may play a role in this structural change. The slower degradation of the viral RNA genome may provide more time for dissociation of the bound NNRTI from the stalled RT-template/primer complex, after which reverse transcription can resume.

The evolution of human immunodeficiency virus type-1 (HIV-1) envelope molecular properties and coreceptor use at all stages of infection in an HIV-1 donor-recipient pair.

To trace the evolutionary patterns underlying evolution of coreceptor use within a host, we studied an HIV-1 transmission pair involving a donor who exclusively harbored CCR5-using (R5) variants throughout his entire disease course and a recipient who developed CXCR4-using variants. Over time, R5 variants in the donor optimized coreceptor use, which was associated with an increased number of potential N-linked glycosylation sites (PNGS) and elevated V3 charge in the viral envelope. Interestingly, R5 variants that were transmitted to the recipient preserved the viral characteristics of this late stage genotype and phenotype. Following a selective sweep, CXCR4-using variants subsequently emerged in the recipient coinciding with a further increase in the number of PNGS and V3 charge in the envelope of R5 viruses. Although described in a single transmission pair, the transmission and subsequent persistence of R5 variants with late stage characteristics demonstrate the potential for coreceptor use adaptation at the population level.

Comparison of in vivo and in vitro evolution of CCR5 to CXCR4 coreceptor use of primary human immunodeficiency virus type 1 variants.

During the course of at least 50% of HIV-1 subtype B infections, CCR5-using (R5) viruses evolve towards a CXCR4-using phenotype. To gain insight in the transition from CCR5 to CXCR4 coreceptor use, we investigated whether acquisition of CXCR4 use in vitro of R5 viruses from four patients resembled this process in vivo. R5 variants from only one patient acquired CXCR4 use in vitro. These variants had envelopes with higher V3 charge and higher number of potential N-linked glycosylation sites when compared to R5 variants that failed to gain CXCR4 use in vitro. In this patient, acquisition of CXCR4 use in vitro and in vivo was associated with multiple mutational patterns not necessarily involving the V3 region. However, changes at specific V3 positions were prerequisite for persistence of CXCR4-using variants in vivo, suggesting that positive selection targeting the V3 loop is required for emergence of CXCR4-using variants during natural disease course.