Identification of novel HIV restriction factors

To efficiently replicate within mammalian cells, viruses have to manoeuvre through complex host mechanisms, hijacking a network of host proteins to achieve successful propagation. To prevent this invasion, cells have evolved over time to efficiently block the incursing pathogen by direct or indirect targeting. Human immunodeficiency virus (HIV) is a retrovirus of major global public health issue. In the last decade, extensive focus on innate immune proteins has been given, and particularly restriction factors, proteins inhibiting HIV replication by affecting various stages of the viral cycle. Because of the importance of developing new HIV therapies that are associated with reduced side effects and resistances, there is an urge to understand the antiviral response against HIV. Using common features of known restriction factors as a signature to identify new anti-HIV factors, candidates were identified. Particularly multiple members of the apolipoproteins L (APOL) family were found. Cotransfection experiments confirmed very potent inhibitory effects on HIV-1 expression. Further characterization of APOL6, the best candidate, was carried out. APOL6 was not able to inhibit HIV specifically but rather inhibited any gene-encoded DNA that was cotransfected and therefore APOL6 does not classify as a bona fide restriction factor. In addition, we were able to map the activity of APOL6 to the MAD domain and mainly to residue 174. We also found that other members of the family identified in the screen, APOL1 and 3, could have similar mechanism of action as APOL6. Finally, although the complete mechanism of action of APOL6 has yet to be elucidated, it might be blocked during transfections, potentially improving transfection of primary cells. -- Pour se répliquer efficacement dans les cellules de mammifères, les virus doivent manoeuvrer à travers des mécanismes cellulaires complexes et détourner un réseau de protéines de l'hôte. Pour empêcher cette invasion, les gènes de l'hôte ont évolué dans le temps pour cibler efficacement, directement ou indirectement, l'agent pathogène. Le virus de l'immunodéficience humaine (VIH) est un rétrovirus de problème majeur de santé publique mondiale, mais le faible risque de transmission du virus pourrait être expliqué par la présence d'un système antiviral de l'hôte qui, en cas d'échec, conduit à une infection productive. Durant la dernière décennie, il y a eu un intérêt spécial porté sur les protéines immunitaires innées appelé facteurs de restriction présentant des effets inhibiteurs puissants sur la réplication du VIH en affectant différentes étapes du cycle viral. En raison de l'importance de la recherche de nouvelles thérapies anti-VIH associées à des effets secondaires et des résistances réduites comparé aux traitements actuels, il existe un besoin de comprendre la réponse antivirale innée contre le VIH. Basé sur des caractéristiques communes des facteurs de restriction connus, nous avons proposé d'identifier de nouveaux facteurs anti-VIH. Nous avons trouvé une famille de protéines, les apolipoprotéines L (APOL) montrant les effets inhibiteurs très puissants contre l'expression du VIH-1 dans des expériences de co-transfection. Nous avons décidé d'approfondir le rôle de ces protéines dans l'immunité innée et de se concentrer sur le meilleur candidat APOL6. Nous avons en outre établi qu'APOL6 n'a pas d'activité anti-virale spécifique et donc pas classé comme un facteur de bonne foi de restriction. Par ailleurs, APOL6 est capable d'inhiber fortement l'expression de tout Plasmide cotransfecté. En outre, nous avons été en mesure de cartographier l'activité d'APOL6 au domaine MAD et principalement au résidu 174. Nous avons également constaté que d'autres membres de la famille identifiés dans l'étude, APOL1 et 3, pourraient avoir le même mécanisme d'action qu'APOL6. Enfin, bien que le mécanisme d'action complet d'APOL6 reste à être élucidé, il pourrait être d'une importance biotechnologique car il pourrait potentiellement faciliter la transfection de cellules primaires après l'inhibition d'APOL6.

Modelling the Evolution and Spread of HIV Immune Escape Mutants.

During infection with human immunodeficiency virus (HIV), immune pressure from cytotoxic T-lymphocytes (CTLs) selects for viral mutants that confer escape from CTL recognition. These escape variants can be transmitted between individuals where, depending upon their cost to viral fitness and the CTL responses made by the recipient, they may revert. The rates of within-host evolution and their concordant impact upon the rate of spread of escape mutants at the population level are uncertain. Here we present a mathematical model of within-host evolution of escape mutants, transmission of these variants between hosts and subsequent reversion in new hosts. The model is an extension of the well-known SI model of disease transmission and includes three further parameters that describe host immunogenetic heterogeneity and rates of within host viral evolution. We use the model to explain why some escape mutants appear to have stable prevalence whilst others are spreading through the population. Further, we use it to compare diverse datasets on CTL escape, highlighting where different sources agree or disagree on within-host evolutionary rates. The several dozen CTL epitopes we survey from HIV-1 gag, RT and nef reveal a relatively sedate rate of evolution with average rates of escape measured in years and reversion in decades. For many epitopes in HIV, occasional rapid within-host evolution is not reflected in fast evolution at the population level.

Assessing the Paradox Between Transmitted and Acquired HIV Type 1 Drug Resistance Mutations in the Swiss HIV Cohort Study From 1998 to 2012.

BACKGROUND: Transmitted human immunodeficiency virus type 1 (HIV) drug resistance (TDR) mutations are transmitted from nonresponding patients (defined as patients with no initial response to treatment and those with an initial response for whom treatment later failed) or from patients who are naive to treatment. Although the prevalence of drug resistance in patients who are not responding to treatment has declined in developed countries, the prevalence of TDR mutations has not. Mechanisms causing this paradox are poorly explored. METHODS: We included recently infected, treatment-naive patients with genotypic resistance tests performed ≤1 year after infection and before 2013. Potential risk factors for TDR mutations were analyzed using logistic regression. The association between the prevalence of TDR mutations and population viral load (PVL) among treated patients during 1997-2011 was estimated with Poisson regression for all TDR mutations and individually for the most frequent resistance mutations against each drug class (ie, M184V/L90M/K103N). RESULTS: We included 2421 recently infected, treatment-naive patients and 5399 patients with no response to treatment. The prevalence of TDR mutations fluctuated considerably over time. Two opposing developments could explain these fluctuations: generally continuous increases in the prevalence of TDR mutations (odds ratio, 1.13; P = .010), punctuated by sharp decreases in the prevalence when new drug classes were introduced. Overall, the prevalence of TDR mutations increased with decreasing PVL (rate ratio [RR], 0.91 per 1000 decrease in PVL; P = .033). Additionally, we observed that the transmitted high-fitness-cost mutation M184V was positively associated with the PVL of nonresponding patients carrying M184V (RR, 1.50 per 100 increase in PVL; P < .001). Such association was absent for K103N (RR, 1.00 per 100 increase in PVL; P = .99) and negative for L90M (RR, 0.75 per 100 increase in PVL; P = .022). CONCLUSIONS: Transmission of antiretroviral drug resistance is temporarily reduced by the introduction of new drug classes and driven by nonresponding and treatment-naive patients. These findings suggest a continuous need for new drugs, early detection/treatment of HIV-1 infection.

Schistosoma mansoni and HIV acquisition in fishing communities of Lake Victoria, Uganda: a nested case-control study.

OBJECTIVE: It has been suggested that Schistosoma mansoni, which is endemic in African fishing communities, might increase susceptibility to human immunodeficiency virus (HIV) acquisition. If confirmed, this would be of great public health importance in these high HIV-risk communities. This study was undertaken to determine whether S. mansoni infection is a risk factor for HIV infection among the fishing communities of Lake Victoria, Uganda. We conducted a matched case-control study, nested within a prospective HIV incidence cohort, including 50 HIV seroconverters (cases) and 150 controls during 2009-2011. METHODS: S. mansoni infection prior to HIV seroconversion was determined by measuring serum circulating anodic antigen (CAA) in stored serum. HIV testing was carried out using the Determine rapid test and infection confirmed by enzyme-linked immunosorbent assays. RESULTS: About 49% of cases and 52% of controls had S. mansoni infection prior to HIV seroconversion (or at the time of a similar study visit, for controls): odds ratio, adjusting for ethnicity, religion, marital status, education, occupation, frequency of alcohol consumption in previous 3 months, number of sexual partners while drunk, duration of stay in the community, and history of schistosomiasis treatment in the past 2 years was 1.23 (95% CI 0.3-5.7) P = 0.79. S. mansoni infections were chronic (with little change in status between enrolment and HIV seroconversion), and there was no difference in median CAA concentration between cases and controls. CONCLUSIONS: These results do not support the hypothesis that S. mansoni infection promotes HIV acquisition.