The breadth of maternal HIV-1 specific neutralizing antibodies is not associated with a lower risk of mother-to-infant transmission

International audienc

Human immunodeficiency virus type-1 (HIV-1) continues to evolve in presence of broadly neutralizing antibodies more than ten years after infection.

BACKGROUND: The evolution of HIV-1 and its immune escape to autologous neutralizing antibodies (Nabs) during the acute/early phases of infection have been analyzed in depth in many studies. In contrast, little is known about neither the long-term evolution of the virus in patients who developed broadly Nabs (bNabs) or the mechanism of escape in presence of these bNabs. RESULTS: We have studied the viral population infecting a long term non progressor HIV-1 infected patient who had developed broadly neutralizing antibodies toward all tier 2/3 viruses (6 clades) tested, 9 years after infection, and was then followed up over 7 years. The autologous neutralization titers of the sequential sera toward env variants representative of the viral population significantly increased during the follow-up period. The most resistant pseudotyped virus was identified at the last visit suggesting that it represented a late emerging escape variant. We identified 5 amino acids substitutions that appeared associated with escape to broadly neutralizing antibodies. They were V319I/S, R/K355T, R/W429G, Q460E and G/T463E, in V3, C3 and V5 regions. CONCLUSION: This study showed that HIV-1 may continue to evolve in presence of both broadly neutralizing antibodies and increasing autologous neutralizing activity more than 10 years post-infection

Continuous evolution of HIV-1 more than ten years after infection in an elite neutralizer

International audienc

Adaptation of HIV-1 Envelope Glycoprotein gp120 to Humoral Immunity over the Course of the Epidemic

Since 2009, a large panel of broad and potent monoclonal neutralizing antibodies (MoNAbs) against HIV-1 have been isolated. These MoNAbs can protect from lllV-1 infection and suppress established infection in animal models. Because their efficacy should be evaluated in human clinical trials, it is of importance to define the sensitivity of the most contemporary transmitted variants to these MoNAbs. We, and others previously, reported that HIV-1 has become more resistant to neutralization over the course of the epidemic (Bunnik et al., Nature Med 2010, Bouvin-Pley et al., PloS Pathog 2013). Methods: Here we extended the analyses to the most potent MoNAbs described since then, either more recently isolated or improved by structure-based gene modifications. Results: We fully confirmed the first observations showing an increasing resistance of HIV-1 clade B over time to MoNAbs targeting the major gp l20 epitopes but not to MoNAbs targeting the gp41 MPER. Despite this evolution, some MoNAbs still were able to neutralize efficiently the most recently transmitted HIV-1 variants (2006-2010). The most potent MoNAbs were the bi-specific PG9- and PG16-iMab that alone were able to neutralize an variants at less than 0.4 mg/mL. The sensitivity to iMAb remained similar over time, suggesting that the trend of increasing resistance to PG9-/PG16-iMAb may be attributed only to die antigen binding domain of PG9/PG16. NIH45-46m2 (and -m7), 10-1074 and 10E8 were also highly potent and, if combined, reached the potency of PG9-/PG16-iMAb. We also observed that 3BNC 117 was almost as potent as the modified NIH45-46 antibodies, and that the lama-derived JM4IgG2b was the most potent Ab among those that do not target the major gp 120 neutralizing epitopes. Conclusions: These data clearly suggest a continuous drift of the env gene of HIV-1 elude B over the epidemic, and that not a single epitope is concerned but the entire gp120 as a whole. The consequences of this adaptation on the envelope functionality are being explored

Phenotypic properties of envelope glycoproteins of transmitted HIV-1 variants from patients belonging to transmission chains.

OBJECTIVE: Transmission of HIV-1 involves a bottleneck in which generally a single HIV-1 variant from a diverse viral population in the transmitting partner establishes infection in the new host. It is still unclear to what extent this event is driven by specific properties of the transmitted viruses or the result of a stochastic process. Our study aimed to better characterize this phenomenon and define properties shared by transmitted viruses. DESIGN: We compared antigenic and functional properties of envelope glycoproteins of viral variants found during primary infection in 27 patients belonging to eight transmission chains. METHODS: We generated pseudotyped viruses expressing Env variants of the viral quasispecies infecting each patient and compared their sensitivity to neutralization by eight human monoclonal broadly neutralizing antibodies (HuMoNAbs). We also compared their infectious properties by measuring their infectivity and sensitivity to various entry inhibitors. RESULTS: Transmitted viruses from the same transmission chain shared many properties, including similar neutralization profiles, sensitivity to inhibitors, and infectivity, providing evidence that the transmission bottleneck is mainly nonstochastic. Transmitted viruses were CCR5-tropic, sensitive to MVC, and resistant to soluble forms of CD4, irrespective of the cluster to which they belonged. They were also sensitive to HuMoNAbs that target V3, the CD4-binding site, and the MPER region, suggesting that the loss of these epitopes may compromise their capacity to be transmitted. CONCLUSION: Our data suggest that the transmission bottleneck is governed by selective forces. How these forces confer an advantage to the transmitted virus has yet to be determined

The role of neutralizing antibodies in prevention of HIV-1 infection: what can we learn from the mother-to-child transmission context?

International audienceIn most viral infections, protection through existing vaccines is linked to the presence of vaccine-induced neutralizing antibodies (NAbs). However, more than 30 years after the identification of AIDS, the design of an immunogen able to induce antibodies that would neutralize the highly diverse HIV-1 variants remains one of the most puzzling challenges of the human microbiology. The role of antibodies in protection against HIV-1 can be studied in a natural situation that is the mother-to-child transmission (MTCT) context. Indeed, at least at the end of pregnancy, maternal antibodies of the IgG class are passively transferred to the fetus protecting the neonate from new infections during the first weeks or months of life. During the last few years, strong data, presented in this review, have suggested that some NAbs might confer protection toward neonatal HIV-1 infection. In cases of transmission, it has been shown that the viral population that is transmitted from the mother to the infant is usually homogeneous, genetically restricted and resistant to the maternal HIV-1-specific antibodies. Although the breath of neutralization was not associated with protection, it has not been excluded that NAbs toward specific HIV-1 strains might be associated with a lower rate of MTCT. A better identification of the antibody specificities that could mediate protection toward MTCT of HIV-1 would provide important insights into the antibody responses that would be useful for vaccine development. The most convincing data suggesting that NAbs migh confer protection against HIV-1 infection have been obtained by experiments of passive immunization of newborn macaques with the first generation of human monoclonal broadly neutralizing antibodies (HuMoNAbs). However, these studies, which included only a few selected subtype B challenge viruses, provide data limited to protection against a very restricted number of isolates and therefore have limitations in addressing the hypervariability of HIV-1. The recent identification of highly potent second-generation cross-clade HuMoNAbs provides a new opportunity to evaluate the efficacy of passive immunization to prevent MTCT of HIV-1

Transport du phosphate chez Mycobacterium tuberculosis

Doctorat en sciences médicalesinfo:eu-repo/semantics/nonPublishe

Etude comparative de l'immunogénicité des virus de l'immunodéficience humaine de type 1 circulant à différentes périodes de l'épidémie

TOURS-BU Sciences Pharmacie (372612104) / SudocSudocFranceF

Role of Viral Envelope Proteins in Determining Susceptibility of Viruses to IFITM Proteins

Interferon-induced transmembrane proteins (IFITMs) are a family of proteins which inhibit infections of various enveloped viruses. While their general mechanism of inhibition seems to be non-specific, involving the tightening of membrane structures to prevent fusion between the viral envelope and cell membrane, numerous studies have underscored the importance of viral envelope proteins in determining the susceptibility of viruses to IFITMs. Mutations in envelope proteins may lead to viral escape from direct interaction with IFITM proteins or result in indirect resistance by modifying the viral entry pathway, allowing the virus to modulate its exposure to IFITMs. In a broader context, the nature of viral envelope proteins and their interaction with IFITMs can play a crucial role in the context of adaptive immunity, leading to viral envelope proteins that are more susceptible to antibody neutralization. The precise mechanisms underlying these observations remain unclear, and further studies in this field could contribute to a better understanding of how IFITMs control viral infections