Mechanisms of resistance to neuraminidase inhibitors in influenza A viruses and evaluation of combined antiviral therapy

Les inhibiteurs de la neuraminidase (INAs) jouent un rôle central dans le contrôle des infections grippales, tant dans le cas des épidémies et des pandémies comme chez les patients immunosuprimés et d'autres patients à risque. Cependant, le développement et la dissémination de la résistance compromettent l'utilité à long terme de cette intervention. En fait, le problème de la résistance aux INAs a été mis en évidence pendant les épidémies de grippe annuelles de 2007-09, avec la dissémination globale d’une variante de la souche A(H1N1) saisonnière résistante à l'oseltamivir. Dans ce cas, les observations préliminaires ont spéculé avec l'existence d'un ensemble de mutations “permissives” qui auraient facilité cette transmission mondiale. Heureusement, l'émergence et la propagation mondiale de la souche pandémique en 2009 a mené au remplacement de la souche saisonnière A/Brisbane/59/2007 (H1N1) résistante à l'oseltamivir, par le virus A(H1N1)pdm09 naturellement sensible aux INA, et, par conséquent, l'oseltamivir a récupéré son utilité clinique. En fait, la plupart des virus A(H1N1)pdm09, A(H3N2) et B circulants à ce jour restent sensibles à l'oseltamivir, avec seulement 1-2% de souches résistantes. Néanmoins, le nombre croissant de souches résistantes récemment détectées en l’absence de traitement fait craindre que ce problème puisse encore augmenter. À cet égard, l'impact de l'émergence et la dissémination de la résistance sur le choix limité des antiviraux actuellement disponibles renforce la nécessité d’une meilleure compréhension des mécanismes sous-jacents à ce phénomène ainsi que de nouvelles approches thérapeutiques. Les différentes études présentées dans le cadre de cette thèse convergent vers l'objectif général de mieux décrire les mécanismes de développement de la résistance aux INAs dans les virus de la grippe. En outre, nous prévoyons que les thérapies combinées pourraient induire une meilleure réponse virologique et immunologique par rapport à la monothérapie antivirale. À la fin, nous nous attendons à ce que notre travail ait un impact sur la gestion des infections grippales en guidant la surveillance mondiale des marqueurs potentiels de résistance, ainsi qu’en proposant des traitements novateurs qui minimisent le développement de souches résistantes.Neuraminidase inhibitors (NAIs) play a central role in the control of influenza infections, with important implications in the management of outbreaks and pandemics as well as in immunocompromised and other at risk patients, with both prophylactic and therapeutic indications. However, the development and dissemination of antiviral drug resistance represents a major limitation that compromises the long-term usefulness of this intervention. Actually, the problem of resistance to NAIs was highlighted by the worldwide dissemination of the oseltamivir-resistant seasonal A(H1N1) neuraminidase H274Y variant during the 2007-09 annual influenza epidemics. In that case, preliminary observations speculated with the existence of a set of “permissive” mutations that could have facilitated this global transmission. Fortunately, the antigenic shift that enabled the emergence of and global spread of the 2009 pandemic strain meant the replacement of the oseltamivir-resistant seasonal A/Brisbane/59/2007 (H1N1) virus by the naturally NAI-susceptible A(H1N1)pdm09 virus, and, consequently, oseltamivir recovered its clinical utility. In fact, most of the circulating A(H1N1)pdm09, A(H3N2) and B viruses remain susceptible to oseltamivir with only 1-2% of tested strains exhibiting phenotypic or genotypic evidence of resistance. Nevertheless, the growing number of resistant strains recently detected in the absence of therapy raises concern that this problem could increase. In that regard, the impact of the emergence and dissemination of resistance on the limited choice of antivirals currently available underscores a better understanding of the mechanisms underlying this phenomenon as well as the necessity for innovative therapeutic approaches. The different studies presented in this thesis converge to the general objective of better describing the mechanisms underlying the development of resistance to NAIs in influenza viruses. Also, we anticipate that combination therapies will induce better virological and immunological responses compared to antiviral monotherapy. In the end, we expect that our work will have an impact on the management of influenza infections by guiding the global surveillance of potential drug resistance markers, as well as proposing innovative ways to improve the clinical outcome and minimizing the development of drug-resistant strains

In vitro evaluation of antiviral activity of single and combined repurposable drugs against SARS-CoV-2

International audienceIn response to the current pandemic caused by the novel SARS-CoV-2, identifying and validating effective therapeutic strategies is more than ever necessary. We evaluated the in vitro antiviral activities of a shortlist of compounds, known for their cellular broad-spectrum activities, together with drugs that are currently under evaluation in clinical trials for COVID-19 patients. We report the antiviral effect of remdesivir, lopinavir, chloroquine, umifenovir, berberine and cyclosporine A in Vero E6 cells model of SARS-CoV-2 infection, with estimated 50% inhibitory concentrations of 0.99, 5.2, 1.38, 3.5, 10.6 and 3 μM, respectively. Virus-directed plus host-directed drug combinations were also investigated. We report a strong antagonism between remdesivir and berberine, in contrast with remdesivir/diltiazem, for which we describe high levels of synergy, with mean Loewe synergy scores of 12 and peak values above 50. Combination of host-directed drugs with direct acting antivirals underscore further validation in more physiological models, yet they open up interesting avenues for the treatment of COVID-19

Human metapneumovirus activates NOD-like receptor protein 3 inflammasome via its small hydrophobic protein which plays a detrimental role during infection in mice

International audienceNOD-like receptor protein 3 (NLRP3) inflammasome activation triggers caspase-1 activation-induced maturation of interleukin (IL)-1β and IL-18 and therefore is important for the development of the host defense against various RNA viral diseases. However, the implication of this protein complex in human metapneumovirus (HMPV) disease has not been fully studied. Herein, we report that NLRP3 inflammasome plays a detrimental role during HMPV infection because NLRP3 inflammasome inhibition protected mice from mortality and reduced weight loss and inflammation without impacting viral replication. We also demonstrate that NLRP3 inflammasome exerts its deleterious effect via IL-1β production since we observed reduced mortality, weight loss and inflammation in IL-1β-deficient (IL-1β-/-) mice, as compared to wild-type animals during HMPV infection. Moreover, the effect on these evaluated parameters was not different in IL-1β-/- and wild-type mice treated with an NLRP3 inflammasome inhibitor. The production of IL-1β was also abrogated in bone marrow derived macrophages deficient for NLRP3. Finally, we show that small hydrophobic protein-deleted recombinant HMPV (HMPV ΔSH) failed to activate caspase-1, which is responsible for IL-1β cleavage and maturation. Furthermore, HMPV ΔSH-infected mice had less weight loss, showed no mortality and reduced inflammation, as compared to wild-type HMPV-infected mice. Thus, NLRP3 inflammasome activation seems to be triggered by HMPV SH protein in HMPV disease. In summary, once activated by the HMPV SH protein, NLRP3 inflammasome promotes the maturation of IL-1β, which exacerbates HMPV-induced inflammation. Therefore, the blockade of IL-1β production by using NLRP3 inflammasome inhibitors might be a novel potential strategy for the therapy and prevention of HMPV infection

Characterization of cellular transcriptomic signatures induced by different respiratory viruses in human reconstituted airway epithelia

International audienceAcute respiratory infections, a large part being of viral origin, constitute a major public health issue. To propose alternative and/or new therapeutic approaches, it is necessary to increase our knowledge about the interactions between respiratory viruses and their primary cellular targets using the most biologically relevant experimental models. In this study, we used RNAseq to characterize and compare the transcriptomic signature of infection induced by different major respiratory viruses (Influenza viruses, hRSV and hMPV) in a model of reconstituted human airway epithelia. Our results confirm the importance of several cellular pathways commonly or specifically induced by these respiratory viruses, such as the innate immune response or antiviral defense. A very interesting common feature revealed by the global virogenomic signature shared between hRSV, hMPV and influenza viruses is the global downregulation of cilium-related gene expression, in good agreement with experimental evaluation of mucociliary clearance. Beyond providing new information about respiratory virus/host interactions, our study also underlines the interest of using biologically relevant experimental models to study human respiratory viruses. Acute respiratory infections (ARI) constitute a leading cause of acute illness worldwide and a major cause of death among young children, with nearly 2 million deaths per year 1-3. Among a panoply of different viral and bacterial pathogens, respiratory viruses, such as influenza A and B viruses (IAV and IBV), respiratory syncytial virus (hRSV-A and hRSV-B), human metapneumovirus (hMPV-A and hMPV-B) or rhinoviruses (RV), represent the main etiologic agents of these infections 2,4,5. In that regard, the limited or non-existent prophylactic and therapeutic arsenal available, coupled with the emergence of antiviral resistance, highlight the public health burden imposed by these respiratory pathogens. It appears therefore urgent to develop alternative and/or new therapeutic approaches, for which it is a necessary condition to increase our knowledge of the interactions between respiratory viruses and their primary cellular targets, namely respiratory epithelial cells. The last decade has witnessed the development of high-throughput "omics" approaches that have contributed to deepen our understanding of the multiple levels of interplay between respiratory viruses and the host cell. Numerous studies have described the impact of infection on host gene expression in vitro or in vivo, mainly in the context of influenza viruses or hRSV and to a lesser extent for other respiratory viruses such hMPV 6-10. For example , several mRNA profiling studies, including ours, have highlighted the role of NF-kB, p53, or MAPK cellula

Molnupiravir combined with different repurposed drugs further inhibits SARS-CoV-2 infection in human nasal epithelium in vitro

International audienc

Human Respiratory Syncytial Virus-induced immune signature of infection revealed by transcriptome analysis of clinical pediatric nasopharyngeal swab samples

International audienceHuman Respiratory Syncytial Virus (HRSV) constitutes one the main causes of respiratory infection in neonates and infants worldwide. Transcriptome analysis of clinical samples using high-throughput technologies remains an important tool to better understand virus-host complex interactions in the real-life setting but also to identify new diagnosis/prognosis markers or therapeutics targets. A major challenge when exploiting clinical samples such as nasal swabs, washes or bronchoalveolar lavages is the poor quantity and integrity of nucleic acids. In this study, we applied a tailored transcriptomics workflow to exploit nasal wash samples from children who tested positive for HRSV. Our analysis revealed a characteristic immune signature as a direct reflection of HRSV pathogenesis and highlighted putative biomarkers of interest such as IP-10, TMEM190, MCEMP1 or TIMM23

Repurposing of Drugs as Novel Influenza Inhibitors From Clinical Gene Expression Infection Signatures

Influenza virus infections remain a major and recurrent public health burden. The intrinsic ever-evolving nature of this virus, the suboptimal efficacy of current influenza inactivated vaccines, as well as the emergence of resistance against a limited antiviral arsenal, highlight the critical need for novel therapeutic approaches. In this context, the aim of this study was to develop and validate an innovative strategy for drug repurposing as host-targeted inhibitors of influenza viruses and the rapid evaluation of the most promising candidates in Phase II clinical trials. We exploited in vivo global transcriptomic signatures of infection directly obtained from a patient cohort to determine a shortlist of already marketed drugs with newly identified, host-targeted inhibitory properties against influenza virus. The antiviral potential of selected repurposing candidates was further evaluated in vitro, in vivo, and ex vivo. Our strategy allowed the selection of a shortlist of 35 high potential candidates out of a rationalized computational screening of 1,309 FDA-approved bioactive molecules, 31 of which were validated for their significant in vitro antiviral activity. Our in vivo and ex vivo results highlight diltiazem, a calcium channel blocker currently used in the treatment of hypertension, as a promising option for the treatment of influenza infections. Additionally, transcriptomic signature analysis further revealed the so far undescribed capacity of diltiazem to modulate the expression of specific genes related to the host antiviral response and cholesterol metabolism. Finally, combination treatment with diltiazem and virus-targeted oseltamivir neuraminidase inhibitor further increased antiviral efficacy, prompting rapid authorization for the initiation of a Phase II clinical trial. This original, host-targeted, drug repurposing strategy constitutes an effective and highly reactive process for the rapid identificatio

Strain-Dependent Impact of G and SH Deletions Provide New Insights for Live-Attenuated HMPV Vaccine Development

International audienceHuman metapneumovirus (HMPV) is a major pediatric respiratory pathogen with currently no specific treatment or licensed vaccine. Different strategies to prevent this infection have been evaluated, including live-attenuated vaccines (LAV) based on SH and/or G protein deletions. This approach showed promising outcomes but has not been evaluated further using different viral strains. In that regard, we previously showed that different HMPV strains harbor distinct in vitro fusogenic and in vivo pathogenic phenotypes, possibly influencing the selection of vaccine strains. In this study, we investigated the putative contribution of the low conserved SH or G accessory proteins in such strain-dependent phenotypes and generated recombinant wild type (WT) and SH-or G-deleted viruses derived from two different patient-derived HMPV strains, A1/C-85473 and B2/CAN98-75. The ∆SH and ∆G deletions led to different strain-specific phenotypes in both LLC-MK2 cell and reconstituted human airway epithelium models. More interestingly, the ∆G-85473 and especially ∆SH-C-85473 recombinant viruses conferred significant protection against HMPV challenge and induced immunogenicity against a heterologous strain. In conclusion, our results show that the viral genetic backbone should be considered in the design of live-attenuated HMPV vaccines, and that a SH-deleted virus based on the A1/C-85473 HMPV strain could be a promising LAV candidate as it is both attenuated and protective in mice while being efficiently produced in a cell-based system