Lucile Pinault scite author profile

Introduction In Marseille, France, following a first SARS-CoV-2 outbreak in March-May 2020, a second epidemic phase occurred from June, involving ten new variants. The Marseille-4 variant caused an epidemic that started in August and is still ongoing. Materials and methods The 1,038 SARS-CoV-2 whole genome sequences obtained in our laboratory by next-generation sequencing with Illumina technology were analyzed using Nextclade and nextstrain/ncov pipelines and IQ-TREE. A Marseille-4-specific qPCR assay was implemented. Demographic and clinical features were compared between patients with Marseille-4 and earlier strains. Results Marseille-4 harbors 13 hallmark mutations. One leads to S477 N substitution in the spike receptor binding domain targeted by current vaccines. Using a specific qPCR, we observed that Marseille-4 caused 12-100% of SARS-CoV-2 infections in Marseille from September 2020, being involved in 2,106 diagnoses. This variant was more frequently associated with hypoxemia than clade 20A strains before May 2020. It caused re-infection in eleven patients SARS-CoV-2-diagnosed with different strains before June 2020, suggesting either short-term protective immunity or lack of cross-immunity. Discussion/conclusion Marseille-4 should be considered as a major SARS-CoV-2 variant. Its sudden appearance points toward an animal reservoir, possibly minks. The protective role of past-exposure and current vaccines against this variant should be evaluated.

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Emergence of Bat-Related Betacoronaviruses: Hazard and Risks

Frutos

Serra‐Cobo

Pinault

et al. 2021

Front. Microbiol.

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The current Coronavirus Disease 2019 (COVID-19) pandemic, with more than 111 million reported cases and 2,500,000 deaths worldwide (mortality rate currently estimated at 2.2%), is a stark reminder that coronaviruses (CoV)-induced diseases remain a major threat to humanity. COVID-19 is only the latest case of betacoronavirus (β-CoV) epidemics/pandemics. In the last 20 years, two deadly CoV epidemics, Severe Acute Respiratory Syndrome (SARS; fatality rate 9.6%) and Middle East Respiratory Syndrome (MERS; fatality rate 34.7%), plus the emergence of HCoV-HKU1 which causes the winter common cold (fatality rate 0.5%), were already a source of public health concern. Betacoronaviruses can also be a threat for livestock, as evidenced by the Swine Acute Diarrhea Syndrome (SADS) epizootic in pigs. These repeated outbreaks of β-CoV-induced diseases raise the question of the dynamic of propagation of this group of viruses in wildlife and human ecosystems. SARS-CoV, SARS-CoV-2, and HCoV-HKU1 emerged in Asia, strongly suggesting the existence of a regional hot spot for emergence. However, there might be other regional hot spots, as seen with MERS-CoV, which emerged in the Arabian Peninsula. β-CoVs responsible for human respiratory infections are closely related to bat-borne viruses. Bats are present worldwide and their level of infection with CoVs is very high on all continents. However, there is as yet no evidence of direct bat-to-human coronavirus infection. Transmission of β-CoV to humans is considered to occur accidentally through contact with susceptible intermediate animal species. This zoonotic emergence is a complex process involving not only bats, wildlife and natural ecosystems, but also many anthropogenic and societal aspects. Here, we try to understand why only few hot spots of β-CoV emergence have been identified despite worldwide bats and bat-borne β-CoV distribution. In this work, we analyze and compare the natural and anthropogenic environments associated with the emergence of β-CoV and outline conserved features likely to create favorable conditions for a new epidemic. We suggest monitoring South and East Africa as well as South America as these regions bring together many of the conditions that could make them future hot spots.

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Human metallo-β-lactamase enzymes degrade penicillin

Diène¹,

Pinault²,

Keshri³

et al. 2019

Sci Rep

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Nonribosomal peptides are assemblages, including antibiotics, of canonical amino acids and other molecules. β-lactam antibiotics act on bacterial cell walls and can be cleaved by β-lactamases. β-lactamase activity in humans has been neglected, even though eighteen enzymes have already been annotated such in human genome. Their hydrolysis activities on antibiotics have not been previously investigated. Here, we report that human cells were able to digest penicillin and this activity was inhibited by β-lactamase inhibitor, i.e. sulbactam. Penicillin degradation in human cells was microbiologically demonstrated on Pneumococcus . We expressed a MBLAC2 human β-lactamase, known as an exosome biogenesis enzyme. It cleaved penicillin and was inhibited by sulbactam. Finally, β-lactamases are widely distributed, archaic, and have wide spectrum, including digesting anticancer and β-lactams, that can be then used as nutriments. The evidence of the other MBLAC2 role as a bona fide β-lactamase allows for reassessment of β-lactams and β-lactamases role in humans.

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Lucile Pinault

Emergence and outcomes of the SARS-CoV-2 ‘Marseille-4’ variant

Emergence of Bat-Related Betacoronaviruses: Hazard and Risks

Human metallo-β-lactamase enzymes degrade penicillin

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