Bats are a key reservoir of coronaviruses (CoVs), including the agent of the severe acute respiratory syndrome, SARS-CoV-2, responsible for the recent deadly viral pneumonia pandemic. However, understanding how bats can harbor several microorganisms without developing illnesses is still a matter under discussion. Viruses and other pathogens are often studied as stand-alone even though it is known that, in nature, they mostly live in multi-species associations called biofilms - both externally and within the host. Microorganisms in biofilms are enclosed by an extracellular matrix that confers protection and improves survival. Previous studies have shown that viruses can secondarily colonize preexisting biofilms, and viral biofilms have also been already described. In this review, we raise the perspective that CoVs can persistently infect bats due to occurrence in biofilm structures. This phenomenon potentially provides an optimal environment for non-pathogenic and well-adapted viruses to interact with the host, as well as for viral recombination. Biofilms can also enhance virion viability in extracellular environments, such as in fomites and aquatic sediments, allowing viral persistence and dissemination. Moreover, understanding CoVs biofilm lifestyle in reservoirs might contribute to explain several burning questions that remain unanswered including persistence and transmissibility by highly pathogenic emerging CoVs.
The reality and intensity of antibiotic resistance in pathogenic bacteria calls for the rapid development of new antimicrobial drugs. In bacteria, trans-translation is the primary quality control mechanism for rescuing ribosomes arrested during translation. Because transtranslation is absent in eukaryotes but necessary to avoid ribosomal stalling and therefore essential for bacterial survival, it is a promising target either for novel antibiotics or for improving the activities of the protein synthesis inhibitors already in use. Oxadiazole derivatives display strong bactericidal activity against a large number of bacteria, but their effects on trans-translation were recently questioned. In this work, a series of new 1,3,4oxadiazole derivatives and analogs were synthesized and assessed for their efficiency as antimicrobial agents against a wide range of gram-positive and gram-negative pathogenic strains. Despite the strong antimicrobial activity observed in these molecules, it turns out that they do not target trans-translation in vivo, but they definitely act on various other cellular pathways. This work was supported by the Direction Générale de l'Armement (#ANR-14-ASTR-0001) and the Agence Nationale pour la Recherche under the frame of the Joint JPI-EC-AMR Project named "Ribotarget-Development of novel ribosome-targeting antibiotics" (SNF No.
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