RESUMO
We provide research findings on the physics of aerosol and droplet dispersion relevant to the hypothesized aerosol transmission of SARS-CoV-2 during the current pandemic. We utilize physics-based modeling at different levels of complexity, along with previous literature on coronaviruses, to investigate the possibility of airborne transmission. The previous literature, our 0D-3D simulations by various physics-based models, and theoretical calculations, indicate that the typical size range of speech and cough originated droplets ( d ⩽ 20 µ m ) allows lingering in the air for O ( 1 h ) so that they could be inhaled. Consistent with the previous literature, numerical evidence on the rapid drying process of even large droplets, up to sizes O ( 100 µ m ) , into droplet nuclei/aerosols is provided. Based on the literature and the public media sources, we provide evidence that the individuals, who have been tested positive on COVID-19, could have been exposed to aerosols/droplet nuclei by inhaling them in significant numbers e.g. O ( 100 ) . By 3D scale-resolving computational fluid dynamics (CFD) simulations, we give various examples on the transport and dilution of aerosols ( d ⩽ 20 µ m ) over distances O ( 10 m ) in generic environments. We study susceptible and infected individuals in generic public places by Monte-Carlo modelling. The developed model takes into account the locally varying aerosol concentration levels which the susceptible accumulate via inhalation. The introduced concept, 'exposure time' to virus containing aerosols is proposed to complement the traditional 'safety distance' thinking. We show that the exposure time to inhale O ( 100 ) aerosols could range from O ( 1 s ) to O ( 1 min ) or even to O ( 1 h ) depending on the situation. The Monte-Carlo simulations, along with the theory, provide clear quantitative insight to the exposure time in different public indoor environments.
RESUMO
Altered prolyl oligopeptidase (PREP) activity is found in many common neurological and other genetic disorders, and in some cases PREP inhibition may be a promising treatment. The active site of PREP resides in an internal cavity; in addition to the direct interaction between active site and substrate or inhibitor, the pathway to reach the active site (the gating mechanism) must be understood for more rational inhibitor design and understanding PREP function. The gating mechanism of PREP has been investigated through molecular dynamics (MD) simulation combined with crystallographic and mutagenesis studies. The MD results indicate the inter-domain loop structure, comprised of 3 loops at residues, 189-209 (loop A), 577-608 (loop B), and 636-646 (loop C) (porcine PREP numbering), are important components of the gating mechanism. The results from enzyme kinetics of PREP variants also support this hypothesis: When loop A is (1) locked to loop B through a disulphide bridge, all enzyme activity is halted, (2) nicked, enzyme activity is increased, and (3) removed, enzyme activity is only reduced. Limited proteolysis study also supports the hypothesis of a loop A driven gating mechanism. The MD results show a stable network of H-bonds that hold the two protein domains together. Crystallographic study indicates that a set of known PREP inhibitors inhabit a common binding conformation, and this H-bond network is not significantly altered. Thus the domain separation, seen to occur in lower taxa, is not involved in the gating mechanism for mammalian PREP. In two of the MD simulations we observed a conformational change that involved the breaking of the H-bond network holding loops A and B together. We also found that this network was more stable when the active site was occupied, thus decreasing the likelihood of this transition.