Significance
Gaining insights into severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) high transmissibility and the role played by inflammatory mediators in viral proliferation are critical to investigating new therapeutic targets against COVID-19. Electron microscopy reveals important SARS-CoV-2 features, including the combination of large, rapidly released viral clusters and the massive shedding of epithelial cells packed with virions. Interleukin-13 (IL-13), a Th2 cytokine up-regulated in allergic asthma and associated with less severe COVID-19, protects against SARS-CoV-2 viral and cell shedding. Using gene expression analyses and biochemical assays, IL-13 is shown to affect viral entry, replication, and cell-to-cell transmission. Given the broad spectrum of COVID-19 clinical symptoms, it is important to elucidate intrinsic factors that modulate viral load and spreading mechanisms.
QuestionCystic fibrosis (CF) is characterised by the accumulation of viscous, adherent mucus in the lungs. While several hypotheses invoke a direct relationship with CFTR dysfunction (i.e., acidic airway surface liquid (ASL) pH, low [HCO3−], airway dehydration), the dominant biochemical alteration of CF mucus remains unknown.Materials/MethodsWe characterised a novel cell line (CFTR-KO Calu3 cells) and the responses of human bronchial epithelial (HBE) cells from subjects with G551D or F508del mutations to Ivacaftor and Elexacaftor-Tezacaftor-Ivacaftor (ETI). A spectrum of assays such as short-circuit currents (Isc), qPCR, ASL pH, western blotting (WB), light scattering/refractometry (SEC-MALS), scanning electron microscopy (SEM), % solids, and particle tracking were performed to determine the impact of CFTR function on mucus properties.ResultsLoss of CFTR function in Calu3 cells resulted in ASL pH acidification and mucus hyperconcentration (dehydration). Modulation of CFTR in CF HBE cells did not affect ASL pH or mucin mRNA expression, but decreased mucus concentration, relaxed mucus network ultrastructure, and improved mucus transport. In contrast with modulator-treated cells, a large fraction of airway mucins remained attached to naïve CF cells following short apical washes, as revealed by the use of reducing agents to remove residual mucus from the cell surfaces. Extended hydration, but not buffers alkalised with NaOH or HCO3−, normalised mucus recovery to modulator-treated cell levels.ConclusionThese results indicate that airway dehydration, not acidic pH and/or low [HCO3−], is responsible for abnormal mucus properties in CF airways and CFTR modulation predominantly restores normal mucin entanglement.
Significance
A potential outbreak of swine acute diarrhea syndrome coronavirus (SADS-CoV) in the human population could be devastating. Using genomewide CRISPR knockout screening, we identified the placenta-associated 8 protein (PLAC8) as an essential host factor for SADS-CoV infection, uncovering a novel antiviral target for CoV infection. The PLAC8-related pathway may also have implications for other CoV infections. Given the ability of SADS-CoV to infect human primary cultures without adaptation, our findings lay the foundation for pandemic preparedness for the potential emergence of SADS-CoVs in response to the One Health Initiative.
Unlike solid organs, human airway epithelia derive their oxygen from inspired air rather than the vasculature. Many pulmonary diseases are associated with intraluminal airway obstruction caused by aspirated foreign bodies, virus infection, tumors, or mucus plugs intrinsic to airway disease, including cystic fibrosis (CF). Consistent with requirements for luminal O
2
, airway epithelia surrounding mucus plugs in chronic obstructive pulmonary disease (COPD) lungs are hypoxic. Despite these observations, the effects of chronic hypoxia (CH) on airway epithelial host defense functions relevant to pulmonary disease have not been investigated. Molecular characterization of resected human lungs from individuals with a spectrum of muco-obstructive lung diseases (MOLDs) or COVID-19 identified molecular features of chronic hypoxia, including increased
EGLN3
expression, in epithelia lining mucus-obstructed airways. In vitro experiments using cultured chronically hypoxic airway epithelia revealed conversion to a glycolytic metabolic state with maintenance of cellular architecture. Chronically hypoxic airway epithelia unexpectedly exhibited increased MUC5B mucin production and increased transepithelial Na
+
and fluid absorption mediated by HIF1α/HIF2α-dependent up-regulation of β and γENaC (epithelial Na
+
channel) subunit expression. The combination of increased Na
+
absorption and MUC5B production generated hyperconcentrated mucus predicted to perpetuate obstruction. Single-cell and bulk RNA sequencing analyses of chronically hypoxic cultured airway epithelia revealed transcriptional changes involved in airway wall remodeling, destruction, and angiogenesis. These results were confirmed by RNA–in situ hybridization studies of lungs from individuals with MOLD. Our data suggest that chronic airway epithelial hypoxia may be central to the pathogenesis of persistent mucus accumulation in MOLDs and associated airway wall damage.
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