In Vitro Screening Identifies TRPV4 and PAR1 as Targets for Endothelial Barrier Stabilization in COVID‐19

Study objective Endothelial dysfunction and increased microvascular permeability are hallmarks of severe COVID‐19. At present, the underlying mechanisms of endothelial barrier failure in COVID‑19 remain elusive. Here, we show that increased thrombin activity in plasma from severe COVID‐19 patients activates endothelial protease‐activated receptor (PAR1), which mediates barrier failure by triggering TRPV4‐mediated Ca2+ influx in lung microvascular endothelial cells. Methods Citrate plasma was sampled as part of the Pa‐COVID‐19 cohort study (ethics approval EA2/066/20) from patients with severe COVID‐19 (high flow O2 or mechanically ventilated;WHO severity score: 5‐7) COVID‑19. Plasma samples were diluted to 10% (v/v) in cell culture medium without FCS and tested for their ability to disrupt barrier integrity of primary human pulmonary microvascular endothelial cells (HPMEC) monolayers by electrical cell‐substrate impedance sensing (ECIS), immunofluorescence for endothelial VE‐cadherin and F‐actin, western blot analyses of PAR‐1 cleavage, and real‐time Ca2+ imaging. Plasma from healthy donors served as control. Results COVID‐19 plasma had elevated thrombin activity while levels of antithrombin III, a key anti‐coagulant with thromboprotective function were decreased. COVID‐19 plasma caused endothelial barrier dysfunction as measured by ECIS and gap formation in HPMEC monolayers. Endothelial barrier disruption and endothelial Ca2+ influx in response to COVID‐19 plasma could be blocked by selective antagonists targeting thrombin (Argatroban), its receptor PAR1 (SCH79797), or TRPV4 (HC‐067047). Conclusion Here, we identify a novel signaling axis involving thrombin, its receptor PAR1, and TRPV4 as mechanism for increased microvascular permeability in COVID‑19. Targeting this signaling axis in endothelial barrier failure may provide a promising adjunctive therapy in COVID‐19.

Bacterial Membrane Vesicles in Pneumonia: From Mediators of Virulence to Innovative Vaccine Candidates.

Pneumonia due to respiratory infection with most prominently bacteria, but also viruses, fungi, or parasites is the leading cause of death worldwide among all infectious disease in both adults and infants. The introduction of modern antibiotic treatment regimens and vaccine strategies has helped to lower the burden of bacterial pneumonia, yet due to the unavailability or refusal of vaccines and antimicrobials in parts of the global population, the rise of multidrug resistant pathogens, and high fatality rates even in patients treated with appropriate antibiotics pneumonia remains a global threat. As such, a better understanding of pathogen virulence on the one, and the development of innovative vaccine strategies on the other hand are once again in dire need in the perennial fight of men against microbes. Recent data show that the secretome of bacteria consists not only of soluble mediators of virulence but also to a significant proportion of extracellular vesicles-lipid bilayer-delimited particles that form integral mediators of intercellular communication. Extracellular vesicles are released from cells of all kinds of organisms, including both Gram-negative and Gram-positive bacteria in which case they are commonly termed outer membrane vesicles (OMVs) and membrane vesicles (MVs), respectively. (O)MVs can trigger inflammatory responses to specific pathogens including S. pneumonia, P. aeruginosa, and L. pneumophila and as such, mediate bacterial virulence in pneumonia by challenging the host respiratory epithelium and cellular and humoral immunity. In parallel, however, (O)MVs have recently emerged as auspicious vaccine candidates due to their natural antigenicity and favorable biochemical properties. First studies highlight the efficacy of such vaccines in animal models exposed to (O)MVs from B. pertussis, S. pneumoniae, A. baumannii, and K. pneumoniae. An advanced and balanced recognition of both the detrimental effects of (O)MVs and their immunogenic potential could pave the way to novel treatment strategies in pneumonia and effective preventive approaches.

In vitro screening identifies TRPV4 as target for endothelial barrier stabilization in COVID-19

Study objective Endothelial dysfunction and increased microvascular permeability are hallmarks of severe COVID-19. At present, the extent of endothelial barrier failure and its underlying mechanisms in COVID?19 remain unclear. We hypothesized that endothelial leak results from bioactive mediators released in COVID-19 rather than direct endothelial infection and can thus be recapitulated ex vivo by treating endothelial cells with patient plasma, thus providing a personalized screening platform for barrier-protective interventions in COVID-19. Methods Citrate plasma was sampled as part of the Pa-COVID-19 cohort study (ethics approval EA2/066/20) in patients with moderate (hospitalized, no invasive ventilation;WHO severity score: 3-4) and severe (high flow O2 or intubated and mechanically ventilated;WHO severity score: 5-7) COVID?19. Plasma samples were diluted to 10% (v/v) in cell culture medium without FCS and tested for their ability to disrupt barrier integrity of primary human pulmonary microvascular endothelial cells (HPMEC) monolayers by electrical cell-substrate impedance sensing (ECIS), immunofluorescence for endothelial VE-cadherin and F-actin, and real-time Ca2+ imaging. Plasma from healthy donors served as control. Results COVID-19 plasma was virus-free but caused endothelial barrier disruption as measured by ECIS and gap formation in HPMEC monolayers. The extent of barrier disruption increased with disease severity but varied considerably between endothelial cells from different microvascular beds (lung/heart >> skin). The TRPV4-antagonist HC-067047 prevented the endothelial Ca2+ response to COVID-19 plasma and protected endothelial barrier integrity in lung microvascular cells. Conclusion Here, we identify TRPV4 as critical regulator of microvascular permeability in COVID?19. Targeting TRPV4-mediated endothelial barrier failure may present a promising adjunctive therapy in COVID-19.