IL-6, IL-10, sFas, granulysin and indicators of intestinal permeability as early biomarkers for a fatal outcome in COVID-19.

The clinical presentation of coronavirus disease 2019 (COVID-19), which is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), ranges between mild respiratory symptoms and a severe disease that shares many of the features of sepsis. Sepsis is a deregulated response to infection that causes life-threatening organ failure. During sepsis, the intestinal epithelial cells are affected, causing an increase in intestinal permeability and allowing microbial translocation from the intestine to the circulation, which exacerbates the inflammatory response. Here we studied patients with moderate, severe and critical COVID-19 by measuring a panel of molecules representative of the innate and adaptive immune responses to SARS-CoV-2, which also reflect the presence of systemic inflammation and the state of the intestinal barrier. We found that non-surviving COVID-19 patients had higher levels of low-affinity anti-RBD IgA antibodies than surviving patients, which may be a response to increased microbial translocation. We identified sFas and granulysin, in addition to IL-6 and IL-10, as possible early biomarkers with high sensitivity (>73 %) and specificity (>51 %) to discriminate between surviving and non-surviving COVID-19 patients. Finally, we found that the microbial metabolite d-lactate and the tight junction regulator zonulin were increased in the serum of patients with severe COVID-19 and in COVID-19 patients with secondary infections, suggesting that increased intestinal permeability may be a source of secondary infections in these patients. COVID-19 patients with secondary infections had higher disease severity and mortality than patients without these infections, indicating that intestinal permeability markers could provide complementary information to the serum cytokines for the early identification of COVID-19 patients with a high risk of a fatal outcome.

Steady-state persistence of respiratory syncytial virus in a macrophage-like cell line and sequence analysis of the persistent viral genome.

Long-term infection by human respiratory syncytial virus (hRSV) has been reported in immunocompromised patients. Cell lines are valuable in vitro model systems to study mechanisms associated with viral persistence. Persistent infections in cell cultures have been categorized at least as in "carrier-state", where there exist a low proportion of cells infected by a lytic virus, and as in "steady-state", where most of cells are infected, but in absence of cytophatic effect. Here, we showed that hRSV maintained a steady-state persistence in a macrophage-like cell line after 120 passages, since the viral genome was detected in all of the cells analyzed by fluorescence in situ hybridization, whereas only defective viruses were identified by sucrose gradients and titration assay. Interestingly, eight percent of cells harboring the hRSV genome revealed undetectable expression of the viral nucleoprotein N; however, when this cell population was sorted by flow cytometry and independently cultured, viral protein expression was induced at detectable levels since the first post-sorting passage, supporting that sorted cells harbored the viral genome. Sequencing of the persistent hRSV genome obtained from virus collected from cell-culture supernatants, allowed assembling of a complete genome that displayed 24 synonymous and 38 nonsynonymous substitutions in coding regions, whereas extragenic and intergenic regions displayed 12 substitutions, two insertions and one deletion. Previous reports characterizing mutations in extragenic regulatory sequences of hRSV, suggested that some mutations localized at the 3' leader region of our persistent virus might alter viral transcription and replication, as well as assembly of viral nucleocapsids. Besides, substitutions in P, F and G proteins might contribute to altered viral assembly, budding and membrane fusion, reducing the cytopathic effect and in consequence, contributing to host-cell survival. Full-length mutant genomes might be part of the repertoire of defective viral genomes formed during hRSV infections, contributing to the establishment and maintenance of virus persistence.