Antiviral fungal metabolites and some insights into their contribution to the current COVID-19 pandemic.

The severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) outbreak, which started in late 2019, drove the scientific community to conduct innovative research to contain the spread of the pandemic and to care for those already affected. Since then, the search for new drugs that are effective against the virus has been strengthened. Featuring a relatively low cost of production under well-defined methods of cultivation, fungi have been providing a diversity of antiviral metabolites with unprecedented chemical structures. In this review, we present viral RNA infections highlighting SARS-CoV-2 morphogenesis and the infectious cycle, the targets of known antiviral drugs, and current developments in this area such as drug repurposing. We also explored the metabolic adaptability of fungi during fermentation to produce metabolites active against RNA viruses, along with their chemical structures, and mechanisms of action. Finally, the state of the art of research on SARS-CoV-2 inhibitors of fungal origin is reported, highlighting the metabolites selected by docking studies.

Human immune response in schistosomiasis: the role of P24 in the modulation of cellular reactivity to Schistosoma mansoni antigens.

Schistosome antigenic components are being tested as vaccine candidates with various degrees of success, but there are only few reports using multivalent antigens to stimulate an appropriate immune response that leads to resistance or granuloma modulation. We investigated the in vitro response of peripheral blood mononuclear cells (PBMC) from chronic intestinal schistosomiasis individuals to PIII, a multivalent antigen prepared from Schistosoma mansoni adult worm antigen, and response to P24, a single antigen obtained from PIII. Treatment of PBMC with either PIII or P24 caused significant decrease in cellular proliferation and granuloma formation induced by S. mansoni antigens, and a significant elevation in IL-10 and TNF-alpha but not in IFN-gamma production. Moreover, P24 promoted an elevation in TNF-alpha level on the in vitro granuloma reaction, when cocultured with polyacrylamide beads (PB) coupled to S. mansoni antigens. These findings suggest that, besides inducing protective immunity, PIII and P24 antigens seem to be important in the regulation of in vitro granuloma formation through stimulation of IL-10 and TNF-alpha production in human schistosomiasis. The more pronounced effect of P24 on reducing the in vitro granulomatous reaction could be associated with a balance between IL-10 and TNF-alpha production.

Potency against enterotoxemia of a recombinant Clostridium perfringens type D epsilon toxoid in ruminants.

Enterotoxemia, a disease that affects domestic ruminants, is caused mainly by the epsilon toxin from Clostridium perfringens type D. Its eradication is virtually impossible, control and prophylaxis are based on systematic vaccination of herds with epsilon toxoids that are efficient in inducing protective antibody production. The use of recombinant toxins is one of the most promising of these strategies. This work evaluates the potency of a Cl. perfringens type D epsilon toxoid expressed by Escherichia coli administered to goats, sheep, and cattle. The etx gene was cloned into the pET-11a plasmid of E. coli strain BL21 to produce the recombinant toxin. Rabbits (n=8), goats, sheep, and cattle (n=5 for each species) were immunized with 0.2mg of the insoluble recombinant protein fraction to evaluate vaccine potency of the epsilon toxoid studied. Antibody titers were 40, 14.3, 26, and 13.1 IU/mL in the rabbit, goat, sheep, and cattle serum pools, respectively. The epsilon toxoid produced and tested in this work is adequate for immunization of ruminants against enterotoxemia.