Ebselen inhibits enterovirus A71-induced apoptosis through reactive oxygen species-mediated signaling pathway.

BACKGROUND: Enterovirus A71 (EV-A71)is a prevalent infection in severe hand, foot and mouth disease HFMD and can induce acute central nervous system seizures. The three EV-A71 vaccines now circulating in the market are produced for a single subtype. While EV-A71 is constantly evolving and the vaccine's efficacy is gradually reducing, no specialized anti-EV-A71 medication has yet been developed. Therefore, it is crucial to consistently develop new anti-EV-A71 medications. METHOD: Ebselen, an organoselenium molecule with glutathione oxidase-like activity, is resistant to a range of viruses. In this investigation, we used the Cell counting kit-8 (CCK-8 kit) assay in a Vero cell model to confirm the effectiveness of ebselen against EV-A71 infection. Later, to examine ebselen's anti-EV-A71 mechanism, we measured the apoptosis level of cells in different treatment groups through Annexin V, JC-1, and cell cycle assays, as well as the intracellular reactive oxygen species (ROS) concentration. Ebselen may have an impact on the apoptotic signaling pathway caused by EV-A71 infection, according to the results of a caspase-3 activity experiment. RESULT: The results showed that Ebselen protected cell damage from ROS generation, decreased the frequency of EV-A71-induced apoptosis, and inhibited caspase-3-mediated apoptosis by lowering caspase-3 activity. CONCLUSION: To summarize, ebselen is a promising anti-EV-A71 medication.

Inhibition of H1N1 by Picochlorum sp. 122 via AKT and p53 signaling pathways.

Influenza viruses cause a severe threat to global health, which can lead to annual epidemics and cause pandemics occasionally. However, the number of anti-influenza therapeutic agents is very limited. Polysaccharides, extracted from Picochlorum sp. (PPE), seaweed Polysaccharides, have exhibited antiviral activity and were expected to be used for influenza treatment. In our research, the capability of PPE to inhibit H1N1 infection was proved in MDCK cells. PPE could make MDCK cells avoid being infected with H1N1 and inhibited nuclear fragmentation and condensation of chromatin. PPE evidently inhibited the generation of reactive oxygen species in MDCK cells. Mechanism study revealed that PPE prevented MDCK cells from H1N1 infection through induction of apoptosis by stimulating AKT signaling pathway and suppressing p-p53 signaling pathway. In conclusion, PPE turns out to act as a prospective antiviral drug for H1N1 influenza.

Inhibition of H1N1 Influenza Virus-induced Apoptosis by Ebselen Through ROS-mediated ATM/ATR Signaling Pathways.

Influenza A viruses can cause global outbreaks and seasonal pandemics. However, the use of conventional anti-influenza drugs leads to an increase in drug-resistant mutations in influenza viruses worldwide. Therefore, numerous studies have focused on developing effective anti-influenza drugs. It is feasible to treat influenza by targeting influenza-mediated oxidative damage. Ebselen is a synthetic organoselenium compound which provides glutathione peroxidase-like activity. It has been shown to play a role in anti-influenza therapy, but the mechanism remains to be further explored. This experiment verified the anti-influenza effect of ebselen. CCK-8 and PCR showed that ebselen had a significant inhibitory effect on virus replication compared with the virus group. In addition, the mechanistic investigations revealed that ebselen could inhibit influenza-mediated apoptosis, mitochondrial damage, accumulation of reactive oxygen species, and DNA breakage. At the same time, ebselen significantly inhibited the phosphorylation of ATM and ATR and promoted the activation of PARP and Caspase-3. Ebselen, on the other hand, reduced the inflammatory response caused by influenza. These results suggest that ebselen is a promising inhibitor for H1N1.

Inhibition of HAdV-14 induced apoptosis by selenocystine through ROS-mediated PARP and p53 signaling pathways.

BACKGROUND: Human Adenovirus (HAdV) can cause severe respiratory symptoms in people with low immunity and there is no targeted treatment for adenovirus infection. Anti-adenoviral drugs have high clinical significance for inhibiting adenovirus infection. Selenium (Se) plays an important role in anti-oxidation, redox signal transduction, and redox homeostasis. The excellent biological activity of Se is mainly achieved by being converted into selenocystine (SeC). Se participates in the active sites of various selenoproteins in the form of SeC. The ability of SeC to resist the virus has raised high awareness due to its unique antioxidative activity in recent years. The antiviral ability of the SeC was determined by detecting the infection rate of the virus in the cells. METHODS: The experiment mainly investigated the antiviral mechanism of SeC by locating the virus in the cell, detecting the generation of ROS, observing the DNA status of the cell, and monitoring the mitochondrial membrane potential. RESULTS: In the present study, SeC was designed to resist A549 cells infections caused by HAdV-14. SeC could prevent HAdV-14 from causing cell apoptosis-related to DNA damage. SeC significantly inhibited ROS generation and protect the cells from oxidative damage induced by ROS against HAdV-14. SeC induced the increase of antiviral cytokines such as IL-6 and IL-8 by activating the Jak2 signaling pathway, and repaired DNA lesions by suppressing ATR, p53, and PARP signaling pathways. CONCLUSION: SeC might provide an effective selenium species with antiviral properties for the therapies against HAdV-14.

Selenadiazole Inhibited Adenovirus-Induced Apoptosis through the Oxidative-Damage-Mediated Bcl-2/Stat 3/NF-κB Signaling Pathway.

Human adenovirus type 7 (HAdV7) infection causes severe pneumonia, yet there are still no breakthroughs in treatment options for adenovirus, and the road to antiviral drug development faces major challenges. We attempted to find new drugs and we stumbled upon one: selenadiazole. Selenadiazole has been shown to have significant anti-tumor effects due to its unique chemical structure and drug activity. However, its effectiveness against viruses has not been evaluated yet. In our study, selenadiazole also showed superior antiviral activity. In vitro experiments, selenadiazole was able to inhibit adenovirus-mediated mitochondrial-oxidative-damage-related apoptosis, and in in vivo experiments, selenadiazole was able to inhibit apoptosis by modulating the apoptotic signaling pathway Bcl-2/Stat3/NF-κB, etc., and was able to largely attenuate adenovirus-infection-induced pneumonia and lung injury in mice. This study aims to describe a new antiviral treatment option from the perspective of anti-adenovirus-mediated oxidative stress and its associated apoptosis and to provide theoretical guidance for the treatment of clinical adenovirus infection to a certain extent.

Selenium nanoparticles inhibited H1N1 influenza virus-induced apoptosis by ROS-mediated signaling pathways.

Influenza A (H1N1) viruses are distributed around the world and pose a threat to public health. Vaccination is the main treatment strategy to prevent influenza infection, but antiviral drugs also play an important role in controlling seasonal and pandemic influenza. Currently, as influenza viruses may be developing antiviral resistance, new agents with different modes of action are being investigated. Recently, selenium nanoparticles (SeNPs), which have antiviral effects, have attracted increasing attention in biomedical interventions. The appearance of nanotechnology has attracted great attention in the field of nanomedicine. SeNPs constitute an attractive vector platform for delivering a variety of drugs to action targets. SeNPs are being explored for potential therapeutic efficacy in a variety of oxidative stress and inflammation-mediated diseases, such as cancer, arthritis, diabetes, and kidney disease. SeNPs could inhibit infection of Madin-Darby canine kidney (MDCK) cells with H1N1 and prevent chromatin condensation and DNA fragmentation. ROS play a key role in physiological processes for apoptosis. SeNPs significantly inhibited the production of reactive oxygen species (ROS) in MDCK cells. Mechanistic investigation revealed that SeNPs inhibited the apoptosis induced by H1N1 virus infection in MDCK cells by improving the level of GPx1. Our results suggest that SeNPs are an effective selenium source and a promising H1N1 influenza antiviral candidate.

Changes of Host Immunity Mediated by IFN-γ+ CD8+ T Cells in Children with Adenovirus Pneumonia in Different Severity of Illness.

The host immunity of patients with adenovirus pneumonia in different severity of illness is unclear. This study compared the routine laboratory tests and the host immunity of human adenovirus (HAdV) patients with different severity of illness. A co-cultured cell model in vitro was established to verify the T cell response in vitro. Among 140 patients with confirmed HAdV of varying severity, the number of lymphocytes in the severe patients was significantly reduced to 1.91 × 109/L compared with the healthy control (3.92 × 109/L) and the mild patients (4.27 × 109/L). The levels of IL-6, IL-10, and IFN-γ in patients with adenovirus pneumonia were significantly elevated with the severity of the disease. Compared with the healthy control (20.82%) and the stable patients (33.96%), the percentage of CD8+ T cells that produced IFN-γ increased to 56.27% in the progressing patients. Adenovirus infection increased the percentage of CD8+ T and CD4+ T cells that produce IFN-γ in the co-culture system. The hyperfunction of IFN-γ+ CD8+ T cells might be related to the severity of adenovirus infection. The in vitro co-culture cell model could also provide a usable cellular model for subsequent experiments.