Mitochondria are vital intracellular organelles that play an important role in regulating various intracellular events such as metabolism, bioenergetics, cell death (apoptosis), and innate immune signaling. Mitochondrial fission, fusion, and membrane potential play a central role in maintaining mitochondrial dynamics and the overall shape of mitochondria. Viruses change the dynamics of the mitochondria by altering the mitochondrial processes/functions, such as autophagy, mitophagy, and enzymes involved in metabolism. In addition, viruses decrease the supply of energy to the mitochondria in the form of ATP, causing viruses to create cellular stress by generating ROS in mitochondria to instigate viral proliferation, a process which causes both intra- and extra-mitochondrial damage. SARS-COV2 propagates through altering or changing various pathways, such as autophagy, UPR stress, MPTP and NLRP3 inflammasome. Thus, these pathways act as potential targets for viruses to facilitate their proliferation. Autophagy plays an essential role in SARS-COV2-mediated COVID-19 and modulates autophagy by using various drugs that act on potential targets of the virus to inhibit and treat viral infection. Modulated autophagy inhibits coronavirus replication; thus, it becomes a promising target for anti-coronaviral therapy. This review gives immense knowledge about the infections, mitochondrial modulations, and therapeutic targets of viruses.
The gut microbiome consists of the trillions of bacteria and other microbes whose metabolic activities and interactions with the immune system go beyond the gut itself. We are all aware that bacteria and other microorganisms have a significant impact on our health. Also, health of the bacteria directly reflects the health status of the body where they reside. Eventually, alterations in the microbiome at different sites of a body is associated with many different diseases such as obesity, IBD, malnutrition, CVD, etc. Microbiota directly or indirectly affects the heart with formation of plaques in the blood vessels and cell wall become prone to the lesion development. This ultimately leads to heighten the overall inflammatory status via increased bacterial translocation. Metabolites derived from the gut microbial metabolism of choline, phosphatidylcholine, and L-carnitine directly contribute to CVD pathology. These dietary nutrients have trimethylamine (TMA) moiety, which participates in the development of atherosclerotic heart disease. The objective of this review was to examine various metabolic pathways regulated by the gut microbiome that appear to alter heart function and lead to the development and progression of cardiovascular diseases, as well as how to target the gut microbiome for a healthier heart. In this review, we had also discussed about various clinical drugs having crosstalk between microbiota and heart and clinical trials for gut-heart microbiome.
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