Therapeutic potentials of stem cell-derived exosomes in cardiovascular diseases.

Exosomes are extracellular vesicles released by many cell types with varying compositions. Major bioactive factors present in exosomes are protein, lipid, mRNA, and miRNA. Exosomes are fundamental regulators of cellular trafficking and signaling in both physiological and pathological conditions. Various conditions such as oxidative stress, endoplasmic reticulum stress, ribosomal stress, and thermal stress alter the concentration of exosomal mRNA, and miRNA, lipids, and proteins. Stem cell-derived exosomes have been shown to regulate a variety of stresses, either inhibiting or promoting cell balance. Stem cell-derived exosomes direct the crosstalk between various cell types which helps recovery by transferring information in proteins, lipids, and so on. This is one of the reasons why exosomes are used as biomarkers for a multitude of disease conditions. This review highlights the bioengineering of fabricated exosomal cargoes. It includes the manipulation and delivery of specific exosomal cargoes such as noncoding RNAs, recombinant proteins, immune modulators, therapeutic drugs, and small molecules. Such therapeutic approaches may precisely deliver the therapeutic drugs at the target site in the management of various disease conditions. Importantly, we have focused on the therapeutic applications of stem cell-derived exosomes in cardiovascular disease conditions such as myocardial infarction, ischemic heart disease, cardiomyopathy, heart failure, sepsis, and cardiac fibrosis. Generally, two approaches are being followed by researchers for exosomal bioengineering. This literature review will shed light on the role of stem cell-derived exosomes in stress balance and provides a new avenue for the treatment of cardiovascular diseases.

Role of ARP2/3 Complex-Driven Actin Polymerization in RSV Infection.

Respiratory syncytial virus (RSV) is the leading viral agent causing bronchiolitis and pneumonia in children under five years old worldwide. The RSV infection cycle starts with macropinocytosis-based entry into the host airway epithelial cell membrane, followed by virus transcription, replication, assembly, budding, and spread. It is not surprising that the host actin cytoskeleton contributes to different stages of the RSV replication cycle. RSV modulates actin-related protein 2/3 (ARP2/3) complex-driven actin polymerization for a robust filopodia induction on the infected lung epithelial A549 cells, which contributes to the virus's budding, and cell-to-cell spread. Thus, a comprehensive understanding of RSV-induced cytoskeletal modulation and its role in lung pathobiology may identify novel intervention strategies. This review will focus on the role of the ARP2/3 complex in RSV's pathogenesis and possible therapeutic targets to the ARP2/3 complex for RSV.