1.
Current Insights on the Role of Irisin in Endothelial Dysfunction.
Luna-Ceron, E, González-Gil, AM, Elizondo-Montemayor, L
Current vascular pharmacology. 2022;(3):205-220
Abstract
Endothelial dysfunction is a crucial physiopathological mechanism for cardiovascular diseases that results from the harmful impact of metabolic disorders. Irisin, a recently discovered adipomyokine, has been shown to exert beneficial metabolic effects by increasing energy consumption, improving insulin sensitivity, and reducing the proinflammatory milieu. Multiple preclinical models have assessed irisin's possible role in the development of endothelial dysfunction, displaying that treatment with exogenous irisin can decrease the production of oxidative stress mediators by up-regulating Akt/mTOR/Nrf2 pathway, promote endothelial-dependent vasodilatation through the activation of AMPK-PI3K-AkteNOS pathway, and increase the endothelial cell viability by activation of ERK proliferation pathway and downregulation of Bad/Bax/Caspase 3 pro-apoptotic pathway. However, there is scarce evidence of these mechanisms in clinical studies, and available results are controversial. Some have shown negative correlations of irisin levels with the burden of coronary atherosclerosis and leukocyte adhesion molecules' expression. Others have demonstrated associations between irisin levels and increased atherosclerosis risk and higher carotid intima-media thickness. Since the role of irisin in endothelial damage remains unclear, in this review, we compare, contrast, and integrate the current knowledge from preclinical and clinical studies to elucidate the potential preventive role and the underlying mechanisms and pathways of irisin in endothelial dysfunction. This review also comprises original figures to illustrate these mechanisms.
2.
Development and Differentiation in Monobodies Based on the Fibronectin Type 3 Domain.
Chandler, PG, Buckle, AM
Cells. 2020;(3)
Abstract
As a non-antibody scaffold, monobodies based on the fibronectin type III (FN3) domain overcome antibody size and complexity while maintaining analogous binding loops. However, antibodies and their derivatives remain the gold standard for the design of new therapeutics. In response, clinical-stage therapeutic proteins based on the FN3 domain are beginning to use native fibronectin function as a point of differentiation. The small and simple structure of monomeric monobodies confers increased tissue distribution and reduced half-life, whilst the absence of disulphide bonds improves stability in cytosolic environments. Where multi-specificity is challenging with an antibody format that is prone to mis-pairing between chains, multiple FN3 domains in the fibronectin assembly already interact with a large number of molecules. As such, multiple monobodies engineered for interaction with therapeutic targets are being combined in a similar beads-on-a-string assembly which improves both efficacy and pharmacokinetics. Furthermore, full length fibronectin is able to fold into multiple conformations as part of its natural function and a greater understanding of how mechanical forces allow for the transition between states will lead to advanced applications that truly differentiate the FN3 domain as a therapeutic scaffold.