Abstract
Characterized by the hardening of arteries, vascular calcification is the deposition of hydroxyapatite crystals in the arterial tissue. Calcification is now understood to be a cell-regulated process involving the phenotypic transition of vascular smooth muscle cells into osteoblast-like cells. There are various pathways of initiation and mechanisms behind vascular calcification, but this literature review highlights the wingless-related integration site (WNT) pathway, along with bone morphogenic proteins (BMPs) and mechanical strain. The process mirrors that of bone formation and remodeling, as an increase in mechanical stress causes osteogenesis. Observing the similarities between the two may aid in the development of a deeper understanding of calcification. Both are thought to be regulated by the WNT signaling cascade and bone morphogenetic protein signaling and can also be activated in response to stress. In a pro-calcific environment, integrins and cadherins of vascular smooth muscle cells respond to a mechanical stimulus, activating cellular signaling pathways, ultimately resulting in gene regulation that promotes calcification of the vascular extracellular matrix (ECM). The endothelium is also thought to contribute to vascular calcification via endothelial to mesenchymal transition, creating greater cell plasticity. Each of these factors contributes to calcification, leading to increased cardiovascular mortality in patients, especially those suffering from other conditions, such as diabetes and kidney failure. Developing a better understanding of the mechanisms behind calcification may lead to the development of a potential treatment in the future.
Highlights
Mechanical influence over tissue homeostasis is a predominant feature in bone formation and maintenance, acting as a promoter and regulator [1,2]
RUNX2 is expressed by wingless-related integration site (WNT) in VSMCs under high phosphate conditions and is a key component of osteogenic differentiation of mesenchymal stem cells alongside changes in the VSMC phenotype
Being a structural component that sees both heavy mechanical strain and periods of extended rest, perhaps the results found from the overloaded tendon cells can be extended to cardiovascular bone, and BMP2 and 4 were expressed heavily
Summary
Mechanical influence over tissue homeostasis is a predominant feature in bone formation and maintenance, acting as a promoter and regulator [1,2]. An ever-increasing prevalence of mineralization is being recognized, in vascular tissues. VSMCs are believed to undergo a phenotypic switch to osteoblast-like cellsD. The exact mechanism that initiates the phenotypic switch is unknown, but many studies research the mechanism behind the change to better understand calcification. KBiionenagsiene1eri(nCg K2012)0,, 7a,dxeFnOoRmPEaEtoRus polyposis coli (APC), and β-catenin, a transcriptional coactivat4oorfo24f WNT-targeted genes [33]. NThoef inthcereaWseNdTlepvaetlhs wofasycl[e3r9o]s.tiTnhaelsoinccorenatsriebdutleedvetlos aodf esccrleearsoestiinnbaolnsoe contributed to a decrease in bone mineral density, which is commonly found in patients with vascular calcification [38]. In the study performed mineral density, which is commonly found in patients with vascular calcification [38]. Whether being induced or inhibited, WNT results in either upregulation or downregulation of specific WNT-targeted genes
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