[Molecular mechanism of vascular calcification.]

Masahiko Kurabayashi
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引用次数: 8

Abstract

Intimal and medial calcification are increased with type 1 and type 2 diabetes, metabolic syndrome, chronic kidney disease, and ageing. There are several biological mechanisms through which vascular calcification increases all-cause mortality and atherosclerotic plaque rupture. Arterial medial calcification increases arterial stiffness that causes systolic hypertension and diastolic dysfunction and heart failure. In contrast, arterial intimal calcification is strongly associated with atherosclerotic plaque burden, predicting adverse arterial events. In particular, micro-calcifications within the fibrous caps are through to increase local stress and risk of plaque rupture. While vascular calcification has originally through to be a passive process, it has become increasingly clear that calcification of both intimal and medial layers is an active and tightly regulated process in which dynamic phenotypic changes of vascular smooth muscle cells plays a major role. Interestingly, the driving factors for medial and intimal calcification differ. Whilst uremia and senescence, high serum calcium and phosphate levels drives medial calcification, inflammation and oxidative stress are critical for intimal calcification. Despite the different drivers and environmental cues, the medial and intimal arterial calcification shares common intracellular signaling cascades to promoter cellular reprogramming and phenotypic switching. Recent studies employing new technologies demonstrate that calcifying extracellular vesicles(EVs)that have specific mineralization-promoting cargos such as tissue nonspecific alkaline phosphatase(TNAP), annexins Ⅱ and Ⅵ, are released from vascular smooth muscle, macrophages, and valvular interstitial cells, and serve as calcifying foci. Recent study identified a specific trafficking protein, sortilin, as a key player in the formation of calcifying EVs secreted by vascular smooth muscle cells. Research on aortic valve calcification using spatiotemporal multi-omics identified many secreted and structural matrix proteins not previously implicated in valvular calcification, and revealed that inflammation is likely to be a significant contributor regardless of the layers and stages of the aortic stenosis progression. Increased understanding of the precise molecular mechanisms of phenotypic switching of vascular smooth muscle offers the best chance to identify the potential drug targets for vascular calcification.

血管钙化的分子机制
随着1型和2型糖尿病、代谢综合征、慢性肾病和衰老,内膜和内侧钙化增加。血管钙化增加全因死亡率和动脉粥样硬化斑块破裂有几种生物学机制。动脉内侧钙化增加动脉僵硬,导致收缩期高血压、舒张功能障碍和心力衰竭。相反,动脉内膜钙化与动脉粥样硬化斑块负荷密切相关,可预测动脉不良事件。特别是纤维帽内的微钙化会增加局部应力和斑块破裂的风险。虽然血管钙化最初被认为是一个被动的过程,但越来越清楚的是,内膜和内层的钙化是一个主动的、受到严格调控的过程,其中血管平滑肌细胞的动态表型变化起着重要作用。有趣的是,内侧和内膜钙化的驱动因素不同。虽然尿毒症和衰老、高血清钙和磷酸盐水平驱动内侧钙化,但炎症和氧化应激对内膜钙化至关重要。尽管存在不同的驱动因素和环境因素,但内侧和内膜动脉钙化具有共同的细胞内信号级联,可促进细胞重编程和表型转换。最近采用新技术的研究表明,钙化细胞外囊泡(EVs)具有特异性的矿化促进物质,如组织非特异性碱性磷酸酶(TNAP)、膜联蛋白Ⅱ和Ⅵ,从血管平滑肌、巨噬细胞和瓣膜间质细胞中释放出来,并作为钙化灶。最近的研究发现,一种特殊的转运蛋白sortilin在血管平滑肌细胞分泌的钙化ev形成过程中起着关键作用。利用时空多组学对主动脉瓣钙化的研究发现了许多以前未涉及瓣膜钙化的分泌和结构基质蛋白,并揭示了炎症可能是主动脉瓣钙化的重要因素,无论主动脉瓣狭窄进展的层数和阶段如何。增加对血管平滑肌表型转换的精确分子机制的理解,为确定血管钙化的潜在药物靶点提供了最好的机会。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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