外泌体调控血管钙化的研究进展

血管钙化是钙、磷等矿物质在血管壁的异常沉积,是一个主动的、活跃的、被高度调控的生物学过程,受到钙磷代谢紊乱、氧化应激、机械应力和炎症等多种因素的影响.作为胞间通讯的重要载体,外泌体已被证实与血管钙化的发生密切相关.一方面,外泌体可以通过在细胞间传递蛋白质、microRNAs等信息,促进血管平滑肌细胞发生成骨样表型转化以及矿物质沉积;另一方面,外泌体还可以诱导血管内皮细胞发生内皮-间充质转化,进而调控血管钙化的进程.但是,外泌体在内皮细胞和平滑肌细胞参与血管钙化进程中的具体作用及机制目前尚不完全清楚.本文就外泌体在调节平滑肌细胞的成骨样表型转化、矿物质沉积、microRNA转运以及内皮细胞的内皮-间充质转化中的作用进行了综述,以期为血管钙化的防治提供新思路.     

内皮间质转化的信号机制

内皮间质转化是上皮间质转化的一种,是新近发现的一种细胞转化类型,和上皮间质转化一样也参与体内各种病理生理过程.已经证实,在转化过程中内皮细胞首先发生细胞与细胞脱联系过程,失去内皮细胞特异性标志物CD31和VE-钙粘蛋白,获得间质细胞特异性标志物α-SMA和FSP1,由原来的鹅卵石样结构转变为细长梭形结构,同时其迁移力和侵袭力明显增强.早期研究显示内皮间质转化在胚胎期心内膜的发育中发挥了十分关键的作用.近些年来,人们逐渐认识到内皮间质转化也参与各种疾病的发生发展,包括心、肺、肾等重要器官纤维化、特发性门脉高压、动脉粥样硬化、肺动脉高压以及肿瘤等.转化生长因子-β、Notch信号、Wnt信号以及MicroRNAs等参与对内皮间质转化的调节,然而,其具体机制尚未完全明确.通过探索内皮间质转化过程中重要信号通路及各因子的作用机制,可能为多种疾病的预防和治疗提供新的指导意见.     

内皮细胞向间充质细胞的转分化

内皮细胞向间充质细胞转分化(endothelial-to-mesenchymal transition,EndMT)过程中,内皮从内皮层分离,获得间充质细胞表型,其特征是细胞连接能力下降,内皮标志物减少,获得间充质细胞标志物,并具有扩散和迁移特性。在受损组织中,内皮细胞能够通过EndMT转分化为成纤维细胞,因此具有EndMT特性的内皮细胞在组织重构和纤维化中发挥重要作用。EndMT不仅参与心脏发育这一重要过程也参与许多病理性疾病如癌症,心脏的纤维化和肺动脉高压等。所以,靶向EndMT对多种疾病具有潜在的治疗意义。     

ALK2使内皮细胞转化为类干细胞的机制

内皮细胞向间充质细胞转分化（endothelial-to-mesenchymal transition,EndMT）过程是血管内皮细胞转化为类干细胞的基础,持续激活状态的ALK2在EndMT过程起到关键的促进作用,EndMT发生后内皮细胞能获得类干细胞的表现型.TGF-β2和BMP4作为特异性配体激活ALK2,下调某些内皮细胞标志物并上调某些间质细胞标志物,促进EndMT过程.此外,编码ALK2的基因序列在206号氨基酸上突变形成R206H ALK2后作用类似持续激活状态ALK2,同样也能达到促进内皮细胞向间充质细胞转分化的目的.     

内皮抑素研究进展

新生血管的生成 (Angiogenesis)与多种生理过程相关 ,受多种促进和抑制因子的调节 ,细胞外基质蛋白经酶解产生的小片段中很多都参与了这一过程的调节。内皮抑素 (Endostatin)是 1997年首先从小鼠血管内皮瘤EOMA细胞培养上清中发现的 ,是细胞外基质蛋白胶原XVⅢα1链NC1结构域C末端 184个Aa的片段。可抑制bFGF和VEGF刺激的血管内皮细胞的增殖和迁移 ,抑制新生血管的形成 ,抑制肿瘤的形成和转移。由于其作用对象是血管内皮细胞 ,而不是转化的肿瘤细胞本身 ,长期反复治疗中不会引起耐药性。它在肿瘤治疗中的应用前景引起多方关注 ,相关研究广泛开展起来。本文综述了近几年在其生物功能、作用机理及应用等方面的研究进展     

沉默PPP3CA对后肾间充质细胞MET转化、凋亡、增殖及迁移的影响

肾脏是人体重要器官,肾脏发育对肾脏的形成和功能至关重要,其中后肾间充质细胞 (Metanephric mesenchyme,MM) 间质-上皮转化 (Mesenchymal-epithelial transition,MET) 是肾单位形成的关键环节。qRT-PCR和Western blotting实验检测蛋白质磷酸酶3催化亚基α (Protein phosphatase 3 catalytic subunit alpha,PPP3CA) 在不同状态MM细胞株mK3、mK4中的表达谱及对MET标志蛋白调控作用;采用慢病毒包装方式构建稳定敲低PPP3CA的mK4细胞株;采用CCK-8、EdU实验、细胞划痕实验、流式细胞技术分别检测PPP3CA对上皮样后肾间充质细胞株mK4细胞生长、迁移、凋亡的调控作用。PPP3CA在mK4细胞中表达量较间质样后肾间充质细胞mK3更高,敲低PPP3CA后,检测MET标志物及细胞生物学行为,结果显示敲低PPP3CA显著上调上皮细胞标志物E-cadherin表达,促进MET过程,且促进细胞凋亡,抑制细胞增殖和迁移。此外,敲低PPP3CA促进ERK1/2磷酸化,提示PPP3CA生物学功能的调控机制可能与其去磷酸化ERK1/2蛋白相关。以上结果提示PPP3CA在MM细胞MET转化和生物学行为调节中发挥重要功能,为发现和解析肾发育过程中潜在的关键调节因子提供了新的理论基础。     

心肌-内皮信号途径在心脏发育中的作用

内皮细胞对于调节和维持心脏发育起着十分重要的作用.随着基因功能研究技术的发展,已有越来越多的资料表明内皮 心肌细胞相互作用对于心脏生长和发育是必须的.目前已经发现包括神经调节蛋白、血管紧张素、NO、TGF β、内皮素等在内的很多细胞信号途径均参与了此过程.就在心脏发育过程中心肌 内皮细胞相互作用的重要信号途径作一综述.     

基质金属蛋白酶在心肌缺血再灌注损伤中的作用

肌缺血再灌注损伤是指缺血心肌组织在恢复血流供给后,其细胞代谢功能障碍及结构破坏反而加重的现象,主要表现在心肌收缩与舒张功能障碍、血管内皮功能障碍、微循环血流紊乱、细胞代谢失调、电解质平衡紊乱、细胞凋亡与坏死等,并伴随着氧自由基的大量产生和毒性损伤以及炎症反应的激活,是一个极其复杂的病理过程。基质金属蛋白酶(MMPs)及其组织抑制物(TIMPs)是心肌组织中多种细胞分泌的内源性细胞因子,其作用涵盖了细胞外基质降解、炎症反应激活、调节血管功能、影响细胞凋亡与存活等众多病理生理过程,而这些过程均在心肌缺血再灌注损伤中发挥着重要的作用。     

基质金属蛋白酶在心肌缺血再灌注损伤中的作用

肌缺血再灌注损伤是指缺血心肌组织在恢复血流供给后,其细胞代谢功能障碍及结构破坏反而加重的现象,主要表现在心肌收缩与舒张功能障碍、血管内皮功能障碍、微循环血流紊乱、细胞代谢失调、电解质平衡紊乱、细胞凋亡与坏死等,并伴随着氧自由基的大量产生和毒性损伤以及炎症反应的激活,是一个极其复杂的病理过程。基质金属蛋白酶（MMPs）及其组织抑制物（TIMPs）是心肌组织中多种细胞分泌的内源性细胞因子,其作用涵盖了细胞外基质降解、炎症反应激活、调节血管功能、影响细胞凋亡与存活等众多病理生理过程,而这些过程均在心肌缺血再灌注损伤中发挥着重要的作用。     

内皮特异性miR-342-5p敲除致小鼠内皮损伤和心血管功能紊乱

摘要 目的：我们前期研究发现有氧运动促进内皮细胞等分泌miR-342-5p,miR-342-5p通过外泌体富集至心肌细胞后发挥心脏保护作用。本研究的主要目的是明确内皮来源的miR-342-5p在心血管功能调控中的作用。方法：我们构建了内皮特异性miR-342-5p敲除小鼠,通过心脏超声检测和血管收缩舒张功能检测观察了该小鼠心血管功能的变化;培养血管内皮细胞,通过对细胞存活率检测、相关蛋白的表达检测等方法对miR-342-5p发挥心血管保护作用的机制进行探究。结果：内皮miR-342-5p敲除致小鼠运动能力降低、心脏收缩功能不变,但舒张功能紊乱。且内皮miR-342-5p敲除致小鼠血管口径变小、微血管密度降低和血管内皮功能紊乱。内皮miR-342-5p敲除致小鼠心血管功能紊乱的机制与其引起的内皮细胞损伤有关。敲低miR-342-5p致内皮细胞中caspase 9水平增加,引起内皮细胞活性降低和凋亡增加。结论：这些结果进一步证实了内皮细胞来源的miR-342-5p在心血管功能中的重要作用,提示miR-342-5p在防治心血管疾病中的潜在应用。     

EndMT: A promising and controversial field

The endothelial to mesenchymal transition (EndMT) is the process by which endothelial cells lose a portion of their cellular features and obtain certain characteristics of mesenchymal cells, including loss of tight junctions, increased motility, and increased secretion of extracellular matrix proteins. EndMT is involved in cardiac development and a variety of diseases processes, such as vascular or tissue fibrosis and tumor. However, its role in specific diseases remains under debate. This review summarizes EndMT-related diseases, existing controversies, different types of EndMT, and molecules and signaling pathways associated with the process.     

miR-222 inhibits cardiac fibrosis in diabetic mice heart via regulating Wnt/β-catenin-mediated endothelium to mesenchymal transition

miR-222 participates in many cardiovascular diseases, but its effect on cardiac remodeling induced by diabetes is unclear. This study evaluated the functional role of miR-222 in cardiac fibrosis in diabetic mice. Streptozotocin (STZ) was used to establish a type 1 diabetic mouse model. After 10 weeks of STZ injection, mice were intravenously injected with Ad-miR-222 to induce the overexpression of miR-222. miR-222 overexpression reduced cardiac fibrosis and improved cardiac function in diabetic mice. Mechanistically, miR-222 inhibited the endothelium to mesenchymal transition (EndMT) in diabetic mouse hearts. Mouse heart fibroblasts and endothelial cells were isolated and cultured with high glucose (HG). An miR-222 mimic did not affect HG-induced fibroblast activation and function but did suppress the HG-induced EndMT process. The antagonism of miR-222 by antagomir inhibited HG-induced EndMT. miR-222 regulated the promoter region of β-catenin, thus negatively regulating the Wnt/β-catenin pathway, which was confirmed by β-catenin siRNA. Taken together, our results indicated that miR-222 inhibited cardiac fibrosis in diabetic mice via negatively regulating Wnt/β-catenin-mediated EndMT.     

The role of endothelial-mesenchymal transition in development and pathological process

Epithelial-mesenchymal transition is an important developmental process, participates in tumor's formation, invasion, and metastasis and has been extensively studied. Recently, endothelial-mesenchymal transition (EndMT), a newly recognized type of cellular transdifferentiation, has been demonstrated to participate in a number of diseases by causing morphology changes and pathological processes. Previous studies showed that EndMT was a critical process of embryonic cardiac development. Not only that recent advances also suggested that EndMT occurred postnatally in cancer and cardiac fibrosis and emerged as a possible source of cancer-associated fibroblasts (CAFs). CAFs were found to acquire properties that promoted tumor development and metastasis formation. Resident endothelial cells undergoing EndMT lose their endothelial markers, acquire a mesenchymal or myofibroblastic phenotype, express mesenchymal cell products such as α-smooth muscle actin and type I collagen and develop invasive and migratory abilities. EndMT-derived cells are believed to function as fibroblasts in damaged tissue and may therefore have an important role in pathological process. However, little is known about the signaling mechanisms that cause endothelial cells to transform into mesenchymal cells. Transforming growth factor-β, Notch, or other signaling pathways could direct or interact to mediate EndMT. Therefore, to explore the signaling mechanisms of EndMT may provide novel therapeutic strategies for treating cancer. ? 2012 IUBMB IUBMB Life, 64(9): 717-723, 2012.     

Inhibition of prostaglandin E2 receptor 4 by lnc000908 to promote the endothelial‐mesenchymal transition participation in cardiac remodelling

Long non‐coding RNAs (lncRNAs) have emerged as potent regulators of cardiac disease; however, the role of lncRNA in cardiac fibrosis remains partially understood. In this study, we identified a cardiac endothelial‐enriched lncRNA‐lnc000908, which was markedly up‐regulated in rats with cardiac fibrosis. In addition, the expression of prostaglandin E2 receptor 4 (EP4) was decreased in cardiac fibrosis. In vivo lnc000908 silencing by lentivirus increased the EP4 level, decreased endothelial‐mesenchymal transition (EndMT) and improved cardiac fibrosis and cardiac function. Consistently, the lnc000908 knockdown also up‐regulated EP4 and suppressed transforming growth factor‐beta (TGF‐β)‐induced EndMT in cardiac microvascular endothelial cells. In contrast, the lnc000908 overexpression by lentivirus decreased the EP4 level and induced EndMT. Of note, these pro‐ or anti‐EndMT effects were reversed by the EP4 overexpression or the EP4 antagonist AH‐23848, respectively. This study demonstrates that lnc000908 is a novel regulator of cardiac fibrosis by modulating the EP4 expression and EndMT.     

Knockout RAGE alleviates cardiac fibrosis through repressing endothelial-to-mesenchymal transition (EndMT) mediated by autophagy

Endothelial-to-mesenchymal transition (EndMT) has been shown to contribute to cardiac fibrosis and heart failure (HF). Recent studies have demonstrated that EndMT is regulated by autophagy, and we previously showed suppression of excessive autophagy and alleviation of cardiac fibrosis in HF mice with inactivated receptor for advanced glycation end products (RAGE). Thus, we investigated whether reduced cardiac fibrosis due to RAGE knockout occurred by inhibiting EndMT mediated by excessive autophagy. We found a decrease in endothelial cells (CD31⁺/VE-Cadherin⁺) and an increase in cells co-expressing CD31 and α-smooth muscle actin (α-SMA, myofibroblast marker) at 8 weeks in heart tissue of mice subjected to transverse aortic constriction (TAC), which implied EndMT. Knockout RAGE decreased EndMT accompanied by decreased expression of autophagy-related proteins (LC3BII/I and Beclin 1), and alleviated cardiac fibrosis and improved cardiac function in TAC mice. Moreover, 3-methyladenine (3-MA) and chloroquine (CQ), inhibitors of autophagy, attenuated EndMT, and cardiac fibrosis in TAC mice. Importantly, EndMT induced by AGEs could be blocked by autophagy inhibitor in vivo and in vitro. These results suggested that AGEs/RAGE-autophagy-EndMT axis involved in the development of cardiac fibrosis and knockout RAGE ameliorated cardiac fibrosis through decreasing EndMT regulated by autophagy, which could be a promising therapeutic strategy for HF.Subject terms: Heart failure, Experimental models of disease