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脂肪因子 Chemerin 源自 PVAT 可增强电场刺激引起的动脉收缩:Chemerin 基因敲除大鼠的应用。

Endogenous Chemerin from PVAT Amplifies Electrical Field-Stimulated Arterial Contraction: Use of the Chemerin Knockout Rat.

机构信息

Department of Pharmacology and Toxicology, Michigan State University, 1355 Bogue Street Rm B445, East Lansing, MI 48824, USA.

出版信息

Int J Mol Sci. 2020 Sep 2;21(17):6392. doi: 10.3390/ijms21176392.

DOI:10.3390/ijms21176392
PMID:32887510
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7503709/
Abstract

We previously reported that the adipokine chemerin, when added exogenously to the isolated rat mesenteric artery, amplified electrical field-stimulated (EFS) contraction. The Chemerin1 antagonist CCX832 alone inhibited EFS-induced contraction in tissues with but not without perivascular adipose tissue (PVAT). These data suggested indirectly that chemerin itself, presumably from the PVAT, facilitated EFS-induced contraction. We created the chemerin KO rat and now test the focused hypothesis that endogenous chemerin amplifies EFS-induced arterial contraction. The superior mesenteric artery +PVAT from global chemerin WT and KO female rats, with endothelium and sympathetic nerve intact, were mounted into isolated tissue baths for isometric and EFS-induced contraction. CCX832 reduced EFS (2-20 Hz)-induced contraction in tissues from the WT but not KO rats. Consistent with this finding, the magnitude of EFS-induced contraction was lower in the tissues from the KO vs. WT rats, yet the maximum response to the adrenergic stimulus PE was not different among all tissues. These studies support that endogenous chemerin modifies sympathetic nerve-mediated contraction through Chemerin1, an important finding relative in understanding chemerin's role in control of blood pressure.

摘要

我们之前曾报道过,脂肪因子趋化素(chemerin)在体外加入到分离的大鼠肠系膜动脉中时,会放大电刺激(EFS)引起的收缩。趋化素 1 拮抗剂 CCX832 单独抑制有血管周围脂肪组织(PVAT)存在或不存在时 EFS 诱导的收缩。这些数据间接表明,chemerin 本身(可能来自 PVAT)促进了 EFS 诱导的收缩。我们创建了 chemerin KO 大鼠,现在检验一个聚焦假说,即内源性 chemerin 放大 EFS 诱导的动脉收缩。从全球 chemerin WT 和 KO 雌性大鼠的肠系膜上动脉+PVAT 中,保留内皮和交感神经,将其安装到分离的组织浴槽中进行等长和 EFS 诱导的收缩。CCX832 降低了 WT 大鼠组织中 EFS(2-20 Hz)诱导的收缩,但对 KO 大鼠组织中的收缩没有影响。与这一发现一致的是,KO 大鼠组织中 EFS 诱导的收缩幅度低于 WT 大鼠组织,但所有组织对肾上腺素刺激 PE 的最大反应没有差异。这些研究支持内源性 chemerin 通过 Chemerin1 调节交感神经介导的收缩,这一发现对于理解 chemerin 在血压控制中的作用非常重要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/18dc/7503709/dd68e8735a4c/ijms-21-06392-g001.jpg

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