Song Erfei, Fan Pengcheng, Huang Bosheng, Deng Han-Bing, Cheung Bernard Man Yung, Félétou Michel, Vilaine Jean-Paul, Villeneuve Nicole, Xu Aimin, Vanhoutte Paul M, Wang Yu
State Key Laboratory of Pharmaceutical Biotechnology, The University of Hong Kong, Hong Kong SAR, China.
J Am Heart Assoc. 2014 Apr 10;3(2):e000837. doi: 10.1161/JAHA.114.000837.
Lipocalin-2 is a proinflammatory adipokine upregulated in obese humans and animals. A pathogenic role of lipocalin-2 in hypertension has been suggested. Mice lacking lipocalin-2 are protected from dietary obesity-induced cardiovascular dysfunctions. Administration of lipocalin-2 causes abnormal vasodilator responses in mice on a high-fat diet (HFD).
Wild-type and lipocalin-2 knockout mice were fed with standard chow or HFD. Immunoassays were performed for evaluating the circulating and tissue contents of lipocalin-2. The relaxation and contraction of arteries were studied using a wire myograph. Blood pressure was monitored with implantable radio telemetry. Dietary obesity promoted the accumulation of lipocalin-2 protein in blood and arteries. Deficiency of this adipokine protected mice from dietary obesity-induced elevation of blood pressure. Mass spectrometry analysis revealed that human and murine lipocalin-2 were modified by polyamination. Polyaminated lipocalin-2 was rapidly cleared from the circulation. Adipose tissue was a major site for lipocalin-2 deamidation. The circulating levels and the arterial accumulation of deamidated lipocalin-2 were significantly enhanced by treatment with linoleic acid (18:2n-6), which bound to lipocalin-2 with high affinity and prevented its interactions with matrix metalloproteinase 9 (MMP9). Combined administration of linoleic acid with lipocalin-2 caused vascular inflammation and endothelial dysfunction and raised the blood pressure of mice receiving standard chow. A human lipocalin-2 mutant with cysteine 87 replaced by alanine (C87A) contained less polyamines and exhibited a reduced capacity to form heterodimeric complexes with MMP9. After treatment, C87A remained in the circulation for a prolonged period of time and evoked endothelial dysfunction in the absence of linoleic acid.
Polyamination facilitates the clearance of lipocalin-2, whereas the accumulation of deamidated lipocalin-2 in arteries causes vascular inflammation, endothelial dysfunction, and hypertension.
脂质运载蛋白-2是一种促炎脂肪因子,在肥胖的人类和动物中表达上调。脂质运载蛋白-2在高血压中的致病作用已被提出。缺乏脂质运载蛋白-2的小鼠可免受饮食性肥胖诱导的心血管功能障碍影响。给予脂质运载蛋白-2会导致高脂饮食(HFD)小鼠出现异常的血管舒张反应。
野生型和脂质运载蛋白-2基因敲除小鼠分别喂食标准饲料或高脂饮食。进行免疫测定以评估脂质运载蛋白-2的循环和组织含量。使用线肌张力测定仪研究动脉的舒张和收缩。用植入式无线电遥测技术监测血压。饮食性肥胖促进了脂质运载蛋白-2蛋白在血液和动脉中的积累。这种脂肪因子的缺乏保护小鼠免受饮食性肥胖诱导的血压升高。质谱分析表明,人和小鼠的脂质运载蛋白-2都发生了多胺化修饰。多胺化的脂质运载蛋白-2可迅速从循环中清除。脂肪组织是脂质运载蛋白-2脱酰胺的主要部位。用亚油酸(18:2n-6)处理可显著提高脱酰胺脂质运载蛋白-2的循环水平和动脉蓄积,亚油酸与脂质运载蛋白-2具有高亲和力结合,并阻止其与基质金属蛋白酶9(MMP9)相互作用。亚油酸与脂质运载蛋白-2联合给药会引起血管炎症和内皮功能障碍,并升高喂食标准饲料小鼠的血压。一种将半胱氨酸87替换为丙氨酸(C87A)的人脂质运载蛋白-2突变体含有的多胺较少,与MMP9形成异二聚体复合物的能力降低。处理后,C87A在循环中保留的时间延长,并在没有亚油酸的情况下诱发内皮功能障碍。
多胺化促进脂质运载蛋白-2的清除,而脱酰胺脂质运载蛋白-2在动脉中的蓄积会导致血管炎症、内皮功能障碍和高血压。
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