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运动训练可恢复肥胖 Zucker 大鼠心脏微小 RNA-16 水平,预防微血管稀疏。

Exercise Training Restores the Cardiac Microrna-16 Levels Preventing Microvascular Rarefaction in Obese Zucker Rats.

机构信息

Laboratory of Biochemistry and Molecular Biology of the Exercise, School of Physical Education and Sport, University of Sao Paulo, Sao Paulo, Brazil.

出版信息

Obes Facts. 2018;11(1):15-24. doi: 10.1159/000454835. Epub 2018 Feb 7.

DOI:10.1159/000454835
PMID:29402872
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5869535/
Abstract

OBJECTIVE

To evaluate the effects of aerobic exercise training (AET) on cardiac miRNA-16 levels and its target gene VEGF related to microvascular rarefaction in obese Zucker rats (OZR).

METHODS

OZR (n = 11) and lean (L; n = 10) male rats were assigned into 4 groups: OZR, trained OZR (OZRT), L and trained L (LT). Swimming exercise training lasted 60 min, 1×/day/10 weeks, with 4% body weight workload. Cardiac angiogenesis was assessed by histological analysis (periodic acid-Schiff) by calculating the capillary/fiber ratio. The protein expressions of VEGF, VEGFR2, and CD31 were evaluated by western blot. The expression of miRNA-16 was evaluated by real-time PCR.

RESULTS

Heart rate decreased in the trained groups compared to sedentary groups. The cardiac capillary/fiber ratio was reduced in OZR compared to L, LT and OZRT groups, indicating that aerobic exercise training (AET) was capable of reversing the microvascular rarefaction in the obese animals. miRNA-16 expression was increased in OZR compared to L, LT and OZRT. In contrast, its target, VEGF protein expression was 24% lower in OZR compared to L group, which has been normalized in OZRT group. VEGFR2 protein expression was increased in trained groups compared to their controls. CD31, a endothelial cells marker, showed increased expression in OZRT compared to OZR, indicating greater vascularization in OZRT group.

CONCLUSION

AET induced cardiac angiogenesis in obese animals. This revascularization is associated with a decrease in miRNA-16 expression permissive for increased VEGF protein expression, suggesting a mechanism for potential therapeutic application in vascular diseases.

摘要

目的

评估有氧运动训练(AET)对肥胖 Zucker 大鼠(OZR)心脏微小 RNA-16 水平及其与微血管稀疏相关的靶基因 VEGF 的影响。

方法

将 11 只 OZR(n = 11)和 10 只 lean(L;n = 10)雄性大鼠分为 4 组:OZR、训练的 OZR(OZRT)、L 和训练的 L(LT)。游泳运动训练持续 60 分钟,每天 1 次,持续 10 周,负荷为体重的 4%。通过计算毛细血管/纤维比,通过组织化学分析(过碘酸希夫)评估心脏血管生成。通过 Western blot 评估 VEGF、VEGFR2 和 CD31 的蛋白表达。通过实时 PCR 评估 miRNA-16 的表达。

结果

与安静组相比,训练组的心率降低。与 L、LT 和 OZRT 组相比,OZR 的心脏毛细血管/纤维比降低,表明有氧运动训练(AET)能够逆转肥胖动物的微血管稀疏。与 L、LT 和 OZRT 相比,OZR 中的 miRNA-16 表达增加。相比之下,其靶基因 VEGF 蛋白在 OZR 中的表达比 L 组低 24%,在 OZRT 组中已正常化。与对照组相比,训练组的 VEGFR2 蛋白表达增加。内皮细胞标志物 CD31 在 OZRT 中的表达高于 OZR,表明 OZRT 组的血管化程度更高。

结论

AET 诱导肥胖动物的心脏血管生成。这种血管生成与 miRNA-16 表达减少相关,后者允许增加 VEGF 蛋白表达,这表明该机制可能在血管疾病的潜在治疗应用中具有潜力。

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