Decoction Prevents Vascular Dysfunction in Diabetes Via Inhibition of Endothelial Arginase 1

Overview

Journal Front Physiol

Date 2020 Apr 10

PMID 32269530

Citations 5

Authors

Hong Cheng

Tian Lu

Jingya Wang

Yucen Xia

Xiaoshu Chai

Minyi Zhang

Yutong Yao

Na Zhou

Sisi Zhou

Xinyi Chen

Weiwei Su

Cunzhi Liu

Wei Yi

Yongjun Chen

Lin Yao

Affiliations

Soon will be listed here.

Abstract

Hyperglycemia induces vascular endothelial dysfunction, which contributes to the development of vascular complication of diabetes. A classic prescription of traditional medicine, Decoction (HGWWD) has been used for the treatment of various cardiovascular and cerebrovascular diseases, which all are related with vascular pathology. The present study investigated the effect of HGWWD treatment in streptozocin (STZ)-induced vascular dysfunction in mouse models. studies were performed using wild type mice as well as arginase 1 knockout specific in endothelial cells (EC-A1) of control mice, diabetes mice and diabetes mice treated with HGWWD (60 g crude drugs/kg/d) for 2 weeks. For studies, aortic tissues were treated with mice serum containing HGWWD with or without adenoviral arginase 1 (Ad-A1) transduction in high glucose (HG) medium. We found that HGWWD treatment restored STZ-induced impaired mean velocity and pulsatility index of mouse left femoral arteries, aortic pulse wave velocity and vascular endothelial relaxation accompanied by elevated NO production in the aorta and plasma, as well as reduced endothelial arginase activity and aortic arginase 1 expression. The protective effect of HGWWD is reversed by an inhibitor of nitric oxide synthesis. Meanwhile, the preventive effect of serum containing HGWWD in endothelial vascular dysfunction is completely blocked by Ad-A1 transduction in HG incubated aortas. HGWWD treatment further improved endothelial vascular dysfunction in STZ induced EC-A1 mice. This study demonstrates that HGWWD improved STZ-induced vascular dysfunction through arginase 1 - NO signaling, specifically targeting endothelial arginase 1.

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