Inhibition of cyclooxygenase-2 causes a decrease in coronary flow in diabetic mice. The possible role of PGE2 and dysfunctional vasodilation mediated by prostacyclin receptor

Tomasz Przygodzki; Marcin Talar; Patrycja Przygodzka; Cezary Watala

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Inhibition of cyclooxygenase-2 causes a decrease in coronary flow in diabetic mice. The possible role of PGE2 and dysfunctional vasodilation mediated by prostacyclin receptor

Tomasz Przygodzki ^[1] ; Marcin Talar ^[1] ; Patrycja Przygodzka ^[1] ; Cezary Watala ^[1]
1. [1] Medical University of Lodz
  
  Medical University of Lodz
  
  Łódź, Polonia
Localización: Journal of physiology and biochemistry, ISSN-e 1877-8755, ISSN 1138-7548, Vol. 71, Nº. 3, 2015, págs. 351-358
Idioma: inglés
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Resumen
- Several lines of evidence suggest that cyclooxygenase-2 (COX-2) activity can have a beneficial role in the maintenance of vascular tone of the blood vessels in diabetes. Specifically, the increased production of prostacyclin (PGI2) and prostaglandin E2 (PGE2), mediated by COX-2, has been suggested to compensate for decreased synthesis of nitric oxide (NO). The study investigates whether inhibition of COX-2 may reduce the coronary flow in diabetic animals and may also lead to decreased synthesis of prostaglandins. Mice aged 18–20 weeks were used for the study: those with leptin receptor deficiency (db/db) served as a model of diabetes while heterozygous (db/+) mice served as controls. Coronary flow was measured by the Langendorff method, and prostaglandin synthesis by myocardia was assayed in heart perfusates. COX-2 inhibition was found to reduce basal coronary flow in db/db mice but had no effect in db/+ mice. Secretion of PGE2 was found to be higher in db/db mice, while prostacyclin synthesis did not differ. COX-2 inhibition decreased production of both prostaglandins to similar levels in both groups. The use of ONO-1301, a specific agonist for the prostacyclin receptor revealed that vasodilating responses mediated by the receptor were impaired in db/db mice. The expression levels of the receptor in cardiac tissue did not differ between the groups. It is concluded that the increased COX-2 contribution to vasodilation in diabetic animals appears to be partially a result of increased COX-2-dependent synthesis of PGE2 and also may be caused by impaired vasodilation mediated by the prostacyclin receptor.