Repetitive coronary artery occlusions induce release of growth factors into the myocardial interstitium

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Repetitive coronary artery occlusions induce release of growth factors into the myocardial interstitium

Dorothee Weihrauch¹, John Tessmer², David C. Warltier², and William M. Chilian¹

¹ Department of Physiology and ² Department of Anesthesiology, Medical College of Wisconsin, Milwaukee, Wisconsin 53226-0509

Our objective was to delineate the temporal sequence of mitogenic activity in myocardial interstitial fluid (IF) during enhancementof collateral growth. Collateral development in chronically instrumenteddogs was induced by eight 2-min coronary occlusions/day for 21days. Collateralization was assessed by measurement of blood flowin the region distal to a total coronary occlusion. MyocardialIF was obtained periodically from an intramyocardial catheter,and mitogenic activity was assessed by proliferative responseof cultured endothelial cells (EC) and vascular smooth musclecells (VSMC) to the IF. Three experiments were conducted to testthat the mitogenic activity is induced by protein growth factors:1) protein digestion of the myocardial IF with Pronase-coupledlatex beads; 2) heat inactivation (boiling) of the IF; and 3)neutralization of the mitogenic activity with antibodies for basicfibroblast growth factor (bFGF) and vascular endothelial growthfactor (VEGF). Blood flow was reconstituted to baseline levelsduring occlusion after 3 wk of repetitive coronary occlusions.After initiation of occlusion the mitogenic activity of the myocardialIF on VSMC and EC increased up to days 12-14 and was reduced ondays 19-23. Pronase treatment and heat inactivation blocked themitogenic effect. Treatment with antibodies for bFGF and VEGFneutralized the proliferative response to the myocardial IF atspecific times. bFGF antibody inhibited the mitogenic effect significantlyon days 12-14. VEGF antibody neutralized the mitogenicity of themyocardial IF on day 7, days 12 and 13, and days 19 and 20 significantly.We conclude that myocardial IF harvested from ischemic myocardiumis highly mitogenic up to 2 wk after initiation of repetitivecoronary occlusions. After 3 wk of ischemia, the degree of mitogenicactivity for VSMC and EC was decreased from peak levels. The antibodiescould not neutralize the mitogenic effect of the myocardial IFduring this time period. These results suggest that mitogens areexpressed during various stages of collateral development in atime-dependent manner, that the mitogens are proteinaceous innature, and that bFGF and VEGF are released into the myocardialIF.

myocardial ischemia; coronary collateral circulation; angiogenesis

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