Coronary flow-induced inotropism is modulated by binding of dextrans to the endothelial luminal surface

doi:10.1152/ajpheart.00323.2002

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Am J Physiol Heart Circ Physiol 284: H1348-H1357, 2003. First published January 2, 2003; doi:10.1152/ajpheart.00323.2002
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Vol. 284, Issue 4, H1348-H1357, April 2003

Coronary flow-induced inotropism is modulated by binding of dextrans to the endothelial luminal surface

Carmen Gonzalez-Castillo¹, Rafael Rubio¹, and Tania Zenteno-Savin²

¹ Facultad de Medicina, Departomento de Fisiologia y Farmacologia, Universidad Autonona de San Luis Potosi, San Luis Potosi, San Luis Potosi CP 78210; and ² Centro de Investigaciones Biologicas del Noroeste, La Paz, Baja California Sur, 23090 Mexico

In isolated perfused guinea pig hearts, coronary flow causes a positive inotropic effect [positive coronary flow-induced effect(+CFIE)] that could be altered by dextrans (Dx) in the coronaryperfusion solution. To test this possibility, Dx of 20, 40, 70,and 500 kDa were infused and found to modulate +CFIE; however,when Dx infusion was terminated, the effect persisted, i.e., wasirreversible/nonwashable, suggesting that Dx may bind to luminalendothelial lectinic structures. This hypothesis was tested whenDx [with fluorescent traces (D*)] bound to the vessel wall washydrolyzed by dextranase infusion and washout of D* fragmentscompletely reverted the +CFIE, and it was found that bound D*to be displaced by free Dx required concentrations 50-100 timesthat used during binding. In addition, dose-response curves forDx on +CFIE show that the higher the Dx molecular mass, the lesserthe concentration required to have an effect. Because a largeDx molecule has a greater number polymeric glucose branches, itcan bind to a larger number of endothelial lectinic sites, requiringa lower concentration to affect +CFIE. Our results suggest thatluminal endothelial lectinic structures are part of the flow-sensingassembly.

shearing stress; protein polymerization; steady state; irreversibility; endothelial glycocalyx; endothelial lectins; dextranase; albumin; interstitial volume

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