RESUMEN
Recent studies on the glucagon antagonist des-His1-[Glu9]glucagon amide have resulted in pure inhibitors of the hormone, suggesting that the inhibitory properties may be centered around position 9. The present study was designed to investigate the chemical characteristics of substitutions in position 9 of glucagon that determine binding affinity and biological activity. Twenty replacement analogs of position 9 of glucagon were synthesized and assessed for their ability to bind to the glucagon receptor in rat hepatocyte membranes and to activate adenylate cyclase. Any substitution of aspartic acid 9 was accompanied by a severely diminished capacity to transmit the biological signal, while retaining receptor binding affinity. These results are an indication of an uncoupling of receptor binding and biological activity at this locus and define a central role of aspartic acid 9 in glucagon activity. Single replacement or deletion of either His1 or Asp9 in glucagon caused a 20- to 50-fold decrease in cyclase activity, whereas these same changes made in tandem caused virtually complete loss of activity, with decreases of 10(4)-to 10(6)-fold. These observations have led us to speculate that, at the molecular level, the region of glucagon required for transduction of the biological response may be distinct from the binding region and is mediated by a coupled interaction between His1 and Asp9 of the hormone and a complementary functional site of the glucagon receptor.