Anomalous insulin-binding activity in the bovine neural retina: a possible mechanism for regulation of receptor binding specificity.

Crude membrane from the bovine neural retina contains one IGF-I and two insulin binding sites. Although both insulin binding sites have a high affinity for insulin (IC50 = 0.1 and 7.0 nM), only one exhibits "classical" specificity and binds insulin with higher affinity than IGF-I. The second insulin binding site is "non-classical" in that it has an equal affinity for IGF-I and insulin. Retinal IGF-I binding exceeds insulin binding by a factor of 10-20. Despite this high level of IGF-I binding it is unlikely that non-classical insulin binding represents insulin binding to an IGF-I receptor because 1) anomalous binding is 30 times greater than that predicted from cross-specificity, 2) low concentrations of unlabeled IGF-I increase IGF-I binding to the IGF-I binding site but do not increase IGF-I binding to the non-classical insulin binding site and 3) the IGF-I receptor's affinity for insulin (and IGF-I) increases greatly during receptor purification. In contrast, the insulin affinity of the non-classical insulin binding site is largely unaffected by this process. Although receptor solubilization and purification had no effect on the insulin receptor's affinity for insulin, it did markedly increase this site's affinity for IGF-I. Thus, the major proportion of purified retinal "insulin receptors" have a higher affinity for IGF-I than insulin. The evidence presented here is consistent with the view that the bovine retina contains one IGF-I and two insulin binding sites and that a detergent-sensitive factor regulates IGF-I affinity of both classes of binding sites.