Receptor binding and biological potency of several split forms (conversion intermediates) of human proinsulin. Studies in cultured IM-9 lymphocytes and in vivo and in vitro in rats

Abstract

The biological activities of several derivatives of human proinsulin (HPI) containing peptide bond cleavages or peptide deletions in the connecting peptide region were examined in vivo in rats and in several in vitro systems. The two derivatives which were tested in vivo, split (32-33)HPI and des-(64,65)HPI, both demonstrated greater potency in lowering blood glucose than did intact HPI. The receptor binding affinities of split (65-66)HPI, des-(57-65)HPI, des-(64,65)HPI, des-(33-56)HPI, des-(31,32)HPI, split (32-33)HPI, and split (56-57)HPI were examined in cultured IM-9 lymphocytes, freshly isolated rat adipocytes, and purified rat liver membranes and were compared to the binding of intact HPI and insulin. In these systems, HPI averaged approximately 1% of the activity of insulin. Modification of proinsulin in the connecting peptide region near the A-chain of insulin to form split (65-66)HPI, des-(57-65)HPI, des-(64,65)HPI, or des-(33-56)HPI resulted in an increase in affinity for receptor binding ranging from 11 to 27-fold over that of intact HPI. In contrast, modifications near the B-chain of insulin to form either des-(31,32)HPI or split (32-33)HPI resulted in roughly a 5-fold increase in affinity, whereas a cleavage within the connecting peptide to form split (56-57)HPI showed only a 2-fold increase in affinity as compared to intact HPI. The biological potencies of these materials were examined in isolated rat adipocytes. At high concentrations (10(-7) M), each derivative produced the same maximal response. At lower concentrations, differences in the relative potencies paralleled the differences in receptor binding affinity previously noted.