Changes in insulin-receptor structure associated with trypsin-induced activation of the receptor tyrosine kinase

Abstract

The tyrosine kinase of the insulin receptor can be activated by trypsin treatment. The concomitant abolition of insulin binding has been postulated to result from proteolytic destruction of the receptor. A discrepancy between the decrease in insulin binding and receptor immunoreactivity after trypsin treatment led us to investigate more closely the structure of the trypsin-treated receptor. After trypsin treatment of the CHOT cell line, which over-expresses transfected human insulin receptors, insulin binding was significantly decreased, but reactivity with five alpha-subunit monoclonal antibodies was either unaffected or only moderately decreased, indicating that the alpha-subunit was substantially intact. Examination of receptor structure after trypsin treatment, receptor autophosphorylation and gel electrophoresis revealed a single band at 110 kDa in non-reduced gels, comprising a small fragment (21 kDa) of the alpha-subunit linked to the beta-subunit by class II disulphides. When the receptor was radio-labelled with 125I, two additional alpha-subunit bands of 142 kDa and 81 kDa (composed of identical reduced bands) were observed on non-reduced gels, which contained disulphide-linked (class I) fragments. All fragments could be precipitated by antibodies to both alpha- and beta-subunits. However, only antibodies directed towards the N-terminus of the receptor could immunoblot trypsin-treated fragments. Thus activation of the receptor tyrosine kinase by trypsin occurs after cleavage, but not loss of the alpha-subunit. This finding has implications for the mechanism of transmembrane activation of the receptor kinase by insulin.