Proteolytic generation of constitutive tyrosine kinase activity of the human insulin receptor.

We measured rates of protein synthesis in vivo in subcellular fractions (soluble, myofibrillar and stromal fractions) of the heart and the gastrocnemius from rats after fasting or under hypoxic conditions (i.e. atmospheres containing 5% or 10% O2). Such interventions are known to inhibit protein synthesis under some circumstances. The recovery of tissue protein after fractionation was 80-100%. The proportions of protein present in the soluble and stromal fractions were different in the two muscles. The rates of protein synthesis in the myofibrillar and stromal fractions were less than those for total mixed tissue protein, whereas the rate for soluble protein was greater. Both fasting and moderate hypoxia (10% O2 for 24 h) inhibited protein synthesis in the gastrocnemius. In this tissue, the synthesis of the myofibrillar fraction was apparently the most sensitive to inhibition, and this resulted in some significant increases in the soluble-fraction/myofibrillar-fraction protein-synthesis rate ratios. In the heart, fasting inhibited protein synthesis, but moderate hypoxia (10% O2 for 24 h) did not. The rate of protein synthesis in the cardiac myofibrillar fraction was again more sensitive to fasting than were the rates in the other fractions, but it was not as sensitive as that in the gastrocnemius. Under severely hypoxic conditions (5% O2 for 1 or 2 h), protein synthesis was decreased in all fractions in both tissues. These results suggest that the rates of protein synthesis in these relatively crude subcellular fractions vary.     

Proteolytic processing of the insulin receptor beta subunit is associated with insulin-induced receptor down-regulation

This report describes the use of an antibody directed against the carboxyl terminus of the insulin receptor beta subunit to assess the fate of the insulin receptor protein over the time course of insulin-induced receptor down-regulation. The insulin receptor beta subunit is lost from the cellular membranes of insulin-treated 3T3-C2 fibroblasts with a time course superimposable with the insulin-induced loss of cellular insulin binding activity. Concomitant with the time-dependent loss of the intact beta subunit from the membranes, a 61,000-Da fragment of the insulin receptor beta subunit accumulates in the cytosol of the cells in a time-dependent manner. The insulin-induced loss of the intact beta subunit from the cellular membranes is inhibited by cycloheximide. Chloroquine and the thiol protease inhibitors leupeptin and E-64 inhibit the insulin-induced loss of the intact beta subunit from the membranes and induce an accumulation of the intact subunit in the membranes. However, in the presence of leupeptin, E-64, or chloroquine, the insulin-induced loss of insulin binding activity occurs normally. These data indicate that down-regulation results in the loss of the intact beta subunit from the cellular membranes with the production of a fragment of the beta subunit in the cytosol. The protease responsible for the generation of the fragment is a thiol protease which requires acidic conditions. Since the insulin-induced proteolysis of the beta subunit can be totally inhibited under conditions where the insulin-induced loss of insulin binding activity proceeds normally, the proteolysis of the beta subunit is a process which is separate and distinguishable from the insulin-induced loss of insulin binding activity.     

Intrinsic kinase activity of the insulin receptor

Since the identification of the insulin receptor by insulin-binding activity almost two decades ago, our understanding of the structure and function of the insulin receptor has progressed tremendously. The importance of the intrinsic tyrosine protein kinase activity of the insulin receptor is implied by the fact that the insulin receptor belongs to a family of receptor tyrosine kinases which play a role in growth control, by experiments demonstrating the intimate association of normal kinase activity and insulin action, and by evidence that the intrinsic kinase activity can be regulated under certain conditions. There are still some major gaps in our knowledge concerning the structure/function of the insulin receptor such as how activation of the intrinsic kinase activity of the receptor leads to altered cellular physiology. The kinase may phosphorylate endogenous substrates or autophosphorylation may simply alter beta subunit conformation so it can then interact with an effector system (i.e. a serine kinase) directly, or indirectly through a G-protein. The truth may lie somewhere between these two pathways.     

Proteolytic processing regulates receptor specificity and activity of VEGF-C.

The recently identified vascular endothelial growth factor C (VEGF-C) belongs to the platelet-derived growth factor (PDGF)/VEGF family of growth factors and is a ligand for the endothelial-specific receptor tyrosine kinases VEGFR-3 and VEGFR-2. The VEGF homology domain spans only about one-third of the cysteine-rich VEGF-C precursor. Here we have analysed the role of post-translational processing in VEGF-C secretion and function, as well as the structure of the mature VEGF-C. The stepwise proteolytic processing of VEGF-C generated several VEGF-C forms with increased activity towards VEGFR-3, but only the fully processed VEGF-C could activate VEGFR-2. Recombinant 'mature' VEGF-C made in yeast bound VEGFR-3 (K[D] = 135 pM) and VEGFR-2 (K[D] = 410 pM) and activated these receptors. Like VEGF, mature VEGF-C increased vascular permeability, as well as the migration and proliferation of endothelial cells. Unlike other members of the PDGF/VEGF family, mature VEGF-C formed mostly non-covalent homodimers. These data implicate proteolytic processing as a regulator of VEGF-C activity, and reveal novel structure-function relationships in the PDGF/VEGF family.     

Proteolytic activity in the genus ficus

The latices of only 13 of a total of 46 species of Ficus examined contained appreciable proteolytic activity. Therefore, high proteolytic activity in the latex is not a distinguishing feature of the genus. The latex of F. stenocarpa had the highest specific activity followed closely by the latices of F. carica and F. glabrata. Latices of 6 species of Ficus were examined by chromatography on CM-cellulose and compared with the results obtained for 9 varieties of F. carica. All of the latices were found to contain multiple proteolytic enzymes. Chromatographically, the multiple enzyme components of the several varieties of F. carica were more similar than those of the several species examined. The latices of 16 varieties of F. carica were all different as determined by free boundary electrophoresis although the specific proteolytic activity of the latices was reasonably constant.     

Proteolytic activity in the maize pollen wall

A new protease from maize ( Zea mays L.) pollen is described. It was purified using gel filtration, ion exchange and high performance liquid chromatography. SDS-PAGE and HPLC showed that the enzyme has a dimeric structure of M, ca 60,000. Inhibitor investigations indicated an aspartic acid residue in its active site. The optimum pH for maize pollen aspartic proteinase activity was 5.6, and the optimum temperature was 45°C. The enzyme is easily eluted from the pollen grains and, as confirmed by enzymoblotting after isoelectric focusing, it is located in the pollen wall. Similar to metallo-proteinases, its activity is inhibited by Zn₂₊. The pL value for purified aspartic proteinase, as estimated after IEF, was 5.0. Two-dimensional electrophoresis analysis of proteins eluted from maize pistils suggests that the enzyme digests the proteins and may be involved in pollen-tube germination. The properties of serine and aspartic proteinases from maize pollen are compared.     

Antiphosphotyrosine antibodies modulate insulin receptor kinase activity and insulin action

Insulin elicits the autophosphorylation of the beta-subunit of its receptor on tyrosine residues: this effect appears to be the earliest post-binding event involved in insulin action. In the present study we have raised highly specific antibodies to phosphotyrosine residues, and we have taken advantage of these antibodies to further evaluate the role of the insulin receptor tyrosine kinase in the generation of insulin's biological responses. Using a cell-free phosphorylation assay, we show here that these antibodies increase the tyrosine kinase activity of the receptor, and its phosphorylation on tyrosine residues. In contrast, the antibodies do not interfere with dephosphorylation of the insulin receptor. Introduction of the same antibodies in living Fao hepatoma cells enhances the effect of insulin on both glucose transport and aminoacid uptake. As a whole our data indicate that the insulin receptor kinase is involved in the generation of an early (glucose transport) and late (aminoacid uptake) response to insulin. Further, conformational changes in phosphotyrosine containing domains of the insulin receptor appear to modulate insulin's biological effects. Finally, the injection of antibodies in intact cells provides us with a novel and promising tool to search for cellular substrates for the insulin receptor tyrosine kinase.     

Tryptic activation of the insulin receptor. Proteolytic truncation of the alpha-subunit releases the beta-subunit from inhibitory control

Trypsin exerts insulin-like effects in intact cells and on partially purified preparations of insulin receptors. To elucidate the mechanism of these insulinomimetic effects, we compared the structures of insulin- and trypsin-activated receptor species with their functions, including insulin binding, autophosphorylation, and tyrosine kinase activity. In vitro treatment of wheat germ agglutinin-purified receptor preparations with trypsin resulted in proteolysis of both alpha- and beta-subunits. The activated form of the receptor had an apparent molecular mass of 110 kDa under nonreducing conditions, compared to the 400-kDa intact receptor, and was separated following reduction into an 85-kDa beta-subunit related fragment and a 25-kDa alpha-subunit related fragment. Treatment of whole cells with trypsin prior to isolation of the insulin receptor resulted in proteolytic modification of the alpha-subunit only. In this case, the total molecular mass of the activated species was 116 kDa, comprised of an intact 92-kDa beta-subunit and again a 25-kDa alpha-subunit related fragment. Values of Km for peptide substrate phosphorylation and Ki for inhibition of receptor autophosphorylation, and sites of autophosphorylation within the beta-subunits were similar for receptors activated either by insulin or trypsin. Insulin had no additional effect on the rate of autophosphorylation of the truncated receptor, and no binding of insulin by the truncated receptor was detected either by direct assay or cross-linking with bifunctional reagents. Based on the deduced amino acid sequence of the insulin receptor and the structural studies presented here we concluded that this activated form of the receptor resulted from tryptic cleavage at the dibasic site Arg576-Arg577. This was accompanied by loss of the insulin binding site and separation of alpha-beta heterodimers. As truncation of the alpha-subunit results in beta-subunit activation, it appears that the beta-subunit is a constitutively activated kinase and that the function of the alpha-subunit in the intact receptor is to inhibit the beta-subunit.     

Protein kinase activity of the insulin receptor from muscle

The insulin receptor is associated with a protein kinase activity. This has been shown for the receptor of liver, fat, and some other tissues which are not primary targets of insulin action. Here kinase activity is demonstrated for the insulin receptor of rat skeletal and cardiac muscle with similar characteristics. Insulin (10(-7) mol/l) stimulates phosphorylation of the 95-kDa receptor subunit 3- to 18-fold. The effect is detectable at 10(-10) mol/l insulin; the ED50 is approx. 3 X 10(-9) mol/l. The kinase phosphorylates exogenous substrate as well, and it is recovered after immunoprecipitation of the receptor with antireceptor antibody suggesting that kinase activity is intrinsic to the muscle receptor.     

Proteolytic activity of largomycin

Largomycin, an antibiotic and antitumor protein, purified from the culture broth of Streptomyces pluricolorescens, displayed specific proteolytic activity. Pure largomycin did not degrade a number of substrates commonly used for detection of aminopeptidase, endopeptidase and carboxypeptidase activity. Pure largomycin degraded angiotensin II, bradykinin, a few dipeptides and a number of proteins of KB cell plasma membranes. The biological activity and the proteolytic activity of largomycin showed similar temperature-dependent patterns, suggesting that one protein is responsible for both activities. The apoprotein of largomycin, which did not show antibiotic activity, contained the proteolytic activity.     

The tyrosine kinase activity of the chicken insulin receptor is similar to that of the human insulin receptor

The tyrosine kinase activity of a chimeric insulin receptor composed of the extracellular domain of the human insulin receptor (IR) and the intracellular domain of the chicken IR was compared with wild-type human IR. The degrees of autophosphorylation, phosphorylation of IRS-1, and in vitro phosphorylation of an exogenous substrate after stimulation by human insulin were similar to that seen with the human IR. We conclude that the insulin resistance of chickens is not attributable to a lower level of intrinsic tyrosine kinase activity of IR.     

Regulation of insulin receptor kinase activity by insulin mimickers and an insulin antagonist

Three agents which mimic insulin action in intact cells (concanavalin A, wheat germ agglutinin, and polyclonal insulin receptor antibody), mimicked insulin's ability to stimulate the kinase activity of purified insulin receptors. In contrast, monoclonal insulin receptor antibody, an antagonist of insulin action, did not stimulate the phosphorylation of the insulin receptor either in intact IM-9 cells or in purified receptor preparations. This antibody, however, antagonized the ability of insulin to stimulate the phosphorylation of the receptor both in intact cells and in the purified receptor. These studies with insulin mimickers and an insulin antagonist are consistent with a role for the kinase activity of the receptor mediating the actions of insulin.     

Various proteins modulate the kinase activity of the insulin receptor

Previous studies of the substrate specificity of the purified insulin receptor tyrosine kinase using synthetic random polymers have demonstrated that the receptor kinase phosphorylates poly (Glu, Tyr) 4:1 but not poly (Glu, Tyr) 1:1. In the present study, insulin treatment of Chinese hamster ovary cells overexpressing the human insulin receptor was found to stimulate the ability of their membrane extracts to phosphorylate poly (Glu, Tyr) 1:1. It was concluded that this activity was due to the receptor itself because: 1) it was precipitated with a monoclonal antibody to the receptor; 2) the addition of various membrane extracts to purified insulin receptor preparations stimulated the ability of these preparations to phosphorylate poly (Glu, Tyr) 1:1; and 3) certain purified proteins, including bovine serum albumin and casein, were also capable of stimulating the purified receptor to phosphorylate poly (Glu, Tyr) 1:1. The effect of albumin was dose-dependent; 0.5 and 10 mg/ml bovine serum albumin stimulated the phosphorylation of poly (Glu, Tyr) 1:1 by 2- and 230-fold, respectively. In contrast, albumin had no effect on the phosphorylation of poly (Glu, Tyr) 4:1. These results indicate that the activity of the insulin receptor kinase on certain substrates can be modulated by the presence of other proteins.     

Proteolytic degradation of insulin and glucagon.

The degradation of insulin and glucagon by a highly purified enzyme isolated from rat skeletal muscle was investigated. A sensitive assay for proteolytic degradation of insulin and glucagon using fluorescamine to detect an increase in primary amine groups was established. As measured by an increase in fluorescamine reactive materials, insulin was rapidly degraded by this highly purified enzyme without requiring initial disulfide cleavage. Associated with the increase in fluorescamine reactive materials was a decrease in immunoassayable insulinmglucagon wal also proteolytically degraded by this enzyme but a number of other peptides and proteins including proinsulin, and A and B chains of insulin were not degraded. Thus, we have demonstrated that insulin (and glucagon) can be proteolytically degraded by an enzyme isolated from an insulin sensitive tissue, skeletal muscle. Proteolytic degradation by this enzyme requires the intact insulin molecule rather than separate A and B chains.