The in vitro synthesized and processed human insulin receptor precursor binds insulin.

The cell-free examination of the human insulin receptor during biogenesis may provide a greater understanding of the elements that contribute to the acquisition of receptor function. The insulin receptor precursor components were produced in a cell-free system and the insulin binding ability of the [35S]methionine-labeled translation products was determined. The processed proreceptor represented by a 190 kDa band was retained on insulin-linked biotin-streptavidin agarose or an insulin column. The insulin binding 190 kDa band migrated slower than the non-binding 190 kDa band on SDS-PAGE which suggests that covalent modifications account for these differences. The trypsin-digested product of the 190 kDa proreceptor was also retained on insulin-linked biotin-streptavidin agarose, however the alpha-subunit precursor was retained on insulin agarose to a much lesser degree. We conclude that a significant fraction of the processed, in vitro translated insulin proreceptor acquires insulin binding ability.     

Ontogeny of insulin binding during chick skeletal myogenesis in vitro.

Our studies show that insulin receptors exist on chicken skeletal muscle cells at all developmental stages in culture. ¹²⁵I-labeled insulin binding at physiological concentrations to mature myotubes demonstrated saturability, binding proportional to cell number, reversibility, and specificity by competition with native hormone which reduced specific binding by 40% with 1 ng/ml and was maximal with 10 μg/ml. Further evidence for specificity was shown by no competition of insulin specific binding with insulin A chain, insulin B chain, growth hormone, and thyrotropin. Two binding sites were detected, with affinity constants of 10¹⁰M^?1 and 2 × 10⁹M^?1. The hormone receptor complex showed rapid dissociation (70% in 30 min) after equilibrium binding. During myogenesis, an increase in insulin receptors occurs from 500 per proliferating myoblast to 3000 per cell equivalent in mature (6 day) myotubes. Since these studies demonstrate that insulin receptors are present and other studies have shown that insulin is present during most of chicken embryogenesis, insulin may regulate muscle development in vivo to a greater degree than previously suspected.     

Effect of insulin on low-density-lipoprotein metabolism in human lymphocytes in vitro.

The metabolism of low-density lipoproteins (LDL) in vitro in the presence of insulin was studied in freshly isolated human peripheral-blood lymphocytes. Insulin appeared to decrease the binding affinity of 125I-LDL to its cell-surface receptor, without any change in apparent Vmax or in the number of LDL receptors. As a consequence, the absolute amounts of 125I-LDL internalized and degraded were lower in the presence of insulin than in its abscence, although the fraction of internalized 125I-LDL degraded in either instance was quite similar. 3-Hydroxy-3-methylglutaryl-CoA reductase activity, and hence cholesterol synthesis, were stimulated by insulin. This effect of insulin was independent of the inhibitory effect of LDL on cholesterol synthesis. At the same time, acid cholesterol esterase and acyl-CoA: cholesterol O-acetyltransferase activities were lower in cells incubated with insulin than in controls. The net effect of these metabolic alterations seems to be that cells accumulate greater quantities of free and esterified cholesterol when treated with insulin.     

Effects of insulin in vitro on protein turnover in rat epitrochlearis muscle.

The hexapeptide Arg-Asn-Gly-epoxyethylglycine-Ala-Val-OMe specifically inactivates membrane-bound N-glycosyltransferases. The specificity is demonstrated by the inability of peptides containing 2,3-epoxypropyl-, allyl- and vinyl-glycine in the epoxyethylglycine position to function as inhibitors. The inhibition is concentration-dependent and follows first-order kinetics, but requires disruption of the membrane vesicles by detergents to achieve accessibility to the transferase. The enzyme can be protected partially against inactivation by the addition of the acceptor peptide Arg-Asn-Gly-Thr-Ala-Val-OMe, pointing to an active-site-directed reaction. Exhaustion of the endogenous pool of glycosyl donor molecules by preincubation of the membrane vesicles with the acceptor peptide before inhibitor application is accompanied by an additional decrease in the inhibition rate. This suggests that inactivation occurs only under conditions where glycosyl transfer is catalysed. A mechanism of inactivation is proposed in which the transferase catalyses its own inactivation by a kind of 'suicide' mechanism.     

In vitro folding/unfolding of insulin/single-chain insulin

Insulin is a double-chain (designated A and B chain respectively) protein hormone containing three disulfides, while insulin is synthesized in vivo as a single-chain precursor and folded well before being released from B-cells. Although the structure and function of insulin have been well characterized, the progress in oxidative folding pathway studies of insulin has been very slow, mainly due to the difficulties brought about by its disulfide-linked double-chain structure. To overcome these difficulties, we recently studied the in vitro oxidative folding process of two single-chain insulins: porcine insulin precursor (PIP) and human proinsulin (HPI). Based on the analysis of the intermediates captured during folding process, the folding pathways have been proposed for PIP and HPI separately. Similarities between the two folding pathways disclose some common principles that govern the insulin folding process. The following unfolding studies of PIP and HPI further indicate that C-peptide might also function during the folding of proinsulin. Here, we gave a brief review on in vitro folding/unfolding process of insulin and single-chain insulin. The implication of these studies on protein folding has also been discussed.     

Shortened insulin with enhanced in vitro potency

After it has been shown that removal of residues B26-B30 leaves insulin with full biological activity, provided the new C-terminus is amidated (Fischer et al. (1985) Biol. Chem. Hoppe-Seyler 366, 521-525), it is demonstrated here that it does not even preclude enhancement of potency. 7 analogues of des-(B26-B30)-insulin-B25-amide were prepared by trypsin-mediated semisynthesis, the replacements being D-PheB24; HisB25, D-PheB25, TrpB25, TyrB25; D-PheB24,B25 and D-PheB24, TyrB25. Mere conversion of the configuration of B25-phenylalanine reduces in vitro potency to 0.5%. If B25-phenylalanine is, however, substituted by histidine or tyrosine activity is increased to 310 or 230, respectively. According to the features common to these two side chains, the favourable effect should be due to their ring structure with balanced aromatic and polar or H-bonding properties, respectively. The results indicate that in the complete insulin molecule the C-terminal pentapeptide modulates the subtle role that residues B24 and/or B25 play in receptor binding and activity; its presence may have a positive or negative effect. The drastic differences in activity between the shortened analogues are in no ways reflected in the CD spectra which are very similar, though clearly different from that of native insulin.     

Bombesin inhibits insulin release from isolated pancreatic islets of rats in vitro.

The effect of bombesin on insulin release from isolated pancreatic islets of rats was examined in vitro. Bombesin, at the doses ranging from 10 ng/ml to 1 microgram/ml, significantly inhibited 16.7 mM glucose-induced insulin release, while bombesin had no inhibitory effect on insulin release at 8.3 mM and 3.3 mM glucose. Moreover, bombesin also suppressed insulin release elicited by 10 mM arginine at the doses of 100 ng/ml and 1 microgram/ml. These results indicate that bombesin has a direct inhibitory action on insulin release.     

Quercetin selectively inhibits insulin receptor function in vitro and the bioresponses of insulin and insulinomimetic agents in rat adipocytes.

We report here that quercetin, a naturally occurring bioflavonoid, is an effective blocker of insulin receptor tyrosine kinase-catalyzed phosphorylation of exogenous substrate. The ID50 was estimated to be 2 +/- 0.2 microM in cell-free experiments, using a partially purified insulin receptor and a random copolymer of glutamic acid and tyrosine as a substrate. Insulin-stimulated autophosphorylation of the receptor itself was not blocked by quercetin (up to 500 microM). In intact rat adipocytes, quercetin inhibited insulin-stimulating effects on glucose transport, oxidation, and its incorporation into lipids. Inhibition of lipogenesis (50%) occurred at 47 +/- 4 microM, whereas full inhibition was evident at 110 +/- 10 microM quercetin. In contrast, the effect of insulin in inhibiting lipolysis remained unaltered in quercetin-treated adipocytes. The inhibitor was devoid of general adverse cell affects. Basal activities and the ability of lipolytic agents to stimulate lipolysis were not affected. Inhibition by quercetin enabled us to evaluate which insulinomimetic agents are dependent on tyrosine phosphorylation of endogenous substrates for stimulating glucose metabolism. Quercetin blocked lipogenesis mediated by insulin, wheat germ agglutinin, and concanavalin A. The lipogenic effect of Zn2+ and Mn2+ was partially blocked, whereas that of vanadate was not affected at all.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of insulin on cartilage differentiation in vitro

A consistent chondrogenesis takes place in high-density microcultures derived from bud mesenchymal cells of 4-day-old chicken embryos in a serum-supplemented medium. In serum-free medium DNA level and uronic acid content in the cultures were low, as well as the 35SO4 uptake and release, and only a small mass of cartilage was formed. With the addition of 0.025-10 micrograms/ml insulin to serum-free medium the uronic acid and DNA content in the cultures increased considerably in a dose-dependent way. The intensity of 35SO4 uptake and release exceeded the values measured in serum-containing medium, more cartilage tissue was formed in them also in a dose-dependent manner. With the use of 20-80 micrograms/ml insulin, the increment in DNA content proved to decrease, and with the use of 80 micrograms/ml insulin the uronic acid content and the cartilage mass decreased to a greater extent than in the case of lover doses.     

In vitro effects of glycosylated insulin in perfused liver and hindquarter in rats.

Using the perfused liver and hindquarter of the rat, the uptake of glycosylated insulin and its effect on glucose output were investigated. Insulin was glycosylated in ambient high glucose concentration, and glycosylated insulin GI80 (insulin incubated with 0.08% glucose), GI350 (incubated with 0.35% glucose), and GI1000 (incubated with 1% glucose) were prepared. The liver and hindquarter were perfused with nonglycosylated insulin (N-GI) or glycosylated insulin at a concentration of 100 or 1000 microU/ml. There were no significant differences in the fractional uptake of insulin by perfused liver and hindquarter despite glycosylation. Insulin-induced decrement in glucose output was significantly lower in the liver perfused with GI1000 than that in the liver perfused with N-GI, GI80, and GI350 at an insulin concentration of 100 microU/ml. There were no significant differences in insulin-induced decrement in glucose output between the hindquarter perfused with N-GI, GI80, GI350, and GI1000. These results suggest that when insulin (100 microU/ml) is incubated with a markedly elevated concentration of glucose (1000 mg/dl) its biological activity is reduced in the liver, but not in the hindquarter.     

The secretion of newly synthesized insulin in vitro

1. An immunological method for the purification of small quantities of insulin has been devised. 2. This method has been used to isolate labelled insulin secreted from pancreas slices incubated in vitro. The insulin had previously been labelled by incubation of the slices with [³H]leucine in vitro. 3. There is some release of labelled insulin when such slices are further incubated in media of low glucose content. When the glucose content of the medium is raised, little additional radioactive insulin is released in the first hour after labelling. However, there is a marked increase in specific radioactivity of insulin released from slices in response to a high concentration of glucose in the second and third hours. Release of labelled insulin is again diminished in the final phase, 4hr. from the start of the experiment. 4. These results are discussed in relation to possible mechanisms of insulin release from the β-cell.     

In vitro effects of insulin on aldosterone production in rat zona glomerulosa cells.

Though long standing diabetes mellitus is frequently accompanied by hypoaldosteronism, the role of insulin in this setting has never been clearly established. In the present study we have examined the direct effects of insulin on aldosterone production in rat zona glomerulosa cells in vitro. Insulin is shown to directly stimulate aldosterone production in a dose dependent manner, and to attenuate angiotensin II mediated aldosterone production, without affecting angiotensin II receptor binding kinetics. Insulin had no effect on aldosterone production mediated by the other physiological stimuli (K+ and ACTH). These data suggest a possible interaction between insulin and angiotensin II in the regulation of aldosterone secretion.