Two pathways for insulin metabolism in adipocytes.

Using selected conditions, the appropriate collagenase, albumin and cell treatment, a preparation of isolated adipocytes was developed with no extracellular insulin degrading activity. Cell mediated insulin degradation rates were 0.68% +/- 0.05%/100,000 cell/h using trichloracetic acid precipitability as a measure. Chloroquine (CQ) increased cell-associated radioactivity and decreased degradation while dansylcadaverine (DC), PCMBS and bacitracin (BAC) decreased degradation with no effect on binding. Extraction and chromatography of the cell-associated radioactivity showed 3 peaks, a large molecular weight peak, a small molecular weight peak and an insulin-sized peak. CQ, DC and BAC all decreased the small molecular weight peak while CQ and DC also increased the peak of large molecular weight radioactivity. Cell mediated insulin degradation in the presence of combinations of inhibitors suggested two pathways in adipocytes, one affected by inhibitors of the insulin degrading enzyme (IDE) (bacitracin and PCMBS) and the other altered by cell processing inhibitors (DC, CQ and phenylarsenoxide). Chloroquine altered the pattern of the insulin-sized cell-associated HPLC assayed degradation products, further supporting two pathways of degradation; one a chloroquine-sensitive and one a chloroquine-insensitive pathway.

Vanadate action on renal phosphate transport.

Insulin stimulates reabsorption of phosphate (Pi) in the renal proximal tubule. Previous studies have shown that vanadate can mimic the action of insulin on various tissues. In the present study, we tested the action of vanadate on renal Pi transport both in control rats and in rats made diabetic by injection of streptozotocin. Vanadate was administered orally for 4 days by inclusion in drinking water (0.7 mg/ml). By the 4th day, vanadate treatment of control rats did not change acid-base status, plasma glucose or the filtered load of Pi, but the urinary excretion of Pi was reduced to 2.5 +/- 0.9 compared with 17.6 +/- 3.5 mumol/mg creatine (P < 0.02) in untreated control rats. However, Na+/Pi cotransport by isolated brush border membrane vesicles was not different between the two groups. Findings in parathyroidectomized rats were similar. By the 4th day of vanadate treatment of diabetic rats, there was reversal of polyuria, polydipsia and hyperglycemia with no change in acid-base status. The filtered load of Pi was decreased by vanadate, and urinary Pi excretion also tended to decrease but not significantly. The values for Pi excretion were 21.4 +/- 7.6 in vanadate treated diabetics and 36.1 +/- 4.5 mumol/mg creatinine in untreated diabetics. In contrast to vanadate, daily injections of insulin did not change the filtered load of Pi but reduced urinary Pi excretion in diabetic rats to 15.6 +/- 2.2 mumol/mg creatinine (P < 0.02). These findings suggest that vanadate stimulated tubular Pi reabsorption in control rats but not in diabetic rats. Vanadate treatment of diabetic rats may tend to decrease tubular Pi reabsorption in contrast to the action of insulin.

Protein degradation in cultured fetal hepatocytes. Absence of an inhibitory effect of insulin.

The role of insulin to regulate protein turnover in fetal liver was investigated using primary cultures of fetal-rat hepatocytes. The basal rate of protein degradation (in the presence of insulin and amino acids) was the same in cultured fetal and adult hepatocytes (2.48 +/- 0.16 versus 2.46 +/- 0.06% of total protein degraded/h respectively). Incubation of cells in an unsupplemented media (without insulin or amino acids) resulted in a deprivation-induced increase in degradation in cells from both groups (P less than 0.05). Rates of proteolysis could be returned to their respective basal values by the addition of amino acids at 5 times their normal plasma concentrations. In adult cells, addition of insulin alone significantly inhibited protein degradation (P less than 0.05), whereas, in contrast, insulin was without effect on protein degradation in fetal hepatocytes. Both fetal and adults cells responded to dibutyryl cyclic AMP with an increase in protein degradation above that seen in the no-additions group. Results of experiments in which the effect of inhibitors of protein degradation (chloroquine, NH4Cl, amino acids and dinitrophenol) were tested suggested that lysosomes were responsible for 20-30% of total protein degradation in fetal hepatocytes. Impaired insulin processing in fetal hepatocytes was examined as a possible cause of the insulin-resistance in these cells. As determined by h.p.l.c. analysis, the same pattern of initial degradation products of insulin was found in fetal hepatocytes as had previously been found in adult hepatocytes. Incubation of cells with various doses of chloroquine resulted in an increase in cell-associated 125I-insulin and a decrease in insulin degradation in both fetal and adult cells. At the highest dose of chloroquine tested (500 microM), a slightly greater increase in insulin binding and a decrease in insulin degradation were observed in fetal cells as compared with adult cells. Rates of insulin internalization were also compared between fetal and adult cells. A 30% slower rate of insulin internalization was observed in fetal cells, as compared with adult cells. It was concluded that the absence of an effect of insulin on protein degradation in fetal hepatocytes is not the result of a major difference in insulin internalization and processing between fetal and adult hepatocytes.

Hepatic metabolism of insulin.

The liver plays a major role in the metabolism of insulin, but the precise cellular mechanisms, the enzymes involved, and the products generated have only recently become clarified. The initial step in insulin degradation by the liver is binding to a cell membrane receptor, following which some insulin is degraded and the products released into the incubation medium, whereas some insulin is internalized and degraded intracellularly. Recently, it has been demonstrated that the degradation of insulin by hepatocytes produces products identical to those generated by the enzyme insulin protease. With both enzyme and intact hepatocytes, two A-chain cleavages and four major and three minor B-chain cleavages occur in intact insulin. It has also been demonstrated that internalized insulin is degraded in early endosomes, primarily by cleavages in the B chain and occurring prior to acidification of the endosome and thus prior to dissociation of insulin from its receptor. The initial cleavages in the B chain of insulin occur in the same sites as are cleaved by insulin protease, supporting a role for this enzyme, both in the extracellular and intracellular metabolism of insulin. These findings also indicate that lysosomes probably play a minor or secondary role for hepatic insulin metabolism.

Conversion of biosynthetic human proinsulin to partially cleaved intermediates by collagenase proteinases adsorbed to isolated rat adipocytes.

Studies of the biological activity of proinsulin have resulted in widely varying conclusions. Relative to insulin, the biological activity of proinsulin has been reported from less than 1% to almost 20%. Many of the assays in vitro for the biological potency of proinsulin have utilized isolated rat adipocytes. To examine further the interaction of proinsulin with rat adipocytes, we prepared specifically-labelled proinsulin isomers that were iodinated on tyrosine residues corresponding to the A14, A19, B16 or B26 residue of insulin. These were incubated with rat adipocytes and their metabolism was examined by trichloroacetic acid precipitation, by Sephadex G-50 chromatography, and by h.p.l.c. chromatography. By trichloroacetic acid-precipitation assay, there was little or no proinsulin degradation. By G-50 chromatography and subsequent h.p.l.c. analysis, however, we found that the labelled proinsulin isomers were converted rapidly and almost completely to materials which eluted differently on h.p.l.c. from intact proinsulin. This conversion was due primarily to proteolytic activity which adsorbed to the fat cells from the crude collagenase used to isolate the cells. Two primary conversion intermediates were found: one with a cleavage at residues 23-24 of proinsulin (the B-chain region of insulin), and one at residues 55-56 in the connecting peptide region. These intermediates had receptor binding properties equivalent to or less than intact proinsulin. These findings show that isolated fat cells can degrade proinsulin to intermediates due to their contamination with proteolytic activity from the collagenase used in their preparation. Thus the previously reported range in biological activities of proinsulin in fat cells may have arisen from such protease contamination. Finally, the present findings demonstrate that a sensitive assay for degradation of hormones is required to examine biological activities in isolated cells.

Insulin-like effects of vanadate in isolated rat adipocytes.

Vanadate has been shown to have a number of insulin-like effects in various cells, including isolated rat adipocytes. In the present study we compared the activities of vanadate and insulin in isolated fat cells using a number of different assays of insulin-like activity. Both insulin and vanadate stimulated [2-3H]glucose incorporation into fat cell lipid in a dose-dependent manner, but the maximal effect of vanadate was markedly greater than that of insulin. At 10(-2) M vanadate the effect was 3-4 times as great as the maximal effect of insulin. This effect was dependent on specific glucose transport. Combinations of insulin and vanadate were not more effective than vanadate alone. Vanadate also produced antilipolysis with an effect somewhat greater than that of insulin. Using [U-14C]glucose both vanadate and insulin stimulated 14CO2 production and [14C]glucose incorporation into lipid, and again the effect of vanadate was greater than that of insulin. Vanadate had a greater effect on 14CO2 production than on [14C]glucose incorporation into lipid. When [1-14C]glucose was used vanadate again had a significantly greater effect on 14CO2 production than did insulin, but when [6-14C]glucose was used the effects of vanadate and insulin were equal. These results demonstrate that vanadate has insulin-like effects in isolated fat cells, but it selectively stimulates certain pathways to a greater extent than does insulin. The greater effect of vanadate than insulin appears to be primarily on the pentose phosphate shunt, suggesting that this agent may be useful for examination of this intracellular pathway in fat cells.

Differential binding of monoiodinated insulins to muscle and liver derived receptors and activation of the receptor kinase.

The binding affinity of monoiodoinsulin analogues to receptors purified from rat skeletal muscle and liver were compared. Insulin iodinated at tyrosine B26 bound to both muscle and liver derived insulin receptors with higher affinity than the A14-iodoisomer or native insulin. The affinity of the B26-iodoanalogue was greater for muscle than for liver derived receptors; by Scatchard analysis the affinity ratio B26/A14 was 2.8 for muscle and 1.3 for liver. The affinity of muscle and liver derived receptors for A14-iodoinsulin was not different. Dose response curves of autophosphorylation and exogenous tyrosine kinase activation showed significantly increased sensitivity to the B26-iodoanalogue (compared to the A14-iodoisomer or native insulin) in muscle derived receptors, but not in liver. The difference in affinity between muscle and liver derived insulin receptors towards B26-monoiodotyrosyl-insulin likely reflects the observed structural difference between the insulin receptor alpha-subunits from muscle and liver.

Degradation products of insulin generated by hepatocytes and by insulin protease.

The enzymatic mechanisms for insulin breakdown by hepatocytes have not been established, nor have the degradation products been identified. Several lines of evidence have suggested that the enzyme insulin protease is involved in insulin degradation by hepatocytes. To identify the products of insulin generated by insulin protease and to compare them with those produced by hepatocytes, we have incubated insulin specifically iodinated at either the B-16 or the B-26 tyrosines with insulin protease and with isolated hepatocytes, separated the products on high performance liquid chromatography (HPLC), and identified the B-chain cleavages. Insulin-sized products were obtained by Sephadex G-50 filtration. These insulin-sized products were injected on reverse-phase HPLC, and the peaks of radioactivity were identified. The product patterns generated by the enzyme and by hepatocytes were essentially identical with both isomers. The products were also sulfitolized to prepare the S-sulfonate derivatives of the B-chain and B-chain peptides. Again, the patterns on HPLC generated by the enzyme and by hepatocytes with both isomers were identical. Each of the original product peaks was also sulfitolized and injected separately on HPLC to relate B-chain peptides with product peaks. Again, the peptide compositions of the product peaks for both enzyme and hepatocytes were essentially identical. To identify the cleavage sites in the B-chain of insulin produced by insulin protease, the peptides from the degradation of [125I]iodo(B-26)insulin were purified and submitted to automated Edman degradation to identify the cycle in which radioactivity appeared. Seven peptides with cleavages on the amino side of the B26 residue were identified, and the cleavage sites were determined. Cleavages were found between B-9 and B-10 (Ser-His), B-10 and B-11 (His-Leu), B-14 and B-15 (Ala-Leu), B-13 and B-14 (Glu-Ala), B-16 and B-17 (Tyr-Leu), B-24 and B-25 (Phe-Phe), and B-25 and B-26 (Phe-Tyr). Peptides were also isolated from [125I]iodoinsulin incubated with isolated hepatocytes, and the cleavage sites in several of these were determined. These agreed exactly with the cleavage sites identified generated by the enzyme. The major peptides generated by the degradation of [125I]iodo(B-16)insulin were also isolated and sequenced, again showing identical cleavage sites.(ABSTRACT TRUNCATED AT 400 WORDS)

Identification of A chain cleavage sites in intact insulin produced by insulin protease and isolated hepatocytes.

The degradation of insulin by the enzyme insulin protease and by isolated hepatocytes results in proteolytic cleavages in both the A and B chains of intact insulin. Previous studies have shown that one of the A chain cleavages is between A13 leucine and A14 tyrosine and that a second cleavage occurs carboxyl to the A14 residue. In the present study we have used insulin specifically iodinated on the A19 tyrosine and examined the A chain cleavages by the enzyme and by hepatocytes. Insulin degradation products were purified by HPLC and sequenced by automated Edman degradation. Only two A chain cleavage sites were identified, one the previously reported A13-A14 and the other between A14 tyrosine and A15 glutamine. These data thus identify the second A chain cleavage site and further support the role of insulin protease in hepatic metabolism of insulin.

HPLC analysis of insulin degradation products from isolated hepatocytes. Effects of inhibitors suggest intracellular and extracellular pathways.

Isolated rat hepatocytes were incubated with A14-[125I]monoiodotyrosyl insulin for 30 min, and labeled material was extracted from the cells and incubation media. The medium and the cell extract were chromatographed on a Sephadex G-50 column, and radioactivity eluting in the position of intact insulin was concentrated and analyzed on HPLC. The HPLC analysis of the cell extract showed two major products eluting from the column at 19 and 23 min, whereas medium extracts showed one prominent product eluting at 14 min. Inclusion of chloroquine in the incubation blocked the formation of cellular products at 19 and 23 min and caused the accumulation of a product eluting at 41 min while not affecting the media products. After sulfitolysis all cellular products contained an intact A-chain. Dansylcadaverine increased media products and altered the cell-extracted product pattern such that it had a major peak at 14 min, similar to media. These results suggest that two pathways for insulin degradation exist within hepatocytes. The extracellular process forms products that are essentially unchanged by chloroquine and dansylcadaverine. The intracellular process is altered by chloroquine and apparently inhibited by dansylcadaverine.

Insulin-stimulated conversion of D-[5-3H] glucose to 3HOH in the perifused isolated rat adipocyte.

Characteristics of basal and insulin-stimulated glucose utilization by perifused adipocytes have been investigated by measuring the formation of 3HOH from D-(5-3H) glucose. At a glucose concentration of 0.55 mmol/L, basal glucose utilization ranged from 0.5 to 1.0 nmol/min/10(6) cells. Perifused adipocytes showed a maximal response to insulin of a threefold to fourfold increase in the conversion of (5-3H) glucose to 3HOH with a half-maximal response at an insulin concentration of 20 microU/mL. The response to insulin was blocked by phlorizin and cytochalasin B, competitive inhibitors of glucose transport, consistent with an effect of insulin on glucose transport. Insulin increased the Vmax for glucose metabolism but had no effect on the apparent affinity for glucose utilization. The characteristics of glucose utilization and the stimulation of glucose metabolism by insulin in the perifused adipocyte are therefore similar to characteristics previously observed with incubated adipocytes. Because insulin can readily be removed from the system, perifused adipocytes are especially suited for studying the termination of insulin action. The termination of insulin-stimulated glucose metabolism occurred at the same rate in the presence of tracer (1 nmol/L) (5-3H)-glucose alone as when 0.55 mmol/L glucose or 2 mmol/L pyruvate were added to the perifusion buffer. The halftime for this process in both cases was approximately 40 minutes. These data suggest that the presence of metabolizable substrate is not required for the termination of the insulin response, but the time course suggests that termination requires more than simply insulin-receptor dissociation.

Localization of insulin degradation products to an intracellular site in isolated rat hepatocytes.

In the present study, we have examined whether insulin degradation products are present on the surface of isolated rat hepatocytes and can be removed by an acid dissociation technique. Hepatocytes were incubated with [125I]insulin for 30 minutes, rapidly washed to remove unbound insulin, and then briefly exposed to acidic conditions (pH 5.0) to remove bound hormone from the cell surface. The radioactive material removed from the cell by acid dissociation and that remaining with the cells were separately analyzed by high performance liquid chromatography. The two primary degradation products of insulin present in control cell extracts were found only with the cell-associated material after acid dissociation. The insulin-sized radioactive material in the extract of acid-dissociable material consisted of only intact [125I]insulin. These results show that the two primary degradation products of insulin in rat hepatocytes are found only intracellularly and suggest that the degradation of the hormone begins after it is internalized.

High performance liquid chromatographic analysis of insulin degradation by rat skeletal muscle insulin protease.

The degradation of [125I]iodoinsulin (A14) by insulin protease (EC 3.4.22.11) was studied using HPLC. A reverse phase HPLC method is presented which allows the separation and quantitation of insulin degradation products. After incubation of [125I]iodoinsulin (A14) with insulin protease, there was an initial rapid loss of radioactivity from the [125I] iodoinsulin (A14) peak, which was quantitatively accounted for by the appearance of radioactivity in 11 different peaks, but was not accompanied by a proportional increase in the solubility of the sample in trichloroacetic acid. Two of the peaks showed appreciable accumulation before the others, and all but the first-eluted peak plateaued by 20 min. After 20 min of incubation, the amount of radioactivity present as the first-eluted peak, solubility in trichloroacetic acid, and insulin loss continued to increase at a steady, but slowed, rate. The order of appearance suggests that insulin protease acts on insulin in an ordered sequence of steps to generate a number of intermediates that are precipitable by trichloroacetic acid, but are subsequently degraded to material that is soluble in trichloroacetic acid. Sulfitolysis of 5 major peaks and subsequent HPLC analysis of the fragments showed none of the peaks to possess intact A chains. Peptide sequencing of 2 of the peaks indicates that the A-chain is cleaved in at least 2 positions, one beyond the 14th position, and one between the 13th and 14th amino acids (leucine and tyrosine).

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.

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.

Time course of changes in albumin synthesis and mRNA in diabetic and insulin-treated diabetic rats.

Albumin synthesis in rat liver in vivo decreased from 12.7 to 2.2% of total protein synthesis during the first 3 days after the induction of diabetes and then remained relatively constant at this depressed rate for another 3 days. Insulin treatment begun on the 3rd day after the induction of diabetes restored albumin synthesis to control values within 3 days. Hybridization of total polyadenylate-containing RNA with a specific albumin cDNA probe revealed a close correspondence between the relative abundance of albumin mRNA and the relative rate of albumin synthesis after induction of diabetes and in response to insulin treatment. The apparent half-life of albumin mRNA, based on the rate of change of the message from one steady-state level to another, was approximately 22 h in both diabetic and insulin-treated diabetic rats. Diabetes of 3-day duration had no effect on the average sizes of total and albumin-synthesizing polysomes or on the ribosomal half-transit time for total protein and albumin. However, the number of albumin-synthesizing polysomes decreased as a result of diabetes to approximately one-third the number found in control livers. Taken together the results indicate that albumin synthesis was regulated by the availability of albumin mRNA and not by alterations in degradation, sequestration, or translation of message.

Evidence that bacitracin alters intracellular insulin metabolism in isolated rat hepatocytes.

The effect of bacitracin on intracellular insulin degradation was investigated using an isolated rat hepatocyte preparation in which essentially all insulin degradation was due to cell-mediated processes. Bacitracin produced a concentration-dependent decrease in the degradation of insulin to products soluble in trichloroacetic acid, with a half-maximal effect at approximately 0.5 mM. These results were confirmed by analysis of extracted cell-bound radioactivity by Sephadex G-50 molecular sieve chromatography. Radioactive material eluting in the position of intact insulin from the G-50 column was further analyzed by reversed-phase, high-performance liquid chromatography. In addition to intact insulin, two peaks of radioactive material less hydrophobic than insulin were evident. Incubation of cells in the presence of 0.5 mM bacitracin significantly (P less than 0.05) altered the distribution of radioactivity in these two peaks. These results indicate that bacitracin significantly affects hepatocyte insulin metabolism and suggest that the continued use of bacitracin in studies of hepatocyte-insulin interaction should be avoided.

In vitro activity of biosynthetic human proinsulin. Receptor binding and biologic potency of proinsulin and insulin in isolated rat adipocytes.

The receptor binding characteristics and biologic protency of biosynthetic human proinsulin (rDNA) were determined in isolated rat adipocytes and compared with those of insulin. In competition with 125I(A14)-iodoinsulin for binding to adipocyte receptors at 15 degrees C, proinsulin showed a 100-fold lower affinity for binding than did insulin. A proinsulin concentration of 3.2 +/- 0.8 X 10(-7) M was required for 50% inhibition of tracer binding as compared with a concentration of 1.7 +/- 0.3 X 10(-9) M for insulin. These results were confirmed in direct competition studies using proinsulin and 125I-iodoproinsulin. A similar 100-fold difference was also observed in competitive binding experiments conducted at 37 degrees C. The biologic potency of human proinsulin was evaluated by its ability to stimulate glucose incorporation into total fat cell lipid and also by its antilipolytic activity. Glucose incorporation into lipid was half-maximal at a proinsulin concentration of 1.5 +/- 0.4 X 10(-8) M, whereas the same response was observed at an insulin concentration of 5.2 +/- 1 X 10(-11) M. Proinsulin also demonstrated an antilipolytic potency that was less than 1% that of insulin. The time course over which insulin and proinsulin stimulated glucose incorporation into lipid was the same, as was the time course over which the stimulation dissipated after removal of the hormones. No synergism of insulin and proinsulin stimulation of lipogenesis was observed when fat cells were incubated with submaximal concentrations of the two hormones.(ABSTRACT TRUNCATED AT 250 WORDS)

Insulin-responsive cultured foetal-rat hepatocytes. Their preparation and characterization.

An improved non-perfusion method for the preparation of cultured foetal-rat hepatocytes is described. Digestion of the liver with collagenase and deoxyribonuclease I gave yields of 40 X 10(6) hepatocytes/g of liver. The plating efficiency of hepatocytes in medium with 10 microM-cortisol was 50%. Cell morphology and metabolism were maintained through 3 days of monolayer culture, with minimal contamination by haematopoietic cells or fibroblasts. The cultured cells bound and degraded 125I-insulin in a time- and dose-dependent manner. The estimated ED50 for competitive binding at 37 degrees C was 1.1 nM. Curvilinear Scatchard plots were observed, with estimates of 16 500 high-affinity sites (Kd = 813 pM) and 53 000 low-affinity sites (Kd = 23 nM) per cell. The cultured cells demonstrated a glycogenic response to insulin, with an estimated ED50 of 120 pM. The degree of glycogenic response to insulin varied with time in culture: 500% above basal on day 1, 200% on day 2, and only 150% on day 3. Cultured foetal cells also exhibited a time-dependent uptake of 2-aminoisobutyric acid, which, in contrast with previous reports with adult cells, was not stimulated by the presence of 10 nM-insulin. Cultured foetal hepatocytes may provide an interesting model with which to study the relationship between insulin-receptor binding and insulin action.

The degradation of monoiodotyrosyl insulin isomers by insulin protease.

The four single-site monoiodotyrosyl insulin isomers were synthesized by lactoperoxidase-catalyzed iodination of porcine insulin and were separated from one another by high performance liquid chromatography. The susceptibility of the four isomers (A14-, A19-, B16-, and B26-monoiodotyrosyl insulin) to degradation by purified insulin protease was examined using several different assay methods, including trichloroacetic acid precipitation, immunoprecipitation, and Sephadex G-50 chromatograpy. Using trichloroacetic acid precipitation, isomer susceptibility, determined from the initial rate of hydrolysis, was highest with the A14 isomer, lowest with the A19 isomer, and intermediate and roughly equal with the two B-chain-labeled isomers. Based upon the initial rate of isomer hydrolysis, the Michaelis Menten constant (Km) of insulin protease was higher for the B16 isomer (55 nM) than for the other three isomers, whose Km values were not different from one another (A14 = 24 nM; A19 = 35 nM; B26 = 29 nM). In addition, the values for maximum velocity (Vmax) were higher for the A14 and B26 isomers than for the A19 and B16 isomers. However, during incubation, the order of isomer susceptibility to insulin protease changed to B26 greater than A14 greater than A19 greater than B16. This change in apparent isomer susceptibility was prevented by including in the incubation mixture a rat renal peptidase, which did not degrade the intact isomers, suggesting that insulin protease converted the isomers to trichloroacetic acid-soluble products via trichloroacetic acid-precipitable intermediates. Using the immunoprecipitation assay, the susceptibility of isomers to hydrolysis did not change during incubation, but remained highest with the A14 isomer, lowest with the A19 isomer, and intermediate with the two B-chain-labeled isomers, of which the B16 isomer was degraded more rapidly. Each isomer was converted more rapidly to nonimmunoprecipitable products than to trichloroacetic acid-soluble products, implying that insulin protease converted the isomers to trichloroacetic acid-precipitable, nonimmunoprecipitable intermediates, which it then converted to trichloroacetic acid-soluble form. Using Sephadex G-50 chromatography (SGC) assay, the susceptibility of isomers to hydrolysis did not change during incubation, but remained highest with the A14 isomer, lowest with the A19 isomer, and intermediate with the two B-chain-labeled isomers, of which the B16 isomer was hydrolyzed more rapidly. With the exception of the A19 isomer, isomer hydrolysis appeared faster with SGC assay than with either of the other two assays.(ABSTRACT TRUNCATED AT 400 WORDS)