Structural modifications of oxidized insulin B-chain induced by glycerol addition

H-NMR studies of the bovine insulin S-sulfonatedB-chain are reported in H₂O/D₂O (9/1) and inglycerol-d₅ (5 M) using two-dimensional NMRspectroscopy. The first results show that the oxidizedinsulin B-chain secondary structure differs from thatof native insulin by a loss of the -helixbetween the two disulfide bridges and that theglycerol favours the structuring of the peptide.     

An alkaline proteinase of an alkalophilicBacillus sp.

An alkaline serine proteinase was purfied from the culture broth of an alkalophilicBacillus sp. NKS-21. The molecular weight was estimated to be 22,000 by a gel filtration method and 31,000 by SDS-polyacrylamide gel electrophoresis. The isoelectric point was determined to be 8.2. The amino acid composition and CD spectrum were determined. The alkaline proteinase had a pH optimum at 10–11 for milk casein digestion. The specific activity of the alkaline proteinase was 0.35 katal/kg of protein at pH 10.0 for milk casein hydrolysis.The substrate specificity of the alkaline proteinase was studied by using the oxidized, insulin B-chain and angiotensin. An initial cleavage site was observed at Leu¹⁵-Tyr¹⁶, secondary site at Leu¹¹-Val¹², and additional sites at Gln⁴-His⁵, Tyr²⁶-Thr²⁷, and Asn³-Gln⁴ in the oxidized insulin B-chain at pH 10.0. In comparison with the subtilisins Carlsberg and Novo, the alkaline proteinase fromBacillus sp. showed a unique specificity toward the oxidized insulin B-chain. Hydrolysis of angiotensin at pH 10.0 with the alkaline proteinase was observed at Tyr⁴-Ile⁵. The proteinase has aK _m of 0.1 mM andk _cat of 3.3 s^–1 with angiotensin as substrate.     

Substrate specificity of carboxyl proteinase fromPycnoporus coccineus,a wood-deteriorating fungus

A carboxyl proteinase was purified from submerged-culture filtrate of a wood-deteriorating basidiomycete,Pycnoporus coccineus. The purified enzyme was found to be essentially homogeneous in disc gel electrophoresis tests at pH 9.4 and 2.3. The specificity and mode of action ofP. coccineus carboxyl proteinase I_a were investigated with the oxidized B-chain of insulinP. coccineus carboxyl proteinase I_a hydrolyzed primarily three peptide bonds, Ala¹⁴-Leu¹⁵, Tyr¹⁶-Leu¹⁷, and Phe²⁴-Phe²⁵ bonds, in the oxidized B-chain of insulin.     

Substrate Specificity of a Novel Alcohol Resistant Metalloproteinase,Vimelysin, from Vibrio sp. T1800

Vimelysin is a novel alcohol resistant metalloproteinase from Vibrio sp. T1800. The substrate specificity of vimelysin was studied by using natural and furylacryloyl dipeptide substrates. Vimelysin cleaved mainly Pro⁷-Phe⁸ bond and slightly Tyr⁴-Ile⁵ bond in human angiotensin I. Vimelysin also cleaved mainly Phe²⁴-Phe²⁵ and Tyr¹⁶-Leu¹⁷ bonds, and slightly His⁵-Leu⁶, His¹⁰-Leu¹¹, Ala¹⁴-Leu¹⁵, and Gly²³-Phe²⁴ bonds in oxidized insulin B-chain. The substrate specificity of vimelysin, by using furylacryloyl (Fua) dipeptides were also studied. The ratio of k_cat/K_m for Fua-Gly-Phe-NH₂/Fua-Gly-Leu-NH₂, Fua-Phe-Leu-NH₂/Fua-Gly-Leu-NH₂, and Fua-Phe-Phe-NH₂/Fua-Gly-Leu-NH₂ were 15.9, 27.8, and 59.0, respectively. These results indicate that vimelysin easily recognizes phenylalanine in P1′ positions, which is different from thermolysin.     

Insulin-like effects of a physiologic concentration of carnitine on cardiac metabolism

Pharmacologic (millimolar) levels of carnitine have been reported to increase myocardial glucose oxidation, but whether physiologically relevant concentrations of carnitine affect cardiac metabolism is not known. We employed the isolated, perfused rat heart to compare the effects of physiologic levels of carnitine (50 M) and insulin (75 mU/l [0.5 nM]) on the following metabolic processes: (1) glycolysis (release of ³H₂O from 5-³H-glucose); (2) oxidation of glucose and pyruvate (production of ¹⁴CO₂ from U-¹⁴C-glucose, 1-¹⁴C-glucose, 3,4-¹⁴C-glucose, 1-¹⁴C-pyruvate, and 2-¹⁴C-pyruvate); and (3) oxidation of palmitate (release of ³H₂O from 9,10-³H-palmitate). We found that addition of carnitine (50 M) to a perfusate containing both glucose (10 mM) and palmitate (0.5 mM) stimulated glycolytic flux by 20%, nearly doubled the rate of glucose oxidation, and inhibited palmitate oxidation by 20%. These actions of carnitine were uniformly similar to those of insulin. When carnitine and insulin were administered together, their effects on the oxidation of glucose and palmitate, but not on glycolysis, were additive. When pyruvate (1 mM) was substituted for glucose, neither carnitine nor insulin influenced the rate of oxidation of pyruvate or palmitate. In combination, however, carnitine and insulin sharply suppressed pyruvate oxidation (75%) and doubled the rate of palmitate oxidation. None of the responses to carnitine or insulin was affected by varying the isotopic labeling of glucose or pyruvate. The results show that carnitine, at normal blood levels, exerts insulin-like effects on myocardial fuel utilization. They also suggest that plasma carnitine in vivo may interact with insulin both additively and permissively on the metabolism of carbohydrates and fatty acids     

Specificities of extracellular and ribosomal serine proteinases from Bacillus natto,a food microorganism

The specificities of extracellular and ribosomal serine proteinase from Bacillus natto, a food microorganism, were investigated. Both proteins have highly restricted and characteristic specificities. With the extracellular serine proteinase, initial cleavage site was observed at Leu¹⁵-Tyr¹⁶, secondary site at Ser⁹-His¹⁰ and additional cleavage sites at Gln⁴-His⁵ and His⁵-Leu⁶ in the oxidized insulin B-chain. Hydrolysis of proangiotensin with the extracellular serine proteinase was observed primarily at Phe⁸-His⁹ and secondary at Tyr⁴-Ile⁵. The extracellular serine proteinase has a K_m of 0.08 mM and k_cat of 3 s⁻¹ for angiotensin hydrolysis. With the ribosomal proteinase, initial cleavage site of the oxidized insulin B-chain was observed at Leu¹⁵-Tyr¹⁶ and additional cleavage site at Phe²⁴-Phe²⁵. Hydrolysis of proangiotensin was observed at Tyr⁴-Ile⁵ bond with the ribosomal proteinase.     

Oral administration of the biomimetic [Cr3O(O2CCH2CH3)6(H2O)3]+ increases insulin sensitivity and improves blood plasma variables in healthy and type 2 diabetic rats

The in vivo effects of gavage administration of the synthetic, functional biomimetic cation [Cr₃O(O₂CCH₂CH₃)₆(H₂O)₃]⁺ to healthy and type 2 diabetic model rats are described. After 24 weeks of treatment (0–1,000 g Cr/kg body mass) of healthy Sprague Dawley rats, the cation results in a lowering (P<0.05) of fasting blood plasma low-density lipoprotein (LDL) cholesterol, total cholesterol, triglycerides, and insulin levels and of 2-h plasma insulin and glucose concentrations after a glucose challenge. Zucker obese rats (a model of the early stages of type 2 diabetes) and Zucker diabetic fatty rats (a model for type 2 diabetes) after supplementation (1,000 g Cr/kg) have lower fasting plasma total, high-density lipoprotein, and LDL cholesterol, triglycerides, glycated hemoglobin, and insulin levels and lower 2-h plasma insulin levels in glucose tolerance tests. The lowering of plasma insulin concentrations with little effect on glucose concentrations suggests that the supplement increases insulin sensitivity. The cation after 12 and 22 or 24 weeks of administration lowers (P<0.05) fasting plasma glycated hemoglobin levels in the Zucker diabetic and Zucker obese rats, respectively, and thus can improve the glucose status of the diabetic models. The effects cannot be attributed to the propionate ligand.Supplementary material is available for this article at .An erratum to this article can be found at     

Substrate specificity of carboxyl proteinase ofAspergillus sojae

The specificity and mode of action ofAspergillus sojae carboxyl proteinase I were investigated with the oxidized B-chain of insulin.A. sojae carboxyl proteinase I hydrolyzed primarily two peptide bonds in the oxidized B-chain of insulin, the Leu¹⁵-Tyr¹⁶ bond and the Phe²⁴-Phe²⁵ bond. Additional cleavage of the bond Tyr¹⁶-Leu¹⁷ was also noted.     

Regulation of nitrous oxide emission associated with benthic invertebrates

1. A number of freshwater invertebrate species emit N₂O, a greenhouse gas that is produced in their gut by denitrifying bacteria (direct N₂O emission). Additionally, benthic invertebrate species may contribute to N₂O emission from sediments by stimulating denitrification because of their bioirrigation behaviour (indirect N₂O emission). 2. Two benthic invertebrate species were studied to determine (i) the dependence of direct N₂O emission on the preferred diet of the animals, (ii) the regulation of direct N₂O emission by seasonally changing factors, such as body size, temperature and availability and (iii) the quantitative relationship between direct and indirect N₂O emission. 3. Larvae of the mayfly Ephemera danica, which prefer a bacteria‐rich detritus diet, emitted N₂O at rates of up to 90 pmol Ind.^?1 h^?1 under in situ conditions and 550 pmol Ind.^?1 h^?1 under laboratory conditions. In contrast, larvae of the alderfly Sialis lutaria, which prefer a bacteria‐poor carnivorous diet, emitted N₂O at invariably low rates of 0–20 pmol Ind.^?1 h^?1. The N₂O emission rate of E. danica larvae was positively correlated with seasonally changing factors (body size, temperature and availability). Direct N₂O emission by E. danica larvae was limited by low temperature in winter, larval development in spring and low availability in summer. 4. Both E. danica and the non‐emitting S. lutaria increased the total N₂O and N₂ emission from sediment in a density‐dependent manner. While N₂O directly emitted by benthic invertebrates can be partially consumed in the sediment (E. danica), non‐emitting species can still indirectly contribute to total N₂O emission from sediment (S. lutaria).     

Insulin‐ and Exercise‐Stimulated Skeletal Muscle Blood Flow and Glucose Uptake in Obese Men

Objective: Insulin resistance in obese subjects results in the impaired use of glucose by insulin‐sensitive tissues, e.g., skeletal muscle. In the present study, we determined whether insulin resistance in obesity is associated with an impaired ability of exercise to stimulate muscle blood flow, oxygen delivery, or glucose uptake. Research Methods and Procedures: Nine obese (body mass index = 36 ± 2 kg/m²) and 11 age‐matched nonobese men (body mass index = 22 ± 1 kg/m²) performed one‐legged isometric exercise during hyperinsulinemia. Rates of femoral muscle blood flow, oxygen consumption, and glucose uptake were measured simultaneously in both legs using [¹⁵O]H₂O, [¹⁵O]O₂, [¹⁸F]fluoro‐deoxy‐glucose, and positron emission tomography. Results: The obese subjects exhibited resistance to insulin stimulation of glucose uptake in resting muscle, regardless of whether glucose uptake was expressed per kilogram of femoral muscle mass (p = 0.001) or per the total mass of quadriceps femoris muscle. At similar workloads, oxygen consumption, blood flow, and glucose uptake were lower in the obese than the nonobese subjects when expressed per kilogram of muscle, but similar when expressed per quadriceps femoris muscle mass. Discussion: We conclude that obesity is characterized by insulin resistance of glucose uptake in resting skeletal muscle regardless of how glucose uptake is expressed. When compared with nonobese individuals at similar absolute workloads and under identical hyperinsulinemic conditions, the ability of exercise to increase muscle oxygen uptake, blood flow, and glucose uptake per muscle mass is blunted in obese insulin‐resistant subjects. However, these defects are compensated for by an increase in muscle mass.     

Preliminary Structure–Function Relationship Studies on Insulin-Like Peptide 5 (INSL5)

Insulin-like peptide 5 (INSL5) is a two-chain, three-disulfide bonded member of insulin/relaxin superfamily of peptides that includes insulin, insulin-like growth factor I and II (IGFI and IGFII), insulin-like peptide 3, 4, 5 and 6 (INSL3, 4, 5 and 6), relaxin-1 (H1 relaxin), -2 (H2 relaxin) and -3 (H3 relaxin). Although it is expressed in relatively high levels in the gut, its biological function remains unclear. However, recent reports suggest a significant orexigenic action and a role in the regulation of insulin secretion and β-cell homeostasis, which implies that both agonists and antagonists of the peptide may have significant therapeutic applications. Modern solid phase synthesis techniques together with regioselective disulfide bond formation were employed for a preliminary structure–function relationship study of mouse INSL5. Two point mutated analogues, mouse INSL5 A-B(R24A, W25A) and mouse INSL5 A-B(K6A, R14A, Y18A) were chemically prepared, where the residues in the B-chain that may be involved in receptor activation and affinity binding, were respectively mutated. Synthetic mouse INSL5 A-B(R24A, W25A) analogue was inactive on RXFP4, the native receptor for INSL5, suggesting Arg^B24 and Trp^B25 are probably directly involved in INSL5 receptor activation. Mouse INSL5 A-B(K6A, R14A, Y18A) analogue had both decreased affinity and potency on RXFP4 (pIC₅₀ 7.7 ± 0.2, pEC₅₀ 7.87 ± 0.18) which indicated that one or more of these residues are critical for the binding to the receptor.     

Prospects of using marine actinobacteria as probiotics in aquaculture

In the present study, optimum culture conditions for the production of extracellular polysaccharides (EPS) in submerged culture of an edible mushroom, Laetiporus sulphureus var. miniatus and their stimulatory effects on insulinoma cell (RINm5F) proliferation and insulin secretion were investigated. The maximum mycelial growth (4.1 g l⁻¹) and EPS production (0.6 g l⁻¹) in submerged flask culture were achieved in a medium containing 30 g l⁻¹ maltose, 2 g l⁻¹ soy peptone, and 2 mM MnSO₄·5H₂O at an initial pH 2.0 and temperature 25°C. In the stirred-tank fermenter under optimized medium, the concentrations of mycelial biomass and EPS reached a maximum level of 8.1 and 3.9 g l⁻¹, respectively. Interestingly, supplementation of deep sea water (DSW) into the culture medium significantly increased both mycelial biomass and EPS production by 4- and 6.7-fold at 70% (v/v) DSW medium, respectively. The EPS were proved to be glucose-rich polysaccharides and were able to increase proliferation and insulin secretary function of rat insulinoma RINm5F cells, in a dose-dependent manner. In addition, EPS also strikingly reduced the streptozotocin-induced apoptosis in RINm5F cells indicating the mode of the cytoprotective role of EPS on RINm5F cells.     

Nitrite-driven nitrous oxide production under aerobic soil conditions: kinetics and biochemical controls

Nitrite (NO₂⁻) can accumulate during nitrification in soil following fertilizer application. While the role of NO₂⁻ as a substrate regulating nitrous oxide (N₂O) production is recognized, kinetic data are not available that allow for estimating N₂O production or soil‐to‐atmosphere fluxes as a function of NO₂⁻ levels under aerobic conditions. The current study investigated these kinetics as influenced by soil physical and biochemical factors in soils from cultivated and uncultivated fields in Minnesota, USA. A linear response of N₂O production rate () to NO₂⁻ was observed at concentrations below 60 μg N g⁻¹ soil in both nonsterile and sterilized soils. Rate coefficients (K_p) relating to NO₂⁻ varied over two orders of magnitude and were correlated with pH, total nitrogen, and soluble and total carbon (C). Total C explained 84% of the variance in K_p across all samples. Abiotic processes accounted for 31–75% of total N₂O production. Biological reduction of NO₂⁻ was enhanced as oxygen (O₂) levels were decreased from above ambient to 5%, consistent with nitrifier denitrification. In contrast, nitrate (NO₃⁻)‐reduction, and the reduction of N₂O itself, were only stimulated at O₂ levels below 5%. Greater temperature sensitivity was observed for biological compared with chemical N₂O production. Steady‐state model simulations predict that NO₂⁻ levels often found after fertilizer applications have the potential to generate substantial N₂O fluxes even at ambient O₂. This potential derives in part from the production of N₂O under conditions not favorable for N₂O reduction, in contrast to N₂O generated from NO₃⁻ reduction. These results have implications with regard to improved management to minimize agricultural N₂O emissions and improved emissions assessments.     

Chromium (D-phenylalanine)3 improves obesity-induced cardiac contractile defect in ob/ob mice

Objective: Low‐molecular weight chromium compounds, such as chromium picolinate [Cr(pic)₃], improve insulin sensitivity, although toxicity is a concern. We synthesized a novel chromium complex, chromium (d ‐phenylalanine)₃ [Cr(d ‐phe)₃], in an attempt to improve insulin sensitivity with reduced toxicity. The aim of this study was to compare the two chromium compounds on cardiac contractile function in ob/ob obese mice. Research Methods and Procedures: C57BL lean and ob/ob obese mice were randomly divided into three groups: H₂O, Cr(d ‐phe)₃, or Cr(pic)₃ (45 µg/kg per day orally for 6 months). Results: The glucose tolerance test displayed improved glucose clearance by Cr(d ‐phe)₃ but not Cr(pic)₃. Myocytes from ob/ob mice exhibited depressed peak shortening (PS) and maximal velocity of shortening/relengthening (±dL/dt), prolonged time‐to‐PS and time‐to‐90% relengthening (TR90), reduced electrically stimulated rise in intracellular Ca²⁺ (Δfura‐2 fluorescence intensity), and slowed intracellular Ca²⁺ decay. Although a 3‐month Cr(d ‐phe)₃ treatment for a separate group of ob/ob and lean 2‐month‐old mice only rectified reduced ±dL/dt in ob/ob mice, all mechanical and intracellular Ca²⁺ abnormalities were significantly attenuated or ablated by 6 months of Cr(d ‐phe)₃ but not Cr(pic)₃ treatment (except TR90). Sarco(endo)plasmic reticulum Ca²⁺ ATPase activity and Na⁺‐Ca²⁺ exchanger expression were depressed in ob/ob mice, which were reversed by both Cr(d ‐phe)₃ and Cr(pic)₃, with a more pronounced effect from Cr(d ‐phe)₃. Cr(d ‐phe)₃ corrected reduced insulin‐stimulated glucose uptake and improved basal phosphorylation of Akt and insulin receptor, as well as insulin‐stimulated phosphorylation of Akt and insulin receptor in ob/ob myocytes. Heart homogenates from ob/ob mice had enhanced oxidative stress and protein carbonyl formation compared with the lean group, which were attenuated by both Cr(d ‐phe)₃ and Cr(pic)₃. Discussion: Our data suggest that the new Cr(d ‐phe)₃ compound possesses better cardio‐protective and insulin‐sensitizing properties against obesity.     

Altered intracellular calcium fluxes in pancreatic cancer induced diabetes mellitus: Relevance of the S100A8 N‐terminal peptide (NT‐S100A8)

After isolating NT‐S100A8 from pancreatic cancer (PC) tissue of diabetic patients, we verified whether this peptide alters PC cell growth and invasion and/or insulin release and [Ca²⁺]_i oscillations of insulin secreting cells and/or insulin signaling. BxPC3, Capan1, MiaPaCa2, Panc1 (PC cell lines) cell growth, and invasion were assessed in the absence or presence of 50, 200, and 500 nM NT‐S100A8. In NT‐S100A8 stimulated β‐TC6 (insulinoma cell line) culture medium, insulin and [Ca²⁺] were measured at 2, 3, 5, 10, 15, 30, and 60 min, and [Ca²⁺]_i oscillations were monitored (epifluorescence) for 3 min. Five hundred nanomolars NT‐S100A8 stimulated BxPC3 cell growth only and dose dependently reduced MiaPaCa2 and Panc1 invasion. Five hundred nanomolars NT‐S100A8 induced a rapid insulin release and enhanced β‐TC6 [Ca²⁺]_i oscillations after both one (F = 6.05, P < 0.01) and 2 min (F = 7.42, P < 0.01). In the presence of NT‐S100A8, [Ca²⁺] in β‐TC6 culture medium significantly decreased with respect to control cells (F = 6.3, P < 0.01). NT‐S100A8 did not counteract insulin induced phosphorylation of the insulin receptor, Akt and IκB‐α, but it independently activated Akt and NF‐κB signaling in PC cells. In conclusion, NT‐S100A8 exerts a mild effect on PC cell growth, while it reduces PC cell invasion, possibly by Akt and NF‐κB signaling, NT‐S100A8 enhances [Ca²⁺]_i oscillations and insulin release, probably by inducing Ca²⁺ influx from the extracellular space, but it does not interfere with insulin signaling. J. Cell. Physiol. 226: 456–468, 2011. © 2010 Wiley‐Liss, Inc.     

Substrate Specificity of a Sulfhydryl Protease Purified from Germinating Corn

Substrate specificity of a sulfhydryl protease (P-Ia) purified from germinating corn was investigated by using synthetic substrates and oxidized insulin B-chain. P-Ia showed a potent activity for p-nitrophenyl esters of various amino acid derivatives, except for those of carbo- benzoxy-L-proline and carbobenzoxy-L-valine. Benzoylarginine-β-naphthylamide, a good substrate for papain and cathepsin Bl, was not hydrolyzed by P-Ia. An investigation with acyl dipeptides showed that P-Ia hydrolyzed preferably the peptide bond adjacent to the carboxyl group of the aromatic amino acid. Oxidized insulin B-chain was hydrolyzed at the peptide bonds Gln⁴-His⁵, Glu¹³-Ala¹⁴, Ala¹⁴-Leu¹⁵, Leu¹⁵-Tyr¹⁶, Tyr¹⁶-Leu¹⁷ and Tyr²⁶- Thr²⁷. P-Ia, in spite of a sulfhydryl protease, seems to be characterized by its similarity to pepsin rather than papain, as far as the substrate specificity studied in the present work is concerned.     

Cyclic AMP metabolism and insulin release in pancreatic islets of the rat Effects of agents which alter microtubular function

In order to investigate the relationship between microtubular function, insulin release and islet cyclic AMP metabolism, the effects of ²H₂O, colchicine and vincristine were studied in rat islets prelabeled with [³H]adenine. Glucose-induced insulin secretion and efflux of cyclic [³H]AMP was markedly inhibited by 8–50% ²H₂O. At a higher concentration (75%), deuterated water still suppressed insulin release, while the inhibition of nucleotide release was abolished. Glucose-induced intra-islet cyclic [³H]AMP accumulation was augmented by ²H₂O progressively with time. With 75% ²H₂O, although efflux of cyclic AMP was no more inhibited, intra-islet accumulation of the nucleotide was still enhanced. The cyclic AMP efflux induced by cholera toxin, or a high concentration of 3-isobutyl-1-methylxanthine was suppressed and the intra-islet nucleotide accumulation was enhanced by ²H₂O. The latter effect tended to be less pronounced than when glucose was the stimulator. All the effects of ²H₂O on glocuse-stimulated islets were mimicked by incubating the tissue in H₂O at 28°C.Colchicine and vincristine had no significant effect on glucose-induced insulin release, and did not enhance the intra-islet cyclic [³H]AMP response; efflux of the nucleotide was, however, significantly inhibited. This pattern of response was shared with probenecid. Preincubation of islets with colchicine did not influence the subsequent effects of ²H₂O on insulin release and cyclic AMP metabolism.It is concluded that: (1) enhancement of intra-islet cyclic AMP accumulation by ²H₂O is not due to inhibition of the nucleotide efflux; (2) the effects on cyclic AMP metabolism described here are not exclusive for microtubular affecting agents and do not seem to be related to the microtubular system of the islet.     

Structural and biological properties of the Drosophila insulin-like peptide 5 show evolutionary conservation

We report the crystal structure of two variants of Drosophila melanogaster insulin-like peptide 5 (DILP5) at a resolution of 1.85 Å. DILP5 shares the basic fold of the insulin peptide family (T conformation) but with a disordered B-chain C terminus. DILP5 dimerizes in the crystal and in solution. The dimer interface is not similar to that observed in vertebrates, i.e. through an anti-parallel β-sheet involving the B-chain C termini but, in contrast, is formed through an anti-parallel β-sheet involving the B-chain N termini. DILP5 binds to and activates the human insulin receptor and lowers blood glucose in rats. It also lowers trehalose levels in Drosophila. Reciprocally, human insulin binds to the Drosophila insulin receptor and induces negative cooperativity as in the human receptor. DILP5 also binds to insect insulin-binding proteins. These results show high evolutionary conservation of the insulin receptor binding properties despite divergent insulin dimerization mechanisms.     

Initial site of cleavage towards oxidized B-chain of insulin by thermophilicStreptomyces alkaline proteinase

The initial site of cleavage towards the oxidized B-chain of insulin by thermophilicStreptomyces alkaline proteinase (EC 3.4.21.14) was investigated. The most susceptible bond was between Leu¹⁵ and Tyr¹⁶. Additional cleavage of the bonds Leu¹¹-Val¹², Leu¹⁷-Val¹⁸, and Gln⁴-His⁵ were noted. The results suggested that the specificity of bond, cleavage of thermophilicStreptomyces alkaline proteinase is close to that of subtilisin Carlsberg.