The synthesis of [A 19-3-iodotyrosine] and [A 19-3,5-diiodotyrosine]insulin (porcine)

The chemical synthesis of [Tyr(I)A19] and [Tyr(I2)A19]insulin (porcine), using the amino-acid derivatives 3-iodotyrosine and 3,5-diiodotyrosine is described. The synthesis of the iodinated A-chains were performed by segment condensation in solution using acid labile protecting groups. The hydroxyl groups of Tyr(I) and Tyr(I2) were unprotected. For the temporary protection of the alpha-amino groups of the A-chain segments containing iodinated tyrosines, the 1-(4-biphenylyl)-1-methylethoxycarbonyl group was selected. After deprotection and sulphitolysis the iodinated A-chain tetra-S-sulphonates were purified by ion exchange chromatography on DEAE cellulose at pH 5.6. Reduction to the sulphhydryl form and the combination with native porcine B-chain yielded [Tyr(I)A19] and [Tyr(I2)A19]insulin (porcine), respectively. Purification of the first product was achieved by gel filtration and of the later by ion exchange chromatography on CM-cellulose at pH 4.5 and gel filtration. The monoiodinated insulin had a biological activity of 24 +/- 2% and the diiodinated analogue 2.6 +/- 0.2% as determined in an in vitro lipogenesis assay with epididymal adipocytes.     

B17-D-leucine]insulin and [B17-norleucine]insulin: synthesis and biological properties

The chemical synthesis of two porcine insulin analogues is described. Leucine in position B17 of the native molecule was substituted by its D-enantiomer and by L-norleucine, respectively. Both B-chain derivatives were synthesized by fragment condensation and purified as di-S-sulphonates by gel filtration followed by ion exchange chromatography on SP-Sephadex at pH3. Combination with native sulphhydryl A-chain yielded [DLeuB17]insulin and [NleB17]insulin. Both insulin analogues were isolated by gel filtration followed by ion exchange chromatography on CM-cellulose at pH 4.0. Biological activities of the analogues were determined relative to native pork insulin: 1) glucose oxidation in rat epididymal adipocytes was 6% for [DLeuB17]insulin and 16% for [NleB17]insulin, 2) receptor-binding affinity tested with cultured human fibroblasts and with rat adipocytes was 3% for [DLeuB17]insulin and 26% for [NleB17]insulin, and 3) thymidine incorporation into DNA of human fibroblasts was 35% for [DLeuB17]insulin and 100% for [NleB17]insulin.     

B22-D-arginine]insulin: synthesis and biological properties

An analogue of porcine insulin which differs from the native molecule in that the amino-acid residue B22-L-arginine is replaced by its D-enantiomer has been synthesized. The [D ArgB22]B-chain was synthesized by the segment condensation method and purified as the di-S-sulfonate by ion exchange chromatoggraphy on SP-Sephadex at pH 3.5. Combination with native porcine sulfhydryl A-chain gave [DArgB22]insulin which was purified by ion exchange chromatography on SP-Sephadex at pH 4.5 with a linear NaCl gradient. The biological activity of this analogue as measured by glucose oxidation in rat epididymal adipocytes was 2%. Thymidine incorporation into DNA of human fibroblast was 16%. The immunoreactivity using antipork insulin antibody in a double antibody immunoassay was 4%. The receptor-binding affinity as measured by radioreceptor assays was 2% with cultured human fibroblasts and 1% with rat adipocytes. These results suggest that the L-configuration at B22-arginine is essential for retaining the biological, immunological and receptor-binding properties of the hormone.     

Porcine tissue plasminogen activator. Immunoaffinity purification, structural properties and glycosylation pattern

Tissue plasminogen activator was purified in high yield from pig heart by immunoaffinity chromatography and characterized by analysis of the glycosylation pattern and the N-terminal amino acid sequence. Comparisons with the human enzyme reveals residue exchanges in the A-chain at positions 3 (porcine Arg/human Gln) and 5 (Thr/Ile), and in the B-chain at positions 6 (Tyr/Phe), 10 (Thr/Ala) and 20 (Val/Ala). The glycosylation pattern for the porcine activator was determined by endoglycosidase treatment followed by gel electrophoresis. The A-chain contains a single high-mannose type of N-linked glycan structure and the B-chain contains a complex type of oligosaccharide. A similar but not identical pattern has been observed for the human activator, purified from melanoma cells.     

Opossum insulin, glucagon and pancreatic polypeptide: Amino acid sequences

Pancreatic hormones have been purified from the opossum, a New World marsupial. Opossum insulin contains a Leu substitution at the N-terminus of the B-chain in place of the Phe that is generally present in mammalian insulins. In addition, there are two other amino acid substitutions in the opossum insulin A-chain (positions 8 and 18) compared to pig insulin. Opossum glucagon is identical to chicken glucagon with both differing from the usual mammalian glucagon by Ser in place of Asn at its penultimate C-terminal position. Opossum PP differs from the porcine peptide in only 3 sites (position 3, 19 and 30).     

Met-Lys-双C肽人胰岛素原基因的构建表达及分离纯化

应用 Ｐ Ｃ Ｒ 定点突变方法构建编码 Ｍ ｅｔ Ｌｙｓ 双 Ｃ 肽人胰岛素原基因,并在大肠杆菌中以包含体方式获得表达 表达产物经还原、重组、 Ｓｅｐｈａｄｅｘ Ｇ ７５ 分离纯化,获得 Ｍ ｅｔ Ｌｙｓ 双 Ｃ 肽人胰岛素原,经胰蛋白酶与羧肽酶 Ｂ的酶解, Ｒｅｓｏｕｒｃｅ Ｔ Ｍ Ｑ 阴离子交换柱层析分离制备得人胰岛素,其放免活性、受体结合活性均与猪胰岛素相同      

The A14 position of insulin tolerates considerable structural alterations with modest effects on the biological behavior of the hormone

As part of our aim to investigate the contribution of the tyrosine residue found in the 14 position of the A-chain to the biological activity of insulin, we have synthesized six insulin analogues in which the A14 Tyr has been substituted by a variety of amino acid residues. We have selected three hydrophilic and charged residues—glutamic acid, histidine, and lysine—as well as three hydrophobic residues—cycloleucine, cyclohexylalanine, and naphthyl-(1)-alanine—to replace the A14 Tyr. All six analogues exhibit full agonist activity, reaching the same maximum stimulation of lipogenesis as is achieved with procine insulin. The potency for five of the six analogues, [A14 Glu]-, [A14 His]-, [A14 Lys]-, [A14 cycloleucine]-, and [A14 naphthyl-(1)-alanine]-insulins in receptor binding assays ranges from 40–71% and in stimulation of lipogenesis ranges from 35-120% relative to porcine insulin. In contrast, the potency of the sixth analogue, [A14 cyclohexylalanine]insulin, in both types of assays is less than 1% of the natural hormone. The retention time on reversed-phase high-performance liquid chromatography for the first five analogues is similar to that of bovine insulin, whereas for the sixth analogue, [A14 cyclohexylalanine]insulin, it is approximately 11 min longer than that of the natural hormone. This suggests a profound change in conformation of the latter analogue. Apparently, the A14 position of insulin can tolerate a wide latitude of structural alterations without substantial decrease in potency. This suggests that the A14 position does not participate directly in insulin receptor interaction. Only when a substitution which has the potential to disrupt the conformation of the molecule is made at this position, is the affinity for the receptor, and hence the biological potency, greatly reduced.     

The formylpeptide chemotactic receptor on rabbit peritoneal neutrophils. I. Evidence for two binding sites with different affinities

F Met-Leu-[3H]Phe and f Nle-Leu-[3H]Phe binding to rabbit peritoneal neutrophils and purified membranes were measured at 4 degrees C silicone oil centrifugation assays, and the results were analyzed by the LIGAND computer program, which permits analysis of ligand binding to multiple classes of binding sites. LIGAND analysis of peptide binding to intact neutrophil indicated that both f Met-Leu-[3H]Phe and f Nle-Leu-[3H]Phe detected two population of binding sites. The apparent Kd values for f Met-Leu-[3H]Phe binding were 1.6 +/- 1.0 X 10(-9) M and 2.2 +/- 0.9 X 10(-8) M, respectively, and 3.1 +/- 0.2 X 10(-9) M and 1.2 +/- 0.6 X 10(-7) M for f Nle-Leu-[3H]Phe. Furthermore, the higher affinity sites detected on whole cells comprised approximately 15 to 30% of the total sites. Two populations of binding sites were also detected on purified neutrophil plasma membranes by both radiolabeled chemotactic peptides. LIGAND analysis of peptide binding to purified membranes yielded apparent Kd values of 5.0 +/- 2.5 X 10(-10) M and 4.8 +/- 0.6 X 10(-8) M for f Met-Leu-[3H]Phe binding, and 4.7 +/- 4.2 X 10(-10) M and 3.0 +/- 1.3 X 10(-8) M for f Nle-Leu-[3H]Phe. The percentage of higher affinity sites detected by f Met-Leu-[3H]Phe and f Nle-Leu-[3H]Phe on purified membranes were 1 to 5% of the total sites detected. These data are consistent either with the existence of two independent binding sites for formylpeptides on rabbit neutrophils or receptor negative cooperativity.     

Semisynthetic sheep des-A1-glycine insulin (author's transl)]

The synthetic Des-1-glycine-A-chain of sheep insulin as the monomeric cyclic bisdisulfide and native bovine B-chain bissulfonate were reduced together with mercaptoethanol. They combined at pH 10.6 to yield Des-A1-glycine-insulin. This was purified by gel and ion exchange chromatography. The low insulin activity (0.4 - 0.6%) as measured by the fat cell test as well as the change in the CD spectrum indicated that the loss of the N-terminal glycine of the A-chain results in fully inactive insulin. This confirms the results obtained earlier by partial synthesis of Des-A1-glycine-insulin.     

Contribution of the B16 and B26 tyrosine residues to the biological activity of insulin

We report the synthesis and biological evaluation of five insulin analogues in which one or both of the B-chain tyrosine residues have been substituted. [B16 Phe]insulin and [B16 Trp]insulin display a very modest reduction in potency (c. 65%) relative to porcine insulin; [B26 Phe]insulin is less active (30–50%), and the doubly substituted [B16 Phe, B26 Phe]insulin displays still lower potency (c. 35%). The further substitution of Asp for B10 His in [B16 Phe, B26 Phe]insulin raises its activity to approximately twofold greater than natural insulin, an increase of approximately fivefold over the parent compound. We conclude that the bulk and/or aromaticity of the amino acid residue at position B16, but not its hydrogen-bonding capacity, contributes to the biological activity of the hormone. We further conclude that hydrogen-bonding capacity or special side-chain packing characteristics are required at the B26 position for insulin to display high biological activity.     

Purification of an insulin-related factor secreted by a teratoma-derived mesodermal cell line

Insulin-related factor (IRF), a polypeptide secreted by the mouse teratoma-derived cell line (1246-3A), was purified 3210-fold to homogeneity from 1246-3A conditioned medium using a rapid three-step procedure including cation-exchange chromatography, immunoaffinity chromatography using a monoclonal antibody against porcine insulin coupled to an agarose gel support, and reverse phase high performance liquid chromatography. 10 micrograms of IRF was purified from 6 liters of 1246-3A conditioned medium. Pure IRF appeared as a single band with the same mobility as insulin by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. IRF stimulates cell proliferation of insulin-dependent cell line 1246 and competes with 125I-insulin for binding to 1246 cells; half-maximal growth stimulation and binding competition were achieved at an IRF concentration of 6.5 ng/ml (1.3 nM) and 25 ng/ml (4 nM), respectively, comparable with those for bovine insulin. The biochemical, biological, and immunological characteristics of IRF, as well as its amino acid composition, strongly suggest that it is closely related to pancreatic insulin in structure and function.     

The effect of placement of tryptophan residues in selected A-chain positions on the biological profile of insulin

In continuation of our efforts to study the solution structure and conformational dynamics of insulin by time-resolved fluorescence spectroscopy, we have synthesized and examined the biological activity of five insulin analogues in which selected naturally occurring residues in the A-chain have been replaced with the strongly fluorescent tryptophan residue. The potency of these analogues was evaluated in lipogenesis assays in isolated rat adipocytes, in receptor binding assays using rat liver plasma membranes, and in two cases, in receptor binding assays using adipocytes. [A3 Trp]insulin displays a potency of 3% in receptor binding assays in both liver membranes and in adipocytes, but only 0.06% in lipogenesis assays as compared to porcine insulin. [A10 Trp] insulin displays a potency ofca. 40% andca. 25% in rat liver receptor binding and lipogenesis assays, respectively. [A13 Trp]insulin displays a potency ofca. 39% in rat liver receptor binding assays, but onlyca. 9% in receptor binding in adipocytes; in lipogenesis assays, [A13 Trp] insulin displays a potency ofca. 12%, comparable to its potency in adipocyte receptor binding assays. [A15 Trp]insulin exhibits a potency of 18% and 9% in rat liver receptor binding and lipogenesis assays, respectively. The doubly substituted analogue, [A14 Trp, A19 Trp] insulin, displays a potency ofca. 0.7% in both rat liver receptor binding assays and lipogenesis assays. These data suggest two major conclusions: (1) the A3 and A15 residues lie in sensitive regions in the insulin molecule, and structural modifications at these positions have deleterious effects on biological activity of the hormone; and (2) [A13 Trp]insulin appears to be a unique case in which an insulin analogue exhibits a higher potency when assayed in liver tissue than when assayed in fat cells.     

Synthesis of two neuromedin U (NMU) analogues and their comparative effect of reducing food intake in rats

To examine the roles of aromatic rings, Tyr residues at positions 1 and 5 and Phe residues at positions 16, 17, and 19 of rat neuromedin U-23 (NMU-23) (Tyr-Lys-Val-Asn-Glu-Tyr-Gln-Gly-Pro-Val-Ala-Pro-Ser-Gly-Gly-Phe-Phe-Leu-Phe-Arg-Pro-Arg-Asn-NH2) for reducing food intake activity in male Wistar rats, two NMU-23 analogues, [Phe(4F)16,17,19] NMU-23 and [Tyr(Me)1,6]NMU-23, were synthesized by Fmoc strategy of manual solid-phase method. The synthetic NMU-23 showed reducing effect on food intake in rats. [Phe(4F)16,17,19]NMU-23 exhibited higher reducing food in take effect than that of NMU-23. On the contrary, [Tyr(- Me)1,6]NMU-23 showed no reducing effect on food intake in rats than that of NMU-23.     

Degradation of the four monoiodoinsulin isomers by the insulin protease of rat liver

The cleavage of insulin by the partially purified insulin protease was studied using the four [¹²⁵I]tyrosine-monoiodoinsulins (tyrosine A-14 and A-19 of the A-chain; tyrosine B-16 and B-26 of the B-chain). The rates of conversion of the four isomers to trichloroacetic acid-soluble form was in the order B-26 > A-14 > A-19 > B-16. The following was observed in experiments which gave 19/14/5/3 percent conversion to trichloroacetic acid-soluble products: the loss of ability to bind to IM-9 lymphocytes was approx. 55% for all four isomers. About 70% of the radioactivity was in the ‘insulin’ peak, and about 30% was in peptides smaller than insulin as judged by gel filtration on Sephadex G-50. The descending limb of the ‘insulin’ peak contained significant amounts of radioactive material not binding to IM-9 lymphocytes. This material showed multiple peaks when applied to high performance liquid chromatography. Other experiments were designed to cause an almost complete degradation of the isomers. Under these conditions, the radioactivity eluted on Sephadex G-50 largely as iodotyrosine (and some small peptides) using the A-14, B-16 and B-26 isomers, whereas iodotyrosine was absent using the A-19 isomer. Thus, the insulin protease appears to first degrade insulin to multiple products with molecular sizes slightly smaller than insulin and subsequently to small peptides (e.g. containing tyrosine A-19) and amino acids (e.g. tyrosine A-14, B-16 and B-26).     

Synthesis and characterization of new radioligands for the mammalian melanin-concentrating hormone (MCH) receptor

Melanin-concentrating hormone (MCH) is a neuropeptide present in the brain of all vertebrates. For the characterization of MCH receptors, a monoiodinated [Phe13, Tyr19]-MCH radioligand analogue was developed. The high susceptibility of [125I]-[Phe13, Tyr19]-MCH to oxidative damage and its very lipophilic nature made it necessary to develop new MCH radioligands. To increase the stability, native methionines were replaced by non-sulphur containing amino acid residues. In one analogue, the L-enantiomer of the phenylalanine residue at position 13 was substituted by the D-enantiomer, which increased the relative affinity of the ensuing [125I]-[D-Phe13, Tyr19]-MCH about 7-fold. The different analogues were iodinated by an enzymatic reaction and used for binding studies with mouse melanoma cells. [125I]-[Met(O)4,8, Phe13, Tyr19]-MCH and [125I]-[Hse4,8, Phe13, Tyr19]-MCH showed only about 19% of total binding and [125I]-[Ser4,8, Phe13, Tyr19]-MCH displayed about 44% of total binding when compared with [125I]-[Phe13, Tyr19]-MCH. Non-specific binding for all tracers was below 11% of total binding of [125I]-[Phe13, Tyr19]-MCH binding. [125I]-[D-Phe13, Tyr19]-MCH was used for saturation binding studies and revealed a KD of 122.7 +/- 15.3 pmol/l. This radioligand was further characterized by association and dissociation binding studies.     

The effect of iodination of particular tyrosine residues on the hormonal activity of insulin

Insulin dissolved in aqueous or methanolic buffer was iodinated to give preparations containing an average of between one and five iodine atoms per insulin monomer. The resultant preparations were fragmented in various ways and the ratio of tyrosine to monoiodotyrosine and di-iodotyrosine was determined in each fragment. This has allowed the distribution of iodine between the combined A-chain tyrosine residues and the individual B-chain tyrosine residues to be determined. The hormonal activity of each of these iodinated insulin preparations was measured from their effect on the production of (14)CO(2) from [1-(14)C]glucose by isolated adipose cells. The results were interpreted as meaning that the iodination of tyrosine residue A19 or B16 leads to the inactivation of insulin. Speculations are made about the nature of an interaction between insulin and a receptor site on the target tissue.     

Mutants of human insulin-like growth factor I with reduced affinity for the type 1 insulin-like growth factor receptor

Four mutants of human insulin-like growth factor I (hIGF I) have been purified from the conditioned media of yeast transformed with an expression vector containing a synthetic gene for hIGF I altered by site-directed mutagenesis. hIGF I has the sequence Phe-23-Tyr-24-Phe-25 which is homologous to a region in the B-chain of insulin. [Phe23,Phe24,Tyr25]IGF I, in which the sequence is altered to exactly correspond to the homologous sequence in insulin, is equipotent to hIGF I at the types 1 and 2 IGF and insulin receptors. [Leu24]IGF I and [Ser24]IGF I have 32- and 16-fold less affinity than hIGF I at the human placental type 1 IGF receptor, respectively. These peptides are 10- and 2-fold less potent at the placental insulin receptor, respectively. [Leu24]IGF I and [Ser24]IGF I have similarly reduced affinities for the type 1 IGF receptor of rat A10 and mouse L cells. Thus, the importance of the interaction of residue 24 with the receptor is conserved in several species. In three cell-based assays, [Leu24]IGF I and [Ser24]IGF I are full agonists with reduced efficacy compared to hIGF I. Desoctapeptide [Leu24]IGF I, in which the loss of aromaticity at position 24 is combined with the deletion of the carboxyl-terminal D region of hIGF I, has 3-fold lower affinity than [Leu24]IGF I for the type 1 receptor and 2-fold higher affinity for the insulin receptor.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of a substrate specificity switch residue of cephalosporin acylase

Residue Phe375 of cephalosporin acylase has been identified as one of the residues that is involved in substrate specificity. A complete mutational analysis was performed by substituting Phe375 with the 19 other amino acids and characterising all purified mutant enzymes. Several mutations cause a substrate specificity shift from the preferred substrate of the enzyme, glutaryl-7-ACA, towards the desired substrate, adipyl-7-ADCA. The catalytic efficiency ( [Formula: see text] (cat)/ [Formula: see text] (m)) of mutant SY-77(F375C) towards adipyl-7-ADCA was increased 6-fold with respect to the wild-type enzyme, due to a strong decrease of [Formula: see text] (m). The [Formula: see text] (cat) of mutant SY-77(F375H) towards adipyl-7-ADCA was increased 2.4-fold. The mutational effects point at two possible mechanisms by which residue 375 accommodates the long side chain of adipyl-7-ADCA, either by a widening of a hydrophobic ring-like structure that positions the aliphatic part of the side chain of the substrate, or by hydrogen bonding to the carboxylate head of the side chain.     

Identification of residues in the insulin molecule important for binding to insulin-degrading enzyme

Insulin-degrading enzyme (IDE) hydrolyzes insulin at a limited number of sites. Although the positions of these cleavages are known, the residues of insulin important in its binding to IDE have not been defined. To this end, we have studied the binding of a variety of insulin analogues to the protease in a solid-phase binding assay using immunoimmobilized IDE. Since IDE binds insulin with 600-fold greater affinity than it does insulin-like growth factor I (25 nM and approximately 16,000 nM, respectively), the first set of analogues studied were hybrid molecules of insulin and IGF I. IGF I mutants [insB1-17,17-70]IGF I, [Tyr55,Gln56]IGF I, and [Phe23,Phe24,Tyr25]IGF I have been synthesized and share the property of having insulin-like amino acids at positions corresponding to primary sites of cleavage of insulin by IDE. Whereas the first two exhibit affinities for IDE similar to that of wild type IGF I, the [Phe23,Phe24,Tyr25]IGF I analogue has a 32-fold greater affinity for the immobilized enzyme. Replacement of Phe-23 by Ser eliminates this increase. Removal of the eight amino acid D-chain region of IGF I (which has been predicted to interfere with binding to the 23-25 region) results in a 25-fold increase in affinity for IDE, confirming the importance of residues 23-25 in the high-affinity recognition of IDE. A similar role for the corresponding (B24-26) residues of insulin is supported by the use of site-directed mutant and semisynthetic insulin analogues. Insulin mutants [B25-Asp]insulin and [B25-His]insulin display 16- and 20-fold decreases in IDE affinity versus wild-type insulin.(ABSTRACT TRUNCATED AT 250 WORDS)