[B10,22-Asp,B25-Tyr-NH2]-去β链C端五肽胰岛素的合成和性质

本文报道了[B10,22-Asp,B25-Tyr-NH2]-去B链羧端五肽胰岛素的制备及其生物活性。结果表明,这一类似物的生物活力比去五肽胰岛素(DPI)的活力高一倍,但却比Gerald所报道的[B10-Asp,B25-Tyr-NH_2]-DPI的活力低很多,说明后者的高活性可能依赖于分子中B22-Arg的存在。     

Semisynthetic des-(B27-B30)-insulins with modified B26-tyrosine

Semisynthetic des-(B27-B30)-insulins containing modified B26-tyrosine residues were prepared to refine the understanding of the importance of position B26 with regard to biological and structural properties of the hormone. The following shortened insulin analogues were synthesized by trypsin-catalysed peptide-bond formation between the C-terminal amino acid ArgB22 of des-(B23-B30)-insulin and synthetic tetrapeptides as amino components: des-(B27-B30)-insulin, des-(B27-B30)-insulin-B26-methyl ester, -B26-carboxamide with varying C-terminal hydrophobicity of the B-chain, and [Tyr(NH2)B26]-, [Tyr(NO2)B26]-, [Tyr(I2)B26]-, [D-TyrB26]des-(B27-B30)-insulin-B26-carboxamide containing non-proteinogenic amino acids in position B26. Starting from insulin and an excess of synthetic Gly-Phe-Phe-Tyr-OMe as nucleophile, des-(B27-B30)-insulin-B26-methyl ester--the formal transpeptidation product at ArgB22--was formed in one step. Biological in vitro properties (binding to cultured human IM-9 lymphocytes, relative lipogenic potency in isolated rat adipocytes) of all semisynthetic analogues are reported, ranging from slightly decreased to two-fold receptor affinity and nearly three-fold biopotency relative to insulin. If the C-terminal tetrapeptide B27-B30 is removed, full relative insulin activity is still preserved, while the shortening results in the loss of ability to associate in solution. Only after carboxamidation or methyl esterification of TyrB26 the self-association typical of native insulin can be observed, and the CD-spectral effects in the near UV spectrum related to association and hexamerization of the native hormone are qualitatively reestablished. The results of this investigation underline the importance of position B26 to the modulation of hormonal properties and solution structure of the shortened insulins.     

Self-association of des-(B26-B30)-insulin. The effect of Ca2+ and some other divalent cations

It has been confirmed by sedimentation equilibrium and sedimentation velocity experiments that des-(B26-B30)-insulin does not self-associate at neutral pH. Sedimentation equilibrium experiments at pH 7, 25 degrees C were conducted to investigate the effects of the structurally and physiologically important divalent cations Zn2+, Cd2+, Pb2+ and Ca2+ on the aggregation state of des-(B26-B30)-insulin (pig) in solution. It was found that all of these ions bring about association of this insulin analogue; Zn2+ and Cd2+ to a more marked degree than Pb2+ and Ca2+. The predominant species in solutions containing Zn2+ appear to be hexamers and hexameric aggregates, in those containing Cd2+, species up to and including tetramers, and in those containing Pb2+ and Ca2+, monomers and dimers of des-(B26-B30)-insulin appear to be the only species present. The possible significance of these findings, especially in relation to a role for Ca2+ in the action of insulin, is discussed.     

1H n.m.r. studies of insulin. Assignment of resonances and properties of tyrosine residues.

The assignment of the aromatic 1H n.m.r. resonances of the four tyrosine residues of bovine 2-zinc insulin is reported, based on double resonance techniques, use of Hahn spin echo pulse sequences and examination of specific derivatives nitrated at tyrosines A14 and A19 as well as des-(B26-B30)-insulin. Titration curves of the four tyrosine residues show that residues A14 and B16 have normal pK' values of 10.3-10.6 in solution, consistent with their accessibility to solvent in monomer and dimer in the crystal. Tyrosine residues A19 and B26 have pK' values of 11.4 and exhibit other features in their titration curves that are consistent with limited accessibility to solvent and a nonpolar environment. The meta protons of residues B16 and B26 both observe the titration of a nearby tyrosine residue, probably A19. Interpretation of the n.m.r. data obtained in solution is consistent with the crystallographic data for the monomer and dimer obtained on insulin crystals [Blundell, Dodson, Hodgkin & Mercola (1972) Adv. Protein Chem. 26, 279-402].     

Structure-function relationships of shortened [LeuB25]insulins, semisynthetic analogues of a mutant human insulin

Replacement of B25-phenylalanine by leucine in the insulin sequence causes marked inactivation. The effect of this sequence variation was studied here in des-(B26-30)-insulin. [LeuB25]des-(B26-30)-insulin and its B25-amide were prepared by trypsin-mediated semisynthesis from N-terminally protected des-(B23-30)-insulin and synthetic tripeptides. The relative lipogenic potency in isolated rat adipocytes was 8.0% for the truncated analogue with a free B25-carboxyl function, and 18.1% for the amidated analogue. Binding to cultured human IM-9 lymphocytes was 4% and 9%, respectively. Thus, both shortened insulins are markedly more active than [LeuB25]insulin. The PheB25----LeuB25 substitution in both the shortened and the full sequence has a moderate effect on the CD spectrum, indicating that the gross main chain conformation is largely retained in both molecules. Independent of the substitution an absolute increase of the circular dichroism is observed upon amidation of the B25-carboxyl group.     

Comparison of reaction rates in trypsin-catalysed transamidation of porcine insulin and its B29-arginine analogue

[B29-Arginine]porcine insulin was prepared from des-(B23-30)-insulin and synthetic octapeptide with the aid of trypsin. Comparison of reaction rates in trypsin-catalysed transamidation of this compound and porcine insulin with threonine ether ester showed that this reaction is determined only by conformational effects and structural features of amino acids leaving from and entering into B30, not by the structure and the pKa value of the basic amino acid in B29.     

Synthesis of A7,B7-dicarbainsulin, an analogue with a noncleavable bond between A- and B-chain. II. Synthesis of the A-chain segments

As part of the total synthesis of [A7,B7-L,L-2,7-diaminosuberoyl]-des-(B26-B30)-insulin B25-amide, an insulin analogue containing a non-cleavable bond between A- and B-chain, the chemical synthesis of the A-chain segments is described. The N-terminal sequence A(1-6), Boc-Gly-Ile-Val-Glu(OBut)-Gln-Cys(SBut)-NH-NH2, was synthesized in solution. The middle segment A(8-16), Ddz-Thr(But)-Ser(But)-Ile-Cys(SBut)-Ser(But)-Leu-Tyr- (But)-Gln-Leu-NH-NH2, was obtained by solid phase synthesis according to the Fmoc strategy. The C-terminal segment A(17-21), Bpoc-Glu(OBut)-Asn-Tyr-Cys(Acm)-Asn-OBut, was prepared in solution.     

Three-dimensional solution structure of an insulin dimer. A study of the B9(Asp) mutant of human insulin using nuclear magnetic resonance, distance geometry and restrained molecular dynamics.

The solution structure of the B9(Asp) mutant of human insulin has been determined by two-dimensional 1H nuclear magnetic resonance spectroscopy. Thirty structures were calculated by distance geometry from 451 interproton distance restraints based on intra-residue, sequential and long-range nuclear Overhauser enhancement data, 17 restraints on phi torsional angles obtained from 3JH alpha HN coupling constants, and the restraints from 17 hydrogen bonds, and the three disulphide bridges. The distance geometry structures were optimized using restrained molecular dynamics (RMD) and energy minimization. The average root-mean-square deviation for the best 20 RMD refined structures is 2.26 A for the backbone and 3.14 A for all atoms if the less well-defined N and C-terminal residues are excluded. The helical regions are better defined, with root-mean-square deviation values of 1.11 A for the backbone and 2.03 A for all atoms. The data analysis and the calculations show that B9(Asp) insulin, in water solution at the applied pH (1.8 to 1.9), is a well-defined dimer with no detectable difference between the two monomers. The association of the two monomers in the solution dimer is relatively loose as compared with the crystal dimer. The overall secondary and tertiary structures of the monomers in the 2Zn crystal hexamer is found to be preserved. The conformation-averaged NMR structures obtained for the monomer is close to the structure of molecule 1 in the hexamer of the 2Zn insulin crystal. However, minor, but significant deviations from this structure, as well as from the structure of monomeric insulin in solution, exist and are ascribed to the absence of the hexamer and crystal packing forces, and to the presence of monomer-monomer interactions, respectively. Thus, the monomer in the solution dimer shows a conformation similar to that of the crystal monomer in molecular regions close to the monomer-monomer interface, whereas it assumes a conformation similar to that of the solution structure of monomeric insulin in other regions, suggesting that B9(Asp) insulin adopts a monomer-like conformation when this is not inconsistent with the monomer-monomer arrangement in the dimer.     

Two-dimensional NMR studies on des-pentapeptide-insulin. Proton resonance assignments and secondary structure analysis

The shortened analogue of insulin, des-(B26-B30)-pentapeptide insulin, has been characterized by two-dimensional 1H NMR. The 1H resonance assignments and the secondary structure in water solution are discussed The results indicate that the secondary structure in solution is very similar to that reported for the crystalline state. A high flexibility of both A and B chains is observed. Of the two conformations seen in the 2-Zn insulin crystals and indicated as molecules 1 and 2 (Chinese nomenclature), the structure of the analogue is more similar to that of molecule 1.     

Photoaffinity labelling of a nitrobenzylthioinosine-binding polypeptide from cultured Novikoff hepatoma cells.

Incubation of pig desoctapeptide-(B23-30)-insulin with trypsin in solvent systems consisting of dimethyl sulphoxide, butane-1,4-diol and Tris buffer resulted in the formation of an extra peptide bond between Arg-B22 and Gly-A1 in the DOPI molecule. This DOPI derivative can also be regarded as pig des-(23-63)-proinsulin. The structure of the new, previously unreported, proinsulin analogue was determined on the basis of amino acid analysis, dansylation and digestion with Staphylococcus aureus V8 proteinase. Receptor-binding ability of des-(23-63)-proinsulin was 20% of that of pig desoctapeptide-(B23-30)-insulin and 0.02% of that of pig insulin.     

High resolution 1H-NMR studies of Des-(B26-B30)-insulin; assignment of resonances and properties of aromatic residues

The assignments of 1H resonances of the eight aromatic residues of Des-(B26-B30)-insulin are reported, based on pH titration, selective spin decoupling and its 500 MHz 1H two-dimensional (2D)-COSY spectrum. The pK values of the three tyrosines A14, A19 and B16 are 10.84, 11.27 and 10.40, respectively. Tyrosine A19 is buried in a hydrophobic environment, while Tyrosine B16 is exposed in a relatively hydrophilic state. Among the three phenylalanines, the ring proton resonances of Phe-B25 undergo abnormal upfield shifts, probably due to the ring currents of the nearby Phe-B24 and Tyr-B16. From this study of the low-field region of 1H-NMR spectrum of Des-(B26-B30)-insulin, we conclude that this molecule probably maintains the major structural features of insulin in aqueous solution, but there are some readjustments of the peptide conformation.     

A comparison of the dynamic behavior of monomeric and dimeric insulin shows structural rearrangements in the active monomer

Molecular dynamics (MD) simulations (5-10ns in length) and normal mode analyses were performed for the monomer and dimer of native porcine insulin in aqueous solution; both starting structures were obtained from an insulin hexamer. Several simulations were done to confirm that the results obtained are meaningful. The insulin dimer is very stable during the simulation and remains very close to the starting X-ray structure; the RMS fluctuations calculated from the MD simulation agree with the experimental B-factors. Correlated motions were found within each of the two monomers; they can be explained by persistent non-bonded interactions and disulfide bridges. The correlated motions between residues B24 and B26 of the two monomers are due to non-bonded interactions between the side-chains and backbone atoms. For the isolated monomer in solution, the A chain and the helix of the B chain are found to be stable during 5ns and 10ns MD simulations. However, the N-terminal and the C-terminal parts of the B chain are very flexible. The C-terminal part of the B chain moves away from the X-ray conformation after 0.5-2.5ns and exposes the N-terminal residues of the A chain that are thought to be important for the binding of insulin to its receptor. Our results thus support the hypothesis that, when monomeric insulin is released from the hexamer (or the dimer in our study), the C-terminal end of the monomer (residues B25-B30) is rearranged to allow binding to the insulin receptor. The greater flexibility of the C-terminal part of the beta chain in the B24 (Phe-->Gly) mutant is in accord with the NMR results. The details of the backbone and side-chain motions are presented. The transition between the starting conformation and the more dynamic structure of the monomers is characterized by displacements of the backbone of Phe B25 and Tyr B26; of these, Phe B25 has been implicated in insulin activation.     

Nonlocal structural perturbations in a mutant human insulin: sequential resonance assignment and 13C-isotope-aided 2D-NMR studies of [PheB24-->Gly]insulin with implications for receptor recognition.

Insulin's mechanism of receptor binding is not well understood despite extensive study by mutagenesis and X-ray crystallography. Of particular interest are "anomalous" analogues whose bioactivities are not readily rationalized by crystal structures. Here the structure and dynamics of one such analogue (GlyB24-insulin) are investigated by circular dichroism (CD) and isotope-aided 2D-NMR spectroscopy. The mutant insulin retains near-native receptor-binding affinity despite a nonconservative substitution (PheB24-->Gly) in the receptor-binding surface. Relative to native insulin, GlyB24-insulin exhibits reduced dimerization; the monomer (the active species) exhibits partial loss of ordered structure, as indicated by CD studies and motional narrowing of selected 1H-NMR resonance. 2D-NMR studies demonstrate that the B-chain beta-turn (residues B20-23) and beta-strand (residues B24-B28) are destabilized; essentially native alpha-helical secondary structure (residues A3-A8, A13-A18, and B9-B19) is otherwise maintained. 13C-Isotope-edited NOESY studies demonstrate that long-range contacts observed between the B-chain beta-strand and the alpha-helical core in native insulin are absent in the mutant. Implications for the mechanism of insulin's interaction with its receptor are discussed.     

Phenol-promoted structural transformation of insulin in solution

Phenolic additives widely used for the preservation of insulin preparations can have a profound effect on the hormone's conformation in solution. m-Cresol, for instance, increases the circular dichroism in the far ultraviolet by 10-20%, corresponding to an increase in helix, and around 255 nm. The CD-spectral changes are strikingly similar to those brought about by halide ions which have been identified to reflect the 2 Zn----4 Zn insulin transition. Its most prominent element is the helix formation at the B-chain N-terminus. In both cases the changes fail to occur with dimeric insulin in the absence of Zn2 and with monomeric des-(B26-B30)-insulin. In the presence of Ni2 which is unable to replace Zn2 in 4 Zn insulin for coordinative reasons, the effect of m-cresol is impeded. m-Cresol thus induces a transition identical with or closely similar to the 2 Zn----4 Zn transformation. 2 Zn insulin crystals, when soaked in m-cresol containing solvents, are destroyed. Crystals grown in the presence of m-cresol, however, are monoclinic and containing symmetrical hexamers of, notably, 4 Zn conformation. Phenol, o- and p-cresol, m-nitrophenol, Nipagin M and benzene were further additives tested, all of them inducing largely the same spectral effects except for benzene. The results presented corroborate the close correspondence of insulin's structure in solution and in the crystal as well as insulin's capacity for structural variation.     

The use of Fmoc-Lys(Pac)-OH and penicillin G acylase in the preparation of novel semisynthetic insulin analogs.

In this paper, we present the detailed synthetic protocol and characterization of Fmoc-Lys(Pac)-OH, its use for the preparation of octapeptides H-Gly-Phe-Tyr-N-MePhe-Thr-Lys(Pac)-Pro-Thr-OH and H-Gly-Phe-Phe-His-Thr-Pro-Lys(Pac)-Thr-OH by solid-phase synthesis, trypsin-catalyzed condensation of these octapeptides with desoctapeptide(B23-B30)-insulin, and penicillin G acylase catalyzed cleavage of phenylacetyl (Pac) group from Nepsilon-amino group of lysine to give novel insulin analogs [TyrB25, N-MePheB26,LysB28,ProB29]-insulin and [HisB26]-insulin. These new analogs display 4 and 78% binding affinity respectively to insulin receptor in rat adipose membranes.     

TyrB26位点改变的人类胰岛素类似物的化学合成与体外活性

摘要：为了研究人类胰岛素B链第26位的酪氨酸对胰岛素和受体之间的结合的影响,包括单独的氨基酸替换或化合物替换的不同的胰岛素类似物被合成,其中化合物替代的类似物的B链C末端都减少了4个氨基酸。在对它们与胰岛素受体的亲和力进行研究中,结果发现它们与胰岛素受体的亲和力没有丢失, HisB26类似物和N-MeHisB26类似物的结合能力与胰岛素相比改变不大,分别是胰岛素的72 %和107 %。N-MeGluB26类似物,AadB26类似物和Phe (4-carboxy) B26类似物的结合能力有很大的提高,分别是130 %, 234 %和160 %。     

FTIR studies of secondary structures of bovine insulin and its derivatives

The amide I bands of the deconvolved FTIR spectrum of bovine insulin, despentapeptide (B26-B30) insulin and desoctapeptide (B23-B30) insulin in D2O solution have been assigned to alpha-helix, the 3(10) helix, irregular helix, extended chains, beta-turns and other secondary structures. From the peak areas the relative contents of these structures obtained are in general agreement with those calculated from the known structures of porcine insulin and DPI in the crystalline state. The main difference in the structure of DOI with those of insulin and DPI is the shortening of the helix segment and an extended chain for the C terminal segment in the B chain.     

Structural and Functional Study of the GlnB22-Insulin Mutant Responsible for Maturity-Onset Diabetes of the Young

The insulin gene mutation c.137G>A (R46Q), which changes an arginine at the B22 position of the mature hormone to glutamine, causes the monogenic diabetes variant maturity-onset diabetes of the young (MODY). In MODY patients, this mutation is heterozygous, and both mutant and wild-type (WT) human insulin are produced simultaneously. However, the patients often depend on administration of exogenous insulin. In this study, we chemically synthesized the MODY mutant [GlnB22]-insulin and characterized its biological and structural properties. The chemical synthesis of this insulin analogue revealed that its folding ability is severely impaired. In vitro and in vivo tests showed that its binding affinity and biological activity are reduced (both approximately 20% that of human insulin). Comparison of the solution structure of [GlnB22]-insulin with the solution structure of native human insulin revealed that the most significant structural effect of the mutation is distortion of the B20-B23 β-turn, leading to liberation of the B chain C-terminus from the protein core. The distortion of the B20-B23 β-turn is caused by the extended conformational freedom of the GlnB22 side chain, which is no longer anchored in a hydrogen bonding network like the native ArgB22. The partially disordered [GlnB22]-insulin structure appears to be one reason for the reduced binding potency of this mutant and may also be responsible for its low folding efficiency in vivo. The altered orientation and flexibility of the B20-B23 β-turn may interfere with the formation of disulfide bonds in proinsulin bearing the R46Q (GlnB22) mutation. This may also have a negative effect on the WT proinsulin simultaneously biosynthesized in β-cells and therefore play a major role in the development of MODY in patients producing [GlnB22]-insulin.     

The solution structure of a superpotent B-chain-shortened single-replacement insulin analogue

This paper reports on an insulin analogue with 12.5-fold receptor affinity, the highest increase observed for a single replacement, and on its solution structure, determined by NMR spectroscopy. The analogue is [D-AlaB26]des-(B27-B30)-tetrapeptide-insulin-B26-amide. C-terminal truncation of the B-chain by four (or five) residues is known not to affect the functional properties of insulin, provided the new carboxylate charge is neutralized. As opposed to the dramatic increase in receptor affinity caused by the substitution of D-Ala for the wild-type residue TyrB26 in the truncated molecule, this very substitution reduces it to only 18% of that of the wild-type hormone when the B-chain is present in full length. The insulin molecule in solution is visualized as an ensemble of conformers interrelated by a dynamic equilibrium. The question is whether the "active" conformation of the hormone, sought after in innumerable structure/function studies, is or is not included in the accessible conformational space, so that it could be adopted also in the absence of the receptor. If there were any chance for the active conformation, or at least a predisposed state to be populated to a detectable extent, this chance should be best in the case of a superpotent analogue. This was the motivation for the determination of the three-dimensional structure of [D-AlaB26]des-(B27-B30)-tetrapeptide-insulin-B26-amide. However, neither the NMR data nor CD spectroscopic comparison of a number of related analogues provided a clue concerning structural features predisposing insulin to high receptor affinity. After the present study it seems more likely than before that insulin will adopt its active conformation only when exposed to the force field of the receptor surface.     

The T<-->R structural transition of insulin; pathways suggested by targeted energy minimization.

The transition of insulin between its crystallographically defined states T and R is connected with considerable change even of backbone structure: the N-terminal B chain (residues B1-B8) refolds from extended conformation in T into helical in R, and vice versa. Although hitherto observed only in hexamers the transition of the monomer was adequate for developing and testing the method of 'targeted energy minimization' (TEM), capable of coping with conformational changes of such extent at moderate computational expenditure. The simulation is performed in a predetermined number of steps consisting of two atomic displacements each, one by force in the direction of the target structure, the second by energy minimization releasing the constraint caused in the first. The transition pathway is represented by the string of energy minimized transient structures. Due to the directedness of the algorithm the simulated pathway for R-->T is not the reversal of that for T-->R. It is, therefore, not pretended that the minimum energy pathway was identified. In the T-->R direction the N-terminal B chain first swivels while remaining largely stretched and then winds up extending the pre-existing helix B9-B19. The A chain advances into the space abandoned and withdraws from it in the R-->T simulation. In the latter the extended helix first kinks at B8/B9, and then the B1-B8 segment is unwound and stretched. The helical H-bonds of that segment are formed late in T-->R and are maintained during almost half of R-->T. The AN helix is less stable and more involved in the transitions than helix AC.(ABSTRACT TRUNCATED AT 250 WORDS)