Role of B13 Glu in insulin assembly. The hexamer structure of recombinant mutant (B13 Glu-->Gln) insulin.

The assembly of the insulin hexamer brings the six B13 glutamate side-chains at the centre into close proximity. Their mutual repulsion is unfavourable and zinc co-ordination to B10 histidine is necessary to stabilize the well known zinc-containing hexamers. Since B13 is always a carboxylic acid in all known sequences of hexamer forming insulins, it is likely to be important in the hormone's biology. The mutation of B13 Glu-->Gln leads to a stable zinc-free hexamer with somewhat reduced potency. The structures of the zinc-free B13 Gln hexamer and the 2Zn B13 insulin hexamer have been determined by X-ray analysis and refined with 2.5 A and 2.0 A diffraction data, respectively. Comparisons show that in 2Zn B13 Gln insulin, the hexamer structure (T6) is very like that of the native hormone. On the other hand, the zinc-free hexamer assumes a quaternary structure (T3/R3) seen in the native 4Zn insulin hexamer, and normally associated only with high chloride ion concentrations in the medium. The crystal structures show the B13 Gln side-chains only contact water in contrast to the B13 glutamate in 2Zn insulin. The solvation of the B13 Gln may be associated with this residue favouring helix at B1 to B8. The low potency of the B13 Gln insulin also suggests the residue influences the hormone's conformation.     

Cooperativity and intermediate states in the T----R-structural transformation of insulin

With respect to T----R-structural transformation, cobalt insulin hexamers appear as dimers of two positively cooperative trimers which are related by negative cooperativity. Transformation of the first trimer causes polarization of the hexamer which is insurmountable by inorganic anions (SCN theta) used as transforming agents, and in the case of phenolic agents (m-cresol), which can achieve complete transformation of the hexamer, allows the identification of the T3R3 intermediate. Zinc insulin hexamers are also transformed in a stepwise manner, but for the first step the sigmoidal shape of the titration curve cannot be detected.     

Enhancing the T-->R transition of insulin by helix-promoting sequence modifications at the N-terminal B-chain

Structurally, the T-->R transition of insulin mainly consists of a rearrangement of the N-terminal B-chain (residues B1-B8) from extended to helical in one or both of the trimers of the hexamer. The dependence of the transition on the nature of the ligands inducing it, such as inorganic anions or phenolic compounds, as well as of the metal ions complexing the hexamer, has been the subject of extensive investigations. This study explores the effect of helix-enhancing modifications of the N-terminal B-chain sequence where the transition actually occurs, with special emphasis on N-capping. In total 15 different analogues were prepared by semisynthesis. 80% of the hexamers of the most successful analogues with zinc were found to adopt the T3R3 state in the absence of any transforming ligands, as compared to only 4% of wild-type insulin. Transformation with SCN- ions can exceed the T3R3 state where it stops in the case of wild-type insulin. Full transformation to the R6 state can be achieved by only one-tenth the phenol concentration required for wild-type insulin, i.e. almost at the stoichiometric ratio of 6 phenols per hexamer.     

Cobalt probing of structural alternatives for insulin in solution

Inorganic anions and phenolic compounds make the subunits of insulin hexamers undergo the T----R transition whereby the extended N-terminal B chain becomes helical and the octahedral metal coordination tetrahedral. The role of the metal ions is permissive. With cresol the transition is also undergone by metal-free hexamers. For coordinative reasons only zinc insulin can be transformed by moderate concentrations of inorganic anions. At higher concentrations and particularly with cresol transformation is also possible if Zn2+ is replaced by other metal ions. Owing to its d--d transitions in the visible cobalt lends itself as a spectroscopic probe for studying the interdependence of transformation and coordination. The transformation-related change in coordination is reflected in both the isotropic absorption and the CD spectrum. Cresol achieves T6----R6 transformation whereas that induced by SCN- ions is T6----T'3R3 with only the axial metal-binding site being realized in the R3 trimer. The spectral effects of the transformation of the two trimers are not additive; an extra contribution seems to be indicative of trimer/trimer interaction. Oxidation of 2 Co2+ insulin to a certain extent affects the structure of insulin; a characteristic positive band appears at 251 nm. Because of its extremely stable and exclusively octahedral complexes the Co3+ ion most strongly withstands transformation. The oxidation of tetrahedrally liganded Co2+ ions in R3 trimers proceeds with reduced velocity. Independent transformation of the Zn2+ trimers is possible in Zn2+/Co3+ metal hybrids of insulin.     

1H Fourier transform NMR studies of insulin: coordination of Ca2+ to the Glu(B13) site drives hexamer assembly and induces a conformation change

1H Fourier transform NMR investigations of metal ion binding to insulin in 2H2O were undertaken as a function of pH* to determine the effects of metal ion coordination to the Glu(B13) site on the assembly and structure of the insulin hexamer. The C-2 histidyl regions of the 1H NMR spectra of insulin species containing respectively one Ca2+ and two Zn2+/hexamer and three Cd2+/hexamer have been assigned. Both the Cd2+ derivative (In)6(Cd2+)2Cd2+, where two of the Cd2+ ions are coordinated to the His(B10) sites and the remaining Cd2+ ion is coordinated to the Glu(B13) site [Sudmeier, J.L., Bell, S.J., Storm, M. C., & Dunn, M.F. (1981) Science (Washington, D.C.) 212, 560], and the Zn2+-Ca2+ derivative (In)6-(Zn2+)2Ca2+, where the two Zn2+ ions are coordinated to the His(B10) sites and Ca2+ ion is coordinated to the Glu(B13) site, give spectra in which the C-2 proton resonances of His(B10) are shifted upfield relative to metal-free insulin. Spectra of insulin solutions (3-20 mg/mL) containing a ratio of In:Zn2+ = 6:2 in the pH* region from 8.6 to 10 were found to contain signals both from metal-free insulin species and from the 2Zn-insulin hexamer, (In)6(Zn2+)2. The addition of either Ca2+ (in the ratio In:Zn2+:Ca2+ = 6:2:1) or 40 mM NaSCN was found to provide sufficient additional thermodynamic drive to bring about the nearly complete assembly of insulin hexamers. Cd2+ in the ratio In:Cd2+ = 6:3 also drives hexamer assembly to completion. We postulate that the additional thermodynamic drive provide by Ca2+ and CD2+ is due to coordination of these metal ions to the Glu(B13) carboxylates of the hexamer. At high pH*, this coordination neutralizes the repulsive Coulombic interactions between the six Glu(B13) carboxylates and forms metal ion "cross-links" across the dimer-dimer interfaces. Comparison of the aromatic regions of the 1H NMR spectra for (In)6(Zn2+)2 with (In)6(Zn2+)2Ca2+, (In)6(Cd2+)2Cd2+, and (In)6(Cd2+)2Ca2+ indicates that binding of either Ca2+ or Cd2+ to the Glu(B13) site induces a conformation change that perturbs the environments of the side chains of several of the aromatic residues in the insulin structure. Since these residues lie on the monomer-monomer and dimer-dimer subunit interfaces, we conclude that the conformation change includes small changes in the subunit interfaces that alter the microenvironments of the aromatic rings.     

X-ray structure of an unusual Ca2+ site and the roles of Zn2+ and Ca2+ in the assembly, stability, and storage of the insulin hexamer.

Metal ion binding to the insulin hexamer has been investigated by crystallographic analysis. Cadmium, lead, and metal-free hexamers have been refined to R values of 0.181, 0.172, and 0.172, against data of 1.9-, 2.5-, and 2.5-A resolution, respectively. These structures have been compared with each other and with the isomorphous two-zinc insulin. The structure of the metal-free hexamer shows that the His(B10) imidazole rings are arranged in a preformed site that binds a water molecule and is poised for Zn2+ coordination. The structure of the cadmium derivative shows that the binding of Cd2+ at the center of the hexamer is unusual. There are three symmetry-related sites located within 2.7 A of each other, and this position is evidently one-third occupied. It is also shown that the coordinating B13 glutamate side chains of this derivative have two partially occupied conformations. One of these conformations is two-thirds occupied and is very similar to that seen in two-zinc insulin. The other, one-third-occupied conformation, is seen to coordinate the one-third-occupied metal ion. The binding of Ca2+ to insulin is assumed to be essentially identical with that of Cd2+. Thus, we conclude that the Ca2+ binding site in the insulin hexamer is unlike that of any other known calcium binding protein. The crystal structures reported herein explain how binding of metal ions stabilizes the insulin hexamer. The role of metal ions in hexamer assembly and dissociation is discussed.     

Crystallographic and solution studies of N-lithocholyl insulin: a new generation of prolonged-acting human insulins

The addition of specific bulky hydrophobic groups to the insulin molecule provides it with affinity for circulating serum albumin and enables it to form soluble macromolecular complexes at the site of subcutaneous injection, thereby securing slow absorption of the insulin analogue into the blood stream and prolonging its half-life once there. N-Lithocholic acid acylated insulin [Lys(B29)-lithocholyl des-(B30) human insulin] has been crystallized and the structure determined by X-ray crystallography at 1.6 A resolution to explore the molecular basis of its assembly. The unit cell in the crystal consists of an insulin hexamer containing two zinc ions, with two m-cresol molecules bound at each dimer-dimer interface stabilizing an R(6) conformation. Six covalently bound lithocholyl groups are arranged symmetrically around the outside of the hexamer. These form specific van der Waals and hydrogen-bonding interactions at the interfaces between neighboring hexamers, possibly representing the kinds of interactions which occur in the soluble aggregates at the site of injection. Comparison with an equivalent nonderivatized native insulin hexamer shows that the addition of the lithocholyl group disrupts neither the important conformational features of the insulin molecule nor its hexamer-forming ability. Indeed, binding studies show that the affinity of N-lithocholyl insulin for the human insulin receptor is not significantly diminished.     

Conformational analysis by nuclear magnetic resonance: insulin

High-resolution 270-MHz proton nuclear magnetic resonance (NMR) spectra of the native two-zinc insulin hexamer at pH 9 have been obtained, and assignments of key resonances have been made. Spectra of zinc-free insulin titrated with Zn2+ are unchanged after the addition of 1 equiv of zinc per insulin hexamer, indicating that the conformation of the hexamer is fixed at this point and that the second zinc ion does not significantly change the conformation. Titration of the two-zinc insulin hexamer with anions high on the Hofmeister series such as SCN- causes marked changes in the NMR spectra which are interpreted as the result of major conformational changes to a new hexameric form of insulin having a twofold axis perpendicular to the threefold axis. Analysis of difference spectra indicates that this new hexamer (which should be capable of binding six zinc ions) binds 2 equiv of SCN- at two sites which are assumed to be identical and independent (K1 = 10(3), K2 = 2.5 X 10(2) M-1).     

Physicochemical basis for the rapid time-action of LysB28ProB29-insulin: dissociation of a protein-ligand complex.

The rate-limiting step for the absorption of insulin solutions after subcutaneous injection is considered to be the dissociation of self-associated hexamers to monomers. To accelerate this absorption process, insulin analogues have been designed that possess full biological activity and yet have greatly diminished tendencies to self-associate. Sedimentation velocity and static light scattering results show that the presence of zinc and phenolic ligands (m-cresol and/or phenol) cause one such insulin analogue, LysB28ProB29-human insulin (LysPro), to associate into a hexameric complex. Most importantly, this ligand-bound hexamer retains its rapid-acting pharmacokinetics and pharmacodynamics. The dissociation of the stabilized hexameric analogue has been studied in vitro using static light scattering as well as in vivo using a female pig pharmacodynamic model. Retention of rapid time-action is hypothesized to be due to altered subunit packing within the hexamer. Evidence for modified monomer-monomer interactions has been observed in the X-ray crystal structure of a zinc LysPro hexamer (Ciszak E et al., 1995, Structure 3:615-622). The solution state behavior of LysPro, reported here, has been interpreted with respect to the crystal structure results. In addition, the phenolic ligand binding differences between LysPro and insulin have been compared using isothermal titrating calorimetry and visible absorption spectroscopy of cobalt-containing hexamers. These studies establish that rapid-acting insulin analogues of this type can be stabilized in solution via the formation of hexamer complexes with altered dissociation properties.     

Role of metal ions in the T- to R-allosteric transition in the insulin hexamer.

The role of metal ions in the T- to R-allosteric transition is ascertained from the investigation of the T- to R-allosteric transition of transition metal ions substituted-insulin hexamers, as well as from the kinetics of their dissociation. These studies establish that ligand field stabilization energy (LFSE), coordination geometry preference, and the Lewis acidity of the metal ion in the zinc sites modulate the T- to R-state transition. (1)H NMR, (113)Cd NMR, and UV-vis measurements demonstrate that, under suitable conditions, Fe2+/3+, Ni2+, and Cd2+ bind insulin to form stable hexamers, which are allosteric species. (1)H NMR R-state signatures are elicited by addition of phenol alone in the case of Ni(II)- and Cd(II)-substituted insulin hexamers. The Fe(II)-substituted insulin hexamer is converted to the ferric analogue upon addition of phenol. For the Fe(III)-substituted insulin hexamer, appearance of (1)H NMR R-state signatures requires, additionally to phenol, ligands containing a nitrogen that can donate a lone pair of electrons. This is consistent with stabilization of the R-state by heterotropic interactions between the phenol-binding pocket and ligand binding to Fe(III) in the zinc site. UV-vis measurements indicate that the (1)H NMR detected changes in the conformation of the Fe(III)-insulin hexamer are accompanied by a change in the electronic structure of the iron site. Kinetic measurements of the dissociation of the hexamers provide evidence for the modulation of the stability of the hexamer by ligand field stabilization effects. These kinetic studies also demonstrate that the T- to R-state transition in the insulin hexamer is governed by coordination geometry preference of the metal ion in the zinc site and the compatibility between Lewis acidity of the metal ion in the zinc site and the Lewis basicity of the exogenous ligands. Evidence for the alteration of the calcium site has been obtained from (113)Cd NMR measurements. This finding adds to the number of known conformational changes that occur during the T- to R-transition and is an important consideration in the formulation of allosteric mechanisms of the insulin hexamer.     

An electron paramagnetic resonance study of native and modified freeze-dried cupric insulin hexamer.

Cupric insulin was modified by the addition of cross-linking disulphide bridges between hexamers. The electron paramagnetic resonance (EPR) spectrum of this freeze-dried material was compared with that of freeze-dried unmodified cupric insulin containing various amounts of copper and added water. The modified insulin was found to have cupric ion sites magnetically very similar to that of native insulin containing two cupric ions per hexamer. Native hexamer produced in the presence of 2 Cu(II) ions per hexamer gave, after freeze-drying, an EPR spectrum with A_∥^Cu=16.5 mT, g_∥=2.285 and g_⊥=2.059 (site 1). The use of 4 or 6 Cu(II) ions per hexamer resulted in spectra with two components-a major component with the same A_∥^Cu and g_∥ values as the sample containing 2 Cu(II) ions (site 1) and an additional minor component (site 2). These sites have been identified with the analogous zinc binding site within the hexamer formed by three B-10 histidine residues (site 1) [1, 2] and the site formed by the B-1 α-amino and A-17 glutamyl-γ-barboxylic acid functions where excess zinc is bound (site 2) [3, 4]. The addition of water to native hexamer containing 2, 4, or 6 Cu(II) ions resulted in the appearance of three distinct EPR absorptions, one of which had the same parameters as the freeze-dried native insulin containing 2 Cu(II) ions per hexamer (site 1). Two further sites appeared (3 and 4) with the following parameters: A_∥^Cu=15.0 mT, g_∥=2.353, and g_⊥=2.07; A_∥^Cu=16.5 mT, g_∥=2.315, and g_⊥=2.07, respectively.     

Crystal structure of destripeptide (B28-B30) insulin: implications for insulin dissociation

Destripeptide (B28-B30) insulin (DTRI) is an insulin analogue that has much weaker association ability than native insulin but keeps most of its biological activity. It can be crystallized from a solution containing zinc ions at near-neutral pH. Its crystal structure has been determined by molecular replacement and refined at 1.9 A resolution. DTRI in the crystal exists as a loose hexamer compared with 2Zn insulin. The hexamer only contains one zinc ion that coordinates to the B10 His residues of three monomers. Although residues B28-B30 are located in the monomer-monomer interface within a dimer, the removal of them can simultaneously weaken both the interactions between monomers within the dimer and the interactions between dimers. Because the B-chain C-terminus of insulin is very flexible, we take the DTRI hexamer as a transition state in the native insulin dissociation process and suggest a possible dissociation process of the insulin hexamer based on the DTRI structure.     

Thermal dissociation and unfolding of insulin

The thermal stability of human insulin was studied by differential scanning microcalorimetry and near-UV circular dichroism as a function of zinc/protein ratio, to elucidate the dissociation and unfolding processes of insulin in different association states. Zinc-free insulin, which is primarily dimeric at room temperature, unfolded at approximately 70 degrees C. The two monomeric insulin mutants Asp(B28) and Asp(B9),Glu(B27) unfolded at higher temperatures, but with enthalpies of unfolding that were approximately 30% smaller. Small amounts of zinc caused a biphasic thermal denaturation pattern of insulin. The biphasic denaturation is caused by a redistribution of zinc ions during the heating process and results in two distinct transitions with T(m)'s of approximately 70 and approximately 87 degrees C corresponding to monomer/dimer and hexamer, respectively. At high zinc concentrations (>or=5 Zn(2+) ions/hexamer), only the hexamer transition is observed. The results of this study show that the thermal stability of insulin is closely linked to the association state and that the zinc hexamer remains stable at much higher temperatures than the monomer. This is in contrast to studies with chemical denaturants where it has been shown that monomer unfolding takes place at much higher denaturant concentrations than the dissociation of higher oligomers [Ahmad, A., et al. (2004) J. Biol. Chem. 279, 14999-15013].     

A solution equivalent of the 2Zn----4Zn transformation of insulin in the crystal

Circular dichroic spectroscopy clearly reveals a solvent-induced conformational change of insulin in the presence of zinc ions. The spectral change corresponds to an increase in helix content. The transition observed in solution is an equivalent of the 2Zn----4Zn insulin transformation in the crystal. This is inferred from a series of observations. (1) The spectral effects are compatible with the refolding of the B-chain N-terminus into a helix known from crystal studies. (2) The spectral effects are induced by the very same conditions which are known to induce the 2Zn----4Zn insulin transformation in the crystal (i.e. threshold concentrations of NaCl, KSCN, NaI, for example). (3) They fail to be induced by the same conditions that fail to induce the crystal transformation (e.g. Ni2+ instead of Zn2+). It is concluded that the potential to undergo the transition resides in the hexamer since neither insulin dimers nor monomeric des-pentapeptideB26-30-insulin respond detectably to high halide concentration. Secondly the ability of zinc ions to accommodate tetrahedral coordination allows the transition which is not permitted by other divalent metal ions. Thirdly the transition is independent of the off-axial tetrahedral zinc coordination sites since it occurs in [AlaB5]insulin which lacks the B5 histidine necessary for their formation. A symmetrically rearranged hexamer thus appears possible with two tetrahedrally coordinated zinc ions on the threefold axis; this is consistent with the observation that in native insulin two zinc ions per hexamer are sufficient to produce the full spectral effect. The amount of additional helix derived from the circular dichroic spectral change, however, cannot settle whether the transition comprises only three or all six of the subunits to yield a symmetrical hexamer. Finally the transformation in solution evidently still occurs in an intramolecularly A1-B29-cross-linked insulin in spite of the partially reduced flexibility.     

Spectroscopic signatures of the T to R conformational transition in the insulin hexamer

The cobalt(II)-substituted human insulin hexamer has been shown to undergo the phenol-induced T6 to R6 structural transition in solution. The accompanying octahedral to tetrahedral change in ligand field geometry of the cobalt ions results in dramatic changes in the visible region of the electronic spectrum and thus represents a useful spectroscopic method for studying the T to R transition. Changes in the Co2+ spectral envelope show that the aqua ligand associated with each tetrahedral Co2+ center can be replaced by SCN-, CN-, OCN-, N3-, Cl-, and NO2-. 19F NMR experiments show that the binding of m-trifluorocresol stabilizes the R6 state of zinc insulin. The chemical shift and line broadening of the CF3 singlet, which occur due to binding, provide a useful probe of the T6 to R6 transition. Due to the appearance of new resonances in the aromatic region, the 500 MHz 1H NMR spectrum of the phenol-induced R6 hexamer is readily distinguishable from that of the T6 form. 1H NMR studies show that phenol induces the T6 to R6 transition, both in the (GlnB13)6(Zn2+)2 hexamer and in the metal-free GlnB13 species; we conclude that metal binding is not a prerequisite for formation of the R state in this mutant.     

Dogfish insulin. Primary structure, conformation and biological properties of an elasmobranchial insulin

Insulin from an elasmobranch, the spiny dogfish (Squalus acanthias) has been purified to near homogeneity by means of acid-ethanol extraction and salt precipitation. The amino acid sequences of the performic-acid-oxidised A and B chains have been determined and exhibit some unusual features. The A chain contains a total of 22 amino acids; only the insulin from coypu (a member of the Rodentia suborder, Hystricomorpha), has previously been reported to contain an extension past the A21 asparagine. The B10 histidine, which is involved in the formation of the insulin hexamers in higher vertebrates through the co-ordination of zinc, is present in this elasmobranch insulin. Several substitutions relative to bovine insulin occur in the proposed receptor binding region (A5Gln leads to His, B21Glu leads to Pro, B22Arg leads to Lys, B25Phe leads to Tyr). In spite of these substitutions, the maximal response in the rat epididymal fat cell assay is the same for bovine and dogfish insulins; the concentration required to produce the half-maximal response is, however, approximately threefold greater for dogfish insulin than that of bovine insulin. The use of interactive computer graphics model-building predicts that the dogfish insulin can attain a three-dimensional structure very similar to that of bovine insulin; circular dichroic spectra are presented which support the model-building studies.     

Characterization of the R-state insulin hexamer and its derivatives. The hexamer is stabilized by heterotropic ligand binding interactions

1H NMR and UV-visible electronic absorption studies have been performed to investigate the effects of anions and cyclic organic molecules on the interconversion of the T- and R-conformational states (Kaarsholm et al., 1989) of hexameric M (II)-substituted insulin in solution (M = Zn or Co.). Two ligand binding processes that stabilize the R-state conformation of the M(II)-substituted insulin hexamer [M(II)-R6] have been distinguished: (i) The binding of neutral organic molecules to the six, crystallographically identified, protein pockets in the Zn(II)-R6 insulin hexamer (Derewenda et al. 1989) generate homotropic site-site interactions that stabilize the R-state. Cyclohexanol, phenol, 4-nitrophenol, and 4-hydroxymethylbenzoate are shown to bind at these sites. (ii) The coordination of singly charged anions that are able to gain access to the two HisB10 coordinated metal ions of the M(II)-R6 hexamer stabilizes the R-state. Adducts of the M(II)-R6 hexamer are formed, thereby, in which the solvent-accessible fourth coordination position of the M(II) ion is replaced by a competing anion. Binding to these two classes of sites introduces strong heterotropic interactions that stabilize the R-state. UV-visible spectral data and apparent affinity constants for the adducts formed by the Co(II)-R6 hexamer with a wide range of anionic ligands are presented. The Co(II)-R6 adducts have a strong preference for the formation of pseudotetrahedral Co(II) centers. The HCO3- and pyridine-2-thiolate ions form Co(II)-R6 adducts that are proposed to possess pentacoordinate Co(II) geometries. The relevance of the Co(II)-R6 complexes to carbonic anhydrase catalysis and zinc enzyme model systems is discussed.     

Structural signatures of the complex formed between 3-nitro-4-hydroxybenzoate and the Zn(II)-substituted R(6) insulin hexamer

3-Nitro-4-hydroxybenzoate (3N4H) is a probe of the structure and dynamics of the metal-centered His B10 assembly sites of the insulin hexamer. Each His B10 site consists of a approximately 12 A-long cavity situated on the threefold symmetry axis. These sites play an important role in the storage and release of insulin in vivo. The allosteric behavior of the insulin hexamer is modulated by ligand binding to the His B10 zinc sites and to the phenolic pockets. Binding to these sites drives transitions among three allosteric states, designated T(6), T(3)R(3), and R(6). Although a wide variety of mono anions bind to the His B10 zinc sites of R(3), X-ray structures of ligands complexed to this site exist only for H(2)O, Cl(-), and SCN(-). This work combines one- and two-dimensional (1)H NMR and UV-Vis absorbance studies of the structure and dynamics of the 3N4H complex, which establish the following: (1). relative to the NMR time scale, 3N4H exchange between free and bound states is slow, while flipping among three equivalent orientations about the site threefold axis is fast; (2). binding of 3N4H perturbs resonances within the His B10 zinc site and generates NOEs between ligand resonances and the insulin C-alpha and side chain resonances of ValB2, AsnB3, LeuB6, and CysB7; and (3).3N4H exchange for other ligands is limited by a protein conformational transition. These results are consistent with coordination of the 3N4H carboxylate to the His B10 zinc ion and van der Waals interactions with Val B2, Asn B3, Leu B6, and Cys A7.     

Soluble, prolonged-acting insulin derivatives. II. Degree of protraction and crystallizability of insulins substituted in positions A17, B8, B13, B27 and B30

It has previously been found that insulins, to which positive charge has been added by substitutions in position B30, thus raising the isoelectric point towards pH 7, had a prolonged action when injected as slightly acidic solutions because such derivatives crystallize very readily upon neutralization. Positive charge has now been added by substituting the B13 and A17 glutamic acid residues with glutamines and B27 threonine with lysine or arginine. These substitutions were introduced by site-specific mutagenesis in a gene coding for a single-chain insulin precursor. By tryptic transpeptidation the single-chain precursors were transformed to the double-chain insulin structure, concomitantly with incorporation of residue B30. Thus insulins combining B13 glutamine, A17 glutamine and B27 lysine or arginine with B30 threonine, threonine amide or lysine amide were synthesized. The time course of blood glucose lowering effect and the absorption were studied after subcutaneous injection in rabbits and pigs. The prolonged action of B30-substituted insulins was markedly enhanced by B27 lysine or arginine substitutions and by B13 glutamine. The B27 residue is located on the surface of the hexamer, so a basic residue in this position presumably promotes the packing of hexamers at neutral pH. The B13 residues cluster in the centre of the hexamer. When the electrostatic repulsive forces from six glutamic acid residues are abolished by substitution with glutamine, a stabilization of the hexamer can be envisaged.(ABSTRACT TRUNCATED AT 250 WORDS)     

The structure of a mutant insulin uncouples receptor binding from protein allostery. An electrostatic block to the TR transition

The zinc insulin hexamer undergoes allosteric reorganization among three conformational states, designated T(6), T(3)R(3)(f), and R(6). Although the free monomer in solution (the active species) resembles the classical T-state, an R-like conformational change is proposed to occur upon receptor binding. Here, we distinguish between the conformational requirements of receptor binding and the crystallographic TR transition by design of an active variant refractory to such reorganization. Our strategy exploits the contrasting environments of His(B5) in wild-type structures: on the T(6) surface but within an intersubunit crevice in R-containing hexamers. The TR transition is associated with a marked reduction in His(B5) pK(a), in turn predicting that a positive charge at this site would destabilize the R-specific crevice. Remarkably, substitution of His(B5) (conserved among eutherian mammals) by Arg (occasionally observed among other vertebrates) blocks the TR transition, as probed in solution by optical spectroscopy. Similarly, crystallization of Arg(B5)-insulin in the presence of phenol (ordinarily a potent inducer of the TR transition) yields T(6) hexamers rather than R(6) as obtained in control studies of wild-type insulin. The variant structure, determined at a resolution of 1.3A, closely resembles the wild-type T(6) hexamer. Whereas Arg(B5) is exposed on the protein surface, its side chain participates in a solvent-stabilized network of contacts similar to those involving His(B5) in wild-type T-states. The substantial receptor-binding activity of Arg(B5)-insulin (40% relative to wild type) demonstrates that the function of an insulin monomer can be uncoupled from its allosteric reorganization within zinc-stabilized hexamers.