The R-state proinsulin and insulin hexamers mimic the carbonic anhydrase active site

The cobalt(II)-substituted proinsulin and insulin hexamers have been studied in solution via electronic absorption spectroscopy. Hexameric proinsulin is shown to undergo the phenol-induced T6 to R6 conformational transition in a manner analogous to that previously established for insulin. In the absence of coordinating anions, the coordination spheres of the Co(II) ions in the proinsulin and insulin R6 hexamers comprise identical pseudotetrahedral arrangements of 3 histidine residues and 1 hydroxide ion. At alkaline pH, the visible absorption spectrum of the phenol-induced R6 Co(II) center is strikingly similar to the distinctive spectrum of the alkaline form of Co(II)-carbonic anhydrase. Exogenous ligands may coordinate to the Co(II) ions of the R6 proinsulin and insulin hexamers via replacement of the hydroxide ion, forming pseudotetrahedral adducts possessing characteristic spectra. The binding affinity of such ligands is shown to be strongly pH-dependent. The data presented establish that, although the Co(II)-substituted proinsulin and insulin R6 hexamers lack enzyme-like activity, these species duplicate spectrochemical characteristics of the Co(II)-carbonic anhydrase active site that are believed to be important signatures of carbonic anhydrase catalytic function.     

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.     

Structural transition in the metal-free hexamer of protein-engineered [B13 Gln]insulin

For hexamer formation of native insulin the repulsive potential of six B13 Glu carboxylate groups coming together in the centre is overcome by zinc binding to B10 His. Substitution of Gln for Glu in position B13 by site-directed mutagenesis, i.e. replacement of the repelling carboxylates by amide groups, which are offering H-bonding potential, enhances association and allows a metal-free hexamer to form. Merely upon addition of zinc ions this hexamer undergoes the T6----T3R3 respectively T6----R6 structural transition which in the native 2Zn insulin hexamer is inducible only by additives like inorganic anions or phenolic compounds. [B13 Gln]Insulin hexamers are transformed by phenolic compounds, but not by anions, even in the absence of any metal. The structural transformation of insulin can thus be brought about in two ways: By inorganic ions with the zinc ions as their points of attack, which preexist in the nontransformed hexamer, and by phenol, for which the binding sites close to the B5 histidines come into existence only with the transformation. Therefore transformed and non-transformed hexamers, i.e. molecules with helical and extended B chain N-terminus, must be related in a dynamic equilibrium. Phenol acts as a wedge jamming the structure in the transformed state and trapping the zinc ions. Combination of transformed 2Zn[B13 Gln]insulin and metal-free native insulin in the absence of additives results in a redistribution of the zinc ions in favour of native insulin which is an outcome of the dynamic equilibrium and also demonstrates an influence of B13 charge on metal binding affinity. Transformation of a single subunit in a hexamer would lead to bad contacts.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Metal induced structural changes observed in hexameric insulin

The metal ions in insulin hexamer play a crucial role in the T to R conformational transitions. We have determined the crystal structures of 2Mn2+, 1Rb1+ and 4Ni2+ human arg-insulin and compared them with the 2Zn2+ structure. The first two structures exist in the T3R3f state like the native 2Zn2+ arg-insulin, while the 4Ni2+ adopts a T6 conformation. The metal coordination is found to be tetrahedral in all the structures except that of nickel where a dual octahedral and tetrahedral coordination is found at one site. Rubidium occupies only one of the high affinity metal binding sites. The metal induced structural changes observed, have been explained.     

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.     

The Glu(B13) carboxylates of the insulin hexamer form a cage for Cd2+ and Ca2+ ions

Substitution of Cd2+ for Zn2+ yields a hexameric insulin species containing 3 mol of metal ion per hexamer. The Cd2+ binding loci consist of the two His(B10) sites and a new site involving the Glu(B13) residues located at the center of the hexamer [Sudmeier, J. L., Bell, S. J., Storm, M. C., & Dunn, M. F. (1981) Science (Washington, D.C.) 212, 560-562]. Substitution of Co2+ or Co3+ for Zn2+ gives hexamers containing 2 mol of metal per hexamer. Insulin solutions to which both Cd2+ and Co2+ have been added in a ratio of 6:2:1 [In]:[Co2+]:[Cd2+] followed by oxidation to the exchange-inert Co3+ state yield stable hybrid species containing both Co3+ and Cd2+ with a composition of (In)6(Co3+)2Cd2+. The kinetics of the reaction of 2,2',2"-terpyridine (terpy) with the exchange-labile (In)6(Cd2+)2 and (In)6(Co2+)2 derivatives are biphasic and involve the rapid formation of an intermediate with coordination of one terpy molecule to each protein-bound metal ion; then, in a rate-limiting step the terpy-coordinated metal ion dissociates from the protein, and a second molecule of terpy binds to the metal ion to form a bis complex. Reaction of the exchange-inert Co3+ ions of (In)6(Co3+)2 with terpy is a slow apparent first-order process (t1/2 = 13.1 h). In contrast to the kinetic behavior of (In)6(Co2+)2 and (In)6(Cd2+)2, the Cd2+ ions bound to the hybrid (In)6(Co3+)2Cd2+ react quite slowly with terpy (t1/2 = 1 h at pH 8.0).(ABSTRACT TRUNCATED AT 250 WORDS)     

The T to R transition in the copper(II)-substituted insulin hexamer. Anion complexes of the R-state species exhibiting type 1 and type 2 spectral characteristics.

The R-state conformation of the Cu(II)-substituted insulin hexamer has been identified, and a number of its derivatives have been studied via 1H NMR, ESR, and UV-visible spectroscopy. This work establishes that the Cu(II)-substituted insulin hexamer undergoes an analogous T to R conformational transition in solution that has been identified previously for Zn(II)- and Co(II)-insulin hexamers [Roy, M., Brader, M.L., Lee, R. W.-K., Kaarsholm, N.C., Hansen, J., & Dunn, M.F. (1989) J. Biol. Chem. 264, 19081-19085]. The data indicate that each Cu(II) center of the R-state Cu(II)-insulin hexamer possesses a coordination site that is accessible to anions from solution. Both phenol and anionic ligands that coordinate to the Cu(II) ions are required to generate the necessary heterotropic interactions that stabilize the R-state structure. With phenylmethylthiolate (PMT), a Cu(II)-R6 adduct that displays the spectral features of blue (type 1) copper proteins is obtained. This complex is proposed to embody a pseudotetrahedral CuIIN3S(PMT) chromophore, in which N is HisB10 (imidazolyl). The remaining ligands examined gave rise to Cu(II)-R6 adducts that possessed the spectral characteristics of normal (type 2) Cu(II) proteins. Under reducing conditions, Cu(I)-T6 and Cu(I)-R6 hexamers have been identified.     

Kinetic measurements of T----R structural transitions in insulin.

The T6----T3R3 and T3R3----R6-structural transitions of cobalt insulin hexamers as induced by SCN ions or m-cresol were studied in stopped-flow experiments using the absorption in the visible for monitoring their time course. The T6----T3R3 transition induced by either SCN or limited concentrations of m-cresol is mono-exponential with a rate constant of 0.1 s-1 and 0.4 s-1, respectively. A mono-exponential time course is also encountered for the m-cresol-induced T3R3----R6 transition when starting from the T3R3 state preestablished by either SCN or m-cresol. The corresponding rate constants are 1.3 s-1 and 0.49 s-1, respectively. If m-cresol is used beyond the concentration range where transformation is limited to one trimer, two exponentials are required for fitting the time course. The second exponential corresponds to the T3R3----R6 step with a concentration-independent rate constant of 0.4 s-1. The rate constant for the faster T6----T3R3 transition, however, increases with increasing excess of m-cresol.     

Comparison of solution structural flexibility and zinc binding domains for insulin, proinsulin, and miniproinsulin

The chromophoric divalent metal ion chelators 4-(2-pyridylazo)resorcinol (PAR) and 2,2',2"-terpyridine (terpy) are used as kinetic and spectroscopic probes to investigate in solution the SCN- -induced conformational transformations of the insulin, proinsulin, and miniproinsulin hexamers (miniproinsulin is a proinsulin analogue wherein the C-chain is replaced by a dipeptide cross-link between Gly-A1 and Ala-B30). Herein we designate the 2Zn and 4Zn crystal forms of the hexamer as the T6 and T3R3 conformations, respectively. For all three proteins, addition of SCN- reduces the rate of sequestering and removal of zinc ion by chelator. The effect of SCN- on the rate of this process saturates at the same concentration (30 mM) known to induce the T6 to T3R3 transformation in the insulin crystal. Under both T6 and T3R3 conditions, the critical stoichiometry for high-affinity interaction between Zn2+ and each of the three proteins is shown to be 2 mol of Zn2+/mol of protein hexamer. Consequently, we confirm the finding that off-axial coordination of Zn2+ via His-B10 and His-B5 residues is of minor importance for the SCN- -induced conformation change in solution [Renscheidt, H., Strassburger, W., Glatter, U., Wollmer, A., Dodson, G. G., & Mercola, D. A. (1984) Eur. J. Biochem. 142, 7-14]. Under T6 conditions, the kinetics of the reactions between insulin, proinsulin, and miniproinsulin and a variable excess of terpy are similar and biphasic.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

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.     

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.     

Role of divalent cations in the 3',5'-exonuclease reaction of DNA polymerase I.

X-ray studies of the proofreading 3',5'-exonuclease site of the large (Klenow) fragment of DNA polymerase I have detected a binuclear metal complex consisting of a pentacoordinate metal (site A) which shares a ligand, Asp-355, with an octahedral metal (site B) [Freemont, P. S., Friedman, J. M., Beese, L. S., Sanderson, M. R., & Steitz, T. A. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 8924-8928; Beese, L. S., & Steitz, T. A. (1991) EMBO J. 10, 25-33]. Kinetic studies of the activation of the 3',5'-exonuclease reaction by Co2+, Mn2+, or Mg2+, at low concentrations of DNA, reveal sigmoidal activation curves for the three metal ions with Hill coefficients of 2.3-2.4 and K0.5 values of 16.6 microM, 4.2 microM, and 343 microM, respectively. The binding of Co2+ to the enzyme results in the appearance of an intense visible absorption spectrum of the metal ion with maxima at 633, 570, and 524 nm and extinction coefficients of 190, 194, and 150 M-1 cm-1, respectively, suggesting the formation of a pentacoordinate Co2+ complex. Optical titration with Co2+ yields a sigmoidal titration curve which is best fit by assuming the cooperative binding of three Co2+ ions with a K0.5 of 39.9 microM, comparable to the value of 16.6 microM obtained kinetically. Displacement of Co2+ by 1 equiv of Zn2+, which binds tightly to the A site of the 3',5'-exonuclease, shifts the optical spectrum to 524 nm and lowers the extinction coefficient to 30 -1 cm-1, indicative of octahedral coordination.2+ the formation of the binuclear complex.     

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.     

2,2-dipyridyl binding to metal substituted horse liver alcohol dehydrogenase

The binding of 2,2-dipyridyl to metal substituted horse liver alcohol dehydrogenase was measured by spectrophotometric titrations. Large changes in the visible absorption spectra were seen for the Co2+, Cu2+ and Ni2+ hybrids upon coordination of 2,2-dipyridyl, due to a change in coordination number. The formation constants for binding to the Co2+ and Cd2+ hybrids are of the order 10(6) M-1, which means that these hybrids have a 500-fold higher affinity for 2,2-dipyridyl than the native Zn2+ enzyme. 2,2-dipyridyl has a 100-fold higher affinity for enzyme bound Cd2+ than for aqueous Cd2+ ions, while for Cu2+ and Zn2+ the opposite is the case. None of the substituted metal ions were removed from the active site during titration with the chelator 2,2-dipyridyl.     

Raman signatures of ligand binding and allosteric conformation change in hexameric insulin.

Hexameric insulin is an allosteric protein that undergoes transitions between three conformational states (T(6), T(3)R(3), and R(6)). These allosteric states are stabilized by the binding of ligands to the phenolic pockets and by the coordination of anions to the His B10 metal sites. Raman difference (RD) spectroscopy is utilized to examine the binding of phenolic ligands and the binding of thiocyanate, p-aminobenzoic acid (PABA), or 4-hydroxy-3-nitrobenzoic acid (4H3N) to the allosteric sites of T(3)R(3) and R(6). The RD spectroscopic studies show changes in the amide I and III bands for the transition of residues B1-B8 from a meandering coil to an alpha helix in the T-R transitions and identify the Raman signatures of the structural differences among the T(6), T(3)R(3), and R(6) states. Evidence of the altered environment caused by the approximately 30 A displacement of phenylalanine (Phe) B1 is clearly seen from changes in the Raman bands of the Phe ring. Raman signatures arising from the coordination of PABA or 4H3N to the histidine (His) B10 Zn(II) sites show these carboxylates give distorted, asymmetric coordination to Zn(II). The RD spectra also reveal the importance of the position and the type of substituents for designing aromatic carboxylates with high affinity for the His B10 metal site.     

An insight to conserved water molecular dynamics of catalytic and structural Zn(+2) ions in matrix metalloproteinase 13 of human

Matrix Metalloproteinase (MMP)--13 or Collagenase--3 plays a significant role in the formation and remodeling of bone, tumor invasion and causes osteoarthritis. Water molecular dynamic studies of the five (1XUC, 1XUD, 1XUR, 456C, 830C) PDB and solvated structures of MMP-13 in human have been carried out upto 5 ns on assigning the differential charges (+2, +1, +0.5 e) to both the Zinc ions. The MM and MD-studies have revealed the coordination of three water molecules (W(H), W(I) and W(S)) to Zn(c) and one water to Zn(s). The transition of geometry around the Znc from tetrahedral to octahedral via trigonal bipyramidal, and for Zn(s) from tetrahedral to trigonal bipyramidal are seem interesting. Recognition of two zinc ions through water molecular bridging (Zn(c) - W(H) (W(1))...W(2)....W(3)....H(187) Zn(s)) and the stabilization of variable coordination geometries around metal ions may indicate the possible involvement of Zn(c) ...Zn(s) coupled mechanism in the catalytic process. So the hydrophilic topology and stereochemistry of water mediated coupling between Zn-ions may provide some plausible hope towards the design of some bidentate/polydentate bridging ligands or inhibitors for MMP-13.