Carboxymethylation of horse-liver alcohol dehydrogenase in the crystalline state. The active-site zinc region and general anion-binding site of the enzyme correlated in primary and teritiary structures.

Horse liver alcohol dehydrogenase (isozyme EE) in the crystalline state was alkylated with iodoacetate under conditions resulting in the single substitution of Cys-46, which is a ligand to the active-site zinc atom. Alkylation was facilitated by the prior formation of a complex with imidazole bound to the zinc atom. Extent and specificity of the reaction were determined by use of 14C-labelled iodoacetate and by analyses of radioactive peptides after cleavage with trypsin. Ternary complexes of the enzyme with coenzymes and inhibitors effectively protected the protein against alkylation. ADP-ribose, Pt(CN)2-/4 , 1,10-phenanthroline, Au(CN)-/2 and AMP also prevented alkylation with decreasing effectiveness. Crystallographic studies of the alkylated enzyme show that the carboyxmethylated sulfur atom of Cys-46 is still liganded to the active-site zinc atom and that the iodide ion liberated during alkylation is bound as the fourth ligand to zinc, displacing imidazole. Crystallographic analyses were also performed of the binding of AMP and Pt(CN2-/4 to the enzyme. It was found that Arg-47 interacts with the phosphate moiety of the nucleotide. Lys-228 and Arg-47 interact in the platinate complex with the bulky anion, the center of which coincides with the position of the nucleotide phosphate. Some of the cyano-ligands to platinum occupy a crevice between the coenzyme phosphate binding site and the active-site zinc atom. The results of the combined studies on primary and tertiary structures confirm previous suggestions that iodoacetate enters the active site via reversible binding to an anion-binding site. This site interacts with the negatively charged groups of the coenzyme as well as with ADP-ribose, Pt(CN2-/4 and to a lesser extent Au(CN)-/2 and AMP, which therefore prevent the reversible binding of iodoacetate. 1,10-Phenanthroline does not block the binding site but interferes with alkylation presumably by changing the coordination of zinc. Identificationof this labelled residue in both chemical and crystallographic studies correlates the primary and tertiary structures. Characterizations of the active-site zinc region and the general anion-binding site are also presented.     

Zinc-promoted alkyl transfer: a new role for zinc

The roles of zinc in biology are often thought to be limited to activating water, as in hydrolytic enzymes, and conferring structure, as in the zinc finger proteins. Over the past 15 years, it has been shown that there are many zinc-containing proteins that have 'structural-like' zinc sites with multiple cysteine ligands but in which the site promotes the alkylation of a zinc-bound thiolate. Recent work continues to extend the range of proteins showing zinc-promoted alkytransfer activity, and has refined the structural details of these sites. Of particular interest are recent crystal structures suggesting that in most cases the endogenous ligand that is displaced when the substrate thiol bind is an endogenous amino acid and not water, as had been previously thought. Despite extensive study, it remains unclear whether these enzymes function via an associative mechanism (direct alkylation of a zinc-bound thiolate) or a dissociate mechanism (nucleophilic attack by a free thiolate that has dissociated from the zinc).     

Quantum Molecular Modeling of the Interaction Between Guanine and Alkylating Agents - 2 - Nitrogen Mustard

Abstract

The alkylation mechanism of guanine by nitrogen mustard (HN2) was studied by using a supermolecular modeling at the ab initio 6–31G level. Our computations show that interaction of guanine with the aziridinium form of HN2 necessitates a transition state for the N7 alkylation route. The pathway of N7-guanine alkylation by nitrogen and sulfur mustards is discussed on the basis of the Molecular Electrostatic Potential and HOMO-LUMO properties of these molecules.     

Inhibition of sulfur mustard-increased protease activity by niacinamide,N-acetyl-L-cysteine or dexamethasone

The pathologic mechanisms underlying sulfur mustard-induced skin vesication remain undefined. Papirmeister et al. (1985) have postulated a biochemical mechanism for sulfur mustard-induced cutaneous injury involving DNA alkylation, metabolic disruption, and enhanced proteolysic activity. We have previously utilized a chromogenic peptide substrate assay to establish that human peripheral blood lymphocytes exposed to sulfur mustard exhibited enhanced proteolytic activity. In this study, compounds known to alter the biochemical events associated with sulfur mustard exposure or to reduce protease activity were tested for their ability to block the sulfur mustard-increased proteolysis. Treatment of cells with niacinamide, N-acetyl-L-cysteine, or dexamethasone resulted in a decrease of sulfur mustard-increased protease activity. Complete inhibition of sulfur mustard-increased proteolysis was achieved by using protease inhibitors (antipain, leupeptin, and 4-(2-aminoethyl)-benzenesulfonylfluoride). These data suggest that therapeutic intervention in the biochemical pathways that culminate in protease activation or direct inhibition of proteolysis might serve as an approach to the treatment of sulfur mustard-induced pathology.Abbreviations APMSF 4-(2-aminoethyl)-benzenesulfonylfluoride, HCI - CPSPA Chromogenic Peptide Substrate Protease Assay - EDTA ethylenediaminetetraacetic acid - HD sulfur mustard - PBL human peripheral blood lymphocytes - pNA p-nitroaniline     

Facile alkylation of methionine by benzyl bromide and demonstration of fumarase inactivation accompanied by alkylation of a methionine residue.

Benzyl bromide is a selective alkylator of sulfur nucleophiles including methionine and cysteine. Only the mercaptide ion is a more efficient nucleophile than is the sulfur ether of methionine. Alkylation rates relative to methionine are 200: less than or equal to 0.03: less than or equal to 0.03: less than or equal to 0.02 for GS-, histidine, tryptophan, and GSH, respectively. Alkylation of methionine by benzyl bromide is more than 50 times faster than alkylation by iodoacetate. Fumarase is readily inactivated by exposure to benzyl bromide at pH 6.6 to 6.8 accompanied by alkylation of close to 1 methionine residue/subunit. Fumarase fully inactivated by exposure to benzyl bromide shows no detected alkylation of amino acid residues other than methionine. The rate of inactivation of fumarase by benzyl bromide is decreased about 4-fold by the presence of excess substrates. Denaturation of fumarase in 6 M urea at pH 6.5 exposes additional methionine as well as cysteine residues to alkylation.     

The ligand environment of zinc stored in vesicles

Zinc serves regulatory functions in cells and thus, several mechanisms exist for tight control of its homeostasis. One mechanism is storage in and retrieval from vesicles, so-called zincosomes, but the chemical speciation of zincosomal zinc has remained enigmatic. Here, we determine the intravesicular zinc-coordination in isolated zincosomes in comparison to intact RAW264.7 murine macrophage cells. In elemental maps of a cell monolayer, generated by microbeam X-ray fluorescence, zincosomes were identified as spots of high zinc accumulation. A fingerprint for the binding motif obtained by μXANES (X-ray absorption near edge structure) matches the XANES from isolated vesicles; zinc is not free, but present as a complexed form (average coordination; 1.0 sulfur, 2,5 histidines 30 and 1.0 oxygen), resembling regulatory or catalytic zinc sites in proteins. Such coordination enables reversible binding, acting as a ‘zinc sink’, facilitating the accumulation of high amounts of zinc against a concentration gradient.     

Thiolate exchange in [TmR]ZnSR' complexes and relevance to the mechanisms of thiolate alkylation reactions involving zinc enzymes and proteins

The zinc and cadmium thiolate complexes [TmBut]MSCH2C(O)N(H)Ph (M = Zn, Cd) may be obtained via treatment of the respective methyl complex [TmBut]MMe with PhN(H)C(O)CH2SH. The molecular structure of [TmBut]ZnSCH2C(O)N(H)Ph has been determined by X-ray diffraction, thereby demonstrating the presence of an intramolecular N-H S hydrogen bond between the amide N-H group and thiolate sulfur atom. [TmBut]ZnSCH2C(O)N(H)Ph mimics the function of the Ada DNA repair protein by undergoing alkylation with MeI to give [TmBut]ZnI and MeSCH2C(O)N(H)Ph. A series of crossover experiments and 1H NMR magnetization transfer studies establish that thiolate exchange between [TmR]ZnSR' derivatives is facile in this system, an observation that supports the previous suggestion that the alkylation of [TmPh]ZnSCH2C(O)N(H)Ph by MeI may proceed via a sequence that involves dissociation of [PhN(H)C(O)CH2S]-.     

Enzyme regulation by reversible zinc inhibition: glycerol phosphate dehydrogenase as an example

Since cellular zinc is not freely available as the inorganic ion, zinc proteins must acquire their metal from some other source. But how, when, and where they acquire it is unknown. Metallothionein can participate in the controlled delivery of zinc by binding it with high stability and by mobilizing it through a novel biochemical mechanism that critically depends on the redox activity of the zinc–sulfur bond. Thus, metallothionein activates zinc-depleted alcohol (sorbitol) dehydrogenases by glutathione-modulated zinc transfer. In addition to its catalytic, co-catalytic, and/or structural roles in a myriad of enzymes, zinc also inhibits some enzymes that are not necessarily zinc enzymes, e.g. glyceraldehyde and glycerol phosphate dehydrogenases, and aldehyde dehydrogenase. Zinc inhibits glycerol phosphate dehydrogenase with an IC₅₀ value of 100 nM. Zinc binding is slow at low pH, but instantaneous at high pH. Thionein, the apoprotein of metallothionein, re-activates the zinc-inhibited enzyme. Tight inhibition by zinc and activation of glycerol phosphate dehydrogenase by thionein, a biological chelating agent, provide further support that modulation of zinc binding by metallothionein and thionein is a physiological mechanism of enzyme regulation. Since glycerol phosphate dehydrogenase is a key enzyme in energy metabolism, the effect of zinc is expected to elicit significant physiological responses.     

On the competition for available zinc

Extended x-ray absorption fine structure (EXAFS) spectroscopy was combined with thermodynamic and kinetic approaches to investigate zinc binding to a zinc finger (C2H2) and a tetrathiolate (C4) peptide. Both peptides represent structural zinc sites of proteins and rapidly bind a single zinc ion with picomolar dissociation constants. In competition with EDTA the transfer of peptide-bound zinc ions proved to be 6 orders of magnitude faster than predicted for a dissociation-association mechanism thus requiring ligand exchange mechanisms via peptide-zinc-EDTA complexes. EXAFS spectra of C2H2 showed the expected Cys2His2-ligand geometry when fully loaded with zinc. For a 2-fold excess of peptide, however, the existence of zinc-bridged peptide-peptide complexes with dominating sulfur coordination could be clearly shown. Whereas zinc binding kinetics of C2H2 appeared as a simple second order process, the suggested mechanism for C4 comprises a zinc-bridged Zn-(C4)2 species as well as a Zn-C4 species with less than 4 metal-bound thiolates, which is supported by EXAFS results. A rapid equilibrium of bound and unbound states of individual ligands might explain the kinetic instability of zinc-peptide complexes, which enables fast ligand exchange during the encounter of occupied and unoccupied acceptor sites. Depending on relative concentrations and stabilities, this results in a rapid transfer of zinc ions in the virtual absence of free zinc ions, as seen for the zinc transfer to EDTA, or in the formation of zinc-bridged complexes, as seen for both peptides with excess of peptides over available zinc.     

Identification of the two zinc-bound cysteines in the ferric uptake regulation protein from Escherichia coli: chemical modification and mass spectrometry analysis.

Selective chemical modification of thiol groups combined with mass spectrometry analysis was used to characterize cysteine ligands in the zinc-binding site of the Fur protein. Fur is a metalloregulatory protein involved in the regulation of almost all bacterial genes related to iron uptake in Gram-negative bacteria such as Escherichia coli. In addition to the iron site, Fur also possesses a tight-binding zinc site that likely comprises two cysteines. Using a new procedure, we confirm the involvement of two cysteines in zinc binding and identify them within the two pairs of cysteines present in the protein. The protein was treated under nondenaturing conditions with iodoacetamide, and the progressive alkylation of the thiol groups monitored by quenching the reaction at different times and measuring the extent of alkylation by mass spectrometry. Complementary experiments were carried out in the absence or presence of EDTA, a strong zinc chelator, to determine which of the cysteines were protected from alkylation by the zinc atom. Enzymatic digestion of the modified protein and analysis of the peptide mixture by mass spectrometry enabled fast identification of reactive and protected thiol groups. Two cysteines, Cys92 and Cys95, were thus assigned as zinc ligands. Examination of the sequence comprising the zinc site indicates that it may belong to a new type of structural zinc site. Furthermore, Cys132 was shown to be the fastest reacting cysteine, implying it is a surface-exposed residue.     

Cellular zinc and redox buffering capacity of metallothionein/thionein in health and disease

Zinc is involved in virtually all aspects of cellular and molecular biology as a catalytic, structural, and regulatory cofactor in over 1000 proteins. Zinc binding to proteins requires an adequate supply of zinc and intact molecular mechanisms for redistributing zinc ions to make them available at the right time and location. Several dozen gene products participate in this process, in which interactions between zinc and sulfur donors determine the mobility of zinc and establish coupling between cellular redox state and zinc availability. Specifically, the redox properties of metallothionein and its apoprotein thionein are critical for buffering zinc ions and for controlling fluctuations in the range of picomolar concentrations of "free" zinc ions in cellular signaling. Metallothionein and other proteins with sulfur coordination environments are sensitive to redox perturbations and can render cells susceptible to injury when oxidative stress compromises the cellular redox and zinc buffering capacity in chronic diseases. The implications of these fundamental principles for zinc metabolism in type 2 diabetes are briefly discussed.     

Effect of sulfur exposure on protease activity in human peripheral blood lymphocytes

Sulfur mustard is a waemical warfare blistering agent for which neither the mechanism of action nor an antidote is known. Papirmeister et al. (1985) have postulated a biochemical hypothesis for mustard-induced cutaneous injury involving a sequelae of DNA alkylation, metabolic disruption and activation of protease. Human peripheral blood lymphocytes in cell cultures were employed as an in vitro model for alkylating agent toxicity. A chromogenic peptide substrate assay was used for detection of protease in lymphocytes treated with sulfur mustard or chloroethyl ethyl sulfide. Exposure of human peripheral blood lymphocytes from normal donors to these alkylating agents resulted in an increase in cell associated protease activity. This increase in protease activity may contribute to the pathology or act as an indicator to predict methods of therapeutic intervention for sulfur mustard toxicity.Abbreviations PBL peripheral blood lymphocytes - CEES chloroethyl ethyl sulfide - DFP diisopropyl fluoro-phosphate - pNA p-nitroaniline - CPSPA Chromogenic Peptide Substrate Protease Assay The opinions or assertions herein are the private views of the authors and are not to be construed as official or as reflecting the views of the Department of the Army or the Department of Defense.     

Synthesis of a novel class of sulfonium ions as potential inhibitors of UDP-galactopyranose mutase

Two sulfonium salts of 1,4-anhydro-4-thio-D-galactitol, with structures related to the known sulfonium salt glycosidase inhibitor, salacinol, have been synthesized as potential inhibitors of UDP-galactopyranose mutase. The synthetic strategy relies on the alkylation reaction of 1,4-anhydro-2,3,5,6-tetra-O-benzyl-4-thio-D-galactitol at the sulfur atom with 2,4-O-benzylidene-D- or -L-erythritol-1,3-cyclic sulfate. In each case, the reaction proceeded stereoselectively to yield only one stereoisomer at the stereogenic sulfur atom. The effect of the polar solvent, 1,1,1,3,3,3-hexafluoroisopropanol (HFIP), in promoting high-yielding reactions is highlighted. The target compounds are then obtained by hydrogenolysis.     

Identification of the zinc ligands in cobalamin-independent methionine synthase (MetE) from Escherichia coli

Cobalamin-independent methionine synthase (MetE) from Escherichia coli catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine to form tetrahydrofolate and methionine. It contains 1 equiv of zinc that is essential for its catalytic activity. Extended X-ray absorption fine structure analysis of the zinc-binding site has suggested tetrahedral coordination with two sulfur (cysteine) and one nitrogen or oxygen ligands provided by the enzyme and an exchangeable oxygen or nitrogen ligand that is replaced by the homocysteine thiol group in the enzyme-substrate complex [González, J. C., Peariso, K., Penner-Hahn, J. E., and Matthews, R. G. (1996) Biochemistry 35, 12228-34]. Sequence alignment of MetE homologues shows that His641, Cys643, and Cys726 are the only conserved residues. We report here the construction, expression, and purification of the His641Gln, Cys643Ser, and Cys726Ser mutants of MetE. Each mutant displays significantly impaired activity and contains less than 1 equiv of zinc upon purification. Furthermore, each mutant binds zinc with lower binding affinity (K(a) approximately 10(14) M(-)(1)) compared to the wild-type enzyme (K(a) > 10(16) M(-)(1)). All the MetE mutants are able to bind homocysteine. X-ray absorption spectroscopy analysis of the zinc-binding sites in the mutants indicates that the four-coordinate zinc site is preserved but that the ligand sets are changed. Our results demonstrate that Cys643 and Cys726 are two of the zinc ligands in MetE from E. coli and suggest that His641 is a third endogenous ligand. The effects of the mutations on the specific activities of the mutant proteins suggest that zinc and homocysteine binding alone are not sufficient for activity; the chemical nature of the ligands is also a determining factor for catalytic activity in agreement with model studies of the alkylation of zinc-thiolate complexes.     

S-nitrosothiols react preferentially with zinc thiolate clusters of metallothionein III through transnitrosation

Metallothionein (MT) is a two-domain protein with zinc thiolate clusters that bind and release zinc depending on the redox states of the sulfur ligands. Since S-nitrosylation of cysteine is considered a prototypic cellular redox signaling mechanism, we here investigate the reactions of S-nitrosothiols with different isoforms of MT. MT-III is significantly more reactive than MT-I/II toward S-nitrosothiols, whereas the reactivity of all three isoforms toward reactive oxygen species is comparable. A cellular system, in which all three MTs are similarly effective in protecting rat embryonic cortical neurons in primary culture against hydrogen peroxide but where MT-III has a much more pronounced effect of protecting against S-nitrosothiols, confirms this finding. MT-III is the only isoform with consensus acid-base sequence motifs for S-nitrosylation in both domains. Studies with synthetic and zinc-reconstituted domain peptides demonstrate that S-nitrosothiols indeed release zinc from both the alpha- and the beta-domain of MT-III. S-Nitrosylation occurs via transnitrosation, a mechanism that differs fundamentally from that of previous studies of reactions of MT with NO*. Our data demonstrate that zinc thiolate bonds are targets of S-nitrosothiol signaling and further indicate that MT-III is biologically specific in converting NO signals to zinc signals. This could bear importantly on the physiological action of MT-III, whose biological activity as a neuronal growth inhibitory factor is unique, and for brain diseases that have been related to oxidative or nitrosative stress.     

Selective enrichment of thiophosphorylated polypeptides as a tool for the analysis of protein phosphorylation

A chemoselective alkylation method is described for the isolation and subsequent identification of thiophosphorylated peptides/proteins. The method involves thiophosphorylation of proteins using adenosine 5'-O-(thiotriphosphate) (ATPgammaS) followed by selective in situ alkylation of the newly thiophosphorylated proteins resulting in a stable covalent bond. The chemoselective alkylation exploits the relatively high nucleophilicity at low pH of the sulfur in thiophosphate residues, whereas the nucleophilicities of phosphates, amines, and other functionality of amino acids are negligible or significantly suppressed. Modified alkylation reagents linked to biotin or solid supports (e.g. glass or Sepharose beads) with or without a photocleavable linker facilitate the isolation of the thiophosphorylated peptide/proteins. This approach is demonstrated through the localization of phosphorylation sites on myosin regulatory light chain. We anticipate that this technique will be useful for isolation and subsequent identification of newly thiophosphorylated proteins, produced either in vivo or in vitro, thus facilitating the dissection of protein phosphorylation networks.     

Environmental and injected cadmium are sequestered by two major isoforms of basal copper, zinc-metallothionein in gibel (Carassius auratus langsdorfi) liver

Gibels were exposed to cadmium in their aquarium at a concentration of 10 micrograms Cd/l for up to 39 weeks. Distributions of cadmium, copper and zinc in the liver soluble fraction were determined along with sulfur by high performance liquid chromatography-inductively coupled argon plasma-atomic emission spectrometry. Cadmium was sequestered by the two major isoforms of gibel metallothionein as in the case of cadmium injected intraperitoneally into gibel. Several peaks with cadmium, copper, zinc and sulfur were observed other than the two major isoforms and their relative ratios were different between the control and cadmium-exposed fishes.     

Binding of ligands to the catalytic zinc ion in horse liver alcohol dehydrogenase

The affinity of nitrogen and sulfur ligands for the catalytic zinc ion in horse liver alcohol dehydrogenase has been investigated by their influence on the affinity labeling reaction with iodoacetate. All the nitrogen compounds including ammonia, a primary and a secondary amine, and heterocycles containing a pyridine-type nitrogen with the exception of 2,2-dipyridyl were found to activate the affinity labeling reaction. Activation results from inner-sphere ligand coordination to the catalytic zinc ion. Closely related pyridine compounds gave a regular increase in affinity for the enzyme with increasing basicity, as expected for coordination to a metal ion. The sulfur compounds penicillamine and mercaptoethanol also activated the affinity labeling reaction, but dimercaptopropanol bound very tightly as a bidentate inhibited the reaction. The anions hydrosulfide, diethyldithiocarbamate, and cyanide coordinated to the catalytic zinc ion, whereas azide, thiocyanate, tetrazole, and iodide complexed the anion-binding site. The anionic metal ligands increased the rate of inactivation of the enzyme with iodoacetamide by binding to the catalytic zinc ion, while the binding of iodoacetate to the anion-binding site was prevented.     

Crystal structure of carboxypeptidase A complexed with D-cysteine at 1.75 A - inhibitor-induced conformational changes

D-Cysteine differs from the antiarthritis drug D-penicillamine by only two methyl groups on the beta-carbon yet inhibits carboxypeptidase A (CPD) by a distinct mechanism: D-cysteine binds tightly to the active site zinc, while D-penicillamine catalyzes metal removal. To investigate the structural basis for this difference, we solved the crystal structure of carboxypeptidase A complexed with D-cysteine (D-Cys) at 1.75-A resolution. D-Cys binds the active site zinc with a sulfur ligand and forms additional interactions with surrounding side chains of the enzyme. The structure explains the difference in potency between D-Cys and L-Cys and provides insight into the mechanism of D-penicillamine inhibition. D-Cys binding induces a concerted motion of the side chains around the zinc ion, similar to that found in other carboxypeptidase-inhibitor crystal structures and along a limited path. Analysis of concerted motions of CPD and CPD-inhibitor crystal structures reveals a clustering of these structures into distinct groups. Using the restricted conformational flexibility of a drug target in this type of analysis could greatly enhance efficiency in drug design.     

Oxidation of biological thiols by highly reactive disulfide-S-oxides

Oxidative stress involves the generation of a number of reactive species, among them 'reactive oxygen species' and 'reactive nitrogen species'. Recent reports have indicated that disulfide-S-monoxides (thiosulfinates) and disulfide-S-dioxides (thiosulfonates) are formed under conditions of oxidative stress. We have now been able to demonstrate that these species are highly reactive and rapidly oxidise thiols. Glutathione and cysteine were oxidised to mixed disulfides by the action of disulfide-S-oxides. Oxidative attack on the zinc/sulfur protein metallothionein with concomitant zinc release was readily accomplished by these 'reactive sulfur species' whereas hydrogen peroxide showed minimal zinc release.