Active-site zinc ligands and activated H2O of zinc enzymes

Synaptobrevin/vesicle-associated membrane protein (VAMP) of Aplysia californica: structure and proteolysis by tetanus toxin and botulinal neurotoxins type D and F

Synaptobrevin/vesicle-associated membrane protein (VAMP) and syntaxin are potential vesicle donor and target membrane receptors of a docking complex that requires N-ethylmaleimide-sensitive factor (NSF) and soluble NSF-attachment proteins as soluble factors for vesicle fusion with target membranes. Members of this docking complex are the target of clostridial neurotoxins that act as zinc-dependent proteases. Molecular cloning of the Aplysia californica synaptobrevin cDNA revealed a 180-residue polypeptide (M(r), 19,745) with a central transmembrane region and an atypically large C-terminal intravesicular domain. This polypeptide integrates into membranes at both the co- and posttranslational level, as shown by modification of an artificially introduced N-glycosylation site. The soluble and membrane-anchored forms of synaptobrevin are cleaved by the light chains of the botulinal toxins type D and F and by tetanus toxin involving the peptide bonds Lys49-Ile50, Gln48-Lys49, and Gln66-Phe67, respectively. The active center of teh tetanus toxin light chain was identified by site-specific mutagenesis. His233, His237, Glu234, and Glu270/271 are essential to this proteolytic activity. Modification of histidine residues resulted in loss of zinc binding, whereas a replacement of Glu234 only slightly reduced the zinc content.

The structure of bacteriophage T7 lysozyme, a zinc amidase and an inhibitor of T7 RNA polymerase

The lysozyme of bacteriophage T7 is a bifunctional protein that cuts amide bonds in the bacterial cell wall and binds to and inhibits transcription by T7 RNA polymerase. The structure of a mutant T7 lysozyme has been determined by x-ray crystallography and refined at 2.2-A resolution. The protein folds into an alpha/beta-sheet structure that has a prominent cleft. A zinc atom is located in the cleft, bound directly to three amino acids and, through a water molecule, to a fourth. Zinc is required for amidase activity but not for inhibition of T7 RNA polymerase. Alignment of the zinc ligands of T7 lysozyme with those of carboxypeptidase A and thermolysin suggests structural similarity among the catalytic sites for the amidase and these zinc proteases. Mutational analysis identified presumed catalytic residues for amidase activity within the cleft and a surface that appears to be the site of binding to T7 RNA polymerase. Binding of T7 RNA polymerase inhibits amidase activity.

Identification of the histidine ligands to the binuclear metal center of phosphotriesterase by site-directed mutagenesis

In order to identify which of the seven histidines in phosphotriesterase participate at the active site/binuclear metal center of the enzyme, site-directed mutagenesis has been employed to change, individually, each of the seven histidine residues to asparagine. In addition, the gene for the wild-type enzyme has been subcloned without its leader sequence behind a modified ribosomal binding site, leading to a 5-fold increase in protein expression. The seven mutants, H55N, H57N, H123N, H201N, H230N, H254N, and H257N, exhibit varying degrees of activity compared to the wild-type enzyme. The H123N and H257N mutants are as active as the wild-type enzyme, but all of the other mutant enzymes have 10% or less activity. The metal content of the cobalt-purified mutant enzymes has been determined to be less than that of the wild-type enzyme in all cases. Each of the mutant enzymes has been converted to apoenzyme and reconstituted with 2 equiv of zinc(II), cadmium(II), or cobalt(II). The kinetic parameters, Vmax and V/Km, and apparent pKa's have been determined for each of the reconstituted enzyme derivatives. In almost all cases, the apparent pKa's have shifted toward higher values. The pH-rate profiles for some of the reconstituted mutant enzymes are significantly different from those for the wild-type enzyme, indicating that other groups may become involved in the reaction mechanism upon mutation of the histidine residue to asparagine. His-123 is the only histidine residue that appears to have no involvement in the catalytic activity of phosphotriesterase.(ABSTRACT TRUNCATED AT 250 WORDS)

Structure of the catalytic domain of human fibroblast collagenase complexed with an inhibitor

In rheumatoid and osteoarthritis, degradation of articular cartilage is mediated by the matrix metalloproteinases collagenase, stromelysin and gelatinase. The key event in this process is the cleavage of triple helical collagen by collagenase. We have determined the crystal structure of the catalytic domain of human recombinant fibroblast collagenase complexed with a synthetic inhibitor at 2.2 A resolution. The protein fold is similar to the amino termini of the zinc endopeptidases astacin thermolysin and elastase despite a lack of primary sequence homology. The conformation of the bound inhibitor provides a molecular basis for the design of inhibitors of collagenase and other matrix metalloproteinases. Such inhibitors should be useful in the treatment of a variety of diseases including arthritis and cancer.

Probing the metal binding sites of Escherichia coli isoleucyl-tRNA synthetase

The metal binding properties of isoleucyl-tRNA synthetase (IleRS) from Escherichia coli were studied by in vivo substitution of the enzyme-bound metals. Purified E. coli IleRS was shown to have two tightly bound zinc atoms per active site. Cobalt- and cadmium-substituted IleRS were also found to contain two tightly bound Co2+ and Cd2+ atoms per polypeptide chain, respectively. The d-d transitions in the low energy absorption spectrum of Co(2+)-substituted IleRS were characteristic of that expected for two tetrahedrally coordinated Co2+ metals. Apo-IleRS was found to be inactive in both the aminoacylation of tRNA(Ile) and in the isoleucine-dependent ATP-pyrophosphate exchange reactions. Both Co(2+)- and Cd(2+)-substituted IleRS were found to have kcat/Km values in the isoleucine-dependent ATP-pyrophosphate exchange assay approximately 5-fold lower than the native Zn2+ enzyme. A single enzyme-bound Zn2+ or Co2+ atom per polypeptide chain could be removed by dialysis of Zn(2+)- or Co(2+)-substituted IleRS against 1,10-phenanthroline. Removal of one of the two enzyme-bound Zn2+ atoms per polypeptide chain with 1,10-phenanthroline was found to decrease (kcat/Km)Ile by approximately 130-fold. The dependence of the kinetic parameters on the identity and number of enzyme-bound metals in the isoleucine-dependent ATP-pyrophosphate exchange reaction suggests that at least one enzyme-bound metal is indirectly involved in aminoacyladenylate formation. Metal substitution or removal of one of the two enzyme-bound metals in IleRS was found to have little effect on the Km value for tRNA(Ile) or the kcat value for aminoacylation of tRNA(Ile).(ABSTRACT TRUNCATED AT 250 WORDS)

Proteinase yscD (oligopeptidase yscD). Structure, function and relationship of the yeast enzyme with mammalian thimet oligopeptidase (metalloendopeptidase, EP 24.15)

The yeast PRD1 gene, encoding proteinase yscD, was cloned by complementation of the prd1-6 point mutation. Sequencing of the gene revealed an open reading frame of 2.136 kb, encoding a protein of 712 amino acids with a calculated molecular mass of 81.8 kDa. The sequence HEGLG beginning at residue 501 represents the HEXXH motif, unique for the zinc metallo-peptidases. Sequence comparison revealed complete identity of the proteinase yscD gene with a recently published open reading frame of yeast chromosome III. We found 34.8% identity between proteinase yscD and rat metalloendopeptidase (thimet oligopeptidase, EP 24.15). Proteinase yscD hydrolyzes several chromogenic and fluorogenic peptides that are substrates of thimet oligopeptidase. N-[1-(RS)-carboxy-3-phenylpropyl]-Ala-Ala-Phe-p-aminobenzoic acid, a compound designed as specific inhibitor of EP 24.15, is also a strong inhibitor of the yeast enzyme. Proteinase yscD is a nonvacuolar enzyme. 3-5% of the total enzyme activity can be detected in the intermembrane space of mitochondria. In a mutant carrying a deletion of the PRD1 gene no proteinase yscD activity is detectable in the cytoplasm and in mitochondria of these cells. They do not show any grossly altered phenotype but exhibit a decrease in the intracellular degradation of peptides. This suggests a function of proteinase yscD in the late stages of protein degradation.

Molecular characterization of microbial alcohol dehydrogenases

There is an astonishing array of microbial alcohol oxidoreductases. They display a wide variety of substrate specificities and they fulfill several vital but quite different physiological functions. Some of these enzymes are involved in the production of alcoholic beverages and of industrial solvents, others are important in the production of vinegar, and still others participate in the degradation of naturally occurring and xenobiotic aromatic compounds as well as in the growth of bacteria and yeasts on methanol. They can be divided into three major categories. (1) The NAD- or NADP-dependent dehydrogenases. These can in turn be divided into the group I long-chain (approximately 350 amino acid residues) zinc-dependent enzymes such as alcohol dehydrogenases I, II, and III of Saccharomyces cerevisiae or the plasmid-encoded benzyl alcohol dehydrogenase of Pseudomonas putida; the group II short-chain (approximately 250 residues) zinc-independent enzymes such as ribitol dehydrogenase of Klebsiella aerogenes; the group III "iron-activated" enzymes that generally contain approximately 385 amino acid residues, such as alcohol dehydrogenase II of Zymomonas mobilis and alcohol dehydrogenase IV of Saccharomyces cerevisiae, but may contain almost 900 residues in the case of the multifunctional alcohol dehydrogenases of Escherichia coli and Clostridium acetobutylicum. The aldehyde/alcohol oxidoreductase of Amycolatopsis methanolica and the methanol dehydrogenases of A. methanolica and Mycobacterium gasti are 4-nitroso-N,N-dimethylaniline-dependent nicotinoproteins. (2) NAD(P)-independent enzymes that use pyrroloquinoline quinone, haem or cofactor F420 as cofactor, exemplified by methanol dehydrogenase of Paracoccus denitrificans, ethanol dehydrogenase of Acetobacter and Gluconobacter spp. and the alcohol dehydrogenases of certain archaebacteria. (3) Oxidases that catalyze an essentially irreversible oxidation of alcohols, such as methanol oxidase of Hansenula polymorpha and probably the veratryl alcohol oxidases of certain fungi involved in lignin degradation. This review deals mainly with those enzymes for which complete amino acid sequences are available. The discussion focuses on a comparison of their primary, secondary, tertiary, and quaternary structures and their catalytic mechanisms. The physiological roles of the enzymes and isoenzymes are also considered, as are their probable evolutionary relationships.

Correlation of apoptosis with change in intracellular labile Zn(II) using zinquin [(2-methyl-8-p-toluenesulphonamido-6-quinolyloxy)acetic acid], a new specific fluorescent probe for Zn(II)

Zinquin [(2-methyl-8-p-toluenesulphonamido-6-quinolyloxy)-acetic acid], a membrane-permeant fluorophore specific for Zn(II), was used with spectrofluorimetry and video image analysis to reveal and quantify labile intracellular Zn. Zinquin labelled human chronic-lymphocytic-leukaemia lymphocytes, rat splenocytes and thymocytes with a weak diffuse fluorescence that was quenched when intracellular Zn was chelated with NNN'N'-tetrakis-(2-pyridylmethyl)ethylenediamine (TPEN) and was greatly intensified by pretreatment of cells with the Zn ionophore pyrithione and exogenous Zn. There was substantial heterogeneity of labile Zn among ionophore-treated cells, and fluorescence was largely extranuclear. The average contents of labile Zn in human leukaemic lymphocytes, rat splenocytes and rat thymocytes were approx. 20, 31 and 14 pmol/10(6) cells respectively. Morphological changes and internucleosomal DNA fragmentation indicated substantial apoptosis in these cells when the level of intracellular labile Zn was decreased by treatment with TPEN. Conversely, increasing labile Zn by pretreatment with Zn plus pyrithione suppressed both spontaneous DNA fragmentation and that induced by the potent apoptosis-induced agents colchicine and dexamethasone. These results suggest that prevention of apoptosis is a function of labile Zn, and that a reduction below a threshold concentration in this Zn pool induces apoptosis.

Bacterial extracellular zinc-containing metalloproteases

Extracellular zinc-containing metalloproteases are widely distributed in the bacterial world. The most extensively studied are those which are associated with pathogenic bacteria or bacteria which have industrial significance. They are found practically wherever they are sought in both gram-negative and gram-positive microorganisms, be they aerobic or anaerobic. This ubiquity in itself implies that these enzymes serve important functions for the organisms which produce them. Because of the importance of zinc to enzymatic activity, it is not surprising that there is a pervasive amino acid sequence homology in the primary structure of this family of enzymes regardless of their source. The evidence suggests that both convergent and divergent evolutionary forces are at work. Within the large family of bacterial zinc-containing metalloendopeptidases, smaller family units are observed, such as thermolysin-like, elastase-like, and Serratia protease-like metalloproteases from various bacterial species. While this review was in the process of construction, a new function for zinc-containing metalloproteases was discovered: the neurotoxins of Clostridium tetani and Clostridium botulinum type B have been shown to be zinc metalloproteases with specificity for synaptobrevin, an integral membrane protein of small synaptic vesicles which is involved in neurotransmission. Additional understanding of the mode of action of proteases which contribute to pathogenicity could lead to the development of inhibitors, such as chelators, surrogate substrates, or antibodies, which could prevent or interrupt the disease process. Further studies of this broad family of metalloproteases will provide important additional insights into the pathogenesis and structure-function relationships of enzymes and will lead to the development of products, including "designer proteins," which might be industrially and/or therapeutically useful.

The Cytochrome c Reductase Integrated Processing Peptidase from Potato Mitochondria Belongs to a New Class of Metalloendoproteases

The general mitochondrial processing peptidase that removes the N-terminal targeting signals from proteins imported into mitochondria forms part of a respiratory protein complex in potato (Solanum tuberosum L.). We have termed this complex the "cytochrome c reductase/processing peptidase complex" and show that it acts on a variety of precursor proteins from different intramitochondrial locations. In potato, biochemical methods fail to separate the ubiquinol cytochrome c oxidoreductase function from the function of the processing protease. On the other hand, inhibition of electron flow with antimycin A or myxothiazol does not affect processing activity. The integration into an oligomeric protein complex causes the unique properties of the processing enzyme. It is fully active at high pH and in the presence of high salt. It does not need externally added metal ions, but it is inhibited by EDTA and 1,10-phenanthroline. Other protease inhibitors have no effect on the processing activity. Taken together, the molecular genetic and physiological results indicate that the mitochondrial processing protease does not belong to the thermolysin superfamily of metalloproteinases but may be a member of a new class of metalloendoproteases.

Cysteine-102 is positioned in the metal binding activation site of the Corynebacterium diphtheriae regulatory element DtxR

DNA sequence analysis of dtxR has shown that the M(r) 25,316 regulatory protein contains a single cysteine residue at position 102. DtxR readily forms inactive disulfide-linked dimers. We have used saturation site-directed mutagenesis of the cysteine codon (TGC) at position 102 in order to determine the role of this residue in metal ion binding. We show that the insertion of amino acids other than cysteine or aspartic acid into this position abolishes DtxR function both in vitro and in recombinant Escherichia coli DH5 alpha:lambda RS45toxPO/lacZ. Only those mutant alleles in which the TGC codon for Cys-102 was replaced by either TGT (Cys) or GCA (Asp) were found to direct the expression of active forms of DtxR that regulate the expression of beta-galactosidase from the toxPO/lacZ transcriptional fusion.

Botulinum neurotoxin A selectively cleaves the synaptic protein SNAP-25

Neurotransmitter release is potently blocked by a group of structurally related toxin proteins produced by Clostridium botulinum. Botulinum neurotoxin type B (BoNT/B) and tetanus toxin (TeTx) are zinc-dependent proteases that specifically cleave synaptobrevin (VAMP), a membrane protein of synaptic vesicles. Here we report that inhibition of transmitter release from synaptosomes caused by botulinum neurotoxin A (BoNT/A) is associated with the selective proteolysis of the synaptic protein SNAP-25. Furthermore, isolated or recombinant L chain of BoNT/A cleaves SNAP-25 in vitro. Cleavage occurred near the carboxyterminus and was sensitive to divalent cation chelators. In addition, a glutamate residue in the BoNT/A L chain, presumably required to stabilize a water molecule in the zinc-containing catalytic centre, was required for proteolytic activity. These findings demonstrate that BoNT/A acts as a zinc-dependent protease that selectively cleaves SNAP-25. Thus, a second component of the putative fusion complex mediating synaptic vesicle exocytosis is targeted by a clostridial neurotoxin.

Repair of DNA methylphosphotriesters through a metalloactivated cysteine nucleophile

The Escherichia coli Ada protein repairs methylphosphotriesters in DNA by direct, irreversible methyl transfer to one of its own cysteines. Upon methyl transfer, Ada acquires the ability to bind specific DNA sequences and thereby to induce genes that confer resistance to methylating agents. The amino-terminal domain of Ada, which comprises the methylphosphotriester repair and sequence-specific DNA binding elements, contains a tightly bound zinc ion. Analysis of the zinc binding site by cadmium-113 nuclear magnetic resonance and site-directed mutagenesis revealed that zinc participates in the autocatalytic activation of the active site cysteine and may also function as a conformational switch.

Basic features of class-I alcohol dehydrogenase: variable and constant segments coordinated by inter-class and intra-class variability. Conclusions from characterization of the alligator enzyme

The enzymatic and structural properties of alligator liver alcohol dehydrogenase have been determined. Aliphatic and alicyclic alcohols serve as substrates for this first reptilian form of the enzyme characterized, with Km values decreasing rapidly from methanol to hexanol, as for the human class I enzymes, and a Km of 1.2 mM for ethanol at pH 9.9. The N-terminus of the 374-residue protein chain is acetyl-blocked. The enzyme is related in descending order to class I > III > V > II of the structurally characterized mammalian alcohol dehydrogenases. This observation is compatible with the presence of a I/III ancestral line. Differences of the enzyme classes exceed those of the species, suggesting an early origin of the classes. Within its enzyme class, the reptilian protein is most closely related to the avian form (82% residue identities), and is closer to the human than to the amphibian form (76%, versus 69%, respectively). This establishes class I alcohol dehydrogenase as an enzyme having fairly constant rate of change during much of vertebrate evolution, approximately 10% residue differences/100 million years of separation between pairs compared. Residues interacting with the substrate and coenzyme are largely conserved. In the alligator enzyme, there are only four replacements in the substrate pocket compared with the human class I gamma subunit, and those are not known to have functional roles. These properties account for the kinetic parameters, and suggest distinct metabolic functions for the class I enzyme in vertebrates. Comparisons of the enzymes of the different vertebrate lines reveal that segment patterns are characteristic features of the class I enzymes. Three segments are 'variable', while two are 'constant', and both these types of segment are identical with those of the classes. There is extensive variability in close proximity to the active site of the enzyme and this appears to constitute a fundamental property of class I liver alcohol dehydrogenases in general.

Zinc coordination in mammalian sorbitol dehydrogenase. Replacement of putative zinc ligands by site-directed mutagenesis

Rat sorbitol dehydrogenase was expressed in Escherichia coli and purified to homogeneity, resulting in a protein with a specific activity of 4.7 U/mg, close to that of the enzyme isolated from mammalian liver. A Glu residue has been postulated to replace the Cys of alcohol dehydrogenase as a ligand to the active-site zinc atom of sorbitol dehydrogenase. This Glu (position 155 in the rat enzyme) was mutated both to Cys, in order to mimic the alcohol dehydrogenase relationships, and to Ala, as a control. A third mutation, Cys164 to Ala, was also performed since Cys has also been considered as a possible zinc ligand. With Ala at position 155, an inactive enzyme was obtained, showing that correct active-site relationships have been destroyed. With Cys at position 155, the enzyme is still partly active, but rapidly looses activity unless stabilized by the addition of ZnSO4. The catalytic efficiency in the oxidation of sorbitol is 120-fold less than that of the native form, and reduction of fructose is lost completely. In contrast, the activity of the Cys164Ala mutant is comparable with that of the native enzyme and, in fact, even increased in the oxidation of sorbitol. Combined, the results strongly suggest that Glu155 is a ligand to the active-site zinc atom. Zinc analysis of the different variants of sorbitol dehydrogenase establishes that all contain one atom of zinc/subunit, also when the catalytic function is lost. Apparently, zinc remains coordinated even after replacement with an amino acid residue (Ala) unable to ligand metal atoms.

Two distinct proteinase activities required for the processing of a putative nonstructural precursor protein of hepatitis C virus

Gene products of hepatitis C virus (HCV), a possible major causative agent of posttransfusion non-A, non-B hepatitis, are considered to be produced from a precursor polyprotein via proteolytic processing mediated by either host cell or viral proteinases. The presence of HCV serine proteinase has been proposed from analyses of amino acid sequence homology. To examine the processing mechanism of the HCV precursor polyprotein, the amino-terminal region of the putative nonstructural protein region of the HCV genome, containing the serine proteinase motif, was expressed and analyzed by using an in vitro transcription/translation system and a transient expression system in cultured cells. Two distinct proteinase activities which function in the production of a 70-kDa protein (p70) from the precursor polyprotein were detected. One of these proteinase activities, which cleaved the carboxyl (C)-terminal side of p70, required the presence of the serine proteinase motif, which is located in the amino (N)-terminal region of p70. That suggested that the predicted HCV serine proteinase was functional. The other activity, which was responsible for the cleavage of the N-terminal side of p70, required the expression of the region upstream and downstream of that cleavage site, including the p70 serine proteinase domain. From the results of pulse-chase analysis, using proteinase inhibitors coupled with a point mutation analysis, the latter activity was proposed to be a novel zinc-dependent metalloproteinase.

Implications of the three-dimensional structure of astacin for the structure and function of the astacin family of zinc-endopeptidases

Astacin, a zinc-endopeptidase from the crayfish Astacus astacus L., represents a structurally distinct group of metalloproteinases termed the 'astacin family'. This protein family includes oligomeric membrane-bound proteins with zinc proteinase domains found in rodent kidneys (meprins A and B) and human small intestine (N-benzoyl-L-tyrosyl-4-aminobenzoate hydrolase). Another branch of this family comprises morphogenetically active proteins, which induce bone formation (human bone morphogenetic protein 1), or which play specific roles during the embryonic development of amphibians, fishes, echinoderms, and insects. The X-ray crystal structure of astacin has recently been solved to a resolution of 0.18 nm [Bode et al. (1992) Nature 358, 164-167]. This structure is different from hitherto known metalloendopeptidase structures and has been used in the present study to analyze the structures of the other members of the astacin protein family. Computer-assisted modelling of the proteolytic domain of the alpha-subunit of meprin A based on the astacin structure is possible if five single and one double residue deletions and three single residue insertions are implied. The proteinase domains of the other astacins can be included in the model-based sequence alignment by introducing additionally three insertions and one deletion. All of these insertions and deletions are observed in loop segments connecting regular secondary structure elements and should leave the overall structure unaltered. The topology of residues forming the zinc-binding active site of astacin corresponds to almost identical arrangements in all other astacins, suggesting that these are likewise metalloproteinases. Based on this similarity, it is proposed that the active-site metal ion of the astacins is penta-coordinated by three histidine residues, a tyrosine residue and a water molecule in a trigonal bipyramidal geometry. Other remarkable common features are a hydrophobic cluster in the N-terminal domain and a conserved, solvent-filled cavity buried in the C-terminal domain. Most interestingly, the amino-termini of all astacins can be modelled to start in a corresponding internal water cavity as seen in the astacin template, where the terminal alanine residue forms a water-linked salt bridge to Glu103, directly adjacent to His102, the third zinc ligand. Therefore, an activation mechanism for the astacins reminiscent of that of the trypsin-like proteinases had been suggested, which now seems to be probable also for the other astacins. Besides these common traits, there are some minor differences which may have important consequences on the function of the astacins.(ABSTRACT TRUNCATED AT 400 WORDS)

Cocatalytic zinc motifs in enzyme catalysis

Cocatalytic zinc binding sites are characteristic of enzyme molecules which contain two or more zinc and/or other metal atoms. In each site an aspartate, glutamate, or histidine residue simultaneously binds to two zinc atoms or a zinc and a different metal atom. In the resultant amino acid bridge, two of the cocatalytic metal atoms bind to the same amino acid. Consequently the participating metal atoms are in close proximity and function as a catalytic unit, typical of this motif. In these functional units aspartate seems to be preferred over glutamate. Serine, threonine, tryptophan, and lysine residues are encountered as zinc ligands, although they have not so far been identified as ligands in monozinc enzymes or DNA-binding zinc proteins. The resultant coordination spheres and their mechanistic implications raise interesting questions for further study.

Specificity of Streptomyces griseus aminopeptidase and modulation of activity by divalent metal ion binding and substitution

Streptomyces griseus aminopeptidase is a calcium-activated zinc metalloenzyme characterized by a high enzymic reactivity, high thermal stability and low molecular mass [Spungin, A. and Blumberg, S. (1989) Eur. J. Biochem. 183, 471-477]. A study of the specificity of S. griseus aminopeptidase using amino acid 4-nitroanilide substrates shows that the leucine derivative is the best substrate. Derivatives of other hydrophobic amino acids, methionine and phenylalanine, are also excellent substrates for the enzyme. The 4-nitroanilides of alanine, valine, proline and lysine are good substrates whereas those of the small size glycine and the acidic amino acids are very poor. No hydrolysis of a terminal Xaa residue can be detected with Xaa-proline N-terminal sequences. Calcium ions bind to the enzyme and modulate its activity in a substrate-dependent manner. The catalytically essential zinc of S. griseus aminopeptidase is removed by dialysis against 1,10-phenanthroline and replaced by manganese or cobalt ions, resulting in enzyme derivatives of altered specificities. Thus, whereas the zinc enzyme hydrolyzes leucine 4-nitroanilide at a 10-fold faster rate than the manganese or cobalt enzymes, the cobalt enzyme hydrolyzes alanine 4-nitroanilide at a more than 20-fold faster rate than the zinc or manganese enzymes.

Phosphomannose isomerase from Saccharomyces cerevisiae contains two inhibitory metal ion binding sites

Phosphomannose isomerase (PMI) from Saccharomyces cerevisiae is a zinc-dependent metalloenzyme. Besides its role in catalysis, zinc is also a potent inhibitor of the enzyme. The inhibition is competitive with the substrate mannose 6-phosphate, with Kis = 6.4 microM in 50 mM Tris-HCl buffer, pH 8.0, at 37 degrees C. This inhibition constant is 4 orders of magnitude smaller than for group II divalent cations, indicating that the binding is not primarily electrostatic. Micromolar inhibition is also observed with ions of the other metals of the electronic configuration d10. Under identical conditions, cadmium is a predominantly competitive inhibitor with Kis = 19.5 microM. Inhibition by mercury is predominantly competitive with Kis = 6.0 microM but shows a hyperbolic Dixon plot. Theorell-Yonetani double-inhibition analysis shows that zinc and cadmium ions are mutually exclusive inhibitors against mannose 6-phosphate. However, analysis of zinc and mercury double inhibition shows that they can simultaneously bind in the mannose 6-phosphate binding pocket, with only a small mutual repulsion. Inhibition of the enzyme by cadmium and zinc ions is strongly pH dependent with pKa = 9.2 for cadmium and one pKa at 6.6 and two at 8.9 for zinc. The inhibitory species are the monohydroxide forms, Zn(OH)+ and Cd(OH)+. However, inhibition by mercury is relatively pH-independent, consistent with the neutral Hg(OH)2 being the inhibitory species. In all three cases, the metal ion binding causes a conformational change in the enzyme as judged by tryptophan fluorescence.(ABSTRACT TRUNCATED AT 250 WORDS)

Human 92 kDa type IV collagenase: functional analysis of fibronectin and carboxyl-end domains

Two closely related secreted metalloproteases 72 and 92 kDa type IV collagenases (72- and 92T4Cl) consist of several structural domains, the functions of which are poorly understood. Both metalloproteases can bind to gelatin as well as form complexes with specific inhibitors in the proenzyme form. The biologic role of the proenzyme-inhibitor complex formation remained unclear. Here we summarize results demonstrating that the fibronectin-like domain of 92T4Cl mediates gelatin binding of the proenzyme, while the hemopexin like carboxy-terminal domain is essential for the complex formation of the proenzyme with TIMP. The formation of a 92T4Cl proenzyme complex with TIMP prevents dimerization, formation of the novel complex with ClI proenzyme, and activation of the 92T4Cl by stromelysin. Conversely, formation of the covalent 92T4Cl homodimer excludes the formation of a proenzyme-TIMP complex, thus allowing this form of enzyme to enter into the proteolytic cascade of activation. Both components of the 92T4Cl-ClI complex can be activated in a fashion similar to that of free enzymes, yielding a complex active against both gelatin and fibrillar collagen.

Zyxin and cCRP: two interactive LIM domain proteins associated with the cytoskeleton

Interaction with extracellular matrix can trigger a variety of responses by cells including changes in specific gene expression and cell differentiation. The mechanism by which cell surface events are coupled to the transcriptional machinery is not understood, however, proteins localized at sites of cell-substratum contact are likely to function as signal transducers. We have recently purified and characterized a low abundance adhesion plaque protein called zyxin (Crawford, A. W., and M. C. Beckerle. 1991. J. Biol. Chem. 266:5847-5853; Crawford, A. W., J. W. Michelsen, and M. C. Beckerle. 1992. J. Cell Biol. 116:1381-1393). We have now isolated and sequenced zyxin cDNA and we report here that zyxin exhibits an unusual proline-rich NH2-terminus followed by three tandemly arrayed LIM domains. LIM domains have previously been identified in proteins that play important roles in transcriptional regulation and cellular differentiation. LIM domains have been proposed to coordinate metal ions and we have demonstrated by atomic absorption spectroscopy that purified zyxin binds zinc, a result consistent with the idea that zyxin has zinc fingers. In addition, we have discovered that zyxin interacts in vitro with a 23-kD protein that also exhibits LIM domains. Microsequence analysis has revealed that the 23-kD protein (or cCRP) is the chicken homologue of the human cysteine-rich protein (hCRP). By double-label indirect immunofluorescence, we found that zyxin and cCRP are extensively colocalized in chicken embryo fibroblasts, consistent with the idea that they interact in vivo. We conclude that LIM domains are zinc-binding sequences that may be involved in protein-protein interactions. The demonstration that two cytoskeletal proteins, zyxin and cCRP, share a sequence motif with proteins important for transcriptional regulation raises the possibility that zyxin and cCRP are components of a signal transduction pathway that mediates adhesion-stimulated changes in gene expression.

Reverse transcriptase of human immunodeficiency virus can use either human tRNA(3Lys) or Escherichia coli tRNA(2Gln) as a primer in an in vitro primer-utilization assay

Although the reverse transcriptase (RT) of human immunodeficiency virus (HIV) uses human tRNA(3Lys) as a primer of viral genome DNA synthesis in vivo, HIV RT binds Escherichia coli glutamine tRNA and in vitro-made human lysine tRNA with nearly equivalent affinities. We show that HIV RT can use either tRNA(3Lys) or tRNA(2Gln) as a primer for DNA synthesis in vitro without the addition of any other host or viral proteins. E. coli tRNA(2Gln) can serve as a primer for HIV RT if a primer-binding site sequence complementary to the 3' end of tRNA(2Gln) is at the 3' end of the template. With this reduced template, the specificity of binding the proper tRNA is due to base-pairing between a bound tRNA to the primer-binding site of the viral RNA template rather than sequence-specific recognition of tRNA(3Lys) by RT. If an 8-nucleotide viral sequence 3' to the primer-binding site is included in the template, then addition of Zn2+ or Co2+ is required for tRNA(3Lys)-primed synthesis, and tRNA(2Gln) now fails to prime synthesis. The latter result implies that a template sequence adjacent to the primer-binding site and containing 6 nucleotides complementary to the anticodon loop of human tRNA(3Lys) plays an active role in tRNA discrimination.

Progressive sequence alignment and molecular evolution of the Zn-containing alcohol dehydrogenase family

Sequences of 47 members of the Zn-containing alcohol dehydrogenase (ADH) family were aligned progressively, and an evolutionary tree with detailed branch order and branch lengths was produced. The alignment shows that only 9 amino acid residues (of 374 in the horse liver ADH sequence) are conserved in this family; these include eight Gly and one Val with structural roles. Three residues that bind the catalytic Zn and modulate its electrostatic environment are conserved in 45 members. Asp 223, which determines specificity for NAD, is found in all but the two NADP-dependent enzymes, which have Gly or Ala. Ser or Thr 48, which makes a hydrogen bond to the substrate, is present in 46 members. The four Cys ligands for the structural zinc are conserved except in zeta-crystallin, the sorbitol dehydrogenases, and two bacterial enzymes. Analysis of the evolutionary tree gives estimates of the times of divergence for different animal ADHs. The human class II (pi) and class III (chi) ADHs probably diverged about 630 million years ago, and the newly identified human ADH6 appeared about 520 million years ago, implying that these classes of enzymes may exist or have existed in all vertebrates. The human class I ADH isoenzymes (alpha, beta, and gamma) diverged about 80 million years ago, suggesting that these isoenzymes may exist or have existed in all primates. Analysis of branch lengths shows that these plant ADHs are more conserved than the animal ones and that class III ADHs are more conserved than class I ADHs. The rate of acceptance of point mutations (PAM units) shows that selection pressure has existed for ADHs, implying that these enzymes play definite metabolic roles.

A synthetic peptide encompassing the binding site of the second zinc atom (the 'structural' zinc) of alcohol dehydrogenase

A 23-residue peptide was synthesized that incorporates the loop which binds the structural zinc atom of mammalian alcohol dehydrogenases and contributes, in part, to subunit interactions in the native enzyme. Neither the amino acid composition nor the sequence of the peptide resemble those of zinc fingers. The reduced peptide stoichiometrically binds zinc or cobalt to form stable complexes with a dissociation constant of the peptide/CO2+ complex of 2.1 microM at pH 7.5. EDTA disrupts the complex. The absorption and magnetic circular dichroic spectra of the cobalt-peptide are indicative of a tetrahedral coordination geometry, and are similar to those of the cobalt-substituted structural site of horse and human (beta 1 beta 1) liver alcohol dehydrogenases. Consequently, the synthetic peptide can serve as a model for the metal-binding segment of alcohol dehydrogenase and for studies of fundamental problems concerning protein/metal interactions.

Characterization of 4-hydroxyphenylpyruvate dioxygenase. Primary structure of the Pseudomonas enzyme

The primary structure of Pseudomonas 4-hydroxyphenylpyruvate dioxygenase was determined. Sequence degradation of the intact protein and of peptides from three different digests of the carboxymethylated protein established a 357-residue polypeptide chain with a free alpha-amino group. Hydroxylamine cleavage at a single Asn-Gly sequence was useful. Comparisons with known structures in data banks revealed no close relationship with other characterized proteins. The human enzyme has a related composition, suggesting that also the eukaryotic form belongs to this protein type, but with a blocked N-terminus like in many other eukaryotic intracellular proteins. Secondary structure predictions suggest an alpha/beta mixed structure, fairly typical of globular proteins, without long segments of hydrophobicity or charge, although a region in the middle of the C-terminal third of the subunit appears to have the most extreme properties. A ferric centre, correlating with enzyme activity and absorbance at 595 nm, has previously been assigned to tyrosinate coordination. The Tyr and His distributions, and the position of a single Cys residue, all suggest a few likely sites, outside the C-terminal segment, for this centre.

Bestatin inhibits covalent coupling of [3H]LTA4 to human leukocyte LTA4 hydrolase

The covalent coupling of [3H]LTA4 to human leukocyte LTA4 hydrolase is inhibited in a concentration-dependent fashion by pre-incubation with bestatin. This inhibition correlated with the concentration-dependent inhibition by bestatin of LTB4 and LTB5 synthesis by LTA4 hydrolase. Epibestatin, a diastereomer of bestatin, neither inhibited LTB4 or LTB5 production by LTA4 hydrolase nor prevented the covalent coupling of [3H]LTA4 to the enzyme. In contrast, captopril inhibited both LTB4 synthesis by LTA4 hydrolase and covalent coupling of [3H]LTA4 to the enzyme.

Zinc plays both structural and catalytic roles in metalloproteins

Zinc is bound to the catalytic site of zinc-dependent hydrolases by three amino acid residues, commonly histidines and glutamic acid, and to the structural site of gene transcription regulators by cysteine and histidine. Site-directed mutagenesis of even one catalytic-site ligand destroys enzyme activity without changing physical properties of the protein, including immunoreactivity. However, nutritional studies demonstrating loss of transcriptional activity upon zinc deprivation have not been reported.

Purification and Developmental Analysis of a Metalloendoproteinase from the Leaves of Glycine max

A metalloendoproteinase from leaves of soybean (Glycine max) has been purified 1160-fold to electrophoretic homogeneity. The native protein is monomeric with a molecular mass of 15 kilodaltons as estimated by gel filtration and 19 kilodaltons as estimated by denaturing gel electrophoresis. The enzyme has a pH optima of 8.0 to 9.0 using Azocoll as substrate. The proteolytic activity is susceptible to metal chelating agents and the inactivated enzyme can be restored to 69% of original activity by the addition of ZnCl(2). Western analysis shows that a fraction of the soybean metalloendoproteinase is present within the extracellular space of older leaves. Soybean metalloendoproteinase 1 is the Azocollase A activity first described by Ragster and Chrispeels (Plant Physiol 64: 857-862; 1979).

Zn(2+)-induced deprotonation of a peptide nitrogen in angiotensin I

The interaction of Zn2+ with angiotensin I, a decapeptide containing two histidyl residues, has been studied by 1H-NMR spectroscopy in both water and dimethylsulfoxide. When Zn2+ is added to the peptide in dimethylsulfoxide, binding occurs by coordination of the imidazole rings of both histidines to the metal-ion, enabling the deprotonation of the Phe peptide nitrogen.

Dimerization of human growth hormone by zinc

Size-exclusion chromatography and sedimentation equilbrium studies demonstrated that zinc ion (Zn2+) induced the dimerization of human growth hormone (hGH). Scatchard analysis of 65Zn2+ binding to hGH showed that two Zn2+ ions associate per dimer of hGH in a cooperative fashion. Cobalt (II) can substitute for Zn2+ in the hormone dimer and gives a visible spectrum characteristic of cobalt coordinated in a tetrahedral fashion by oxygen- and nitrogen-containing ligands. Replacement of potential Zn2+ ligands (His18, His21, and Glu174) in hGH with alanine weakened both Zn2+ binding and hGH dimer formation. The Zn(2+)-hGH dimer was more stable than monomeric hGH to denaturation in guanidine-HCl. Formation of a Zn(2+)-hGH dimeric complex may be important for storage of hGH in secretory granules.

Sorbitol dehydrogenase: cDNA coding for the rat enzyme. Variations within the alcohol dehydrogenase family independent of quaternary structure and metal content

Two separate cDNA-clones, together coding for rat sorbitol dehydrogenase, have been isolated from a liver cDNA library in lambda gt11 by screening with oligonucleotide probes. One clone contained a 1020-bp fragment starting at the codon for amino acid residue 104 and ending with a 261-bp 3' non-coding region, the second encompassed the entire 5' region and ended with a 3' truncation corresponding to amino acid residue 315. The coding region consists of 356 amino acid residues, one more than in the human and sheep enzymes. The presence of the extra residue at position 3, a proline, can be explained by a shifted splice point in the mRNA. The primary structure of rat sorbitol dehydrogenase allows triplet comparisons of three distinct rat-ungulate-human enzymes differing in quaternary structure and metal content within the zinc-containing alcohol dehydrogenase family. The variability of sorbitol dehydrogenase (tetramer with one zinc atom/subunit; no activity towards ethanol) is large (18%), exactly like that for the class I alcohol dehydrogenase (dimer with two zinc atoms/subunit; no activity towards sorbitol), differing threefold from that of the class III alcohol dehydrogenase/glutathione-dependent formaldehyde dehydrogenase (dimer with two zinc atoms/subunit; 6% variability) suggesting that the distinct extents of variability within this protein family are independent of substrate specificity, metal content and quaternary structure.