Site-directed mutagenesis of the putative catalytic triad of poliovirus 3C proteinase.

Based on predictions of the structure of proteinase 3C of poliovirus, mutations have been made at residues that are supposed to constitute the catalytic triad. Wild-type and mutant 3C were expressed in Escherichia coli, purified to homogeneity, and characterized by the ability to cleave a synthetic peptide substrate or an in vitro translated polypeptide consisting of part of the polyprotein of poliovirus. Additionally, the ability of autocatalytic processing of a precursor harboring wild-type or mutant 3C sequences was tested. Single substitutions of the residues His-40, Glu-71, and Cys-147 by Tyr, Gln, and Ser, respectively, resulted in an inactive enzyme. Replacement of Asp-85 by Asn resulted in an enzyme that was as active as wild-type enzyme in trans cleavage assays but whose autoprocessing ability was impaired. Our results are consistent with the proposal that residues His-40, Glu-71, and Cys-147 constitute the catalytic triad of poliovirus 3C proteinase. Furthermore, residue Asp-85 is not required for proper proteolytic activity despite being highly conserved between different picornaviruses. This indicates that Asp-85 might be involved in a different function of 3C.     

Molecular isolation and characterization of novel four subisoforms of ECE-2

Although the four polypeptides of blasticidin S (BS) deaminase (BSD) are packed rather tightly coordinated to the "structural and catalytic" zinc atom of each subunit, the C-terminal region of the enzyme was suggested to be somewhat molten and flexible [M. Kimura, S. Sekido, Y. Isogai, and I. Yamaguchi (2000) J. Biochem. 127, 955-963]. To understand roles of this flexible region, we constructed five C-terminal deletion variants of BSD (each successively deleted from the C-terminal end up to five residues) and analyzed their biochemical properties focusing on the structure and activity of the enzyme. BSD and all of the deletion mutants showed the unique rigid conformation (e.g., characterized by their stabilities in SDS solution) and high levels of resistance against protease digestions. Furthermore, both the wild-type and deletion apoenzymes exhibited similar physical properties in thermodynamic refolding into the stable tetramer conformation. However, these small C-terminal deletions exerted deleterious effects on the catalytic efficiency of the enzyme as indicated by their strongly reduced k(cat)/K(m) value. Judging from the altered kinetic parameters and unaltered structural properties of the deletion variants, these C-terminal residues appear to be directly involved in enzyme-substrate interaction. In this short flexible region, Tyr-126, Trp-128, and Gly-130 were the key residues. Most notably, removal of Gly-130 markedly increased K(m) for BS without affecting its k(cat) value. These results indicate that the flexible C-terminal region is important for catalytic function and that a single Gly residue at the C-terminal end of BSD contributes significantly in facilitating access of a substrate to the active site.     

Solvent-stable Pseudomonas aeruginosa PseA protease gene: identification, molecular characterization, phylogenetic and bioinformatic analysis to study reasons for solvent stability

We have previously isolated a solvent-stable protease from a novel solvent-tolerant strain of Pseudomonas aeruginosa (PseA). Here we report cloning and characterization of the gene coding for this solvent-tolerant protease. A homology search of the N-terminal amino acid sequence of the purified PseA protease revealed an exact match to a P. aeruginosa PST-01 protease gene, lasB. The c-DNA sequence of the PST-01 protease was used to design primers for the amplification of a 1,494-bp open reading frame encoding a 53.6-kDa, 498-amino-acid PseA LasB polypeptide. The deduced PseA LasB protein contained a 23-residue signal peptide (2.6 kDa) followed by a propeptide of 174 residues and a 33-kDa mature product of 301 residues. A phylogenetic analysis placed PseA lasB closest to the known zinc metalloproteases from P. aeruginosa. This gene was also found to contain a conserved HEXXH zinc-binding motif, characteristic of all zinc metallopeptidases. The 3D structure analysis of PseA protease revealed the presence of 7 alpha-helices (36% of the sequence). The molecule was found to have two disulfide bonds (between Cys-227 and Cys-255 and between Cys-467 and Cys-494) and had a number of hydrophobic clusters at the protein surface. These hydrophobic patches (21% of the sequence) and disulfide bonds may possibly be responsible for the solvent-stable nature of the enzyme.     

Structural, kinetic, and mutational studies of the zinc ion environment in tetrameric cytidine deaminase

The zinc-containing cytidine deaminase (CDA, EC 3.5.4.5) is a pyrimidine salvage enzyme catalyzing the hydrolytic deamination of cytidine and 2'-deoxycytidine forming uridine and 2'-deoxyuridine, respectively. Homodimeric CDA (D-CDA) and homotetrameric CDA (T-CDA) both contain one zinc ion per subunit coordinated to the catalytic water molecule. The zinc ligands in D-CDA are one histidine and two cysteine residues, whereas in T-CDA zinc is coordinated to three cysteines. Two of the zinc coordinating cysteines in T-CDA form hydrogen bonds to the conserved residue Arg56, and this residue together with the dipole moments from two alpha-helices partially neutralizes the additional negative charge in the active site, leading to a catalytic activity similar to D-CDA. Arg56 has been substituted by a glutamine (R56Q), the corresponding residue in D-CDA, an alanine (R56A), and an aspartate (R56D). Moreover, one of the zinc-liganding cysteines has been substituted by histidine to mimic D-CDA, alone (C53H) and in combination with R56Q (C53H/R56Q). R56A, R56Q, and C53H/R56Q contain the same amount of zinc as the wild-type enzyme. The zinc-binding capacity of R56D is reduced. Only R56A, R56Q, and C53H/R56Q yielded measurable CDA activity, R56A and R56Q with similar K(m) but decreased V(max) values compared to wild-type enzyme. Because of dissociation into its inactive subunits, it was impossible to determine the kinetic parameters for C53H/R56Q. R56A and C53H/R56Q display increased apparent pK(a) values compared to the wild-type enzyme and R56Q. On the basis of the structures of R56A, R56Q, and C53H/R56Q an explanation is provided of kinetic results and the apparent instability of C53H/R56Q.     

"Zn-link": a metal-sharing interface that organizes the quaternary structure and catalytic site of the endoribonuclease, RNase E

Ribonuclease E is an essential hydrolytic endonuclease in Escherichia coli, and it plays a central role in maintaining the balance and composition of the messenger RNA population. The enzyme is also required for rRNA and tRNA processing. We have shown earlier that the highly conserved catalytic domain of E. coli RNase E is a homotetramer [Callaghan, A. J. et al. (2003) Biochemistry 42, 13848-13855]. Here, we report that this quaternary organization requires zinc. Two protomers share a single zinc ion, and quantitative analysis indicates that each protein contributes two cysteine thiols toward the coordination of the metal. The candidate cysteines are part of a motif that is conserved in the RNase E protein family, and mutation of these residues causes the partial loss of zinc, the complete disruption of the tetramer into dimers, and effective catalytic inactivation. However, these mutations do not affect RNA binding. The tetramer can be artificially maintained by disulfide bond formation, which fully displaces the zinc but largely preserves the catalytic activity. Thus, catalytic activity does not require zinc directly but does require the quaternary structure, for which the metal is essential. We propose that the RNase E tetramer has two nonequivalent subunit interfaces, one of which is mediated by a single, tetrathiol-zinc complex, which we refer to as a "Zn-link" motif. One or both interfaces organize the active site, which is distinct from the primary site of RNA binding.     

Crystal structures of blasticidin S deaminase (BSD): implications for dynamic properties of catalytic zinc

The set of blasticidin S (BS) and blasticidin S deaminase (BSD) is a widely used selectable marker for gene transfer experiments. BSD is a member of the cytidine deaminase (CDA) family; it is a zinc-dependent enzyme with three cysteines and one water molecule as zinc ligands. The crystal structures of BSD were determined in six states (i.e. native, substrate-bound, product-bound, cacodylate-bound, substrate-bound E56Q mutant, and R90K mutant). In the structures, the zinc position and coordination structures vary. The substrate-bound structure shows a large positional and geometrical shift of zinc with a double-headed electron density of the substrate that seems to be assigned to the amino and hydroxyl groups of the substrate and product, respectively. In this intermediate-like structure, the steric hindrance of the hydroxyl group pushes the zinc into the triangular plane consisting of three cysteines with a positional shift of approximately 0.6 A, and the fifth ligand water approaches the opposite direction of the substrate with a shift of 0.4 A. Accordingly, the zinc coordination is changed from tetrahedral to trigonal bipyramidal, and its coordination distance is extended between zinc and its intermediate. The shift of zinc and the recruited water is also observed in the structure of the inactivated E56Q mutant. This novel observation is different in two-cysteine cytidine deaminase Escherichia coli CDA and might be essential for the reaction mechanism in BSD, since it is useful for the easy release of the product by charge compensation and for the structural change of the substrate.     

Identification of acid-base catalytic residues of high-Mr thioredoxin reductase from Plasmodium falciparum

High-M(r) thioredoxin reductase from the malaria parasite Plasmodium falciparum (PfTrxR) contains three redox active centers (FAD, Cys-88/Cys-93, and Cys-535/Cys-540) that are in redox communication. The catalytic mechanism of PfTrxR, which involves dithiol-disulfide interchanges requiring acid-base catalysis, was studied by steady-state kinetics, spectral analyses of anaerobic static titrations, and rapid kinetics analysis of wild-type enzyme and variants involving the His-509-Glu-514 dyad as the presumed acid-base catalyst. The dyad is conserved in all members of the enzyme family. Substitution of His-509 with glutamine and Glu-514 with alanine led to TrxR with only 0.5 and 7% of wild type activity, respectively, thus demonstrating the crucial roles of these residues for enzymatic activity. The H509Q variant had rate constants in both the reductive and oxidative half-reactions that were dramatically less than those of wild-type enzyme, and no thiolateflavin charge-transfer complex was observed. Glu-514 was shown to be involved in dithiol-disulfide interchange between the Cys-88/Cys-93 and Cys-535/Cys-540 pairs. In addition, Glu-514 appears to greatly enhance the role of His-509 in acid-base catalysis. It can be concluded that the His-509-Glu-514 dyad, in analogy to those in related oxidoreductases, acts as the acid-base catalyst in PfTrxR.     

Cytidine deaminases from B. subtilis and E. coli: compensating effects of changing zinc coordination and quaternary structure.

Cytidine deaminase from E. coli is a dimer of identical subunits (M(r) = 31 540), each containing a single zinc atom. Cytidine deaminase from B. subtilis is a tetramer of identical subunits (M(r) = 14 800). After purification from an overexpressing strain, the enzyme from B. subtilis is found to contain a single atom of zinc per enzyme subunit by flame atomic absorption spectroscopy. Fluorescence titration indicates that each of the four subunits contains a binding site for the transition state analogue inhibitor 5-fluoro-3,4-dihydrouridine. A region of amino acid sequence homology, containing residues that are involved in zinc coordination in the enzyme from E. coli, strongly suggests that in the enzyme from B. subtilis, zinc is coordinated by the thiolate side chains of three cysteine residues (Cys-53, Cys-86, and Cys-89) [Song, B. H., and Neuhard, J. (1989) Mol. Gen. Genet. 216, 462-468]. This pattern of zinc coordination appears to be novel for a hydrolytic enzyme, and might be expected to reduce the reactivity of the active site substantially compared with that of the enzyme from E. coli (His-102, Cys-129, and Cys-132). Instead, the B. subtilis and E. coli enzymes are found to be similar in their activities, and also in their relative binding affinities for a series of structurally related inhibitors with binding affinities that span a range of 6 orders of magnitude. In addition, the apparent pK(a) value of the active site is shifted upward by less than 1 unit. Sequence alignments, together with model building, suggest one possible mechanism of compensation.     

Site-directed mutagenesis and high-resolution NMR spectroscopy of the active site of porphobilinogen deaminase

The active site of porphobilinogen (PBG)1 deaminase (EC 4.3.1.8) from Escherichia coli has been found to contain an unusual dipyrromethane derived from four molecules of 5-aminolevulinic acid (ALA) covalently linked to Cys-224, one of the two cysteine residues conserved in E. coli and human deaminase. By use of a hemA- strain of E. coli the enzyme was enriched from [5-13C]ALA and examined by 1H-detected multiple quantum coherence spectroscopy, which revealed all of the salient features of a dipyrromethane composed of two PBG units linked head to tail and terminating in a CH2-S bond to a cysteine residue. Site-specific mutagenesis of Cys-99 and Cys-242, respectively, has shown that substitution of Ser for Cys-99 does not affect the enzymatic activity, whereas substitution of Ser for Cys-242 removes essentially all of the catalytic activity as measured by the conversion of the substrate PBG to uro'gen I. The NMR spectrum of the covalent complex of deaminase with the suicide inhibitor 2-bromo-[2,11-13C2]PBG reveals that the aninomethyl terminus of the inhibitor reacts with the enzyme's cofactor at the alpha-free pyrrole. NMR spectroscopy of the ES2 complex confirmed a PBG-derived head-to-tail dipyrromethane attached to the alpha-free pyrrole position of the enzyme. A mechanistic rationale for deaminase is presented.     

Determination of disulfide array and subunit structure of taste-modifying protein, miraculin

The taste-modifying protein, miraculin (Theerasilp, S. et al. (1989) J. Biol. Chem. 264, 6655-6659) has seven cysteine residues in a molecule composed of 191 amino acid residues. The formation of three intrachain disulfide bridges at Cys-47-Cys-92, Cys-148-Cys-159 and Cys-152-Cys-155 and one interchain disulfide bridge at Cys-138 was determined by amino acid sequencing and composition analysis of cystine-containing peptides isolated by HPLC. The presence of an interchain disulfide bridge was also supported by the fact that the cystine peptide containing Cys-138 showed a negative color test for the free sulfhydryl group and a positive test after reduction with dithiothreitol. The molecular mass of non-reduced miraculin (43 kDa) in sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) was nearly twice the calculated molecular mass based on the amino acid sequence and the carbohydrate content of reduced miraculin (25 kDa). The molecular mass of native miraculin determined by low-angle laser light scattering was 90 kDa. Application of a crude extract of miraculin to a Sephadex G-75 column indicated that the taste-modifying activity appears at 52 kDa. It was concluded that native miraculin in pure form is a tetramer of the 25 kDa-peptide and native miraculin in crude state or denatured, non-reduced miraculin in pure form is a dimer of the peptide. Both tetramer miraculin and native dimer miraculin in crude state had the taste-modifying activity.     

Identification of essential amino acid residues for catalytic activity and thermostability of novel chitosanase by site-directed mutagenesis

The functional importance of a conserved region in a novel chitosanase from Bacillus sp. CK4 was investigated. Each of the three carboxylic amino acid residues (Glu-50, Glu-62, and Asp-66) was changed to Asp and Gln or Asn and Glu by site-directed mutagenesis, respectively. The Asp-66-->Asn and Asp-66-->Glu mutation remarkably decreased kinetic parameters such as Vmax and kcat to approximately 1/1,000 those of the wild-type enzyme, indicating that the Asp-66 residue was essential for catalysis. The thermostable chitosanase contains three Cys residues at positions 49, 72, and 211. The Cys-49-->Ser/Tyr and Cys-72-->Ser/Tyr mutant enzymes were as stable to thermal inactivation and denaturating agents as the wild-type enzyme. However, the half-life of the Cys-211-->Ser/Tyr mutant enzyme was less than 10 min at 80 degrees C, while that of the wild-type enzyme was about 90 min. Moreover, the residual activity of Cys-211-->Ser/Tyr enzyme was substantially decreased by 8 M urea; and it lost all catalytic activity in 40% ethanol. These results show that the substitution of Cys with any amino acid residues at position 211 seems to affect the conformational stability of the chitosanase.     

Identification of a zinc finger domain in the human NEIL2 (Nei-like-2) protein

The recently identified human NEIL2 (Nei-like-2) protein, a DNA glycosylase/AP lyase specific for oxidatively damaged bases, shares structural features and reaction mechanism with the Escherichia coli DNA glycosylases, Nei and Fpg. Amino acid sequence analysis of NEIL2 suggested it to have a zinc finger-like Nei/Fpg. However, the Cys-X2-His-X16-Cys-X2-Cys (CHCC) motif present near the C terminus of NEIL2 is distinct from the zinc finger motifs of Nei/Fpg, which are of the C4 type. Here we show the presence of an equimolar amount of zinc in NEIL2 by inductively coupled plasma mass spectrometry. Individual mutations of Cys-291, His-295, Cys-315, and Cys-318, candidate residues for coordinating zinc, inactivated the enzyme by abolishing its DNA binding activity. H295A and C318S mutants were also shown to lack bound zinc, and a significant change in their secondary structure was revealed by CD spectra analysis. Molecular modeling revealed Arg-310 of NEIL2 to be a critical residue in its zinc binding pocket, which is highly conserved throughout the Fpg/Nei family. A R310Q mutation significantly reduced the activity of NEIL2. We thereby conclude that the zinc finger motif in NEIL2 is essential for its structural integrity and enzyme activity.     

Characterization of the metallocenter of rabbit skeletal muscle AMP deaminase. Evidence for a dinuclear zinc site

XAS of Zn-peptide binary and ternary complexes prepared using peptides mimicking the potential metal binding sites of rabbit skeletal muscle AMP deaminase (AMPD) strongly suggest that the region 48-61 of the enzyme contains a zinc binding site, whilst the region 360-372 of the enzyme is not able to form 1:1 complexes with zinc, in contrast with what has been suggested for the corresponding region of yeast AMPD. XAS performed on fresh preparations of rabbit skeletal muscle AMPD provides evidence for a dinuclear zinc site in the enzyme compatible with a (mu-aqua)(mu-carboxylato)dizinc(II) core with an average of two histidine residues at each metal site and a Zn-Zn distance of about 3.3 Angstrom. The data indicate that zinc is not required for HPRG/AMPD interaction, both zinc ions being bound to the catalytic subunit of the enzyme, one to the three conserved amino acid residues among those four assumed to be in contact with zinc in yeast AMPD, and the other at the N-terminal region, probably to His-52, Glu-53 and His-57. Tryptic digests of different enzyme preparations demonstrate the existence of two different protein conformations and of a zinc ion connecting the N-terminal and C-terminal regions of AMPD.     

Characterization of the large subunit of EcoHK31I methyltransferase by structural modeling and mutagenesis

M.EcoHK31I is a naturally occurring mC5-methyltransferase with a large alpha polypeptide and a small beta polypeptide. Polypeptide alpha contains conserved motifs I-VIII and X, and polypeptide beta contains motif IX. To understand how polypeptide alpha carries out its function, a molecular model of the large domain of polypeptide alpha was generated using M.HhaI and M.HaeIII as templates. The large domain is a mixed alpha/beta structure. Residues 15-19 in motif I (Phe-Naa-Gly-Naa) are conserved for cofactor binding. The key catalytic residue Cys-79 in motif IV is also conserved in comparison with other C-5 MTases. Comparing polypeptide alpha with M.HhaI and M.HaeIII revealed a unique region upstream of motif X. To understand the role of this region, 14 charged residues between R224 and E271 in the putative small domain were mutated. Activity assays indicated that most of these charges can be eliminated or changed conservatively. Among these charged residues, R224, E240, D245 and D251 may take part in proper interaction with DNA in the presence of polypeptide beta.     

Leukotriene A4 hydrolase/aminopeptidase. Glutamate 271 is a catalytic residue with specific roles in two distinct enzyme mechanisms.

Leukotriene A(4) hydrolase/aminopeptidase is a bifunctional zinc metalloenzyme that converts the fatty acid epoxide leukotriene A(4) into leukotriene B(4), a potent chemoattractant and immune-modulating lipid mediator. Recently, the structure of leukotriene A(4) hydrolase revealed that Glu-271, which belongs to a conserved GXMEN motif in the M1 family of zinc peptidases, and Gln-136 are located at the active site. Here we report that mutagenetic replacements of Glu-271, but not Gln-136, abrogate both catalytic activities of leukotriene A(4) hydrolase. Furthermore, the 2.1 A crystal structure of [E271Q]leukotriene A(4) hydrolase revealed minimal conformational changes that could not explain the loss of enzyme function. We propose that the carboxylate of Glu-271 participates in an acid-induced opening of the epoxide moiety of leukotriene A(4) and formation of a carbocation intermediate. Moreover, Glu-271 appears to act as an N-terminal recognition site and may potentially stabilize the transition-state during turnover of peptides, a property that most likely pertains to all members of the M1 family of zinc aminopeptidases. Hence, Glu-271 is a unique example of an amino acid, which has dual and separate functions in two different catalytic reactions, involving lipid and peptide substrates, respectively.     

Site-directed mutagenesis study of yeast peptide:N-glycanase. Insight into the reaction mechanism of deglycosylation.

Yeast peptide:N-glycanase (Png1p; PNGase), a deglycosylation enzyme involved in the proteasome dependent degradation of proteins, has been reported to be a member of the transglutaminase superfamily based on sequence alignment. In this study we have investigated the structure-function relationship of Png1p by site-directed mutagenesis. Cys-191, His-218, and Asp-235 of Png1p are conserved in the sequence of factor XIIIa, where these amino acids constitute a catalytic triad. Point mutations of these residues in Png1p resulted in complete loss in activity, consistent with a role for each in catalyzing deglycosylation of glycoproteins. Other conserved amino acid residues, Trp-220, Trp-231, Arg-210, and Glu-222, were also vitally important for folding and structure stability of the enzyme as revealed by circular dichroism analysis. The potential effects of the mutations were predicted by mapping the conserved amino acids of Png1p within the known three-dimensional structure of factor XIIIa. Our data suggest that the lack in enzyme activity when any of the catalytic triad residues is mutated is either due to the absence of charge relay in the case of the triad or due to the disruption of the native fold of the enzyme. These findings strongly suggest a common evolutionary lineage for the PNGases and transglutaminases.     

A smallest 6 kda metalloprotease,mini-matrilysin,in living world: a revolutionary conserved zinc-dependent proteolytic domain- helix-loop-helix catalytic zinc binding domain (ZBD)

Background

The Aim of this study is to study the minimum zinc dependent metalloprotease catalytic folding motif, helix B Met loop-helix C, with proteolytic catalytic activities in metzincin super family. The metzincin super family share a catalytic domain consisting of a twisted five-stranded β sheet and three long α helices (A, B and C). The catalytic zinc is at the bottom of the cleft and is ligated by three His residues in the consensus sequence motif, HEXXHXXGXXH, which is located in helix B and part of the adjacent Met turn region. An interesting question is - what is the minimum portion of the enzyme that still possesses catalytic and inhibitor recognition?”

Methods

We have expressed a 60-residue truncated form of matrilysin which retains only the helix B-Met turn-helix C region and deletes helix A and the five-stranded β sheet which form the upper portion of the active cleft. This is only 1/4 of the full catalytic domain. The E. coli derived 6 kDa MMP-7 ZBD fragments were purified and refolded. The proteolytic activities were analyzed by Mca-Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH2 peptide assay and CM-transferrin zymography analysis. SC44463, BB94 and Phosphoramidon were computationally docked into the 3day structure of the human MMP7 ZBD and TAD and thermolysin using the docking program GOLD.

Results

This minimal 6 kDa matrilysin has been refolded and shown to have proteolytic activity in the Mca-Pro-Leu-Gly-Leu-Dpa-Ala-Arg-NH2 peptide assay. Triton X-100 and heparin are important factors in the refolding environment for this mini-enzyme matrilysin. This minienzyme has the proteolytic activity towards peptide substrate, but the hexamer and octamer of the mini MMP-7 complex demonstrates the CM-transferrin proteolytic activities in zymographic analysis. Peptide digestion is inhibited by SC44463, specific MMP7 inhibitors, but not phosphorimadon. Interestingly, the mini MMP-7 can be processed by autolysis and producing ~ 6 ~ 7 kDa fragments. Thus, many of the functions of the enzyme are retained indicating that the helix B-Met loop-helix C is the minimal functional “domain” found to date for the matrixin family.

Conclusions

The helix B-Met loop-helix C folding conserved in metalloprotease metzincin super family is able to facilitate proteolytic catalysis for specific substrate and inhibitor recognition. The autolysis processing and producing 6 kDa mini MMP-7 is the smallest metalloprotease in living world.     

Identification of two essential glutamic acid residues in glycogen synthase

The detailed catalytic mechanism by which glycosyltransferases catalyze the transfer of a glycosyl residue from a donor sugar to an acceptor is not known. Through the multiple alignment of all known eukaryotic glycogen synthases we have found an invariant 17-amino acid stretch enclosed within the most conserved region of the members of this family. This peptide includes an E-X(7)-E motif, which is highly conserved in four families of retaining glycosyltransferases. Site-directed mutagenesis was performed in human muscle glycogen synthase to analyze the roles of the two conserved Glu residues (Glu-510 and Glu-518) of the motif. Proteins were transiently expressed in COS-1 cells as fusions to green fluorescence protein. The E510A and E518A mutant proteins retained the ability to translocate from the nucleus to the cytosol in response to glucose and to bind to intracellular glycogen. Although the E518A variant had approximately 6% of the catalytic activity shown by the green fluorescence protein-human muscle glycogen synthase fusion protein, the E510A mutation inactivated the enzyme. These results led us to conclude that the E-X(7)-E motif is part of the active site of eukaryotic glycogen synthases and that both conserved Glu residues are involved in catalysis. We propose that Glu-510 may function as the nucleophile and Glu-518 as the general acid/base catalyst.     

A DNase from the trypanosomatid Crithidia fasciculata.

We have purified to homogeneity a DNase from a Crithidia fasciculata crude mitochondrial lysate. The enzyme is present in two forms, either as a 32 kDa polypeptide or as a multimer containing the 32 kDa polypeptide in association with a 56 kDa polypeptide. Native molecular weight measurements indicate that these forms are a monomer and possibly an alpha 2 beta 2 tetramer, respectively. The monomeric and multimeric forms of the enzyme are similar in their catalytic activities. Both digest double-stranded DNA about twice as efficiently as single-stranded DNA. They introduce single-strand breaks into a supercoiled plasmid but do not efficiently make double-strand breaks. They degrade a linearized plasmid more efficiently than a nickel plasmid. Both enzymes degrade a 5'-32P-labeled double-stranded oligonucleotide to completion, with the 5'-terminal nucleotide ultimately being released as a 5'-mononucleotide. One difference between the monomeric and multimeric forms of the enzyme, demonstrated by a band shift assay, is that the multimeric form binds tightly to double-stranded DNA, possibly aggregating it.