Structural similarities in glucoamylases by hydrophobic cluster analysis

The model of the catalytic domain of Aspergillus awamori var.X100 glucoamylase was related to 14 other glucoamylase proteinsequences belonging to five subfamilies. Structural featuresof the different sequences were revealed by multisequence alignmentfollowing hydrophobic cluster analysis. The alignment agreedwith the hydrophobic microdomains, normally conserved throughoutevolution, evaluated from the 3-D model. Saccharomyces and Clostridiumglucoamylases lack the -helix exterior to the catalytic domain.A different catalytic base was found in the Saccharomyces glucoamylasesubfamily. The starch binding domain of fungal glucoamylaseshas identical structural features and substrate interactingresidues as the C-terminal domain of models of Bacillus circulanscyclodextrin glucosyltransferases. Three putative N-glycosylationsites were found in the same turns in glucoamylases of differentsubfamilies. O-Glycosylation is present at different levelsin the catalytic domain and in the linker between the catalyticand starch binding domains.     

Mutagenesis of conserved residues within the active site of Escherichia coli alkaline phosphatase yields enzymes with increased kcat

The likelihood for improvement in the catalytic properties ofEscherichia coli alkaline phosphatase was examined using site-directedmutagenesis. Mutants were constructed by introducing sequencechanges into nine preselected amino acid sites within 10 A ofthe catalytic residue serine 102. When highly conserved residuesin the family of alkaline phosphatases were mutated, many ofthe resulting enzymes not only maintained activity, but alsoexhibited greatly improved tra,. Of –170 mutant enzymesscreened, 5% (eight mutants) exhibited significant increasesin specific activity. In particular, a substitution by serineof a totally invariant AsplOl resulted in a 35-fold increaseof specific activity over wild-type at pH 10.0. Up to 6-foldincreases the k_cat/k_m ratio were observed.     

The function of the Saccharomyces cerevisiae iso-1-cytochrome c gene is independent of the codon at invariant residue Phe82 when the gene is present on a low-copy-number vector

Phe82 is the most studied invariant residue of cytochrome c.However, the physiological relevance of amino acid substitutionsat this position is unclear because previous studies were eitherperformed in vitro (i.e. using purified protein) or in yeastwhere the gene for the protein is present on a multi-copy vector.Multi-copy vectors yield a level of cytochrome c in yeast thatis greater than the wild-type level. Oligodeoxyribonucleotide-directedmutagenesis was used to change the codon for Phe82 to that ofthe other 19 naturally occurring amino acids as well as theamber stop codon. The alleles are present on a yeast shuttlephagemid containing the CEN6 gene which ensures a vector copynumber of one to two in yeast. All the missense alleles supportgrowth under conditions requiring a functional iso-1-cytochromec. However the F82C, F82P, and F82R variants grow at a significantlylower rate. After selection for function, phagemids were rescuedfrom the transformants and the identity of the mutation verified.It is concluded that all 20 amino acids are capable of supportingfunction. Reasons for the evolutionary invariance of Phe82 arediscussed.     

The {alpha}/{beta} hydrolase fold

We have identified a new protein fold—the /ßhydrolase fold—that is common to several hydrolytic enzymesof widely differing phylogenetic origin and catalytic function.The core of each enzyme is similar: an /ß sheet, notbarrel, of eight ß-sheets connected by -helices. Theseenzymes have diverged from a common ancestor so as to preservethe arrangement of the catalytic residues, not the binding site.They all have a catalytic triad, the elements of which are borneon loops which are the best-conserved structural features inthe fold. Only the histidine in the nucleophile-histidine-acidcatalytic triad is completely conserved, with the nucleophileand acid loops accommodating more than one type of amino acid.The unique topological and sequence arrangement of the triadresidues produces a catalytic triad which is, in a sense, amirror-image of the serine protease catalytic triad. There arenow four groups of enzymes which contain catalytic triads andwhich are related by convergent evolution towards a stable,useful active site: the eukaryotic serine proteases, the cysteineproteases, subtilisins and the /ß hydrolase fold enzymes.     

Cassette mutagenesis of Aspergillus awamori glucoamylase near its general acid residue to probe its catalytic and pH properties

Nine single amino add mutations in the active site of Aspergillusawamori glucoamylase were made by cassette mutagenesis to alterthe pH dependence of the enzyme and to determine possible functionsof the mutated residues. The Glul79-Asp mutation expressed inyeast led to a very large decrease in k_cat but to no changein K_m, verifying this residue's catalytic function. Aspl76-Gluand Glul80-Asp mutations affected K_m a more than k_cat, implyingthat Aspl76 and Glul80 are involved in substrate binding orstructural integrity. The Leul77-Asp mutation decreased k_catonly moderately, probably by changing the position of the generalacid catalytic group, and did not affect K_m. The Trpl78-Aspmutation greatly decreased k_cat while increasing K_m, showingthe importance of Trpl78 in the active site. Vall81-Asp andAsnl82-Asp mutations changed kinetk values little, suggestingthat Vall81 and Asnl82 are of minor catalytic and structuralimportance. Finally, insertions of Asp or Gly between residues176 and 177 resulted in almost complete loss of activity, probablycaused by destruction of the active site structure. No largechanges in pH dependence occurred in those mutations where kineticvalues could be determined, in spite of the increase in mostcases of the total negative charge. Increases in activationenergy of maltoheptaose hydrolysis in most of the mutant glucoamylasessuggested cleavage of individual hydrogen bonds in enzyme-substratecomplexes.     

Expression of human asparagine synthetase in Saccharomyces cerevisiae

Human asparagine synthetase was expressed in the yeast Saccharomycescerevisiae. The identity of the expressed protein was confirmedby immunoblotting and in vitro enzymatic activity. The recombinantenzyme was shown to have both the ammonia-and glutamine-dependentasparagine synthetase activity in vitro. In contrast to overproductionin Escherichia coli, the expressed protein was found to be solublein the yeast cell. Furthermore, expression in yeast made itpossible to isolate non-degraded human asparagine synthetasewhich had also the N-terminal methionine correctly processed.The yeast expression plasmid was constructed for optimal productionof the recombinant enzyme. In addition, unique restriction enzymesites that bracket the first five codons of the human asparaginesynthetase gene were introduced. This will allow the use ofoligonucleotide cassette mutagenesis to investigate the roleof the N-terminal amino acids in asparagine synthetase enzymaticactivity.     

Structure prediction of the EcoRV DNA methyltransferase based on mutant profiling, secondary structure analysis, comparison with known structures of methyltransferases and isolation of catalytically inactive single mutants

The EcoRV DNA methyltransferase (M·EcoRV) is an -adeninemethyltransferase. We have used two different programs to predictthe secondary structure of M·EcoRV. The resulting consensusprediction was tested by a mutant profiling analysis. 29 neutralmutations of M·EcoRV were generated by five cycles ofrandom mutagenesis and selection for active variants to increasethe reliability of the prediction and to get a secondary structureprediction for some ambiguously predicted regions. The predictedconsensus secondary structure elements could be aligned to thecommon topology of the structures of the catalytic domains ofM·HhaI and M·TaqI. In a complementary approachwe have isolated nine catalytically inactive single mutants.Five of these mutants contain an amino acid exchange withinthe catalytic domain of M·EcoRV (Val20-Ala, Lys81Arg,Cys192Arg, Asp193Gly, Trp231Arg). The Trp231Arg mutant bindsDNA similarly to wild-type M·EcoRV, but is catalyticallyinactive. Hence this mutant behaves like a bona fide activesite mutant. According to the structure prediction, Trp231 islocated in a loop at the putative active site of M·EcoRV.The other inactive mutants were insoluble. They contain aminoacid exchanges within the conserved amino acid motifs X, IIIor IV in M·EcoRV confirming the importance of these regions.     

Analysis of the catalyic mechanism of a fungal lipase using computer-aided design and structural mutants

Both an active enzyme conformation and stabilization of tetrahedraltransition states are essential for the catalysis of ester bondhydrolysis by lipases. X-ray structural data and results fromsite-directed mutagenesis experiments with proteases have beenused as a basis for predictions of amino acid residues likelyto have key functions in lipases. The gene encoding a lipasefrom Rhizopus oryzae was cloned and expressed in Escherichiacoli. Site-directed mutagenesis of this gene was used to testthe validity of computer-aided predictions of the functionalroles of specific amino acids in this enzyme. Examination ofthe kinetic constants of the Rhizopus oryzae lipase variantsallowed us to identify amino acid residues which are directlyinvolved in the catalytic reaction or which stabilize the activegeometry of the enzyme. The combination of these results withmolecular mechanics simulations, based on a homology-derivedstructural model, provided new information about structure-functionrelationships. The interpretation of the data is consistentwith results obtained with other hydrolases, such as proteases.     

Properties conferred on Clostridium thermocellum endoglucanase CelC by grafting the duplicated segment of endoglucanase CelD

The DNA sequence encoding the duplicated 22 amino acid segmentof Clostridium thermocellum endoglucanase CelD was fused tothe 3'-terminus of the celC gene encoding C.thermocellum endoglucanaseCelC. The presence of the duplicated segment endowed CelC withthe capacity to form cytoplasmk inclusion bodies containingactive enzyme when the hybrid gene was expressed in Escherichiacoli. Inclusion body formation prevented proteolytic cleavageof the duplicated segment. The intact hybrid protein CelC-Cel'Dwas purified from inclusion bodies and characterized. In contrastto CelC, CelC-Cel'D was able to bind to CipA, a protein actingas a scaffolding component of the C.thermocellum cellulase complex(cellulosome). However, the catalytic properties of CelC-Cel'Dwere similar to those of CelC. These results suggest that foreignproteins tagged with the duplicated segment could be incorporatedinto the cellulosome in order to modify the enzymatic propertiesof the complex. The formation of inclusion bodies by proteinscarrying the duplicated segment may also prove a convenientmeans of purifying cloned gene products that are sensitive toproteolytic degradation.     

Site-directed mutagenesis of the putative active site residues of 3C proteinase of coxsackievirus B3: evidence of a functional relationship with trypsin-like serine proteinases

Picornavirus 3C proteinases (3C^pro) are cysteine proteinasesbut recent sequence analyses have shown that they are relatedto trypsin-like serine proteinases. Two models of 3C^pro structurehave been presented. Both models indicate that residues His40and Cysl47 are members of the catalytic triad but the modelsdiffer in the designation of the third member of the catalytictriad, which is assigned as either Glu71 or Asp85. To test theimportance of these four residues in the catalytic activityof 3C^pro of coxsackievirus B3, a member of the enterovirus subgroupof the picornavirus family, single amino acid substitutionswere introduced at each of the four sites. All of these mutationsresulted in the reduction or inactivation of autocatalytic cleavageof the 3C precursor protein expressed in Escherichia coli, suggestingthat all of these residues are essential for the proteolyticreaction. The substitution of Cysl47 with Ala abolished 3C^proactivity while the mutant in which Cysl47 was replaced withSer retained reduced proteolytic activity both in cis and intrans. Our results strongly support the proposal that Cysl47of 3C^pro functions as a nucleophile analogous to Serl95 of trypsin-likeserine proteinases.     

Multiple interactions of lysine-128 of Escherichia coli glutamate dehydrogenase revealed by site-directed mutagenesis studies

A highly conserved lysine at position 128 of Escherichia coliglutamate dehydrogenase (GDH) has been altered by sitedirectedmutagenesis of the gdhA gene. Chemical modification studieshave previously shown the importance of this residue for catalyticactivity. We report the properties of mutants in which lysine-128has been changed to histidine (K128H) or arginine (K128R). Bothmutants have substantially reduced catalytic centre activitiesand raised pH optima for activity. K128H also has increasedrelative activity with amino acid substrates other than glutamate,especially L-norvaline. These differences, together with alterationsin K_m values, K_d values for NADPH and K₁ values for D-glutamate,imply that lysine-128 is intimately involved in either director indirect interactions with all the substrates and also incatalysis. These multiple interactions of lysine-128 explainthe diverse effects of chemical modifications of the correspondinglysine in homologous GDHs. In contrast, lysine-27, another highlyreactive residue in bovine GDH, is not conserved in all of thesequenced NADP-specific GDHs and is therefore not likely tobe involved in catalysis.     

Involvement of a residue at position 75 in the catalytic mechanism of a fungal aspartic proteinase, Rhizomucor pusilus pepsin. Replacement of tyrosine 75 on the flap by asparagine enhances catalytic efficiency

Residue 75 on the flap, a beta hairpin loop that partially coversthe active site cleft, is tyrosine in most members of the asparticproteinase family. Site-directed mutagenesis was carried outto investigate the functional role of this residue in Rhizomucorpusilus pepsin, an aspartic proteinase with high milk-clottingactivity produced by the fungus Rhizomucor pusillus. A set ofmutated enzymes with replacement of the amino acid at position75 by 17 other amino acid residues except for His and Gly wasconstructed and their enzymatic properties were examined. Strongactivity, higher than that of the wild-type enzyme, was foundin the mutant with asparagine (Tyr75Asn), while weak but distinctactivity was observed in Tyr75Phe. All the other mutants showedmarkedly decreased or negligible activity, less than 1/1000of that of the wild-type enzyme. Kinetic analysis of Tyr75Asnusing a chromogenic synthetic oligopeptide as a substrate revealeda marked increase in k_cat with slight change in K_m, resultingin a 5.6-fold increase in k_cat/k_m. When differential absorptionspectra upon addition of pepstatin, a specific inhibitor foraspartic proteinase, were compared between the wild-type andmutant enzymes, the wild-type enzyme and Tyr75Asn, showing strongactivity, had spectra with absorption maxima at 280, 287 and293 nm, whereas the others, showing decreased or negligibleactivity, had spectra with only two maxima at 282 and 288 nm.This suggests a different mode of the inhibitor binding in thelatter mutants. These observations suggest a crucial role ofthe residue at position 75 in enhancing the catalytic efficiencythrough affecting the mode of substrate-binding in the asparticproteinases.     

Alteration of aspartate 101 in the active site of Escherichia coli alkaline phosphatase enhances the catalytic activity

The function of aspartic acid residue 101 in the active siteof Escherichia coli alkaline phosphatase was investigated bysite-specific mutagenesis. A mutant version of alkaline phosphatasewas constructed with alanine in place of aspartic acid at position101. When kinetic measurements are carried out in the presenceof a phosphate acceptor, 1.0 M Tris, pH 8.0, both the k_cat andthe K_m, for the mutant enzyme increase by –2-fold, resultingin almost no change in the k_cat/K_m ratio. Under conditions ofno external phosphate acceptor and pH 8.0, both the k_cat andthe K_m for the mutant enzyme decrease by {small tilde}2-fold,again resulting in almost no change in the k_cat/K_m ratio. Thek_cat for the hydrolysis of 4-methyl-umbelliferyl phosphate andp-nitrophenyl phosphate are nearly identical for both the wild-typeand mutant enzymes, as is the K₁ for inorganic phosphate. Thereplacement of aspartic acid 101 by alanine does have a significanteffect on the activity of the enzyme as a function of pH, especiallyin the presence of a phosphate acceptor. At pH 9.4 the mutantenzyme exhibits 3-fold higher activity than the wild-type. Themutant enzyme also exhibits a substantial decrease in thermalstability: it is half inactivated by treatment at 49°C for15 min compared to 71°C for the wild-type enzyme. The datareported here suggest that this amino acid substitution altersthe rates of steps after the formation of the phospho-enzymeintermediate. Analysis of the X-ray structure of the wild-typeenzyme indicates that the increase in catalytic rate of themutant enzyme in the presence of a phosphate acceptor may bedue to an increase in accessibility of the active site nearSerl02. The increased catalytic rate of this mutant enzyme maybe utilized to improve diagnostic tests that require alkalinephosphatase, and the reduced heat stability of the mutant enzymemay make it useful in recombinant DNA techniques that requirethe ability to heat-inactivate the enzyme after use.     

Thermal stability of chimeric isopropylmalate dehydrogenase genes constructed from a thermophile and a mesophile

Chimeric isopropylmalate dehydrogenases were constructed byconnecting the genes isolated from an extreme thermophile, Thermusthermophilus, and a mesophile, Bacillus subtilis. These geneswere expressed in Escherichia coli. The enzymes were purifiedand analysed. Enzymes of T.thermophilus and B.subtilis and chimericenzymes showed similar enzymological characteristics exceptfor thermal stability. The stability of each enzyme was approximatelyproportional to the content of the amino acid sequence fromthe TJhermophilus enzyme. The results suggested that amino acidresidues contributing the thermal stability distribute themselves,in general, evenly at least in the N-terminal half of the aminoacid sequence of T.thermophilus isopropylmalate dehydrogenase.     

Directed evolution of subtilisin E in Bacillus subtilis to enhance total activity in aqueous dimethylformamide

Sequential rounds of error-prone PCR to introduce random mutationsand screenrng of the resultant mutant libraries have been usedto enhance the total catalytic activity of subtilisin E significantlyin a non-natural environment, aqueous dimethylformamide (DMF).Seven DNA substitutions coding for three new amino acid substitutionswere identified in a mutant isolated after two additional generationsof directed evolution carried out on 10M subtilisin E, previously‘evolved’ to increase its specific activity in DMF.A Bacillus subtilis-Escherichia coli shuttle vector was developedin order to increase the size of the mutant library that couldbe established in B.subtilis and the stringency of the screeningprocess was increased to reflect total as well as specific activity.This directed evolution approach has been extremely effectivefor improving enzyme activity in a non-natural environment:the resulting-evolved 13M subtilisin exhibits specific catalyticefficiency towards the hydrolysis of a peptide substrate succlnyl-Ala-Ala-Pro-Phe-p-nitroanilidein 60% DMF solution that is three times that of the parent 10Mand 471 times that of wild type subtilisin E. The total activityof the 13M culture supernatant is enhanced 16-fold over thatof the parent 10M.     

6-Phospho-{beta}-galactosidases of Gram-positive and 6-phospho-{beta}-glucosidase B of Gram-negative bacteria: comparison of structure and function by kinetic and immunological methods and mutagenesis of the lacG gene of staphylococcus aureus

The 6-phospho-ß-galactosidase of Staphylococcus aureus,Lactococcus lactis and Lactobacillus casei and 6-phospho-ßglucosidaseB of Escherichia coli build a subfamily inside a greater enzymefamily, named the glycosal hydrolase family 1, which, hi addition,contains nine ß-glycosidases of different origins.Kinetic and immunological evidence is provided in this reportwhich strengthens the relationship of the four 6-phospho-ß-glycosidases.It is shown that the 6-phospho-ß-galactosidases and6-phospho-ß-glucosidase B are able to split aromaticß-galactoside phosphates and ß-glucosidephosphates. The turnover numbers of hydrolysis of substrateswith different epimerization at C-4 of the glycon vary up to15-fold only. Two polydonal antisera, one derived against thenative 6-phospho-ß-galactosidase from S.aureus andthe other derived against the 6-phospho-ß-glucosidaseB, cross-reacted with both enzymes. Peptides of the proteinswere separated by reverse phase HPLC. The cross-reacting peptideswere sequenced and shown to be localized at almost the sameposition in the aligned primary structures of both enzymes.An insertion of nine amino adds near these antigenic domainsis unique for the 6-phospho-ß-glycosidases and missingwithin the sequences of the ß-glycoside-specific membersof the family. The lacG gene of a 6-phospho-ß-galactosidasenegative S.aureus mutant was doned into E.coli and sequenced.In the totally inactive mutant protein only the glycine at position332 was changed to an arginine. This amino acid is part of thesequence insertion near the antigenic domain reacting with bothantisera. These data support the assumption that the regionis of great importance for the function of the enzymes and thatit is possible it determines the specificity of the phosphorylatedform of the substrates. In addition, the 6-phospho-ß-galactosidaseof S.aureus was modified by sitedirected mutagenesis of thecorresponding lacG gene hi order to replace residues Glul60and Glu375, which were suspected of being involved hi the generalacid catalysis of substrate hydrolysis, with glutamine residues.The mutant protein 160EQ retained some catalytic activity whilethe protein 375EQ was totally inactive. Glu375 is the activesite nudeophile of the 6-phospho-ß-galactosidase ofS.aureus. It is located in the sequence motif ENG where Glu358was identified as the catalytkally active nudeophile hi theß-glucosidase of Agrobacterium.     

Overproduction and purification of the regulatory subunit of Escherichia coli aspartate transcarbamoylase

An Escherichia coli strain/plasmid system has been developedfor the overexpression of the regulatory subunit of E.coli aspartatetranscarbamoylase (ATCase). Production of large quantities ofregulatory subunit, by the method described here, should facilitatefuture experiments, such as X-ray crystallography, NMR and hybridizationexperiments, aimed at understanding the heterotropic mechanismthat regulates the activity of ATCase. The plasmid used forthe over-expression carries the gene for the regulatory subunit,pyrI, downstream from the strong pyrB promoter. The host strain,EK1104 [Nowlan, S.F. and Kantrowitz, E.R. (1985) J. Biol. Chem.,260, 14712–14716] carries a deletion in the pyrBI regionof the chromosome, as well as a leaky pyrF allele. When thisstrain/plasmid system is grown under limiting pyrimidine levels,large quantities of the regulatory subunit of ATCase are producedwithout any trace of catalytic subunit or holo-enzyme. A procedurefor the purification of the regulatory subunit from cell extractshas also been developed yielding {small tilde}50 mg of purifiedregulatory subunit per liter of initial culture. The regulatorysubunit produced in this fashion is fully competent in reassociationexperiments with the native catalytic subunit. Furthermore,the reassociated holoenzyme exhibits kinetic properties identicalto those of the wild type enzyme. In addition, we report theconstruction of a pUC119 based plasmid which carries a uniqueNdeI site at the fMet of the pyrB gene of ATCase. This plasmid,which was used in the construction of the system for the overexpressionof the regulatory subunit of ATCase, has been shown to be ofgeneral use for the expression of foreign proteins in E.coli.     

Effects of introduced aspartic and glutamic acid residues on the Pi substrate specificity, pH dependence and stability of carboxypeptidase Y

Carboxypeptidase Y is a serine carboxypeptidase isolated fromSaccharomyces cerevisiae with a preference for Cterminal hydrophobicamino acid residues. In order to alter the inherent substratespecificity of CPD-Y into one for basic amino acid residuesin P'₁, we have introduced Asp and/or Glu residues at a numberof selected positions within the Si binding site. Hie effectsof these substitutions on the substrate specificity, pH dependenceand protein stability have been evaluated. The results presentedhere demonstrate that it is possible to obtain significant changesin the substrate preference by introducing charged amino acidsinto the framework provided by an enzyme with a quite differentspecificity. The introduced acidic amino acid residues providea marked pH dependence of the (k_{cat/Km)FA-A-R-OH/(kcatm})_FA-A-R-OHratio. The change in stability upon introduction of Asp/Gluresidues can be correlated to the difference in the mean buriedsurfac surface area between the substituted and the substitutingamino acid. Thus, the effects of acidic amino acid residueson the protein stability depend upon whether the introducedamino acid protrudes from the solvent accessible surface asdefined by the surrounding residues in the wild type enzymeor is submerged below.     

Effect of Glu-143 and His-231 substitutions on the catalytic activity and secretion of Bacillus subtilis neutral protease

On the basis of the homology with the Bacillus thermoproteolyticuszinc endopeptidase thermotysin, we hypothesized that Glu-143and His-231 are the key residues for the catalytic activityof the Bacillus subtilis neutral protease. To test this possibilityby site-directed mutagenesis, we substituted these two residueswith Ala, Ser, Trp and Arg, and Leu, Val and Cys respectively.All these substitutions dramatically affected the amount ofsecreted mutant proteins, as determined by immunological methods,and their catalytic activities. No appreciable secretion wasobserved with the three Glu mutants Trp, Ser and Arg, whereasthe Glu–Ala mutant enzyme was secreted at a level of afew hundred micrograms per litre of culture. The His mutantswere all secreted at higher levels (in the order of a few milligramsper litre) and their residual catalytic activity could be determinedusing Z-Ala-Leu-Ala as substrate. Our results confirm the keyrole played by Glu-143 and His-231 in catalysis and moreoversuggest the existence of a relationship between the catalyticactivity of the enzyme and the extent of its secretion. In thiscontext, we present data suggesting an autoproteolytic mechanismof cleavage of the precursor form of the enzyme, analogous tothe one previously reported for the B.subtilis subtilisin.