Gene cluster for creatinine degradation in Arthrobacter sp. TE1826

The genes encoding creatininase (CrnA; 258 residues) and creatinase (CreA; 411 residues) from Arthrobacter sp. TE1826 were cloned and sequenced. The genes form a cluster with the sarcosine oxidase gene (soxA) and its regulator gene (soxR), which were cloned previously. The deduced amino acid sequences of CrnA and CreA show 35.9% and 63.1% identity, respectively to the corresponding Pseudomonas enzymes. CrnA and CreA were purified from the recombinant strains and characterized. Other open reading frames (creB and crnB), encoding proteins similar to several transporters, were found downstream of creA and crnA, respectively.

Clavulanic acid biosynthesis in Streptomyces clavuligerus: gene cloning and characterization

Seven classes of Streptomyces clavuligerus mutants defective in clavulanic acid (CLA) biosynthesis have been identified and used to clone the chromosomal DNA encoding eight CLA biosynthetic genes. The complete sequences of three and the partial sequences of two of these biosynthetic genes are reported, together with their known or predicted functions.

[Gene technology to overproduce the enzymes useful as diagnostic reagents]

We cloned the genes encoding the microbial enzymes described below and discussed the possibility as the diagnostic reagents: Creatinase(CR) and sarcosine oxidase(SOX) are useful for a diagnostic measurement of creatinine in combination with creatinase. Bacillus sp. B-0618 produces both CR and SOX enzymes when grown in the presence of an inducer, choline chloride. We cloned these two genes encoding CR and SOX by using recombinant DNA techniques. We found that the SOX-encoding gene is located upstream from the CR-encoding gene. When the CR- and SOX-encoding genes were independently inserted into the pUC-based vector and introduced into Escherichia coli, the transformants produced 15.5-fold more CR and 50-fold more SOX than Bacillus sp. B-0618, respectively, in the absence of the inducer. Although the Bacillus SOX is a flavoprotein, we created an FAD-free SOX by site-directed DNA mutagenesis. The mutant protein no longer expressed the SOX activity. Cholesterol esterase is useful for a diagnostic measurement of total cholesterol in combination with cholesterol oxidase. We cloned a gene encoding the cholesterol esterase enzyme. When the gene was introduced into the non-producing Streptomyces strain, the transformant produced the cholesterol esterase. Phospholipase A2 is a diverse family of enzymes that hydrolyze the sn-2 fatty acyl ester bond of phosphoglycerides producing free fatty acids and lysophospholipids. The enzymes are present in pancreatic juice and in the venoms of snakes and bees, where they serve digestive functions.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification, cloning, sequencing, and overexpression of the gene encoding proclavaminate amidino hydrolase and characterization of protein function in clavulanic acid biosynthesis

Proclavaminate amidino hydrolase (PAH) catalyzes the reaction of guanidinoproclavaminic acid to proclavaminic acid and urea, a central step in the biosynthesis of the beta-lactamase inhibitor clavulanic acid. The gene encoding this enzyme (pah) was tentatively identified within the clavulanic acid biosynthetic cluster in Streptomyces clavuligerus by translation to a protein of the correct molecular mass (33 kDa) and appreciable sequence homology to agmatine ureohydrolase (M.B.W. Szumanski and S.M. Boyle, J. Bacteriol. 172:538-547, 1990) and several arginases, a correlation similarly recognized by Aidoo et al. (K. A. Aidoo, A. Wong, D. C. Alexander, R. A. R. Rittammer, and S. E. Jensen, Gene 147:41-46, 1994). Overexpression of the putative open reading frame as a 76-kDa fusion to the maltose-binding protein gave a protein having the catalytic activity sought. Cleavage of this protein with factor Xa gave PAH whose N terminus was slightly modified by the addition of four amino acids but exhibited unchanged substrate specificity and kinetic properties. Directly downstream of pah lies the gene encoding clavaminate synthase 2, an enzyme that carries out three distinct oxidative transformations in the in vivo formation of clavulanic acid. After the first of these oxidations, however, no further reaction was found to occur in vitro without the intervention of PAH. We have demonstrated that concurrent use of recombinant clavaminate synthase 2 and PAH results in the successful conversion of deoxyguanidinoproclavaminic acid to clavaminic acid, a four-step transformation. PAH has a divalent metal requirement, pH activity profile, and kinetic properties similar to those of other proteins of the broader arginase class.

On the evolution of arginases and related enzymes

Sequence analysis of the arginase/agmatine ureohydrolase family, important enzymes in arginine/agmatine metabolism and the urea cycle, reveals the similarity of arginases to formiminoglutamate hydrolase (hutG) in Klebsiella aerogenes and to a previously unidentified open reading frame adjacent to the HMf locus of the archaebacterium Methanothermus fervidus. The gene structure and distribution of these homologous proteins across primary kingdoms suggest that this family is another example of a primordial enzyme possibly present in the universal common ancestor and that can be used as phylogenetic marker.

Stabilization of creatinase from Pseudomonas putida by random mutagenesis

Creatinase (creatine amidinohydrolase, EC 3.5.3.3) from Pseudomonas putida is a homodimer of 45 kDa subunit molecular mass, the three-dimensional structure of which is known at 1.9 A resolution. Three point mutants, A109V, V355M, and V182I, as well as one double mutant combining A109V and V355M, and the triple mutant with all three replacements, were compared with wild-type creatinase regarding their physical and enzymological properties. High-resolution crystal data for wild-type creatinase and the first two mutants suggest isomorphism at least for these three proteins (R. Huber, pers. comm.). Physicochemical measurements confirm this prediction, showing that the mutations have no effect either on the quaternary structure and gross conformation or the catalytic properties as compared to wild-type creatinase. The replacement of V182 (at the solvent-exposed end of the first helix of the C-terminal domain) does not cause significant differences in comparison with the wild-type enzyme. The other point mutations stabilize the first step in the biphasic denaturation transition without affecting the second one. In sum, the enhanced stability seems to reflect slight improvements in the local packing without creating new well-defined bonds. The increase in hydrophobicity generated by the introduction of additional methyl groups (A109V, V182I) must be compensated by minor readjustments of the global structure. Secondary or quaternary interactions are not affected. In going from single to double and triple mutants, to a first approximation, the increments of stabilization are additive.

Cloning of a creatinase gene from Pseudomonas putida in Escherichia coli by using an indicator plate

A genomic library of Pseudomonas putida DNA was constructed by using plasmid pBR322. Transformants of Escherichia coli in combination with Proteus mirabilis cells grown on creatinase test plates were screened for creatinase activity; transformants were considered positive for creatinase activity if a red-pink zone appeared around the colonies. One creatinase-positive clone was further analyzed, and the gene was reduced to a 2.7-kb DNA fragment. A unique protein band (with a molecular weight of approximately 50,000) was observed in recombinant E. coli by minicell analysis.

Influence of cyclic AMP, agmatine, and a novel protein encoded by a flanking gene on speB (agmatine ureohydrolase) in Escherichia coli

The speB gene of Escherichia coli encodes agmatine ureohydrolase (AUH), a putrescine biosynthetic enzyme. The speB gene is transcribed either from its own promoter or as a polycistronic message from the promoter of the speA gene encoding arginine decarboxylase. Two open reading frames (ORF1 and ORF2) are present on the strand complementary to speB; approximately 90% of ORF2 overlaps the speB coding region. Analysis of transcriptional and translational fusions of ORF1 or ORF2 to lacZ revealed that ORF1 encoded a novel protein while ORF2 was not transcribed. Deletion of ORF1 from a plasmid containing ORF1, ORF2, and speB reduced the activity of AUH by 83%. In contrast, the presence of plasmid-encoded ORF1 caused an 86% increase in chromosomally encoded AUH activity. ORF1 did not stimulate alkaline phosphatase expressed from a phi(speB-phoA) transcriptional fusion encoded on the same plasmid. Western analysis (immunoblot) of a phi(ORF1-lacZ) translational fusion revealed that ORF1 encodes a 25.3-kDa protein. Agmatine induced transcription of phi(speB-phoA) but not phi(speA-phoA) fusions. Consequently, agmatine affects selection between the monocistronic and the polycistronic modes of speB transcription. In contrast, cyclic AMP (cAMP) repressed AUH activity of chromosomally encoded AUH but had no effect on plasmid-borne speB nor phi(speB-phoA). It is concluded that ORF1 encodes a protein which is a posttranscriptional regulator of speB, agmatine induces speB independent of speA, and cAMP regulates speB indirectly.

Sequences of two adjacent genes, one (DAL2) encoding allantoicase and another (DCG1) sensitive to nitrogen-catabolite repression in Saccharomyces cerevisiae

Reported are the nucleotide sequences of the yeast allantoicase-encoding gene (DAL2) and that of an unknown gene adjacent to it. Expression of the unidentified gene is sensitive to nitrogen catabolite repression (NCR) and regulated by the DAL80 product, a previously documented control element regulating allantoin pathway gene expression. Both genes possess multiple upstream activation sequences (UAS) homologous to the UASNTR element shown to be required for sensitivity to NCR. Also present upstream from DAL2 is a mutant form of the upstream induction sequence required for response of DAL7 to induction. Its occurrence in mutant form is consistent with the poor induction of DAL2 expression observed in vivo.

Nucleotide sequence and DNA recognition elements of alc, the structural gene which encodes allantoicase, a purine catabolic enzyme of Neurospora crassa

The nitrogen regulatory circuit of Neurospora crassa contains structural genes that encode nitrogen catabolic enzymes which are subject to complex genetic and metabolic regulation. This set of genes is controlled by nitrogen limitation, by specific induction, and by the action of nit-2, a major positive-acting regulatory gene, and nmr, a negative-acting control gene. The complete nucleotide sequence of alc, the gene that encodes allantoicase, a purine catabolic enzyme, is presented. The alc gene contains a single intron, is transcribed from two initiation sites situated approximately 50 nb upstream of the translation start site, and encodes a protein comprised of 354 amino acids. Mobility shift and DNA footprint experiments identified a single binding site for the NIT2 regulatory protein in the alc promoter region. The binding site contains a 10 nucleotide base pair symmetrical sequence which is flanked by two possible core binding sequences, TATCT and TATCG. Mutant NIT2/beta-gal fusion proteins with amino acid substitutions in a putative zinc-finger motif were shown to be completely deficient in the ability to bind to the alc promoter DNA fragment.

Cloning and expression of the creatinase gene from Flavobacterium sp. U-188 in Escherichia coli

The gene coding for creatinase (creatine amidinohydrolase, EC 3.5.3.3) was isolated from Flavobacterium sp. U-188. The primary structure of creatinase deduced from the nucleotide sequence showed a protein (molecular weight, 42, 651) composed of 378 amino acids. The creatinase gene was over-expressed in Escherichia coli under the control of the lac promoter and the amount of this enzyme was over 20% of the soluble protein in the cell.

Analysis and sequence of the speB gene encoding agmatine ureohydrolase, a putrescine biosynthetic enzyme in Escherichia coli

The speB gene of Escherichia coli encodes the enzyme agmatine ureohydrolase (AUH). AUH catalyzes the hydrolysis of agmatine to urea and putrescine in one of the two polyamine biosynthetic pathways in E. coli. Sequencing of a 2.97-kilobase-pair fragment of the E. coli chromosome containing speB revealed the presence of three intact open reading frames (ORFs), ORF1 and ORF2 on one strand and ORF3 on the opposite strand, as well as a truncated ORF, ORF4, which terminated 92 kilobase pairs upstream from ORF3. ORF3 contained the coding sequence of the speB gene, as confirmed by complementation analysis. Two ORF3 transcripts were detected: a shorter transcript that included only ORF3 and a longer transcript that included both ORF3 and ORF4. The short transcript was abundantly expressed when the ORF4 sequences were deleted, but when ORF4 and its upstream sequences were present, the polycistronic message predominated and the amount of the monocistronic message was drastically reduced. The promoter from which the shorter transcript was produced contained a TATACT sequence at position -12, but sequences upstream from the -12 position seemed to be irrelevant for promoter activity. The predicted amino acid sequence of AUH contained three regions of high homology to the arginases of yeasts, rats, and humans.

Biosynthesis of polyamines in ornithine decarboxylase, arginine decarboxylase, and agmatine ureohydrolase deletion mutants of Escherichia coli strain K-12

Escherichia coli K-12 mutants that carry deletions in their genes for ornithine decarboxylase (L-ornithine carboxy-lyase, EC 4.1.1.17) (speC), arginine decarboxylase (L-arginine carboxy-lyase, EC 4.1.1.19) (speA), and agmatine ureohydrolase (agmatinase or agmatine amidinohydrolase, EC 3.5.3.11) (speB) can still synthesize very small amounts of putrescine and spermidine. The putrescine concentration in these mutants was found to be 1/2500th that in spe+ cells. The pathway of putrescine synthesis appears to be through the biodegradative arginine decarboxylase, which converts arginine to agmatine, in combination with a low agmatine ureohydrolase activity--1/2000th that in spe+ strains. These results suggest that even such low levels of polyamines permit a low level of protein synthesis. Evidence is presented that the polyamine requirement for the growth of the polyamine-dependent speAB, speC deletion mutants, which are also streptomycin resistant, is not due to a decreased ability to synthesize polyamines.

Identification of the ureidoglycolate hydrolase gene in the DAL gene cluster of Saccharomyces cerevisiae

This report describes the isolation of the genes encoding allantoicase (DAL2) and ureidoglycolate hydrolase (DAL3), which are components of the large DAL gene cluster on the right arm of chromosome IX of Saccharomyces cerevisiae. During this work a new gene (DAL7) was identified and found to be regulated in the manner expected for an allantoin pathway gene. Its expression was (i) induced by allophanate, (ii) sensitive to nitrogen catabolite repression, and (iii) responsive to mutation of the DAL80 and DAL81 loci, which have previously been shown to regulate the allantoin degradation system. Hybridization probes generated from these cloned genes were used to analyze expression of the allantoin pathway genes in wild-type and mutant cells grown under a variety of physiological conditions. When comparison was possible, the patterns of mRNA and enzyme levels observed in various strains and physiological conditions were very similar, suggesting that the system is predominantly regulated at the level of gene expression. Although all of the genes seem to be controlled by a common mechanism, their detailed patterns of expression were, at the same time, highly individual and diverse.

Expression of the cloned genes encoding the putrescine biosynthetic enzymes and methionine adenosyltransferase of Escherichia coli (speA, speB, speC and metK)

The speA, speB and speC genes, which code for arginine decarboxylase (ADCase), agmatine ureohydrolase (AUHase) and ornithine decarboxylase (ODCase), respectively, and the metK gene, which encodes methionine adenosyltransferase (MATase), have been cloned. The genes were isolated from hybrid ColE1 plasmids of the Clarke-Carbon collection and were ligated into plasmid pBR322. Escherichia coli strains transformed with the recombinant plasmids exhibit a 7- to 17-fold overproduction of the various enzymes, as estimated from increases in the specific activities of the enzymes assayed in crude extracts. Minicells bearing the pBR322 hybrid plasmids and labeled with radioactive lysine synthesize radiolabeled proteins with Mrs corresponding to those reported for purified ODCase, ADCase and MATase. Restriction enzyme analysis of the plasmids, combined with measurements of specific activities of the enzymes in crude extracts of cells bearing recombinant plasmids, clarified the relative position of speA and speB. The gene order in the 62- to 64-min region is serA speB speA metK speC glc.

Arginine degradation in Pseudomonas aeruginosa mutants blocked in two arginine catabolic pathways

Pseudomonas aeruginosa mutants defective in agmatine utilization (agu) were isolated. The genes encoding agmatine deiminase (aguA) and N-carbamoylputrescine amidinohydrolase (aguB) were 98% cotransducible and mapped between gpu and ser-3 in the 30 min region of the chromosome. Constructed agu arc double mutants (blocked in the arginine decarboxylase and arginine deiminase pathways) used arginine efficiently as the sole carbon and nitrogen source. This suggests the existence of a further arginine catabolic pathway in P. aeruginosa. The mapping data of this study confirm that in P. aeruginosa the chromosomal genes with catabolic functions do not show supraoperonic clustering as found in P. putida.

Antagonistic transcriptional regulation of the putrescine biosynthetic enzyme agmatine ureohydrolase by cyclic AMP and agmatine in Escherichia coli

The putrescine biosynthetic enzyme agmatine ureohydrolase (AUH) (agmatinase; EC 3.5.3.11) catalyzes the conversion of agmatine to putrescine in Escherichia coli. The specific activity of AUH was determined in crude extracts prepared from wild-type strains and from strains with mutations in the adenylate cyclase gene (cya) or the cAMP receptor protein gene (crp) or both. In glucose minimal medium, a delta cya strain exhibited 70 to 90% higher AUH activity than a cya+ strain. Addition of 1 to 10 mM cAMP to cya+ and delta cya strains cultured in glucose repressed AUH activity in a dose-dependent manner. Addition of 1 to 10 mM cAMP to a delta crp strain failed to repress AUH activity. Addition of agmatine resulted in a three- to fourfold induction of AUH in delta cya and delta crp strains. This induction could be blocked by the addition of chloramphenicol. Simultaneous additions of various proportions of cAMP and agmatine resulted in reduced levels of induction and repression of AUH activity. This antagonistic regulation was shown to be exerted by independent mechanisms since AUH activity could be induced by agmatine in a delta crp strain supplemented with cAMP. These results suggest that both agmatine and cAMP antagonistically regulate AUH activity at the level of transcription. In minimal medium supplemented with 1 mM putrescine, the strains did not exhibit repression of AUH activity. In contrast, in minimal medium supplemented with 1 mM ornithine or arginine, cya+ or delta cya strains exhibited induced AUH activity as a result of conversion of these substrates to agmatine. Further experiments in vitro demonstrated that the effects observed with cAMP, agmatine, and arginine were not post-translationally mediated.

Chromosomal location of genes participating in the degradation of purines in Pseudomonas aeruginosa

Genetic mapping of the genes (puu) that encode the enzymes catalysing degradation of purines in Pseudomonas aeruginosa strain PAO has been carried out. Mutants that are deficient in adenine deaminase (puuA), guanine deaminase (puuB), xanthine dehydrogenase (puuC), uricase (puuD), allantoinase (puuE), and/or allantoicase (puuF) were isolated and used for the genetic study. Conjugation by FP5 factor and generalized transduction by phage G101 gave the following map locations of these six genes on the chromosome: hisI--puuB--hisII; trpA,B--puuA--ilv202; met9011--catA1--tyu--nar9011--(puuC, puuD, puuE)--puuF. A close linkage among the puuC, puuD and puuE was demonstrated by the transduction.