A cloned bacterial enzyme for nerve agent decontamination

Organophosphorus acid (OPA) anhydrolases offer considerable potential for safe, non-corrosive decontamination of chemical nerve agents. The Alteromonas sp. strain JD6.5 gene encoding an OPA anhydrolase (designated as OPAA-2), which hydrolyzes a wide variety of nerve agents, has been cloned in Escherichia coli. Employing agent-analog diisopropyl fluorophosphate (DFP) as a substrate, the effects of buffers, pH, temperature, and various protein stabilizing agents on OPAA-2 activity were studied. Ammonium carbonate, which is innocuous and inexpensive, proved to be a superior buffer for enzyme activity. Compared with enzyme assayed under standard conditions, enzyme activity with ammonium carbonate was six-fold greater. To evaluate effects of storage and reconstitution on enzyme activity, the cloned enzyme was lyophilized, rehydrated, and then assessed by measuring activity against DFP. Whereas almost 100% of the hydrolytic activity was recovered with enzyme reconstituted in (NH₄)₂CO₃-buffered distilled water or chlorinated drinking water, approximately 20% of the activity was recovered with ocean water. Enzyme stability in blast-containment foam or fire-fighting foam was also demonstrated by high activity in (NH₄)₂CO₃-buffered distilled water or drinking water. These findings suggest the potential of a foam-based enzyme system for field decontamination of chemical nerve agents.     

Protease II from Escherichia coli: sequencing and expression of the enzyme gene and characterization of the expressed enzyme.

Protease II gene of Escherichia coli HB101 was cloned and expressed in E. coli JM83. The transformant harboring a hybrid plasmid, pPROII-12, with a 2.4 kbp fragment showed 90-fold higher enzyme activity than the host. The whole nucleotide sequence of the inserted fragment of plasmid pPROII-12 was clarified by the dideoxy chain-terminating method. The sequence that encoded the mature enzyme protein was found to start at an ATG codon, as judged by comparison with amino terminal protein sequencing. The molecular weight of the enzyme was estimated to be 81,858 from the nucleotide sequence. The reactive serine residue of protease II was identified as Ser-532 with tritium DFP. The sequence around the serine residue is coincident with the common sequence of Gly-X-Ser-X-Gly, which has been found in the active site of serine proteases. Except for this region, protease II showed no significant sequence homology with E. coli serine proteases, protease IV and protease La (lon gene), or other known families of serine proteases. However, 25.3% homology was observed between protease II and prolyl endopeptidase from porcine brain. Although the substrate specificities of these two enzymes are quite different, it seems possible to classify protease II as a member of the prolyl endopeptidase family from the structural point of view.     

Cloning of the Bacillus subtilis glutamine phosphoribosylpyrophosphate amidotransferase gene in Escherichia coli. Nucleotide sequence determination and properties of the plasmid-encoded enzyme

The Bacillus subtilis gene encoding glutamine phosphoribosylpyrophosphate amidotransferase (amidophosphoribosyltransferase) was cloned in pBR322. This gene is designated purF by analogy with the corresponding gene in Escherichia coli. B. subtilis purF was expressed in E. coli from a plasmid promoter. The plasmid-encoded enzyme was functional in vivo and complemented an E. coli purF mutant strain. The nucleotide sequence of a 1651-base pair B. subtilis DNA fragment was determined, thus localizing the 1428-base pair structural gene. A primary translation product of 476 amino acid residues was deduced from the DNA sequence. Comparison with the previously determined NH2-terminal amino acid sequence indicates that 11 residues are proteolytically removed from the NH2 terminus, leaving a protein chain of 465 residues having an NH2-terminal active site cysteine residue. Plasmid-encoded B. subtilis amidophosphoribosyltransferase was purified from E. coli cells and compared to the enzymes from B. subtilis and E. coli. The plasmid-encoded enzyme was similar in properties to amidophosphoribosyltransferase obtained from B. subtilis. Enzyme specific activity, immunological reactivity, in vitro lability to O2, Fe-S content, and NH2-terminal processing were virtually identical with amidophosphoribosyltransferase purified from B. subtilis. Thus E. coli correctly processed the NH2 terminus and assembled [4Fe-4S] centers in B. subtilis amidophosphoribosyltransferase although it does not perform these maturation steps on its own enzyme. Amino acid sequence comparison indicates that the B. subtilis and E. coli enzymes are homologous. Catalytic and regulatory domains were tentatively identified based on comparison with E. coli amidophosphoribosyltransferase and other phosphoribosyltransferase (Argos, P., Hanei, M., Wilson, J., and Kelley, W. (1983) J. Biol. Chem. 258, 6450-6457).     

Cloning and sequence analysis of the gene encoding Lactococcus lactis malolactic enzyme: Relationships with malic enzymes

Abstract Malolactic enzyme is the key enzyme in the degradation of L-malic acid by lactic acid bacteria. Using degenerated primers designed from the first 20 N-terminal amino acid sequence of lactococcal malolactic enzyme, a 60-bp DNA fragment containing part of the mleS gene was amplified from Lactococcus lactis in a polymerase chain reaction. This specific probe was used to isolate two contiguous fragments covering the gene as a whole. The 1.9-kb region sequenced contains an open reading frame of 1623 bp, coding a putative protein of 540 amino acids. The deduced amino acid sequence reveals that lactococcal putative protein (Mlep) is highly homologous to the malic enzyme of other organisms. Expression of the mleS gene in Escherichia coli results in malolactic activity.     

Biosynthesis of D-alanyl-lipoteichoic acid: cloning, nucleotide sequence, and expression of the Lactobacillus casei gene for the D-alanine-activating enzyme.

The D-alanine-activating enzyme (Dae; EC 6.3.2.4) encoded by the dae gene from Lactobacillus casei ATCC 7469 is a cytosolic protein essential for the formation of the D-alanyl esters of membrane-bound lipoteichoic acid. The gene has been cloned, sequenced, and expressed in Escherichia coli, an organism which does not possess Dae activity. The open reading frame is 1,518 nucleotides and codes for a protein of 55.867 kDa, a value in agreement with the 56 kDa obtained by electrophoresis. A putative promoter and ribosome-binding site immediately precede the dae gene. A second open reading frame contiguous with the dae gene has also been partially sequenced. The organization of these genetic elements suggests that more than one enzyme necessary for the biosynthesis of D-alanyl-lipoteichoic acid may be present in this operon. Analysis of the amino acid sequence deduced from the dae gene identified three regions with significant homology to proteins in the following groups of ATP-utilizing enzymes: (i) the acid-thiol ligases, (ii) the activating enzymes for the biosynthesis of enterobactin, and (iii) the synthetases for tyrocidine, gramicidin S, and penicillin. From these comparisons, a common motif (GXXGXPK) has been identified that is conserved in the 19 protein domains analyzed. This motif may represent the phosphate-binding loop of an ATP-binding site for this class of enzymes. A DNA fragment (1,568 nucleotides) containing the dae gene and its putative ribosome-binding site has been subcloned and expressed in E. coli. Approximately 0.5% of the total cell protein is active Dae, whereas 21% is in the form of inclusion bodies. The isolation of this minimal fragment without a native promoter sequence provides the basis for designing a genetic system for modulating the D-alanine ester content of lipoteichoic acid.     

Identification,cloning, and sequencing of the genes involved in the conversion of D,L-2-amino-delta2-thiazoline-4-carboxylic acid to L-cysteine in Pseudomonas sp. strain ON-4a

The newly isolated strain Pseudomonas sp. ON-4a converts D,L-2-amino-delta2-thiazoline-4-carboxylic acid to L-cysteine via N-carbamoyl-L-cysteine. A genomic DNA fragment from this strain containing the gene(s) encoding enzymes that convert D,L-2-amino-delta2-thiazoline-4-carboxylic acid into L-cysteine was cloned in Escherichia coli. Transformants expressing cysteine-forming activity were selected by growth of an E. coli mutant defective in the cysB gene. A positive clone, denoted CM1, carrying the plasmid pCM1 with an insert DNA of approximately 3.4 kb was obtained, and the nucleotide sequence of a complementing region was analyzed. Analysis of the sequence found two open reading frames, ORF1 and ORF2, which encoded proteins of 183 and 435 amino acid residues, respectively. E. coli DH5alpha harboring pTrCM1, which was constructed by inserting the subcloned sequence into an expression vector, expressed two proteins of 25 kDa and 45 kDa. From the analyses of crude extracts of E. coli DH5alpha carrying deletion derivatives of pTrCM1 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and by enzymatic activity, it was found that the 25-kDa protein encoded by ORF1 was the enzyme L-2-amino-delta2-thiazoline-4-carboxylic acid hydrolase, which catalyzes the conversion of L-2-amino-delta2-thiazoline-4-carboxylic acid to N-carbamoyl-L-cysteine, and that the 45-kDa protein encoded by ORF2 was the enzyme N-carbamoyl-L-cysteine amidohydrolase, which catalyzes the conversion of N-carbamoyl-L-cysteine to L-cysteine.     

Nano-Intercalated Organophosphorus-Hydrolyzing Enzymes in Organophosphorus Antagonism

A dendritic poly(2-alkyloxazoline)-based polymer was studied as a new carrier system for the organophosphorus-hydrolyzing recombinant enzymes, organophosphorus acid anhydrolase and organophosphorus hydrolase. Paraoxon (PO) and diisopropylfluorophosphate (DFP) were used as model organophosphorus compounds. Changes in plasma cholinesterase activity were monitored. The cholinesterase activity was proportional to the concentrations of DFP or PO. Plasma cholinesterase activity was higher in animals receiving enzyme and oxime before the organophosphates than in the oxime-only pretreated groups. These studies suggest that cholinesterase activity can serve as an indicator for the in vivo protection by the nano-intercalated organophosphorus acid anhydrolase or organophosphorus hydrolase against organophosphorus intoxications. These studies represent a practical application of polymeric nano-delivery systems as enzyme carriers in drug antidotal therapy.     

Nucleotide sequence of the dihydrofolate reductase gene of Saccharomyces cerevisiae

The nucleotide sequence of a DNA fragment that contained the Saccharomyces cerevisiae gene DFR coding for dihydrofolate reductase (DHFR) was determined. The DHFR was encoded by a 633-bp open reading frame, which specified an Mr24264 protein. The polypeptide was significantly related to the DHFRs of chicken liver and Escherichia coli. The yeast enzyme shared 60 amino acid (aa) residues with the avian enzyme and 51 aa residues with the bacterial enzyme. DHFR was overproduced about 40-fold in S. cerevisiae when the cloned gene was present in the vector YEp24. As isolated from the Saccharomyces library, the DFR gene was not expressed in E. coli. When the gene was present on a 1.8-kb BamHI-SalI fragment subcloned into the E. coli vector, pUC18, weak expression in E. coli was observed.     

Cloning and characterization of the glycogen branching enzyme gene existing in tandem with the glycogen debranching enzyme from Pectobacterium chrysanthemi PY35

The glycogen branching enzyme gene (glgB) from Pectobacterium chrysanthemi PY35 was cloned, sequenced, and expressed in Escherichia coli. The glgB gene consisted of an open reading frame of 2196bp encoding a protein of 731 amino acids (calculated molecular weight of 83,859Da). The glgB gene is upstream of glgX and the ORF starts the ATG initiation codon and ends with the TGA stop codon at 2bp upstream of glgX. The enzyme was 43-69% sequence identical with other glycogen branching enzymes. The enzyme is the most similar to GlgB of E. coli and contained the four regions conserved among the alpha-amylase family. The glycogen branching enzyme (GlgB) was purified and the molecular weight of the enzyme was estimated to be 84kDa by SDS-PAGE. The glycogen branching enzyme was optimally active at pH 7 and 30 degrees C.     

Nucleotide sequence of plasmid NAH7 gene nahR and DNA binding of the nahR product.

The nah and sal operons of the 80-kilobase-pair (kb) NAH7 plasmid specify catabolism of naphthalene and salicylate under positive regulation by gene nahR. A 1.75-kb fragment (PstI-HindIII) cloned into the pCP13 derivative of vector RK2 complemented in trans five nahR mutations. The fragment sequence contained a 1,122-base-pair open reading frame with a predicted sequence of 374 residues that was rich in basic amino acids with regions similar to known DNA-binding proteins. Clones from the nahR gene region were expressed in mexicells. Plasmid pY1923, carrying the 1.75-kb PstI-HindIII fragment, expressed a protein of Mr ca. 35,000 which bound to the upstream region of gene nahR in a gel electrophoresis DNA-binding assay. Other clones expressed proteins of currently unknown function; pY1311, with the 1.1-kb HindIII fragment, produced a polypeptide with an Mr of 23,000, and pY1812, with the 1.2-kb PstI-SphI fragment, produced a polypeptide (Mr 41,000) which appeared to be a fused nahR-lacZ product.     

Characterization of a second lysine decarboxylase isolated from Escherichia coli.

We report here on the existence of a new gene for lysine decarboxylase in Escherichia coli K-12. The hybridization experiments with a cadA probe at low stringency showed that the homologous region of cadA was located in lambda Kohara phage clone 6F5 at 4.7 min on the E. coli chromosome. We cloned the 5.0-kb HindIII fragment of this phage clone and sequenced the homologous region of cadA. This region contained a 2,139-nucleotide open reading frame encoding a 713-amino-acid protein with a calculated molecular weight of 80,589. Overexpression of the protein and determination of its N-terminal amino acid sequence defined the translational start site of this gene. The deduced amino acid sequence showed 69.4% identity to that of lysine decarboxylase encoded by cadA at 93.7 min on the E. coli chromosome. In addition, the level of lysine decarboxylase activity increased in strains carrying multiple copies of the gene. Therefore, the gene encoding this lysine decarboxylase was designated Idc. Analysis of the lysine decarboxylase activity of strains containing cadA, ldc, or cadA ldc mutations indicated that ldc was weakly expressed under various conditions but is a functional gene in E. coli.     

Gene cloning, sequence analysis, purification, and characterization of a thermostable aminoacylase from Bacillus stearothermophilus.

A genomic DNA fragment encoding aminoacylase activity of the eubacterium Bacillus stearothermophilus was cloned into Escherichia coli. Transformants expressing aminoacylase activity were selected by their ability to complement E. coli mutants defective in acetylornithine deacetylase activity, the enzyme that converts N-acetylornithine to ornithine in the arginine biosynthetic pathway. The 2.3-kb cloned fragment has been entirely sequenced. Analysis of the sequence revealed two open reading frames, one of which encoded the aminoacylase. B. stearothermophilus aminoacylase, produced in E. coli, was purified to near homogeneity in three steps, one of which took advantage of the intrinsic thermostability of the enzyme. The enzyme exists as homotetramer of 43-kDa subunits as shown by cross-linking experiments. The deacetylating capacity of purified aminoacylase varies considerably depending on the nature of the amino acid residue in the substrate. The enzyme hydrolyzes N-acyl derivatives of aromatic amino acids most efficiently. Comparison of the predicted amino acid sequence of B. stearothermophilus aminoacylase with those of eubacterial acetylornithine deacylase, succinyldiaminopimelate desuccinylase, carboxypeptidase G2, and eukaryotic aminoacylase I suggests a common origin for these enzymes.     

Cloning of ubiquitin activating enzyme from wheat and expression of a functional protein in Escherichia coli

The initial step in the conjugation of ubiquitin to substrate proteins involves the activation of ubiquitin by ubiquitin activating enzyme, E1. Previously, we purified and characterized multiple species of E1 from wheat germ. We now describe the isolation and characterization of a cDNA clone encoding E1 from wheat. This clone (UBA1) was isolated from a cDNA expression library with anti-wheat E1 antibodies. It contained an open reading frame coding for 1051 amino acids and directed the synthesis of a protein that comigrated with a wheat germ E1 of 117 kDa. UBA1 was confirmed as encoding E1 by (i) comparison of the peptide map of the protein product of UBA1 synthesized in Escherichia coli with that of purified E1 from wheat, and (ii) amino acid sequence identity of peptides generated from purified E1 with regions of the derived amino acid sequence of UBA1. The isolation of two additional cDNAs closely related to UBA1 indicated that E1 was encoded by a small gene family in wheat. Nonetheless, a single poly(A+) mRNA size class of 4 kilobases hybridized with UBA1. When expressed in E. coli, the product of UBA1 catalyzed the formation of a thiol ester linkage between ubiquitin and an ubiquitin carrier protein. The ability of E. coli containing UBA1 to synthesize an active protein will allow us to identify domains important for E1 function using in vitro mutagenesis.     

A novel thermostable branching enzyme from an extremely thermophilic bacterial species, Rhodothermus obamensis

A branching enzyme (EC 2.4.1.18) gene was isolated from an extremely thermophilic bacterium, Rhodothermus obamensis. The predicted protein encodes a polypeptide of 621 amino acids with a predicted molecular mass of 72 kDa. The deduced amino acid sequence shares 42-50% similarity to known bacterial branching enzyme sequences. Similar to the Bacillus branching enzymes, the predicted protein has a shorter N-terminal amino acid extension than that of the Escherichia coli branching enzyme. The deduced amino acid sequence does not appear to contain a signal sequence, suggesting that it is an intracellular enzyme. The R. obamensis branching enzyme was successfully expressed both in E. coli and a filamentous fungus, Aspergillus oryzae. The enzyme showed optimum catalytic activity at pH 6.0-6.5 and 65 degrees C. The enzyme was stable after 30 min at 80 degrees C and retained 50% of activity at 80 degrees C after 16 h. Branching activity of the enzyme was higher toward amylose than toward amylopectin. This is the first thermostable branching enzyme isolated from an extreme thermophile.     

Characterization of the Butyrivibrio fibrisolvens glgB gene, which encodes a glycogen-branching enzyme with starch-clearing activity.

A Butyrivibrio fibrisolvens H17c glgB gene, was isolated by direct selection for colonies that produced clearing on starch azure plates. The gene was expressed in Escherichia coli from its own promoter. The glgB gene consisted of an open reading frame of 1,920 bp encoding a protein of 639 amino acids (calculated Mr, 73,875) with 46 to 50% sequence homology with other branching enzymes. A limited region of 12 amino acids showed sequence similarity to amylases and glucanotransferases. The B. fibrisolvens branching enzyme was not able to hydrolyze starch but stimulated phosphorylase alpha-mediated incorporation of glucose into alpha-1,4-glucan polymer 13.4-fold. The branching enzyme was purified to homogeneity by a simple two-step procedure; N-terminal sequence and amino acid composition determinations confirmed the deduced translational start and amino acid sequence of the open reading frame. The enzymatic properties of the purified enzyme were investigated. The enzyme transferred chains of 5 to 10 (optimum, 7) glucose units, using amylose and amylopetin as substrates, to produce a highly branched polymer.     

Catechol dioxygenases from Escherichia coli (MhpB) and Alcaligenes eutrophus (MpcI): sequence analysis and biochemical properties of a third family of extradiol dioxygenases.

The nucleotide sequence of the Escherichia coli mhpB gene, encoding 2,3-dihydroxyphenylpropionate 1,2-dioxygenase, was determined by sequencing of a 3.1-kb fragment of DNA from Kohara phage 139. The inferred amino acid sequence showed 58% sequence identity with the sequence of an extradiol dioxygenase, MpcI, from Alcaligenes eutrophus and 10 to 20% sequence identity with protocatechuate 4,5-dioxygenase from Pseudomonas paucimobilis, with 3,4-dihydroxyphenylacetate 2,3-dioxygenase from E. coli, and with human 3-hydroxyanthranilate dioxygenase. Sequence similarity between the N- and C-terminal halves of this new family of dioxygenases was detected, with conserved histidine residues in the N-terminal domain. A model is proposed to account for the relationship between this family of enzymes and other extradiol dioxygenases. The A. eutrophus MpcI enzyme was expressed in E. coli, purified, and characterized as a protein with a subunit size of 33.8 kDa. Purified MhpB and MpcI showed similar substrate specificities for a range of 3-substituted catechols, and evidence for essential histidine and cysteine residues in both enzymes was obtained.     

Cloning and characterization of the genes encoding the malolactic enzyme and the malate permease of Leuconostoc oenos.

Using degenerated primers from conserved regions of the protein sequences of malic enzymes, we amplified a 324-bp DNA fragment by PCR from Leuconostoc oenos and used this fragment as a probe for screening a Leuconostoc oenos genomic bank. Of the 2,990 clones in the genomic bank examined, 7 with overlapping fragments were isolated by performing colony hybridization experiments. Sequencing 3,453 bp from overlapping fragments revealed two open reading frames that were 1,623 and 942 nucleotides long and were followed by a putative terminator structure. The first deduced protein (molecular weight, 59,118) is very similar (level of similarity, 66%) to the malolactic enzyme of Lactococcus lactis; as in several malic enzymes, highly conserved protein regions are present. The synthesis of a protein with an apparent molecular mass of 60 kDa was highlighted by the results of labelling experiments performed with Escherichia coli minicells. The gene was expressed in E. coli and Saccharomyces cerevisiae and conferred "malolactic activity" to these species. The second open reading frame encodes a putative 34,190-Da protein which has the characteristics of a carrier protein and may have 10 membrane-spanning segments organized around a central hydrophilic core. Energy-dependent L-[14C]malate transport was observed with E. coli dicarboxylic acid transport-deficient mutants carrying the malate permease-expressing vector. Our results suggest that in Leuconostoc oenos the genes that encode the malolactic enzyme and a malate carrier protein are organized in a cluster.     

Molecular cloning, functional expression and purification of a glucan branching enzyme from Neisseria denitrificans(1).

The nucleotide sequence containing the complete structural information for a glucan branching enzyme was isolated from a Neisseria denitrificans genomic library. The gene was expressed in Escherichia coli and the active recombinant protein was purified. The deduced protein of 762 amino acids with a calculated molecular weight of 86313 Da shows similarity to the primary protein sequences of other known glucan branching enzymes. Amino acid sequencing of the isolated protein by Edman degradation confirmed the deduced start codon of the structural gene of the glucan branching enzyme. The purified glucan branching enzyme has a stimulating effect on the Neisseria amylosucrase activity.