Cloning and expression of anAeromonas hydrophila chitinase gene inescherichia coli

Multiple roles of Asp313 in the refined catalytic cycle of chitin degradation by Vibrio harveyi chitinase A

Three acidic residues in the DXDXE sequence motif are suggested to play a concerted role in the catalysis of Vibrio harveyi ChiA. An increase in the optimum pH of 0.8 units in mutant D313A/N indicates that Asp313 influences the pKa of the ionizing groups around the cleavage site. D313A showed greatly reduced kcat/Km and increased KD, suggesting that Asp313 participates in catalysis and ligand binding. Investigation of the enzyme-substrate interactions of V. harveyi ChiA and Serratia marcescens ChiB revealed two conformations of Asp313 and (-1)GlcNAc. The first conformation, likely to be the initial conformation, showed that the β-COOH of Asp313 only interacted with the -C=O of the N-acetyl group in the distorted sugar. The second conformation, formed from the first by concerted bond rotations, demonstrated hydrogen bonds between the Asp313 side chain and the -NH of the N-acetyl group and the γ-COOH of Glu315. Here we propose a further refinement of the catalytic cycle of chitin hydrolysis by family-18 chitinases that involves four steps: Step 1: Pre-priming. An acidic pair is formed between Asp311 and Asp313. Step 2: Substrate binding. The Asp313 side chain detaches from Asp311 and rotates to form a H-bond with the C=O of the 2-acetamido group of -1GlcNAc. Step 3: Bond cleavage. The side chain of Asp313 and the 2-acetamido group simultaneously rotate, permitting Asp313 to interact with the side chain of Glu315 and facilitating bond cleavage. Step 4: Formation of reaction intermediate. The transient (-1) C1-GlcNAc cation readily reacts with the 2-acetamido group, forming an oxazolinium ion intermediate. Further attack by a neighboring water results in retention of β-configuration of the degradation products.

Substrate binding modes and anomer selectivity of chitinase A from Vibrio harveyi

High-performance liquid chromatography mass spectrometry (HPLC MS) was employed to assess the binding behaviors of various substrates to Vibrio harveyi chitinase A. Quantitative analysis revealed that hexaNAG preferred subsites −2 to +2 over subsites −3 to +2 and pentaNAG only required subsites −2 to +2, while subsites −4 to +2 were not used at all by both substrates. The results suggested that binding of the chitooligosaccharides to the enzyme essentially occurred in compulsory fashion. The symmetrical binding mode (−2 to +2) was favored presumably to allow the natural form of sugars to be utilized effectively. Crystalline α chitin was initially hydrolyzed into a diverse ensemble of chitin oligomers, providing a clear sign of random attacks that took place within chitin chains. However, the progressive degradation was shown to occur in greater extent at later time to complete hydrolysis. The effect of the reducing-end residues were also investigated by means of HPLC MS. Substitutions of Trp275 to Gly and Trp397 to Phe significantly shifted the anomer selectivity of the enzyme toward β substrates. The Trp275 mutation modulated the kinetic property of the enzyme by decreasing the catalytic constant (k_cat) and the substrate specificity (k_cat/K_m) toward all substrates by five- to tenfold. In contrast, the Trp397 mutation weakened the binding strength at subsite (+2), thereby speeding up the rate of the enzymatic cleavage toward soluble substrates but slowing down the rate of the progressive degradation toward insoluble chitin.

Cloning and expression of an antifungal chitinase gene of a novel Bacillus subtilis isolate from Taiwan potato field

A chitinase producing Bacillus subtilis CHU26 was isolated from Taiwan potato field. This strain exhibited a strong extra-cellular chitinase activity on the colloidal chitin containing agar plate, and showed a potential inhibit activity against phytopathogen, Rhizoctonia solani. The gene encoding chitinase (chi18) was cloned from the constructed B. subtilis CHU26 genomic DNA library. The chi18 consisted of an open reading frame of 1791 nucleotides and encodes 595 amino acids with a deduced molecular weight of 64kDa, next to a promoter region containing a 9 base pair direct repeat sequence (ATTGATGAA). The deduced amino acid sequence of the chitinase from Bacillus subtilis CHU26 exhibits 62% and 81% similarity to those from B. circulans WL-12 and B. licheniformis, respectively. Subcloned chi18 into vector pGEM3Z and pYEP352 to construct recombinant plasmid pGCHI18 and pYCHI18, respectively, chitinase activity could be observed on the colloidal chitin agar plate from recombinant plasmid containing Escherichia coli transformant. Cell-free culture broth of pYCHI18 containing E. coli transformant decreased R. solani pathogenic activity more than 90% in the antagonistic test on the radish seedlings (Raphanus sativus Linn.).

Issues for Microbial Regulation:Aeromonasas a Model

The decision by public health agencies to regulate specific microorganisms that may be found in drinking water can only be made if specific criteria find that a microorganism poses a health risk. These criteria should include: (1) there is a clinical history of an organism causing disease from the ingestion of drinking water; (2) there is epidemiological evidence that drinking water rather than food or other vectors is a major source of disease; (3) there is sufficient evidence that the target organism, if found in water, possesses virulence factors capable of causing disease in humans; (4) there is sufficient evidence that the target organism is not readily removed or inactivated by multi-barrier conventional water treatment process (e.g., coagulation-filtration-disinfection); (5) there is sufficient evidence that the target organism, if surviving conventional treatment, will be viable, virulent, and present in sufficient numbers to cause disease; (6) there are robust analytical methods for the target organism which have acceptable sensitivity, specificity, and reproducibility to measure accurately the presence of the target organism in treated water; and (7) the performance criteria of analytical method(s) for the target organism have been certified by the appropriate public health agency, and there is intra-laboratory field-test performance data to base this certification.

Identification and characterization of the gene cluster involved in chitin degradation in a marine bacterium, Alteromonas sp. strain O-7

Alteromonas sp. strain O-7 secretes chitinase A (ChiA), chitinase B (ChiB), and chitinase C (ChiC) in the presence of chitin. A gene cluster involved in the chitinolytic system of the strain was cloned and sequenced upstream of and including the chiA gene. The gene cluster consisted of three different open reading frames organized in the order chiD, cbp1, and chiA. The chiD, cbp1, and chiA genes were closely linked and transcribed in the same direction. Sequence analysis indicated that Cbp1 (475 amino acids) was a chitin-binding protein composed of two discrete functional regions. ChiD (1,037 amino acids) showed sequence similarity to bacterial chitinases classified into family 18 of glycosyl hydrolases. The cbp1 and chiD genes were expressed in Escherichia coli, and the recombinant proteins were purified to homogeneity. The highest binding activities of Cbp1 and ChiD were observed when alpha-chitin was used as a substrate. Cbp1 and ChiD possessed a chitin-binding domain (ChtBD) belonging to ChtBD type 3. ChiD rapidly hydrolyzed chitin oligosaccharides in sizes from trimers to hexamers, but not chitin. However, after prolonged incubation with large amounts of ChiD, the enzyme produced a small amount of (GlcNAc)(2) from chitin. The optimum temperature and pH of ChiD were 50 degrees C and 7.0, respectively.

Cloning of a chitinase gene from Ewingella americana, a pathogen of the cultivated mushroom, Agaricus bisporus

We have isolated a gene encoding a chitinase (EC 3.2.1.14) from Ewingella americana, a recently described pathogen of the mushroom Agaricus bisporus. This gene, designated chiA (EMBL/Genbank/DDBJ accession number X90562), was cloned by expression screening of a plasmid-based E. americana HindIII genomic library in Escherichia coli using remazol brilliant violet-stained carboxymethylated chitin incorporated into selective medium. The chiA gene has a 918-bp ORF, terminated by a TAA codon, with a calculated polypeptide size of 33.2 kDa, likely corresponding to a previously purified and characterised 33-kDa endochitinase from E. americana. The deduced amino acid sequence shares 33% identity with chitinase II from Aeromonas sp. No. 10S-24 and 7.8% identity with a chitinase from Saccharopolyspora erythraeus. Homology to other chitinase sequences was otherwise low. The peptide sequence deduced from chiA lacks a typical N-terminal signal sequence and also lacks the chitin binding and type III fibronectin homology units common to many bacterial chitinases. The possibility that this chitinase is not primarily adapted for the environmental mineralisation of pre-formed chitin, but rather for the breakdown of nascent chitin, is discussed in the context of mushroom disease.

Construction of a physical and preliminary genetic map of Aeromonas hydrophila JMP636

A physical and preliminary genetic map of the Aeromonas hydrophila JMP636 chromosome has been constructed. The topology of the genome was predicted to be circular as chromosomal DNA did not migrate from the origin during PFGE unless linearized by S1 nuclease. Cleavage of the chromosome with PacI and PmeI produced 23 and 14 fragments, respectively, and enabled calculation of the genome size at 4.5 Mb. Digestion of the chromosome with I-CeuI produced 10 fragments, indicating that 10 rrl (23S) genes were likely to be present. Hybridizations between DNA fragments generated with PacI, PmeI and I-CeuI were used to initially determine the relationship between these segments. To accurately map genes previously characterized from JMP636, the suicide vector pJP5603 was modified to introduce restriction sites for PacI and PmeI, producing pJP9540. Following cloning of genes into this vector and recombinational insertion into the JMP636 chromosome, PacI and PmeI cleavage determined the location of genes within macrorestriction fragments with the additional bands produced forming hybridization probes. From the data generated, it was possible to form a physical map comprising all the fragments produced by PacI and PmeI, and assign the contig of I-CeuI fragments on this map. The preliminary genetic map defines the location of six loci for degradative enzymes previously characterized from JMP636, while the locations of the 10 sets of ribosomal genes were assigned with less accuracy from hybridization data.

Expression and characterization of the recombinant gene encoding chitinase from Aeromonas caviae

The gene encoding a chitinase from Aeromonas caviae was cloned by PCR techniques. Its recombinant gene expression was performed using pET20b(+) in Escherichia coli BL21 (DE3). The recombinant chitinase with the extra 33 and 13 amino acids in its N- and C-termini, respectively, was purified to near homogeneity using His-Tag affinity chromatography. The recombinant chitinase was found to be present in both the culture medium and the cytoplasm. A single protein band on the native polyacrylamide gel was confirmed by both the activity staining and protein staining. The optimum pH and temperature of the recombinant chitinase were determined to be 6.25-6.5 and 42.5 degrees C, respectively. It was stable within the pH range of 5-7. Significant activity stimulation by Cu2+ and inhibition by Fe3+ and Hg2+ were observed. Detergents such as SDS and Triton X-100 strongly inhibited the enzyme activity. Substrates such as 4-methylumbelliferyl-N,N'-diacetylchitobioside and 4-methylumbelliferyl-N,N',N"-triacetylchitotriose were hydrolyzed by the recombinant chitinase; however, 4-methylumbelliferyl-N-acetylglucosaminide was not cleaved during the activity assay periods. When chitin power was suspended in buffer with the chitinase (pH 6.5 and 42.5 degrees C), N-acetylchitooligosaccharides [(GlcNAc)n, n = 1-4] were detected at 24 h.

Secreted enzymes of Aeromonas

A hallmark characteristic of species of Aeromonas is their ability to secrete a wide variety of enzymes associated with pathogenicity and environmental adaptability. Among the most intensively studied are beta-lactamases, lipases, hemolytic enterotoxins, proteases, chitinases, nucleases and amylases. Multiple copies of genes encoding each type of enzyme provide additional biological diversity. Except for the chitinases, these multiple copies show little evolutionary relatedness at the DNA level and only limited similarity at the protein level. Indeed a number of the genes, such as nuclease H of A. hydrophila, have no similarity to known prokaryotic or eukaryotic sequences. The challenge is to determine how these genes evolved, where they originated and why Aeromonas possesses them in such abundance and variety.

The chitin catabolic cascade in the marine bacterium Vibrio furnissii. Molecular cloning, isolation, and characterization of a periplasmic chitodextrinase

Chitin catabolism in Vibrio furnissii comprises several signal transducing systems and many proteins. Two of these enzymes are periplasmic and convert chitin oligosaccharides to GlcNAc and (GlcNAc)2. One of these unique enzymes, a chitodextrinase, designated EndoI, is described here. The protein, isolated from a recombinant Escherichia coli clone, exhibited (via SDS-polyacrylamide gel electrophoresis) two enzymatically active, close running bands ( approximately mass of 120 kDa) with identical N-terminal sequences. The chitodextrinase rapidly cleaved chitin oligosaccharides, (GlcNAc)4 to (GlcNAc)2, and (GlcNAc)5,6 to (GlcNAc)2 and (GlcNAc)3. EndoI was substrate inhibited in the millimolar range and was inactive with chitin, glucosamine oligosaccharides, glycoproteins, and glycopeptides containing (GlcNAc)2. The sequence of the cloned gene indicates that it encodes a 112,690-kDa protein (1046 amino acids). Both proteins lacked the predicted N-terminal 31 amino acids, corresponding to a consensus prokaryotic signal peptide. Thus, E. coli recognizes and processes this V. furnissii signal sequence. Although inactive with chitin, the predicted amino acid sequence of EndoI displayed similarities to many chitinases, with 8 amino acids completely conserved in 10 or more of the homologous proteins. There was, however, no "consensus" chitin-binding domain in EndoI.

Expression of chitinase-encoding genes from Aeromonas hydrophila and Pseudomonas maltophilia in Bacillus thuringiensis subsp. israelensis

Fifty isolates of chitinase (Cts)-producing bacteria were collected from soil samples and tested for their ability to degrade chitin using colloidal chitin agar as the primary plating medium. The results indicated that three isolates could degrade chitin at high pH. Further studies also demonstrated that crude Cts preparations from Bacillus circulans (Bc) No. 4.1 could enhance the toxicity of Bacillus thuringiensis subsp. kurstaki (Bt-k) toward diamondback moth larvae. Thus, it might be useful to increase the toxicity of B. thuringiensis (Bt) toward target insects by introducing a Cts-encoding gene (cts) into Bt. To investigate the expression of cts in Bt, cloned cts from Aeromonas hydrophila (pHYA1) and Pseudomonas maltophilia (pHYB1, pHYB2 and pHYB3) were cloned into the shuttle vector pHY300PLK and transformed into Escherichia coli DH5 alpha using 4-methylumbelliferyl beta-D-N,N'-diacetylchitobioside (4-MUF GlcNAc) as the detecting substrate. The four plasmids were then introduced into B. thuringiensis subsp. israelensis (Bt-i) strain c4Q272 by electroporation. Various transformants harboring cloned cts were selected, and expression and stability of the plasmids in Bt were studied.

Cloning, sequencing, and characterization of the nucH gene encoding an extracellular nuclease from Aeromonas hydrophila JMP636

An Escherichia coli clone expressing activity on DNase agar was obtained by cloning chromosomal DNA of Aeromonas hydrophila JMP636 into plasmid pUC19. Examination (of the clone's nuclease activity on a sodium dodecyl sulfate (SDS)-polyacrylamide gel containing DNA as a substrate revealed an activity band at approximately 100 kDa. Subsequently, subcloning localized the gene, designated nucH, to a 3.6-kb DNA fragment (pJP9521). Southern blotting of the nucH gene against chromosomal DNA of JMP636 confirmed that it had originated from this strain and demonstrated that it was present in a single copy, although additional faint bands were also detected. Analysis of the subclone using in vivo transcription and translation revealed only a single polypeptide of approximately 110 kDa. Sequencing of pJP9521 predicted an open reading frame of 3,213 bp encoding a protein of 1,070 amino acids and having a molecular mass of 114 kDa. Comparison of the deduced nucleotide sequence and the NucH predicted protein sequence with relevant databases indicated that no known homologs have previously been identified. A signal sequence was predicted from these data, and cellular fractionation of a nucH clone in E. coli indicated that the protein was able to be processed to the periplasm. An activity similar in size was detected in an extracellular protein sample of JMP636, while inactivation of the nucH gene resulted in loss of this activity band. By native SDS-polyacrylamide gel electrophoresis, NucH substrate specificity, cofactor requirements, and sensitivity to denaturing agents were assessed.

A specific PulD homolog is required for the secretion of paracrystalline surface array subunits in Aeromonas hydrophila

Aeromonas hydrophila is an important pathogen of fish, and its high-virulence strains display a two-dimensional paracrystalline layer (S-layer) on their outermost surfaces. The nucleotide sequence of a 4.1-kb region located 700 bp upstream of the A. hydrophila TF7 S-layer protein gene (ahsA) has been determined. A sequence analysis of the region revealed the presence of three complete open reading frames ending in a gene encoding a 79.8-kDa polypeptide that shows high homology to the PulD family of secretion proteins. The sequenced region displays both organizational and sequence homology to the Xanthomonas campestris pv. campestris Xps secretory system. Insertional inactivation of the spsD (S-protein secretion D) gene showed that the loss of expression of the PulD homolog coincided with the localization of the S-protein in the periplasm and the loss of the S-layer from the surface of the bacterium. However, the secretion of the enzymes hemolysin, amylase, and protease was unaffected in the mutant with the nonfunctional spsD gene, as was the export of flagella and fimbrial proteins. Southern blot analysis showed that the spsD gene was not conserved among all strains of S-protein-producing A. hydrophila or Aeromonas veronii biotype sobria. Use of the promoterless chloramphenicol acetyltransferase gene showed that unlike pulD and its homologs, spsD contains its own promoter. A. hydrophila has been shown to contain the exe operon, which is responsible for the secretion of a number of extracellular enzymes in this bacterium. A fragment of DNA was generated from the exeD gene of A. hydrophilia Ah65 by PCR and was subsequently used in hybridization studies to probe the chromosome of A. hydrophila TF7. The presence of an exeD homolog in A. hydrophila TF7 was found; therefore, the spsD gene encodes a second pulD homolog that displays a high specificity for the secretion of the S-protein. This gene appears to be part of a second terminal branch of the general secretory pathway in A. hydrophila.

A lipase of Aeromonas hydrophila showing nonhemolytic phospholipase C activity

Extracellular lipase activity detected on tributyrin agar has been identified in a cosmid clone, JM3084, constructed from the chromosome of Aeromonas hydrophila and vector pHC79. This lipase, named apl-1, also exhibits nonhemolytic phospholipase C activity on lecithin and p-nitrophenylphosphorylcholine. Subcloning of the cosmid JMP3084 with partial Sau3a1 digestion localized the lipase gene to a 3.4-kb DNA fragment. Southern blot analysis shows the gene apl-1 to exist in single copy on the A. hydrophila chromosome. Expression of apl-1 in the pT7 system identified a single protein of molecular weight 70 kDa. Nucleotide sequencing of apl-1 has identified an open reading frame of 2055 bases predicting a protein of 73 kDa. The presence of an amino terminal signal sequence of 18 amino acids accounts for this molecular weight disparity. Further analysis of the lipase amino acid sequence revealed the presence of a classical serine active lipase site (Gly-X-Ser-X-Gly) located between residues 561 and 570. The A. hydrophila chromosomal copy of apl-1 has been inactivated by use of the mutagenesis vector pJP5603, resulting in the complete removal of phospholipase C activity and lowered levels of lipase activity detected on tributyrin agar.