Nucleotide sequence of the Erwinia chrysanthemi gene encoding 2-keto-3-deoxygluconate permease

The phytopathogenic bacterium Erwinia chrysanthemi produces a group of pectolytic enzymes able to depolymerise the pectic compounds in plant cell walls. The resulting tissue maceration is known as soft rot disease. The degraded pectin products are transported by 2-keto-3-deoxygluconate permease into the bacterial cell, where they serve as carbon and energy sources. This H+ coupled transport system is encoded by the kdgT gene; we report the nucleotide sequence of kdgT. It is encoded by an open reading frame (ORF) of 1194 bp, which is preceded by an Escherichia coli-type promoter region. The ORF encodes a protein with 398 amino acid (aa) residues and a predicted Mr of 48,550. As would be expected for a membrane protein, it is very hydrophobic, containing 63% nonpolar aa. However, the kdgT gene has no apparent evolutionary relationship to other genes encoding sugar transport proteins, such as lacY, melB or the E. coli citrate transport gene. Southern hybridization experiments indicate a strong homology between the Er. chrysanthemi and E. coli kdgT genes; there is also a second region on the E. coli chromosome with homology to kdgT. The kdgT gene is located near the ade-377 marker on the Er. chrysanthemi chromosome (equivalent to the region between 20 and 30 min in E. coli), whereas the E. coli kdgT gene is located at 88 min. Thus, these two enterobacteria show some significant differences in their genomic organization.     

Rapid large-scale preparation of recombinant Erwinia chrysanthemi L-asparaginase.

L-asparaginase from Erwinia provides an alternative to the enzyme from E. coli for the effective treatment of acute lymphoblastic leukaemia. A procedure was required for the large-scale partial purification of the recombinant Erwinia enzyme cloned and expressed in Erwinia. Enzyme was extracted from Erwinia at high pH and extraneous protein precipitated at low pH. S-Sepharose FF was selected as the medium of choice for the chromatography step since it was adequate for the high flow rates required (linear flow rate 315 cm h-1) and the methylsulphonate functional groups exploited the high pI of the enzyme by allowing binding of L-asparaginase at pH 4.8 while most of the other proteins passed through the column. The useful capacity of the matrix was up to 34 mg enzyme/ml matrix at a linear flow rate of 95 cm h-1 and 15.4 mg enzyme/ml matrix at a linear flow rate of 315 cm h-1. Weakly bound protein was removed by a wash at pH 6.0. The L-asparaginase was eluted by a wash at pH 6.8 (linear flow rate 95 cm h-1) and was substantially pure, only requiring polishing steps to be suitable for use as a parenteral agent. The purity of the protein was complemented by a 92% recovery of active enzyme from this cation-exchange matrix.     

Structural basis for the activity and substrate specificity of Erwinia chrysanthemi L-asparaginase

Bacterial L-asparaginases, enzymes that catalyze the hydrolysis of L-asparagine to aspartic acid, have been used for over 30 years as therapeutic agents in the treatment of acute childhood lymphoblastic leukemia. Other substrates of asparaginases include L-glutamine, D-asparagine, and succinic acid monoamide. In this report, we present high-resolution crystal structures of the complexes of Erwinia chrysanthemi L-asparaginase (ErA) with the products of such reactions that also can serve as substrates, namely L-glutamic acid (L-Glu), D-aspartic acid (D-Asp), and succinic acid (Suc). Comparison of the four independent active sites within each complex indicates unique and specific binding of the ligand molecules; the mode of binding is also similar between complexes. The lack of the alpha-NH3(+) group in Suc, compared to L-Asp, does not affect the binding mode. The side chain of L-Glu, larger than that of L-Asp, causes several structural distortions in the ErA active side. The active site flexible loop (residues 15-33) does not exhibit stable conformation, resulting in suboptimal orientation of the nucleophile, Thr15. Additionally, the delta-COO(-) plane of L-Glu is approximately perpendicular to the plane of gamma-COO(-) in L-Asp bound to the asparaginase active site. Binding of D-Asp to the ErA active site is very distinctive compared to the other ligands, suggesting that the low activity of ErA against D-Asp could be mainly attributed to the low k(cat) value. A comparison of the amino acid sequence and the crystal structure of ErA with those of other bacterial L-asparaginases shows that the presence of two active-site residues, Glu63(ErA) and Ser254(ErA), may correlate with significant glutaminase activity, while their substitution by Gln and Asn, respectively, may lead to minimal L-glutaminase activity.     

Nucleotide sequence of pnl gene from Erwinia carotovora Er

The nucleotide sequence of pnl gene encoding pectin lyase (PNL; EC4.2.2.10)from Erwinia carotovora Er was determined. The structural gene of pnl consisted of 942 base pairs. An open reading frame that could encode a 33,700 dalton polypeptide consisting 314 amino acids was assigned. The molecular size of the polypeptide predicted from the amino acid composition was close to the value of PNL determined in E.carotovora Er. The nucleotide sequence of the 5'-flanking region showed the presence of the consensus sequence of ribosome binding site, Pribnow box and the RNA polymerase recognition site in E.carotovora and Escherichia coli. Between the presumed Pribnow box and the ribosome binding site, two pairs of inverted repeats were found. By comparing the predicted amino acid sequences of pnl, several reported bacterial pectate lyases and Aspergillus niger pectin lyase, short regions of homology were found despite the different substrate specificities of these enzymes.     

Molecular cloning and nucleotide sequence of the pectin methyl esterase gene of Erwinia chrysanthemi B374

The gene encoding pectin methyl esterase (pme) has been cloned from Erwinia chrysanthemi B374. Expression of pme in Escherichia coli allowed the enzyme to be characterized. Pectin methyl esterase (PME) was found to have an apparent molecular weight of 36,000 Daltons and an isoelectric point of approximately 9.9. The structural gene was sequenced and consists of a 1098-bp open reading frame encoding a polypeptide of 39,318 Daltons, which includes an amino-terminal signal peptide. The isolation of the Erwinia gene provides a simple method for the production of PME free from depolymerizing pectinases thereby extending its potential uses.     

Characterization of the Erwinia chrysanthemi osmoprotectant transporter gene ousA.

Growth of Erwinia chrysanthemi in media of elevated osmolarity can be achieved by the uptake and accumulation of various osmoprotectants. This study deals with the cloning and sequencing of the ousA gene-encoded osmoprotectant uptake system A from E. chrysanthemi 3937. OusA belongs to the superfamily of solute ion cotransporters. This osmotically inducible system allows the uptake of glycine betaine, proline, ectoine, and pipecolic acid and presents strong similarities in nucleotide sequence and protein function with the proline/betaine porter of Escherichia coli encoded by proP. The control of ousA expression is clearly different from that of proP. It is induced by osmotic strength and repressed by osmoprotectants. Its expression in E. coli is controlled by H-NS and is rpoS dependent in the exponential phase but unaffected by the stationary phase.     

Pectate lyase gene regulatory mutants of Erwinia chrysanthemi.

The pelB gene, which encodes one of the five pectate lyase isoenzymes of Erwinia chrysanthemi 3937, was mutagenized with a mini-Mu transposable element that can form gene fusions to the neomycin phosphotransferase-encoding region. Secondary mutants resistant to kanamycin in the absence of polygalacturonate, an inducer of wild-type pectate lyase activities, were selected. Such mutants produced other pectate lyase isoenzymes in the absence of the inducer.     

Extracellular polysaccharide of Erwinia chrysanthemi A350 and ribotyping of Erwinia chrysanthemi spp

Erwinia chrysanthemi spp. are gram-negative bacterial phytopathogens causing soft rots in a number of plants. The structure of the extracellular polysaccharide (EPS) produced by the E. chrysanthemi strain A350, which is a lacZ- mutant of the wild type strain 3937, pathogenic to Saintpaulia, has been determined using a combination of chemical and physical techniques including methylation analysis, low-pressure gel-filtration and anion-exchange chromatography, high-pH anion-exchange chromatography, partial acid hydrolysis, mass spectrometry and 1- and 2D NMR spectroscopy. In contrast to the structures of the EPS reported for other strains of E. chrysanthemi, the EPS from strain A350 contains D-GalA, together with L-Rhap and D-Galp in a 1:4:1 ratio. Evidence is presented for the following hexasaccharide repeat unit: [structure: see text] All the Erwinia chrysanthemi spp. studied to date have been analyzed by ribotyping and collated into families, which are consistent with the related structures of their EPS.     

Cloning and expression of the Erwinia chrysanthemi asparaginase gene in Escherichia coli and Erwinia carotovora

A genomic library of Erwinia chrysanthemi DNA was constructed in bacteriophage lambda 1059 and recombinants expressing Er. chrysanthemi asparaginase detected using purified anti-asparaginase IgG. The gene was subcloned on a 4.7 kb EcoRI DNA restriction fragment into pUC9 to generate the recombinant plasmid pASN30. The position and orientation of the asparaginase structural gene was determined by subcloning. The enzyme was produced at high levels in Escherichia coli (5% of soluble protein) and was shown to be exported to the periplasmic space. Purified asparaginase from E. coli cells carrying pASN30 was indistinguishable from the Erwinia enzyme on the basis of specific activity [660-700 units (mg protein)-1], pI value (8.5), and subunit molecular weight (32 X 10(3]. Expression of the cloned gene was subject to glucose repression in E. coli but was not significantly repressed by glycerol. Recombinant plasmids, containing the asparaginase gene, when introduced into Erwinia carotovora, caused increased synthesis of the enzyme (2-4 fold higher than the current production strain).     

Expression of the pectate lyase gene from Erwinia chrysanthemi ENA49 in cells of other Erwinia species

The gene for a pectate lyase of E. chrysanthemi ENA49 cloned in a recombinant plasmid pPTL1 (a derivative of RSF1010) was transferred into E. carotovora. The pectate lyase determined by the cloned gene was secreted into the cultural medium from the cells of E. crysanthemi EC16. Partial secretion of the enzyme was registered for E. carotovora cells. The major part of EC1 E. chrysanthemi pectate lyase synthesized by E. carotovora cells is accumulated in periplasmic and cytoplasmic fractions. The obtained results suggest the different specificity or efficiency of pectate lyase secretion systems in the studied Erwinia strains.     

Osmoregulated periplasmic glucans of Erwinia chrysanthemi

We report the initial characterization of the osmoregulated periplasmic glucans (OPGs) of Erwinia chrysanthemi. OPGs are intrinsic components of the bacterial envelope necessary to the pathogenicity of this phytopathogenic enterobacterium (F. Page, S. Altabe, N. Hugouvieux-Cotte-Pattat, J.-M. Lacroix, J. Robert-Baudouy and J.-P. Bohin, J. Bacteriol. 183:0000-0000, 2001 [companion in this issue]). OPGs were isolated by trichloracetic acid treatment and gel permeation chromatography. The synthesis of these compounds appeared to be osmoregulated, since lower amounts of OPGs were produced when bacteria were grown in media of higher osmolarities. However, a large fraction of these OPGs were recovered in the culture medium. Then, these compounds were characterized by compositional analysis, high-performance anion-exchange chromatography, matrix-assisted laser desorption mass spectrometry, and (1)H and (13)C nuclear magnetic resonance analyses. OPGs produced by E. chrysanthemi are very heterogeneous at the level of both backbone structure and substitution of these structures. The degree of polymerization of the glucose units ranges from 5 to 12. The structures are branched, with a linear backbone consisting of beta-1,2-linked glucose units to which a variable number of branches, composed of one glucose residue, are attached by beta-1,6 linkages in a random way. This glucan backbone may be substituted by O-acetyl and O-succinyl ester-linked residues.     

recA-genes of Erwinia chrysanthemi ENA49

The recA gene of Erwinia chrysanthemi ENA49 has been cloned in vivo in Escherichia coli K12, recA13 cells using the plasmid pULB113. On the basis or DNA repair and recombination deficiencies complementation, of restoration of the inducible "SOS"-response functions the functional identity of the cloned gene with the recA gene was concluded. The recA gene was localized in the 18th min region of the chromosomal genetical map of Erwinia chrysanthemi ENA49 between the genes proA and pheA.