Expression of Erwinia chrysanthemi ENA49 uvr gene in Escherichia coli K12 cells

The uvrA gene of Erwinia chrysanthemi ENA49 similar to uvrA gene of Escherichia coli K12 has been cloned in vivo in Escherichia coli AB1886 uvrA6 cells using the plasmid pULB113 (RP4mini Mu). The presence of pULB113 carrying uvrA gene of Erwinia in Escherichia coli K12 uvrA- cells resulted in suppression of this mutation while uvrB and uvrC are not suppressed by this locus. The genetic control of excision repair of UV-damage in Erwinia chrysanthemi ENA49 is concluded to be similar to the one in Escherichia coli K12.     

Cloning of pectate-lyase genes of Erwinia chrysanthemi in Escherichia coli cells

Erwinia chrysanthemi DNA fragment digested by restriction endonuclease EcoRI and carrying the gene EC16 determining the synthesis of pectatelyase with Rf 0.20 and mol. mass 40kD has been cloned in plasmid pUC 9 plasmid in Escherichia coli HB101 cells. Three genes for pectatelyases of Erwinia chrysanthemi ENA49 have been cloned in vector phage lambda 47.1 in Escherichia coli cells. Two genes determining the synthesis of pectatelyases with Rf 0.06 and 0.19 and mol. masses 40 kD and 39 kD have been cloned as a part of an 7 kb Eco RI-fragment, that suggested their close location on the chromosome of Erwinia chrysanthemi ENA49. All of the cloned pectatelyase genes are expressed constitutively with pectatelyases accumulating in periplasm and being unable to secret into the cultural medium.     

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.     

Cloning and analysis of structural and regulatory pectate lyase genes of Erwinia chrysanthemi ENA49

Erwinia chrysanthemi ENA49 structural and regulatory ptl genes, coding for pectate lyase (Ptl) were cloned in Escherichia coli cells. Phage vector lambda L47.1 and phasmid vector lambda pMYF131 were used for constructing libraries of BamHI and EcoRI fragments, respectively, of Er. chrysanthemi chromosomal DNA. Among the 1,100 hybrid clones containing BamHI Er. chrysanthemi DNA fragments and 11,000 hybrid clones containing EcoRI fragments, six and 45 clones, respectively, were identified as having pectolytic activity. Two different structural genes, designated ptlA and ptlB, have been subcloned on multi-copy plasmids. Genes ptlA and ptlB are located side by side on the chromosome of Er. chrysanthemi and transcribe in the same direction. Each of the genes has its own promoter. Southern-blot hybridization analysis showed that the cloned ptl genes shared practically no homology and each of the genes was represented by a single copy on the Er. chrysanthemi chromosome. Other ptl genes capable of expression in E. coli cells were not found in the gene libraries. Negative regulation of the ptlA gene expression by a cloned gene called ptlR was shown. To screen the gene library for the ptlR gene, a specific genetic system was devised. The genes studied are located within an EcoRI chromosomal DNA fragment of 7.3 kb in the order: ptlA-ptlB-ptlR.     

Mapping of the locus encoding the bacteriocinogenicity trait in Erwinia chrysanthemi ENA49

The bacteria Erwinia chrysanthemi ENA49 have been found to produce bacteriocin that is similar in structure to the tail fibers of bacteriophages and suppressing viability of a number of Erwinia, Pseudomonas and Xanthomonas strains. Genetic control of bacteriocin synthesis is determined by the determinants localized on the 68 min of chromosomal genetic map.     

UV-induced formation of filamentous forms in bacteria of Erwinia genus

Cells of 56 pectolytic Erwinia strains of different origin tested are prone to filamentation after UV-irradiation. The fact makes one possible to consider them natural fil+ organisms. Bacteria E. herbicola (9 strains) that are unable to synthesize pectatelyases are not transformed into filaments after NV-irradiation. The function of fil+ genes is recA-dependent in bacteria E. chrysanthemi ENA49 and is phenotypically analogous to fil+ gene function in E. coli B or lon- mutation in E. coli K12.     

Isolation and genetic study of Erwinia mutants devoid of common components of the phosphoenolpyruvate-dependent phosphotransferase system

Mutants of bacteria belonging the genus Erwinia (Erwinia chrysanthemi and Erwinia carotovora) with pleiotropic disturbances in the utilization of many substrates were obtained through chemical and transposon mutagenesis. Genetic studies revealed that these mutants had defective ptsI or ptsH genes responsible for the synthesis of common components of the phosphoenolpyruvate-dependent phosphotransferase system, enzyme I and the HPr protein, respectively. The ptsI+ allele in both Erwinia species was cloned in vivo. Mapping of obtained mutations indicated that the ptsI and ptsH genes of E. chrysanthemi do not constitute a linkage group. The ptsI gene is located at 100 min of the chromosomal map, whereas the ptsH gene is located at 175 min. Sequencing of a portion of the E. chrysanthemi ptsI gene showed that a product of the cloned DNA region had up to 68% homology with the N terminus of Escherichia coli enzyme I.     

The role of te transposition of Tn1000 from Flac+-plasmid into chromosome of Erwinia chrysanthemi in the formation of Hfr-type donors

Based on the data of stability of the donor state of Hfr-like strain Erwinia chrysanthemi VY1-10 in RecA+ and RecA- cells, it can be suggested that the donor properties of the strain are mediated by the presence of the genetic homology region which occurred as a result of transposition of the Tn1000 from the Flac+ plasmid into the chromosome of E. chrysanthemi. Tn1000 may be transposed into several sites on the chromosome of E. chrysanthemi ENA49. This leads to the appearance of donors transferring their chromosome from several fixed points oriT and in opposite directions. The location of these points and the direction of transfer are determined by Tn1000 insertion sites and their orientation.     

Regulation and role in pathogenicity of Erwinia chrysanthemi 3937 pectin methylesterase.

The gene pem, encoding the pectin methylesterase (PME) of Erwinia chrysanthemi 3937, was cloned and mutagenized by mini-Mu transposable elements. A second gene, pecY, which could act as a negative regulator of PME was found 5' to the pem gene. A PME-E. chrysanthemi derivative inoculate onto Saintpaulia plants was shown to be clearly noninvasive, demonstrating the important role of this enzyme in soft rot disease.     

An nptI-sacB-sacR cartridge for constructing directed, unmarked mutations in gram-negative bacteria by marker exchange-eviction mutagenesis

A technique for marker exchange-eviction mutagenesis that enables the construction of directed, unmarked mutations in Gram-negative bacteria was demonstrated in Erwinia chrysanthemi. The technique employs an nptI-sacB-sacR cartridge that is carried on a 3.8-kb BamHI fragment and confers kanamycin (Km) resistance and sucrose sensitivity (due to the production of levansucrase by sacB) in E. chrysanthemi. The cartridge was inserted into a Sau3A site in a cloned E. chrysanthemi pelC gene (encoding pectate lyase isozyme PLc) and then introduced into the Erwinia genome by gene exchange recombination. The resulting mutant was KmR, sucrose-sensitive, and PLc-deficient. The cartridge was then excised from the plasmid-borne pelC gene by PstI cleavage to leave a 28-bp frame-shifting insertion. The pelC allele containing the 28-bp insertion was exchanged for the chromosomal allele containing the nptI-sacB-sacR cartridge by selection for sucrose tolerance. The resulting E. chrysanthemi mutant was Kms and PLc-deficient. The technique permits the construction of complex strains with many directed mutations without the introduction of a corresponding number of antibiotic resistance markers and should prove useful, for example, in exploring the role of the multiple pel genes in E. chrysanthemi.     

Cloning of a galacturonic acid uptake gene from Erwinia chrysanthemi EC16

Abstract A 3.4 kb fragment of Erwinia chrysanthemi EC16 DNA capable of complementing galacturonic acid uptake mutants ( exuT ) was identified and cloned into a multicopy vector. In E. chrysanthemi B374 exuT mutants, the cloned DNA provided for growth of the mutant strains on galacturonic acid by complementing the galacturonic acid uptake defect. Alkaline phosphatase ( phoA ) gene fusions with the cloned DNA suggested that most of the cloned DNA was necessary for complementation of exuT mutant strains. Using anti-alkaline phosphatase antibody, a hybrid ExuT-PhoA protein was localized to the membrane fraction of the bacterium.     

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).     

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.     

Mu-lac insertion-directed mutagenesis in a pectate lyase gene of Erwinia chrysanthemi.

The pelC gene, which encodes one of the five major pectate lyase (PL) isoenzymes in Erwinia chrysanthemi 3937, designated PLc, was subcloned from a hybrid lambda phage into a pBR322 derivative and mutagenized with a mini-Mu-lacZ transposable element able to form fusions to the lacZ gene. One plasmid (pAD1) which had an inactivated pelC gene and a Lac+ phenotype was selected in Escherichia coli. This plasmid was introduced into Erwinia chrysanthemi, and the pelC::mini-Mu insertion was substituted for the chromosomal allele by homologous recombination. This strain lacks the PLc isoenzyme. This Erwinia chrysanthemi strain has a Lac+ phenotype that is inducible by polygalacturonate, as are the wild-type PL activities.     

Cloning of genes encoding extracellular metalloproteases from Erwinia chrysanthemi EC16.

A 14-kilobase BamHI-EcoRI DNA fragment cloned from Erwinia chrysanthemi EC16 contained a gene encoding a metalloprotease inhibitor as well as three tandem prt genes encoding metalloproteases. The prt genes were separated from the inhibitor gene by a ca. 4-kilobase region that was necessary for extracellular secretion of the proteases. When individually subcloned downstream from vector promoters, the three prt genes each led to substantial extracellular secretion of the proteases by Escherichia coli cells, provided that the 4-kilobase required region was supplied in cis or trans. One of the protease structural genes, prtC, was sequenced and had high homology to a metalloprotease gene previously described from Serratia species as well as to the prtB gene of E. chrysanthemi B374. Marker exchange mutants of E. chrysanthemi EC16 defective in production of one or all of the extracellular proteases were not impaired in virulence on plant tissue.     

Cloning and sequencing of pel gene responsible for CMCase activity from Erwinia chrysanthemi PY35

The phytopathogenic bacterium Erwinia chrysanthemi secretes multiple isozymes of plant cell wall disrupting enzymes such as pectate lyase and endoglucanase. We cloned genomic DNA from Erwinia chrysanthemi PY35. One of the E. coli XL1-Blue clones contained a 5.1-kb BamHI fragment and hydrolyzed carboxymethyl cellulose and polygalacturonic acid. By subsequent subcloning, we obtained a 2.9-kb fragment (pPY100) that contained the pel gene responsible for CMCase and pectate lyase activities. The pel gene had an open reading frame (ORF) of 1,278 bp encoding 425 amino acids with a signal peptide of 25 amino acids. Since the deduced amino acid sequence of this protein was very similar to that of PelL of E. chrysanthemi EC16, we concluded that it belonged to the pectate lyase family EC 4.2.2.2, and we designated it PelL1. Sequencing showed that the PeIL1 protein contains 400 amino acids and has a calculated pI of 7.15 and a molecular mass of 42,925 Da. The molecular mass of PelL1 protein expressed in E. coli XL1-Blue, as analyzed by SDS-PAGE, appeared to be 43 kDa. The optimum pH for its enzymatic activity was 9, and the optimum temperature was about 40 decreased C.     

Characterization of pectin methylesterase B, an outer membrane lipoprotein of Erwinia chrysanthemi 3937

The secretion of extracellular pectinases, among which there are least six isoenzymes of pectate lyase and one pectin methylesterase, allows the phytopathogenic bacterium Erwinia chrysanthemi to degrade pectin. A gene coding for a novel pectin methylesterase has been cloned from an E. chrysanthemi strain 3937 gene library. This gene, pemB , codes for a 433-amino-acid protein. The PemB N-terminal region has the characteristics of lipoprotein signal sequences. We have shown that the PemB precursor is processed and that palmitate is incorporated into the mature protein. The PemB lipoprotein is not released into the extracellular medium and is localized in the outer membrane. The PemB sequence presents homology with other pectin methylesterases from bacterial and plant origin. pemB -like proteins were detected in four other E. chrysanthemi strains but not in Erwinia carotovora strains. PemB was overproduced in Escherichia coli and purified to homogeneity. PemB activity is strongly increased by non-ionic detergents. The enzyme is more active on methylated oligogalacturonides than on pectin, and it is necessary for the growth of the bacteria on oligomeric substrates. PemB is more probably involved in the degradation of methylated oligogalacturonides present in the periplasm of the bacteria, rather than in a direct action on extracellular pectin. pemB expression is inducible in the presence of pectin and is controlled by the negative regulator KdgR.     

Molecular cloning in Escherichia coli of Erwinia chrysanthemi genes encoding multiple forms of pectate lyase.

The phytopathogenic enterobacterium Erwinia chrysanthemi excretes multiple isozymes of the plant tissue-disintegrating enzyme, pectate lyase (PL). Genes encoding PL were cloned from E. chrysanthemi CUCPB 1237 into Escherichia coli HB101 by inserting Sau3A-generated DNA fragments into the BamHI site of pBR322 and then screening recombinant transformants for the ability to sink into pectate semisolid agar. Restriction mapping of the cloned DNA in eight pectolytic transformants revealed overlapping portions of a 9.8-kilobase region of the E. chrysanthemi genome. Deletion derivatives of these plasmids were used to localize the pectolytic genotype to a 2.5-kilobase region of the cloned DNA. PL gene expression in E. coli was independent of vector promoters, repressed by glucose, and not induced by galacturonan. PL accumulated largely in the periplasmic space of E. coli. An activity stain used in conjunction with ultrathin-layer isoelectric focusing resolved the PL in E. chrysanthemi culture supernatants and shock fluids of E. coli clones into multiple forms. One isozyme with an apparent pI of 7.8 was produced at a far higher level in E. coli and was common to all of the pectolytic clones. Activity staining of renatured PL in sodium dodecyl sulfate-polyacrylamide gels revealed that this isozyme comigrated with the corresponding isozyme produced by E. chrysanthemi. The PL isozyme profiles produced by different clones and deletion derivative subclones suggest that the cloned region contains at least two PL isozyme structural genes. Pectolytic E. coli clones possessed a limited ability to macerate potato tuber tissues.     

Influence of gyrA mutation on expression of Erwinia chrysanthemi clb genes cloned in Escherichia coli.

Erwinia chrysanthemi clb genes cloned into Nals Escherichia coli allowed growth on cellobiose, arbutin, or salicin. In contrast, Nalr isogenic strains grew only on cellobiose. It is proposed that expression of cloned E. chrysanthemi clb genes is reduced by the E. coli chromosomal gyrA (Nalr) mutation, resulting in apparent segregation of the Clb and Arb Sal characters.     

Genetic regulation of pathogenicity and virulence factors in bacteria Erwinia carotovora subsp. atroseptica: identification of kduD gene

A mutant that cannot utilize pectin substances of plant cell walls was obtained via insertion of mini-mini-Tn5xylE transposon into the chromosome of phytopathogenic bacteria Erwinia carotovora subsp. atroseptica. The inability of mutant cells to utilize these substrates was caused by a failure to accomplish the catabolism of unsaturated digalacturonic acid (UDA). Study of enzymatic activities has established that mutant bacteria lost the ability to produce 2,5-diketo-3-deoxygluconate dehydrogenase, an enzyme of intracellular UDA utilization. Molecular cloning of the mutant gene was conducted, and its nucleotide sequence was determined. It was shown that the nucleotide sequence of this gene had an 82% homology with the sequence of Erwinia chrysanthemi EC3937 kduD gene encoding 2,5-diketo-3-deoxygluconate dehydrogenase. The intergene kdul-kduD region in bacteria Erwinia carotovora subsp. atroseptica is shorter in length by 98 nucleotides than the corresponding region of Erwinia chrysanthemi and does not contain promoter sequences. The kduD gene was located at 126.8 min of the Erwinia carotovora subsp. atroseptica genetic map.