Erwinia chrysanthemi EC16 Produces a Second Set of Plant-Inducible Pectate Lyase Isozymes

The enterobacterium Erwinia chrysanthemi causes soft-rot diseases involving extensive tissue maceration in a wide variety of plants and secretes multiple pectic enzymes that degrade plant cell walls and middle lamellae. An E. chrysanthemi mutant with directed deletions or insertions in genes pehX, pelX, pelA, pelB, pelC, and pelE, which encode exo-poly-alpha-d-galacturonosidase, exopolygalacturonate lyase, and four isozymes of pectate lyase, respectively, was constructed by the marker exchange of a cloned pehX::TnphoA fragment into E. chrysanthemi CUCPB5010, a Delta(pelA pelE) Delta(pelB pelC)::28bp Delta(pelX)Delta4bp derivative of strain EC16. This mutant, E. chrysanthemi CUCPB5012, no longer caused pitting in a standard pectate semisolid agar medium used to detect pectolytic activity in bacteria. Nevertheless, the mutant still macerated leaves of chrysanthemum (Chrysanthemum morifolium), although with reduced virulence. The mutant was found to produce significant pectate lyase activity in rotting chrysanthemum tissue and in minimal media containing chrysanthemum extracts or cell walls as the sole carbon source. Activity-stained, ultra-thin-layer isoelectric focusing gels revealed the presence in these preparations of several pectate lyase isozymes with pIs ranging from highly acidic to highly alkaline. Sterile culture fluids containing these isozymes were able to macerate chrysanthemum leaf tissue. Unlike the products of the pelA, pelB, pelC, and pelE genes in E. chrysanthemi EC16, these plant-inducible pectate lyase isozymes were not produced in minimal medium containing pectate. The results suggest that E. chrysanthemi produces two sets of independently regulated pectate lyase isozymes that are capable of macerating plant tissues.     

Use of Tn5tac1 to clone a pel gene encoding a highly alkaline, asparagine-rich pectate lyase isozyme from an Erwinia chrysanthemi EC16 mutant with deletions affecting the major pectate lyase isozymes.

Erwinia chrysanthemi mutant CUCPB5047, delta(pelA pelE) delta(pelB pelC)::28bp delta(pelX) delta 4bp pehX::omega Cmr, was constructed, mutated with Tn5tac1, and screened for isopropyl-beta-D-thiogalactopyranoside-dependent pectate lyase (Pel) production. A Kmr SacI fragment from the hyperexpressing Pel+ mutant CUCPB5066 was cloned into Escherichia coli and sequenced. The gene identified, pelL, encodes a novel, asparagine-rich, highly alkaline enzyme that is similar in primary structure to PelX and in enzymological properties to PelE.     

Expression in Myxococcus xanthus of foreign genes coding for secreted pectate lyases of Erwinia chrysanthemi

Structural genes for the five major pectate lyases of Erwinia chrysanthemi, pelA, pelB, pelC, pelD and pelE, have been transferred and expressed in Myxococcus xanthus. These proteins, which are secreted by their original host, are also produced, mainly into the medium, by Myxococcus. These results are discussed in the context of current knowledge about secretion in bacteria.     

Isolation of Erwinia chrysanthemi mutants altered in pectinolytic enzyme production

Various mutations in the pectin catabolic pathway of Erwinia chrysanthemi were isolated by selection of Mu-lac insertions, resulting in expression of the lac genes inducible by pectin degradation products. This approach allowed us to isolate lacZ fusions with the genes pelC, pelD, ogl and pem, encoding pectate lyases PLc and PLd, oligogalacturonate lyase and pectin methytesterase, respectively. Moreover, we obtained mutations affecting the regulation of pectinolytic enzymes; a locus called peel appeared to be involved in induction of pectate tyases and pectin methylesterase. A second locus, called pect, may encode an activator protein acting on pectate lyase production. Both peel and pecL expression are induced in the presence of pectic polymers. The expression of the pem gene was studied in more detail by analysis of the pem-lacZ fusions. The expression of pem appears to be controlled by the negative regulatory gene kdgR, which controls alt the genes involved in pectin degradation (pem, pel, ogl, kduD, kduf, kdgK, kdgA). This study confirmed that 2-keto-3-deoxy-gluconate is a key intermediate for the induction of the pectin catabolic pathway. The three genes pem, pelD and pecl were localized in the same region, near the ade-377 marker on the genetic map of the E. chrysanthemi strain 3937. The pem gene was located more precisely on an 18kb DNA fragment containing the pelADE cluster. However, this 18 kb DNA fragment did not complement the pecl mutation. The pecL mutations were located near the ile-2 marker on the genetic map of E. chrysanthemi strain 3937.     

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.     

Evidence of homology between the pectate lyase-encoding pelB and pelC genes in Erwinia chrysanthemi.

The genes for two of several pectate lyase isozymes produced by the phytopathogenic enterobacterium Erwinia chrysanthemi 1237 were subcloned and compared by DNA-DNA hybridization, and the encoded proteins were analyzed. The borders of the genes were located on a restriction map by incremental exonuclease III deletions. DNA-DNA hybridization studies revealed a low percentage of mismatch (7 to 17%) between pelB and pelC. No homology was detected between pelC and other regions of the E. chrysanthemi 1237 chromosome, in which three other isozyme genes apparently reside. The pectate lyase isozymes were readily purified by chromatofocusing or granulated-gel bed isoelectric focusing from the periplasmic shock fluids of Escherichia coli subclones. The molecular weights of PLb and PLc were 30,000 and 33,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Their isoelectric points were 7.6 and 8.1, respectively, as determined by equilibrium isoelectric focusing in ultrathin polyacrylamide gels. The Km values for PLb and PLc were 0.20 and 0.32 mg/ml, respectively, with polygalacturonate as a substrate. Thin-layer chromatography of reaction products and viscometric assays revealed little difference between the two isozymes. All our data indicate that the genes are duplicates and that the proteins are isofunctional.     

Analysis of Erwinia chrysanthemi EC16 pelE::uidA, pelL::uidA, and hrpN::uidA mutants reveals strain-specific atypical regulation of the Hrp type III secretion system

The plant pathogen Erwinia chrysanthemi produces a variety of factors that have been implicated in its ability to cause soft-rot diseases in various hosts. These include HrpN, a harpin secreted by the Hrp type III secretion system; PelE, one of several major pectate lyase isozymes secreted by the type II system; and PelL, one of several secondary Pels secreted by the type II system. We investigated these factors in E. chrysanthemi EC16 with respect to the effects of medium composition and growth phase on gene expression (as determined with uidA fusions and Northern analyses) and effects on virulence. pelE was induced by polygalacturonic acid, but pelL was not, and hrpN was expressed unexpectedly in nutrient-rich King's medium B and in minimal salts medium at neutral pH. In contrast, the effect of medium composition on hrp expression in E. chrysanthemi CUCPB1237 and 3937 was like that of many other phytopathogenic bacteria in being repressed in complex media and induced in acidic pH minimal medium. Northern blot analysis of hrpN and hrpL expression by the wild-type and hrpL::omegaCmr and hrpS::omegaCmr mutants revealed that hrpN expression was dependent on the HrpL alternative sigma factor, whose expression, in turn, was dependent on the HrpS putative sigma54 enhancer binding protein. The expression of pelE and hrpN increased strongly in late logarithmic growth phase. To test the possible role of quorum sensing in this expression pattern, the expI/expR locus was cloned in Escherichia coli on the basis of its ability to direct production of acyl-homoserine lactone and then used to construct expI mutations in pelE::uidA, pelL::uidA, and hrpN::uidA Erwinia chrysanthemi strains. Mutation of expI had no apparent effect on the growth-phase-dependent expression of hrpN and pelE, or on the virulence of E. chrysanthemi in witloof chicory leaves. Overexpression of hrpN in E. chrysanthemi resulted in approximately 50% reduction of lesion size on chicory leaves without an effect on infection initiation.