Isolation and characterization of Erwinia chrysanthemi mutants defective in degradation of hexuronates

Fermentation of d-Xylose and l-Arabinose to Ethanol by Erwinia chrysanthemi

Erwinia spp. are gram-negative facultative anaerobes within the family Enterobacteriacae which possess several desirable traits for the conversion of pentose sugars to ethanol, such as the ability to ferment a broad range of carbohydrates and the ease with which they can be genetically modified. Twenty-eight strains of Erwinia carotovora and E. chrysanthemi were screened for the ability to ferment d-xylose to ethanol. E. chrysanthemi B374 was chosen for further study on the basis of its superior (4%) ethanol tolerance. We have characterized the fermentation of d-xylose and l-arabinose by the wild type and mutants which bear plasmids containing the pyruvate decarboxylase gene from Zymomonas mobilis. Expression of the gene markedly increased the yields of ethanol (from 0.7 up to 1.45 mol/mol of xylose) and decreased the yields of formate, acetate, and lactate. However, the cells with pyruvate decarboxylase grew only one-fourth as fast as the wild type and tolerated only 2% ethanol. Alcohol tolerance was stimulated by the addition of yeast extract to the growth medium. Xylose catabolism was characterized by a high saturation constant K(s) (4.5 mM).

The exuT gene of Erwinia chrysanthemi EC16: nucleotide sequence, expression, localization, and relevance of the gene product

Galacturonic acid (GalUA) is a major component of pectin and polygalacturonic acid in the plant cell wall. In the phytopathogen Erwinia chrysanthemi, the uptake of molecules derived from degradation of these polymers is an important early step in the events preceding induction of pectinases, ultimately leading to plant tissue maceration. Uptake systems for GalUA and dimers of GalUA have been described and shown to be inducible in E. chrysanthemi. The GalUA uptake gene (exuT) was cloned and sequenced. Nucleotide sequence analysis identified an open reading frame encoding a 345-amino-acid polypeptide with a calculated mass of 37,825 Da. This polypeptide is predicted to be an integral membrane protein based on its high nonpolar amino acid content and hydropathic profile. Localization studies with the labeled polypeptide in the T7-RNA polymerase system also suggest that ExuT is a membrane protein. This evidence is further supported by the observation of hybrid ExuT-PhoA proteins in the bacterial cytoplasmic membrane following immunoblot analysis. Northern (RNA) analysis indicated that the gene is inducible in the presence of the monomer, GalUA. A targeted mutation in the exuT gene affected the utilization of GalUA as a role carbon source for growth. Maceration of potato tuber tissue by this mutant was delayed and reduced, when compared with the parental strain EC16.

Fermentation of biomass-derived glucuronic acid by pet expressing recombinants of E. coli B

The economics of large-scale production of fuel ethanol from biomass and wastes requires the efficient utilization of all the sugars derived from the hydrolysis of the heteropolymeric hemicellulose component of lignocellulosic feedstocks. Glucuronic and 4-O-methyl-glucuronic acids are major side chains in xylans of the grasses and hardwoods that have been targeted as potential feedstocks for the production of cellulosic ethanol. The amount of these acids is similar to that of arabinose, which is now being viewed as another potential substrate in the production of biomass-derived ethanol. This study compared the end-product distribution associated with the fermentation of D-glucose (Glc) and D-glucuronic acid (GlcUA) (as sole carbon and energy sources) by Escherichia coli B (ATCC 11303) and two different ethanologenic recombinants--a strain in which pet expression was via a multicopy plasmid (pLOI297) and a chromosomally integrated construct, strain KO11. pH-stat batch fermentations were conducted using a modified LB medium with 2% (w/v) Glc or GlcUA with the set-point for pH control at either 6.3 or 7.0. The nontransformed host culture produced only lactic acid from glucose, but fermentation of GlcUA yielded a mixture of ethanol, acetic, and lactic acids, with acetic acid being the predominant end-product. The ethanol yield associated with GlcUA fermentation by both recombinants was similar, but acetic acid was a significant by-product. Increasing the pH from 6.3 to 7.0 increased the rate of glucuronate fermentation, but it also decreased the ethanol mass yield from 0.22 to 0.19 g/g primarily because of an increase in acetic acid production. In all fermentations there was good closure of the carbon mass balance, the exception being the recombinant bearing plasmid pLOI297 that produced an unidentified product from GlcUA. The metabolism of GlcUA by this metabolically engineered construct remains unresolved. The results offered insights into metabolic fluxes and the regulation of pyruvate catabolism in the wild-type and engineered strains. End-product distribution for metabolism of glucuronic acid by the nontransformed, wild-type E. coli B and recombinant strain KO11 suggests that the enzyme pyruvate-formate lyase is not solely responsible for the production of acetylCoA from pyruvate and that derepressed pyruvate dehydrogenase may play a significant role in the metabolism of GlcUA.

Regulation of pectinolysis in Erwinia chrysanthemi

Erwinia chrysanthemi is an enterobacterium that causes various plant diseases. Its pathogenicity results from the secretion of pectinolytic enzymes responsible for the disorganization of the plant cell wall. The E. chrysanthemi strain 3937 produces two pectin methylesterases, at least seven pectate lyases, a polygalacturonase, and a pectin lyase. The extracellular degradation of the pectin leads to the formation of oligogalacturonides that are catabolized through an intracellular pathway. The pectinase genes are expressed from independent cistrons, and their transcription is favored by environmental conditions such as presence of pectin and plant extracts, stationary growth phase, low temperature, oxygen or iron limitation, and so on. Moreover, transcription of the pectin lyase gene responds to DNA-damaging agents. The differential expressions of individual pectinase genes presumably reflect their role during plant infection. The regulation of pel genes requires several regulatory systems, including the KdgR repressor, which mediates the induction of all the pectinolysis genes in the presence of pectin catabolites. KdgR also controls the genes necessary for pectinase secretion and other pectin-inducible genes not yet characterized. PecS, a cytoplasmic protein homologous to other transcriptional regulators, can bind in vitro to the regulatory regions of pectinase and cellulase genes. The PecT protein, a member of the LysR family of transcriptional regulators, represses the expression of some pectinase genes and also affects other metabolic pathways of the bacteria. Other proteins involved in global regulations, such as CRP or HNS, can bind to the regulatory regions of the pectinase genes and affect their transcription.

Expanded linkage map of Erwinia chrysanthemi strain 3937

In this paper we describe the chromosomal location of various loci in Erwinia chrysanthemi strain 3937. Auxotrophic markers were obtained by chemical mutagenesis, antibiotic resistances were isolated spontaneously and mutations in sugar utilization were obtained by means of Mu insertions. These markers were located on the genetic linkage map of strain 3937 by using a conjugative system mediated by RP4::mini-Mu plasmids which permitted transfer of genetic material from any point of origin. The location of these markers was compared to that of previously located mutations. Many genes involved in pectinolysis were also located on the E. chrysanthemi 3937 map. These results permitted us to present a new genetic map containing 61 markers distributed over 34 widely scattered loci on the chromosome. Some pairs of markers giving high cotransfer frequencies were tested for cotransduction mediated by the generalized transducing phage phi-EC2; nine cotransducing pairs were found. It appears that the chromosomal locations of many of these loci are quite different to those of the well-known enterobacterium Escherichia coli but seem similar to those described for other E. chrysanthemi strains.

Regulation of expression of pectate lyase genes pelA, pelD, and pelE in Erwinia chrysanthemi

The regulation of pelA, pelD, and pelE genes encoding three of the five major pectate lyase isoenzymes (PLa, PLd, and PLe) in Erwinia chrysanthemi B374 was analyzed by using genetic fusions to lacZ. These three genes are clustered on a 5-kilobase DNA fragment in the order pelD-pelE-pelA and constitute three independent transcriptional units. We localized the pelDEA cluster near the pro-1 marker on the genetic map of B374 by chromosomal mobilization with RP4::mini-Mu plasmid pULB110. Three classes of regulatory mutations responsible for constitutive pectate lyase synthesis have been described (kdgR, gpiR, and cri). We studied the effects of each mutation on pelE, pelD, and pelA expression independently. The mutations kdgR and gpiR mainly affect the expression of pelE and pelD, although PLa synthesis is slightly increased. The cri mutation results in a low level of constitutive expression of the three pel genes, but it is a pleiotropic mutation since other genes not involved in pectinolysis are also affected. In addition, we demonstrated that exuR, a negative regulatory gene governing the catabolism of hexuronates, does not modify the expression of pel genes. The frequency of gpiR or cri mutations (about 10(-8)) and the resulting constitutivity of pectate lyase synthesis suggest that these genes act as negative regulatory genes in addition to kdgR, which is already known to encode a repressor. Moreover, we found that expression of pel-lac fusions carried on pBR322 derivatives was higher in E. chrysanthemi than in Escherichia coli; this fact suggests the existence of positive regulation of pectate lyase synthesis in E. chrysanthemi.

Hexuronate catabolism in Erwinia chrysanthemi

In the phytopathogenic enterobacterium Erwinia chrysanthemi, the catabolism of hexuronates is linked to the degradation of pectic polymers. We isolated Mu lac insertions in each gene of the hexuronate pathway and used genetic fusions with lacZ (the beta-galactosidase gene of Escherichia coli) to study the regulation of this pathway. Three independent regulatory genes (exuR, uxuR, and kdgR) were found. Galacturonate and glucuronate were converted into 2-keto-3-deoxygluconate (KDG) by separate three-step pathways encoded by the uxaC, uxaB, and uxaA genes and the uxaC, uxuB, and uxuA genes, respectively. The two aldohexuronates entered the cell by a specific transport system, encoded by exuT. Wild-type strain 3937 was unable to use glucuronate as a carbon source since glucuronate was unable to induce the exuT expression. Mutants able to use glucuronate possessed an inactivated exuR gene. The product of the regulatory gene exuR negatively controlled the expression of exuT, uxaC, uxaB, and uxaA, which was inducible in the presence of galacturonate. The two genes specifically involved in glucuronate catabolism, uxuA and uxuB, formed two independent transcriptional units regulated separately, uxuB expression was not inducible, whereas uxuA expression was induced in the presence of glucuronate and controlled by the uxuR product. KDG, the common end product of both pathways, is cleaved by the kdgK and kdgA gene products. KDG enters the cell by a specific transport system, encoded by kdgT. The regulatory gene kdgR controlled the expression of kdgT, kdgK, and kdgA and partially that of the pel genes encoding pectate-lyases. The real inducer of pectate-lyase synthesis, originating from catabolism of galacturonate or glucuronate, appeared to be KDG. The genes of E. chrysanthemi affecting hexuronate catabolism are separated into six independent transcriptional units exuT, uxaCBA, uxuA, uxuB, kdgK, and kdgA, but only three gene clusters were localized on the genetic map: exuT-uxaCBA, uxuA-uxuB-kdgK, and kdgA-exuR.

Molecular cloning of an Erwinia chrysanthemi oligogalacturonate lyase gene involved in pectin degradation

Mutants of Erwinia chrysanthemi 3937 deficient in the pectin catabolic enzyme oligogalacturonate lyase were isolated by chemical and phage Mud(Aplac) insertion mutagenesis. The ogl mutation was biochemically characterized and localized near the trp his markers on the E. chrysanthemi chromosomal map. Analysis of Mud(Aplac) insertions, which generate polar mutations, revealed that oligogalacturonate lyase was the only affected enzyme in the pectin catabolic pathway, indicating that the ogl gene probably forms a separate transcriptional unit. Out of the two Mud(Aplac) insertions obtained, neither was an ogl-lac fusion. We cloned the ogl gene by complementing the mutation using the RP4::miniMu plasmid pULB113. pR'ogl plasmids were analyzed for the presence of other unselected genes of strain 3937. One of them, called pROU2, also carried the kduD and kdgR genes encoding 2-keto-3-deoxygluconate oxidoreductase, an enzyme of the pectin catabolic pathway, and the KdgR repressor, governing the expression of several genes of pectin degradation, respectively. The plasmid pROU2 harbored a chromosomal DNA insert of about 35 kb indicating that ogl, kduD and kdgR are very closely linked. Structural analysis of the ogl gene was carried out in subcloning experiments. This gene was localized on a 3.5-kb PstI fragment.

Isolation of Erwinia chrysanthemi kduD mutants altered in pectin degradation

Mutants of Erwinia chrysanthemi impaired in pectin degradation were isolated by chemical and Mu d(Ap lac) insertion mutagenesis. A mutation in the kduD gene coding for 2-keto-3-deoxygluconate oxidoreductase prevented the growth of the bacteria on polygalacturonate as the sole carbon source. Analysis of the kduD::Mu d(Ap lac) insertions indicated that kduD is either an isolated gene or the last gene of a polycistronic operon. Some of the Mu d(Ap lac) insertions were kduD-lac fusions in which beta-galactosidase synthesis reflected kduD gene expression. In all these fusions, beta-galactosidase activity was shown to be sensitive to catabolite repression by glucose and to be inducible by polygalacturonate, galacturonate, and other intermediates of polygalacturonate catabolism. Galacturonate-mediated induction was prevented by a mutation which blocked its metabolism to 2-keto-3-deoxygluconate. 2-Keto-3-deoxygluconate appeared to be the true inducer of kduD expression resulting from galacturonate degradation. 5-Keto-4-deoxyuronate or 2,5-diketo-3-deoxygluconate were the true inducers, originating from polygalacturonate cleavage. These three intermediates also appeared to induce pectate lyases, oligogalacturonate lyase, and 5-keto-4-deoxyuronate isomerase synthesis.