Structure of the oligogalacturonate-specific KdgM porin.

The phytopathogenic Gram-negative bacterium Dickeya dadantii (Erwinia chrysanthemi) feeds on plant cell walls by secreting pectinases and utilizing the oligogalacturanate products. An outer membrane porin, KdgM, is indispensable for the uptake of these acidic oligosaccharides. Here, the crystal structure of KdgM determined to 1.9 Šresolution is presented. KdgM is folded into a regular 12-stranded antiparallel ß-barrel with a circular cross-section defining a transmembrane pore with a minimal radius of 3.1 Å. Most of the loops that would face the cell exterior in vivo are disordered, but nevertheless mediate contact between densely packed membrane-like layers in the crystal. The channel is lined by two tracks of arginine residues facing each other across the pore, a feature that is conserved within the KdgM family and is likely to facilitate the diffusion of acidic oligosaccharides.

Catabolism of Hexuronides, Hexuronates, Aldonates, and Aldarates.

Following elucidation of the regulation of the lactose operon in Escherichia coli, studies on the metabolism of many sugars were initiated in the early 1960s. The catabolic pathways of D-gluconate and of the two hexuronates, D-glucuronate and D-galacturonate, were investigated. The post genomic era has renewed interest in the study of these sugar acids and allowed the complete characterization of the D-gluconate pathway and the discovery of the catabolic pathways for L-idonate, D-glucarate, galactarate, and ketogluconates. Among the various sugar acids that are utilized as sole carbon and energy sources to support growth of E. coli, galacturonate, glucuronate, and gluconate were shown to play an important role in the colonization of the mammalian large intestine. In the case of sugar acid degradation, the regulators often mediate negative control and are inactivated by interaction with a specific inducer, which is either the substrate or an intermediate of the catabolism. These regulators coordinate the synthesis of all the proteins involved in the same pathway and, in some cases, exert crosspathway control between related catabolic pathways. This is particularly well illustrated in the case of hexuronide and hexuronate catabolism. The structural genes encoding the different steps of hexuronate catabolism were identified by analysis of numerous mutants affected for growth with galacturonate or glucuronate. E. coli is able to use the diacid sugars D-glucarate and galactarate (an achiral compound) as sole carbon source for growth. Pyruvate and 2-phosphoglycerate are the final products of the D-glucarate/galactarate catabolism.

The PDZ domain of OutC and the N-terminal region of OutD determine the secretion specificity of the type II out pathway of Erwinia chrysanthemi.

The plant pathogens Erwinia chrysanthemi and Erwinia carotovora secrete multiple exoproteins by a type II pathway, the Out system. Secretion in Erwinia is species-specific: exoproteins of one species cannot be secreted by the other. We analysed the role of two components of the Out system, the bitopic inner membrane protein OutC and the secretin OutD, in the specific recognition of secreted proteins. We demonstrated that the PDZ domain of OutC determines its secretion specificity towards certain exoproteins. The secretin is the major determinant of specificity of the Out system: OutD of E. carotovora changes the secretion specificity of E. chrysanthemi and enables it to secrete heterologous exoproteins. Construction of chimeric OutD showed that the N-terminal region is the specificity domain of the secretin. Thus, both the PDZ domain of OutC and the N-terminal region of OutD are required for specific recognition of secreted proteins. Systematic analysis of the secretion of several exoproteins demonstrated that different exoproteins secreted by the Out machinery have different requirement for their presumed targeting signals on OutC and OutD. This strongly indicates that diverse exoproteins possess a variable number of targeting signals which are recognised by different regions of OutC and OutD.

Characterization of SotA and SotB, two Erwinia chrysanthemi proteins which modify isopropyl-beta-D-thiogalactopyranoside and lactose induction of the Escherichia coli lac promoter.

The expression, in Escherichia coli, of variants of the Erwinia chrysanthemi secretion genes outB and outS under the Ptac promoter is toxic to the cells. During attempts to clone E. chrysanthemi genes able to suppress this toxicity, I identified two genes, sotA and sotB, whose products are able to reduce the isopropyl-beta-D-thiogalactopyranoside (IPTG) induction of the E. coli lac promoter. SotA and SotB belong to two different families of the major facilitator superfamily. SotA is a member of the sugar efflux transporter family, while SotB belongs to the multidrug efflux family. The results presented here suggest that SotA and SotB are sugar efflux pumps. SotA reduces the intracellular concentration of IPTG, lactose, and arabinose. SotB reduces the concentration of IPTG, lactose, and melibiose. Expression of sotA and sotB is not regulated by their substrates, but sotA is activated by the cyclic AMP receptor protein (CRP), while sotB is repressed by CRP. Lactose is weakly toxic for E. chrysanthemi. This toxicity is increased in a sotB mutant which cannot efficiently efflux lactose. This first evidence for a physiological role of sugar efflux proteins suggests that their function could be to reduce the intracellular concentration of toxic sugars or sugar metabolites.

The exopolygalacturonate lyase PelW and the oligogalacturonate lyase Ogl, two cytoplasmic enzymes of pectin catabolism in Erwinia chrysanthemi 3937.

Erwinia chrysanthemi 3937 secretes into the external medium several pectinolytic enzymes, among which are eight isoenzymes of the endo-cleaving pectate lyases: PelA, PelB, PelC, PelD, and PelE (family 1); PelI (family 4); PelL (family 3); and PelZ (family 5). In addition, one exo-cleaving pectate lyase, PelX (family 3), has been found in the periplasm of E. chrysanthemi. The E. chrysanthemi 3937 gene kdgC has been shown to exhibit a high degree of similarity to the genes pelY of Yersinia pseudotuberculosis and pelB of Erwinia carotovora, which encode family 2 pectate lyases. However, no pectinolytic activity has been assigned to the KdgC protein. After verification of the corresponding nucleotide sequence, we cloned a longer DNA fragment and showed that this gene encodes a 553-amino-acid protein exhibiting an exo-cleaving pectate lyase activity. Thus, the kdgC gene was renamed pelW. PelW catalyzes the formation of unsaturated digalacturonates from polygalacturonate or short oligogalacturonates. PelW is located in the bacterial cytoplasm. In this compartment, PelW action could complete the degradation of pectic oligomers that was initiated by the extracellular or periplasmic pectinases and precede the action of the cytoplasmic oligogalacturonate lyase, Ogl. Both cytoplasmic pectinases, PelW and Ogl, seem to act in sequence during oligogalacturonate depolymerization, since oligomers longer than dimers are very poor substrates for Ogl but are good substrates for PelW. The estimated number of binding subsites for PelW is three, extending from subsite -2 to +1, while it is probably two for Ogl, extending from subsite -1 to +1. The activities of the two cytoplasmic lyases, PelW and Ogl, are dependent on the presence of divalent cations, since both enzymes are inhibited by EDTA. In contrast to the extracellular pectate lyases, Ca2+ is unable to restore the activity of PelW or Ogl, while several other cations, including Co2+, Mn2+, and Ni2+, can activate both cytoplasmic lyases.

The PecT repressor coregulates synthesis of exopolysaccharides and virulence factors in Erwinia chrysanthemi.

Erwinia chrysanthemi 3937 synthesizes an exopolysaccharide (EPS) composed of rhamnose, galactose, and galacturonic acid. Fourteen transcriptional fusions in genes required for EPS synthesis, named eps, were obtained by Tn5-B21 mutagenesis. Eleven of them are clustered on the chromosome and are repressed by PecT, a regulator of pectate lyase synthesis. In addition, expression of these fusions is repressed by the catabolite regulatory protein, CRP, and induced in low osmolarity medium. The three other mutations are located in genes that are not regulated by pecT. A 13-kb DNA fragment containing pecT-regulated eps genes has been cloned. All the genes identified on this fragment are transcribed in the same orientation and could form a large operon. The promoter region of this operon has been sequenced. It contains a JUMP-start sequence, a sequence required for the expression of polysaccharide-associated operons. E. chrysanthemi 3937 produces a systemic soft rot on its host Saintpaulia ionantha. An eps mutant was less efficient than the wild-type strain in initiating a maceration symptom, suggesting that production of EPS is required for the full expression of the E. chrysanthemi virulence.

The PecT repressor interacts with regulatory regions of pectate lyase genes in Erwinia chrysanthemi.

Erwinia chrysanthemi is a broad host range phytopathogenic enterobacterium responsible for soft-rot disease of many plant species. The pecT gene encodes a repressor that negatively regulates the expression of virulence factors, such as pectinases, motility or exopolysaccharide synthesis. The cloned pecT gene was overexpressed using a phage T7 system. The purification of PecT involved the use of a TSK-heparin column and delivered the PecT protein that was purified to near homogeneity. The purified repressor displayed a 34 kDa apparent molecular mass. Gel-filtration experiments revealed that the PecT protein is a dimer. Band-shift assays demonstrated that the tetramer of the PecT protein could specifically bind in vitro to the regulatory regions of the pectate lyase genes with variable affinities. In addition, we demonstrated that PecT represses its own synthesis by interacting independently with two 200 bp regions, R1 and R2, located from -382 to -632 and -17 to -234, respectively, from the distal P1 promoter and from -465 to -715 and -100 to -317 from the P2 proximal promoter. We propose a model that explains the regulation exerted by PecT on its target genes and that integrates the phenotype obtained with a PecT overproducing pec-1 mutant or a pecT mutant.

Specific interaction between OutD, an Erwinia chrysanthemi outer membrane protein of the general secretory pathway, and secreted proteins.

OutD is an outer membrane component of the main terminal branch of the general secretory pathway (GSP) in Erwinia chrysanthemi. We analyzed the interactions of OutD with other components of the GSP (Out proteins) and with secreted proteins (PelB, EGZ and PemA). OutD is stabilized by its interaction with another GSP component, OutS. The 62 C-terminal amino acids of OutD are necessary for this interaction. In vivo formation of OutD multimers, up to tetramers, was proved after the dissociation in mild conditions of the OutD aggregates formed in the outer membrane. Thus, OutD could form a channel-like structure in the outer membrane. We showed that OutD is stabilized in vivo when co-expressed with Out-secreted proteins. This stabilization results from the formation of complexes that were detected in experiments of co-immunoprecipitation and co-sedimentation in sucrose density gradients. The presence of the N-terminal part of OutD is required for this interaction. The interaction between OutD and the secreted protein PelB was confirmed in vitro, suggesting that no other component of the GSP is required for this recognition. No interaction was observed between the E. carotovora PelC and the E. chrysanthemi OutD. Thus, the interaction between GspD and the secreted proteins present in the periplasm could be the key to the specificity of the secretion machinery and a trigger for that process.

The Erwinia chrysanthemi pecT gene regulates pectinase gene expression.

A new type of Erwinia chrysanthemi mutant displaying a derepressed synthesis of pectate lyase was isolated. The gene mutated in these strains, pecT, encodes a 316-amino-acid protein with a size of 34,761 Da that belongs to the LysR family of transcriptional activators and presents 61% identity with the E. coli protein LrhA. PecT represses the expression of pectate lyase genes pelC, pelD, pelE, pelL, and kdgC, activates pelB, and has no effect on the expression of pelA or the pectin methylesterase genes pemA and pemB. PecT activiates its own expression. The mechanism by which PecT regulates pectate lyase synthesis is independent of that of the two characterized regulators of pectate lyase genes, KdgR and PecS. In contrast to most of the members of the LysR family, pecT is not transcribed in a direction opposite that of a gene that it regulates. pecT mutants are mucoid when grown on minimal medium plates and flocculate when grown in liquid minimal medium, unless leucine or alanine is added to the medium. Thus, pecT may regulate other functions in the bacterium.

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.

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.

Purification and characterization of the nuclease NucM of Erwinia chrysanthemi.

The major periplasmic nuclease of Erwinia chrysanthemi strain 3937, NucM, has been purified near to homogeneity by a one step purification procedure, using chromatography on a sulfopropyl column. NucM cleaves randomly single and double-stranded DNA and RNA. It does not need divalent cations for its action, and is more active in low salt buffers. A serine and a histidine residue could be present in the catalytic site. Formation of disulfide bonds is necessary for NucM activity. NucM is probably synthesized as a reduced inactive polypeptide and becomes active in the periplasm once disulfide bonds are formed.

Differential effect of dsbA and dsbC mutations on extracellular enzyme secretion in Erwinia chrysanthemi.

An Erwinia chrysanthemi gene able to complement an Escherichia coli dsbA mutation has been cloned and sequenced. This gene codes for a periplasmic protein with disulphide isomerase activity that has 69% identity and 94% similarity with the E. coli DsbA protein. An E. chrysanthemi dsbA-uidA fusion mutant has been constructed. dsbA expression seems to be constitutive. This mutant has multiple phenotypes resulting from the absence of disulphide bond formation in periplasmic and secreted proteins. Pectate lyases and the cellulase EGZ are rapidly degraded in the periplasm of the dsbA mutant. E. chrysanthemi synthesizes another periplasmic protein with disulphide isomerase activity, namely DsbC. The dsbC gene introduced on a multicopy plasmid in a dsbA mutant was only partially able to restore EGZ secretion, indicating that even if DsbA and DsbC possess disulphide oxydoreductase activity, they are not completely interchangeable. Moreover, pectate lyases expressed in an E. coli dsbA mutant were very instable but their stability was unaffected in a dsbC mutant. These results indicate that DsbA and DsbC could have different substrate specificities.

Characterization of DsbC, a periplasmic protein of Erwinia chrysanthemi and Escherichia coli with disulfide isomerase activity.

We identified and characterized an Erwinia chrysanthemi gene able to complement an Escherichia coli dsbA mutation that prevents disulfide bond formation in periplasmic proteins. This gene, dsbC, codes for a 24 kDa periplasmic protein that contains a characteristic active site sequence of disulfide isomerases, Phe-X-X-X-X-Cys-X-X-Cys. Besides the active site, DsbC has no homology with DsbA, thioredoxin or eukaryotic protein disulfide isomerase and it could define a new subfamily of disulfide isomerases. Purified DsbC protein is able to catalyse insulin oxidation in a dithiothreitol dependent manner. The E.coli gene xprA codes for a protein functionally equivalent to DsbC. The in vivo function of DsbC seems to be the formation of disulfide bonds in proteins. The presence of XprA could explain the residual disulfide isomerase activity existing in dsbA mutants. Re-oxidation of XprA does not seem to occur through DsbB, the protein that probably re-oxidizes DsbA.

Specific interactions of Erwinia chrysanthemi KdgR repressor with different operators of genes involved in pectinolysis.

The Erwinia chrysanthemi kdgR gene encodes a repressor that negatively regulates the expression of genes involved in pectinolysis and in pectinase secretion. The cloned kdgR gene was overexpressed in Escherichia coli by using a phage T7 system. Overproduced repressor was purified to homogeneity by two chromatographic steps. Gel retardation and DNase I protection experiments demonstrated the specific binding of the KdgR protein to the operators of pectinase genes (pelA, pelB, pelC, pelE), to the operator of genes involved in pectin catabolism (kdgT, ogl, kduI-kdgF) and to that of the outT gene involved in pectinase secretion. These interactions involved one (pelA, pelB, kduI-kdgF, outT) or several operator sites (pelC, pelE, ogl, kdgT) that generally overlap the promoter. Despite the presence of potential KdgR binding sites (KdgR-box) in the regulatory regions of four genes involved in pectin catabolism (kdgC, kduD, pem, kdgA) and in a pectinase secretion gene outC, no DNA-repressor complex could be observed by in vitro experiments. By using a missing contact experiment on the coding strand of ogl and pelE regulatory regions, a new KdgR-binding consensus was proposed. This new consensus, constituted by two half motifs (AATGAAAACT)N(NTCGATTTCTA), is well conserved in the operators which interact in vitro with the KdgR repressor. In contrast, this repressor-recognized motif is degenerated in the other operators that cannot interact in vitro with the repressor. These results suggest the existence of different regulation mechanisms mediated by the KdgR protein for the two classes of operators.

Characterization of the nucM gene coding for a nuclease of the phytopathogenic bacteria Erwinia chrysanthemi.

The gene nucM encoding a nuclease was cloned from a genomic library of Erwinia chrysanthemi. The nucM gene was subcloned, and mutagenized by insertion of a uidA-KanR cartridge. This mutation was introduced by recombination into the Erwinia chrysanthemi chromosome. The nucM mutant lost NucM activity when tested on a DNA plate after 24 hours, but still possessed secondary weak nuclease activity. The nucleotide sequence of nucM was determined. It presents a 798 bp open reading frame, coding for a 266-amino-acid protein, with a predicted molecular mass of 29,910 Da. The deduced NucM protein shows 59% sequence identity with the DNase I precursor from Vibrio cholerae. It contains a typical leader sequence. Experiments of cell fractionation showed that NucM is periplasmic in E. chrysanthemi. The transcription start has been determined by S1 mapping. The -10 and -35 regions do not show homology with consensus sequence of the promoters recognized by sigma 70. In fact, the promoter seems to be dependent on the sigma 70, but the first transcription nucleotide is unusually far from the -10 region. nucM seems to be expressed constitutively.

Some of the out genes involved in the secretion of pectate lyases in Erwinia chrysanthemi are regulated by kdgR.

The out genes of Erwinia chrysanthemi are required for the translocation across the outer membrane of pectate lyases and cellulases. We present the characterization and the nucleotide sequence of five genes of the out cluster. The products of outS, B, C, D and E have significant homology with the PulS, B, C, D and E proteins necessary to the secretion of pullulanase in Klebsiella pneumoniae. An open reading frame, outT, located between outB and outC has no homology with the pul cluster but is involved in secretion. outC, outD and outE form an operon while outS, outB and outT constitute independent transcription units. outT and the outCDE operon are regulated by kdgR, the negative regulatory gene controlling pectinase production. outB and outS seem to be expressed constitutively.

Analysis of an Erwinia chrysanthemi gene cluster involved in pectin degradation.

A group of four genes of Erwinia chrysanthemi involved in pectin degradation has been characterized. These four genes form independent transcription units and are regulated by the negative regulatory gene, kdgR. The functions of two of these genes are known: kduD codes for the 2-keto-3-deoxygluconate oxydoreductase and kdul for the 5-keto-4-deoxyuronate isomerase, two enzymes of the pectin degradation pathway. kdgC has 36% homology with pectate lyase genes of the periplasmic family but its product does not seem to have pectinolytic activity. The fourth gene, kdgF, could have a role in the pathogenicity of E. chrysanthemi. A comparison of the regulatory regions of all the genes controlled by kdgR allowed better definition of the KdgR-binding-site consensus.

Inducing properties of analogs of 2-keto-3-deoxygluconate on the expression of pectinase genes of Erwinia chrysanthemi.

In Erwinia chrysanthemi, all the genes involved in pectin degradation are controlled by the negative regulatory gene kdgR. 2-keto-3-deoxy-gluconate (KDG) is the inducing molecule that interacts with KdgR to allow the expression of all the genes of the kdg regulon. The inducing properties on the expression of genes regulated by kdgR of various analogs and derivatives of KDG were tested. All the inducers share the common moiety COOH-CO-CH2-CHOH-C-C included in a pyranic cycle. Our results show that esterification of C1 prevents induction. Presence of a ketone function on C2 and absence of hydroxyl on C3 are necessary for induction. The nature and the configuration of substituent on C5 has no influence on induction. Two compounds have interesting properties: 5-O-methyl-KDG is a gratuitous inducer, and gluconic acid can prevent induction.