Characterization of Rhizobium leguminosarum Exopolysaccharide Glycanases That Are Secreted via a Type I Exporter and Have a Novel Heptapeptide Repeat Motif

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J Bacteriol, April 1998, p. 1691-1699, Vol. 180, No. 7
0021-9193/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Characterization of Rhizobium leguminosarum Exopolysaccharide Glycanases That Are Secreted via a Type I Exporter and Have a Novel Heptapeptide Repeat Motif

Christine Finnie, Angeles Zorreguieta, Nigel M. Hartley, and J. Allan Downie^*

John Innes Centre, Norwich NR7 4UH, United Kingdom

Received 30 September 1997/Accepted 22 January 1998

	ABSTRACT

Top Abstract Introduction Materials & Methods Results Discussion References

The prsDE genes encode a type I protein secretion system required for the secretion of the nodulation protein NodO and atleast three other proteins from Rhizobium leguminosarum bv. viciae.At least one of these proteins was predicted to be a glycanaseinvolved in processing of bacterial exopolysaccharide (EPS). Twostrongly homologous genes (plyA and plyB) were identified as encodingsecreted proteins with polysaccharide degradation activity. BothPlyA and PlyB degrade EPS and carboxymethyl cellulose (CMC), andthese extracellular activities are absent in a prsD (protein secretion)mutant. The plyA gene is upstream of prsD but appears to be expressedat a very low level (if at all) in cultured bacteria. A plyB::Tn5mutant has a very large reduction in degradation of EPS and CMC.Cultures of plyB mutants contained an increased ratio of EPS repeatunits to reducing ends, indicating that the EPS was present ina longer-chain form, and this correlated with a significant increasein culture viscosity. Thus, PlyB may play a role in processingof EPS. Analysis of the symbiotic properties of a plyA plyB doublemutant revealed that these genes are not required for symbioticnitrogen fixation and that nodulation was not significantly affected.PlyA and PlyB are similar to bacterial and fungal polysaccharidelyases; they contain 10 copies of what we propose as a novel heptapeptiderepeat motif that may constitute a fold similar to that foundin the family of extracellular pectate lyases. PlyA and PlyB lackthe Ca²⁺-binding RTX nonapeptide repeat motifs usually found in proteinssecreted via type I systems. We propose that PlyA and PlyB aremembers of a new family of proteins secreted via type I secretionsystems and that they are involved in processing of EPS.

	INTRODUCTION

Top Abstract Introduction Materials & Methods Results Discussion References

The Rhizobium-legume symbiosis involves an exchange of signalling molecules between plant and bacterium. The main signalsproduced by the bacterium are lipochitooligosaccharides (Nod factors),which are synthesized by the products of the nod genes and areessential for nodulation. The structure and variety of differentNod factors determine the types of legumes that can be nodulated.Some rhizobial strains also secrete proteins that may be involvedin signalling during nodulation (13, 14, 23, 44), providingan extension of the Nod factor-based signalling pathway.

The prsDE genes encode two components of a type I protein secretion system that is required for the secretion of the nodulationsignalling protein NodO and at least three other proteins fromRhizobium leguminosarum bv. viciae (16). One of the other proteinssecreted via the Prs system is thought to be a glycanase thatcleaves the bacterial expolysaccharide (EPS), since a prsD mutantlacks the ability to degrade EPS in a plate assay and producesEPS with an increased degree of polymerization (16). EPS isrequired at an early stage in nodule invasion, and a low-molecular-weightform has been implicated in the infection of roots by Rhizobiummeliloti (2, 43). However, the mutant of R. leguminosarumbv. viciae defective in protein secretion and cleavage of EPSformed fully infected nodules containing bacteroids (16).

Protein secretion via a type I pathway involves a C-terminal, noncleaved secretion signal (46), and, indeed, the C-terminal24 amino acids of NodO is essential for its secretion (39).No clear consensus sequence exists for these C-terminal secretionsignals; their specificity seems to reside in conserved propertiesof secondary structure (48, 53). Most proteins that are secretedvia type I secretion systems (including NodO) contain a characteristicnonapeptide tandem called RTX (repeat in toxin), so called becausethese repeats are present in many secreted protein toxins. Membersof this family of toxins include Escherichia coli alpha-hemolysin,Erwinia chrysanthemi proteases, Pseudomonas aeruginosa alkalineprotease, and Serratia marcescens protease and lipase. The structuresof some proteins carrying this motif have been determined (3,4). The RTX repeats form a $beta$ -roll structure stabilized by Ca²⁺ ions coordinated between adjacent coils of the $beta$ -roll. In somecases, the RTX repeats are required for efficient secretion, especiallyof large, heterologous proteins (12, 25, 39, 46).

The genes encoding type I secretion systems are usually adjacent to the genes encoding the secreted proteins (11, 15,26, 27, 47), whereas nodO is unlinked to the genes requiredfor NodO secretion (37). Genes encoding other proteins secretedby the PrsDE system are unlinked to nodO, since they are not presenton the symbiotic plasmid pRL1JI (16). Therefore the R. leguminosarumbv. viciae Prs system is apparently different from most othercharacterized type I systems, which usually secrete only a singleprotein or several very similar proteins that are encoded by genesadjacent to one another.

	MATERIALS AND METHODS

Top Abstract Introduction Materials & Methods Results Discussion References

Microbiological methods. Rhizobia were grown at 28°C in TY medium (6) with appropriate antibiotics at the following concentrations (micrograms permilliliter): streptomycin, 400; kanamycin, 20; gentamicin, 200;spectinomycin, 20; tetracycline, 10; lividomycin, 5. Where requiredfor the induction of nod genes, hesperetin was added to a finalconcentration of 1 µM. Culture optical densities were measuredat 600 nm with an MSE Spectro-Plus spectrophotometer. The bacterialstrains and plasmids used are described in Table 1 or the text.

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TABLE 1. Strains and plasmids used in this study

For polysaccharide analysis, bacteria were grown in Y medium (38) containing mannitol (0.2%, wt/vol) as the carbon source.E. coli strains were grown in L broth (31), at 37°C. Plasmidswere transferred to E. coli by transformation and to Rhizobiumby triparental mating with a helper plasmid. Strains A616 andA617 were made by transduction (8) of 8401 and 8401(pRL1JI)with phage RL38 propagated on the glycanase mutant A600.

Mutagenesis of pIJ7298 was done as follows. An E. coli strain carrying pIJ7298 and Tn5 on the chromosome was grown overnightin an inhibitory concentration of kanamycin (1 mg/ml) to enrichfor cells in which Tn5 had transposed onto pIJ7298. The cellswere subcultured in fresh medium containing no kanamycin, andplasmid DNA was isolated. Transformants of E. coli carrying Tn5in pIJ7298 were selected on tetracycline and kanamycin. Recombinationof the Tn5 mutations into R. leguminosarum bv. viciae was doneby marker exchange (35).

Nodulation tests were conducted on peas (Pisum sativum var. Wisconsin Perfection) with a minimum of 12 plants per test oron vetch (Vicia hirsuta), as described by Knight et al. (22),with at least 20 plants per test.

Construction of plyA plyB double mutants. To construct strains carrying mutations in both plyA and plyB, a plyA3::Spc^r allele was constructed. The 16-kb EcoRI fragment carrying plyA2::Tn5was cloned from pIJ7419 into pBluescript(SK+) (Stratagene) toform pIJ7474. Digestion of pIJ7474 with HpaI resulted in the lossof an internal Tn5 fragment that included the kanamycin resistancegene. The 2-kb Spc^r cassette from pHP45 $Omega$ (32) was cloned as a SmaI fragment intothe HpaI-digested pIJ7474 to make pIJ7754. The resulting plyA3::Spc^r allele was cloned as an EcoRI fragment into the sacB suicidevector pJQ200(KS) (33) to make pIJ7765. The double mutants A636and A640 were made by marker exchange of the plyA3::Spc^r allele from pIJ7765 into the plyB mutants A616 and A617, respectively.Double mutants were identified as spectinomycin-, kanamycin-,and sucrose-resistant, gentamicin-sensitive colonies.

Protein analysis. For rapid and sensitive detection of secreted NodO, 250 µl of culture supernatant was loaded onto a nitrocellulose membrane(Sartorius) with a slot blot apparatus. The membrane was thenimmunostained with a mixture of NodO-specific monoclonal antibodies(39) and goat anti-rat immunoglobulin conjugated to horseradishperoxidase (Sigma). The bound complex was visualized with theenhanced chemiluminescence (ECL) kit (Amersham) as specified bythe manufacturer.

For analysis of secreted proteins, rhizobia were grown for 24 h at 28°C in TY medium to an optical density of 0.6. Culture-supernatantproteins were concentrated by precipitation with 10% trichloroaceticacid, as described previously (13), except that after precipitation,the trichloroacetic acid was extracted by washing the precipitatewith acetone. Proteins from an equivalent of 5 to 10 ml of culturesupernatant were separated by sodium dodecyl sulfate-polyacrylamidegel electrophoresis (SDS-PAGE) (7) with 8% acrylamide and visualizedby staining with Coomassie brilliant blue R-250.

PlyB was labelled with [³⁵S]methionine by using an E. coli T7 RNA polymerase expression system. The EcoRI-BamHI fragment carryingplyB (see Fig. 1b) was cloned behind the T7 promoter in pT7-5(40). Expression and labelling with [³⁵S]methionine were carried out in E. coli K38(pGP1-2) in the presenceof rifampin as described previously (40). Labelled proteinswere detected by autoradiography of SDS-PAGE gels. The molecularweight standards used were the broad-range prestained markersfrom New England Biolabs.

Plate assays for enzyme activities. For detection of glycanase activity, EPS was precipitated from 5-day cultures of strain A408 with 3 volumes of ethanol andredissolved in sterile water. EPS was incorporated into Y agarplates at about 2 mg ml¹. Colonies were grown for 3 days on this medium and then washedoff with water. The plates were flooded with 0.1% Congo Red (42)for 15 min and washed with 5% acetic acid. Degradation of EPSwas observed as clearings (reduction of staining) under the colony.Carboxymethyl cellulose (CMC) or polygalacturonic acid degradationwas detected similarly, except that colonies were grown on Y agarcontaining 0.1% CMC or polygalacturonic acid instead of EPS. CMCplates were washed for 10 min with 1 M NaCl before being washedwith 5% acetic acid.

Isolation of glycanase mutants and complementation by pIJ7647. For the isolation of mutants lacking polysaccharide-degrading activity, Tn5-induced mutants were picked onto CMC or EPS agarplates and analyzed for the ability to produce clearings. Colonieswhich gave reduced degradation were rescreened by the same procedure.For the isolation of a cosmid (pIJ7647) which complemented theplyB mutant for activity on CMC agar, an R. leguminosarum bv.viciae cosmid library (9) was introduced into A617 (plyB).Transconjugants were selected for streptomycin, kanamycin, andtetracycline resistance and were tested for CMC degradation onplates. The Tn5 mutation from A617 was recombined onto pIJ7647,to make pIJ7653, by conjugating A617(pIJ7647) with an E. colistrain carrying a helper plasmid. E. coli transconjugants whichcontained recombinant derivatives of pIJ7647 carrying the Tn5insertion from A617 were selected on L medium containing kanamycinand tetracycline, and the location of Tn5 was mapped with severalrestriction endonucleases. The precise location of Tn5 was obtainedby cloning EcoRI-BamHI fragments containing each end of the Tn5into pUC18 and sequencing from the ends of Tn5 with an oligonucleotideprimer.

Polysaccharide analysis. Culture supernatants were analyzed by the anthrone method (29) to determine the concentration of sugars and by the Lever(28) method to determine the concentration of reducing sugars.Measurements of total sugars were made with reference to a standardmixture of sugars corresponding to the molar ratio of sugar residuespresent in the bacterial EPS (glucose/glucuronic acid/galactoseratio, 5:2:1) (10). The ratio of EPS repeat units to reducingends was calculated on the assumption that EPS accounted for allthe carbohydrate present in the culture supernatants. An estimateof the molar concentration of the EPS repeat unit was calculatedon the assumption that the concentration of the repeat unit isone-eighth of the total estimated sugar concentration. This wasthen divided by the measured molar concentration of reducing sugarsto obtain the ratio of EPS repeat units to reducing ends. Theresults are presented as the mean values from duplicate experiments(see Table 2). Variation between duplicate experiments was lessthan 20%. Qualitatively similar results were obtained in severaldifferent experiments, although the actual values were variable(probably due to changes occurring during growth), making it difficultto meaningfully average all the results. The viscosities of thecultures were compared by measuring the time taken to flow betweenmarks on a 0.1-ml glass pipette. The readings were normalizedagainst the results for the wild-type strain 8401(pRL1JI). Theresults are given as the mean values from duplicate experimentsand are representative of several experiments (see Table 2).Variation between duplicate experiments was less than 10%. Sugarsin the EPS were converted to alditol acetate derivatives and analyzedby gas chromatography (21).

DNA manipulation and sequence analysis. Standard DNA manipulations were carried out by the method of Sambrook et al. (36). A 9.6-kb EcoRI fragment, cloned in pBluescript(SK+) (Stratagene) and carrying plyA, prsD, and prsE, was digestedwith NarI and SmaI and religated, resulting in the deletion of6.2 kb. The remaining 3.4-kb carrying plyA and part (809 bp) ofprsD was cloned into pKT230 as an EcoRI-SacI fragment to formpIJ7871. Double-stranded DNA sequencing was carried out on pIJ7708and on subcloned fragments of pIJ7349 by using exonuclease IIIdeletions to generate templates. Cycle sequencing was done ona Perkin-Elmer PCR 9600 instrument with M13 forward and reverseprimers, using ABI "Prism" Dye Primer cycle-sequencing ready-reactionkits. Reactions were run on ABI 377 and 373A DNA sequencers.

Sequence analysis was carried out with the GCG package (version 8; Genetics Computer Group, Madison, Wis.). Homologous proteinsin the data library at the National Center for Biotechnology Informationwere identified with the blastp program (1). Predictions ofsecondary structure for protein sequences were obtained with thePredictProtein server (34).

	RESULTS

Top Abstract Introduction Materials & Methods Results Discussion References

Isolation of mutants defective in polysaccharide degradation. Previously we observed that mutation of prsD in R. leguminosarum bv. viciae abolished the secretion of several proteins andthat this correlated with an inability of the prsD mutant to cleaveEPS and CMC (16). On the assumption that a gene(s) encodingsuch one secreted protein(s) may be close to prsD, we extendedthe DNA sequence upstream of prsD (there was no evidence for suchgenes downstream of prsD). This sequencing revealed an open readingframe (ORF) upstream of and in the same orientation as prsD (Fig.1a). Since the ORF ends 541 bp upstream from prsD, it is unlikelyto be transcribed as part of the same operon; indeed, a Tn5 insertionin this ORF (see below) had no polar effect on the secretion ofNodO (data not shown), indicating that the mutation is not polaron prsD, which is required for NodO secretion. The 450 bp upstreamof the ORF is predicted to be noncoding and therefore may includea promoter.

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FIG. 1. (a) Map of the 9.6-kb EcoRI fragment carring the prsDE genes. Downstream from prsDE and ORF3 and in the opposite orientation are four genes (pssFCDE) homologous to glycosyl transferases in R. leguminosarum bv. trifolii (45) and R. meliloti (19). Upstream from prsDE is plyA, encoding a putative polysaccharide lyase. (b) The plyB gene is located in a 3.6-kb EcoRI fragment. Tn5 insertions identified in prsD, plyA, and plyB are indicated by solid circles. E, EcoRI; B, BamHI.

Since the predicted protein sequence encoded by this ORF has significant similarity to that of bacterial and fungal polysaccharidelyases (see below), we thought that it might be responsible forthe CMC and/or EPS degradation by R. leguminosarum bv. viciae,and we called the gene plyA. Two Tn5 insertions within plyA wereidentified by restriction mapping of mutated derivatives of pIJ7298(which carries plyA and prsDE); the Tn5 insertion sites were confirmedby DNA sequencing from the Tn5 ends (Fig. 1a). The mutations (plyA1::Tn5and plyA2::Tn5) were recombined into R. leguminosarum bv. viciaeby homologous recombination to make the mutants A632 (plyA1::Tn5)and A633 (plyA2::Tn5). Neither mutant was affected in its abilityto degrade CMC or EPS in agar plates containing these substrates.This is illustrated for A632 grown on CMC-agar plates (Fig. 2a);as shown, the degradation seen below the A632 colony is not significantlydifferent from that seen with the isogenic control strain (strain8401). In contrast, degradation of CMC is essentially absent fromthe prsD (protein secretion) mutant A408. These observations showedthat the degradation of CMC and EPS observed in the plate assaysdoes not require plyA and must be due to a secreted enzyme encodedby another gene.

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FIG. 2. Degradation of CMC by ply mutants. CMC degradation is estimated by the lack of staining (seen as cleared regions) by Congo Red in the agar directly below the colonies. (a) Comparison of the CMC degradation by 8401 (wild-type control), A632 (plyA), A616 (plyB), A408 (prsD), and A636 (plyA plyB) on CMC agar. (b) Introduction of pIJ7647 (carrying plyB) results in increased degradation of CMC by A616 (plyB) but not by A408 (prsD). (c) Introduction of pIJ7871 (carrying plyA) causes strong degradation by A616 (plyB) but not by A408 (prsD). (d) Egl from A. caulinodans, expressed from pRGC1, causes increased CMC degradation by 8401 and A616 (plyB) but not by A408 (prsD). (e) Similar results were obtained with Egl expressed from pGV910-C1, except that the CMC degradation extended beyond the diameter of the colony.

To identify this other gene, plate assays were used to screen for mutants unable to degrade EPS or CMC. A population of Tn5-inducedmutants was screened on plates containing either CMC or EPS, andcolonies that gave a reduced clearing in comparison with the controlstrain were identified. This screen was expected to result inthe isolation of two classes of mutants: those with mutationsin the prs genes, which would prevent secretion of the endoglycanase,and those with mutations in a gene encoding a secreted enzymethat degrades CMC and/or EPS. From a total of 12,000 mutant coloniesscreened, 5 were identified which produced reduced clearing onboth EPS and CMC plates. No colonies that degraded only one ofthe substrates were identified. Genetic complementation studiesand mapping of the sites of Tn5 insertions revealed that fourof the five mutations were in prsD, and biochemical studies (datanot shown) confirmed that these mutants were identical to theprsD protein secretion mutant described previously (16). Theinsertion sites of three of the prsD Tn5 mutations are shown inFig. 1a.

One mutant was not complemented by the prsDE plyA region cloned on pIJ7298. The Tn5 from this mutant cotransduced (100%) withthe defect in CMC and EPS degradation, confirming that a singleevent caused both phenotypes. The test of CMC degradation by oneof the transductants (A616) is illustrated in Fig. 2a. This revealsthat there is very little CMC degradation, although a low residuallevel appears to be present, suggesting that another CMC-degradingenzyme may be present. A similar observation was made with EPSdegradation (data not shown). The residual level of CMC degradationby the mutant A616 is highlighted in Fig. 2c, in which the levelof staining is enhanced. This shows the presence of a zone ofdegradation below the A616 colony. There also appears to be alow level of CMC degradation below the prsD secretion mutant A408;this may be due to a low level of lysis of some cells in the colony.To determine if the mutation in A616 caused a general effect onprotein secretion, the Tn5 mutation was transduced into a straincarrying the nodO gene on the symbiotic plasmid. This mutant (A617)was confirmed to be defective in CMC degradation but retainedthe ability to secrete NodO (data not shown). This indicates thatthe Tn5 mutation affects a gene involved in CMC and EPS degradationrather than a component of the type I protein secretion system.

Identification of plyB, which encodes a polysaccharide-degrading enzyme. A cosmid library of Rhizobium DNA was crossed into the mutant (A616) defective for CMC and EPS degradation to identify complementingcosmids. The transconjugant colonies were screened for restorationof degradation by using CMC agar plates, and the cosmid pIJ7647was isolated from one such complemented colony. When pIJ7647 wastransferred back into A616, it again restored CMC degradation,demonstrating that pIJ7647 complements the mutation in A616 (Fig.2b). A 2-kb EcoRI-HindIII fragment subcloned from pIJ7647 couldalso complement the mutant, and DNA sequencing of this 2-kb fragmentrevealed a long ORF (1,494 bp). DNA sequencing from the ends ofthe Tn5 mutation (cloned from A616) revealed that the Tn5 is inserted666 nucleotides downstream of the proposed translation start ofthe ORF (Fig. 1b). The ORF encoded a predicted protein of 51.5kDa that is 76% similar (71% identical) to PlyA, and the genewas called plyB. In comparison with PlyB, PlyA contains an extra50 amino acids located 120 residues from the C terminus. Apartfrom this insert, the similarity extends along the full lengthof two proteins.

Both PlyA and PlyB show significant similarity to bacterial and fungal polysaccharide lyases, including about 20% identityto PlyD from Aspergillus niger (20), PelC from E. chrysanthemi(41), and SpsR from Sphingomonas strain 888. SpsR may be involvedin processing of the sphingan EPS produced by Sphingomonas (49).These similarities strongly suggest that plyB and plyA encodeenzymes with polysaccharide-degrading activity; the observationthat mutation of plyB strongly reduces the degradation of EPSsuggests that the primary role of PlyB is the processing of EPS.Since the secretion of CMC and EPS degradation activity is blockedby mutation of prsD, we conclude that PlyB is secreted via theprsDE-encoded type I secretion system. It is clear that thereis little or no degradation of CMC by the prsD mutant A408, evenwhen the plyB gene is cloned on the multicopy plasmid pIJ7647(Fig. 2b).

In view of the level of identity between PlyA and PlyB, it seemed likely that plyA also encodes an enzyme with polysaccharide-degradingactivity. To test this, plyA was cloned behind a vector promoterto generate pIJ7871, which was then introduced into the plyB mutant(A616), in which the EPS and CMC degradation is greatly reduced.As shown in Fig. 2c, pIJ7871 strongly increases the degradationof CMC, and similar results were seen on EPS-agar plates (notshown). There was no significant CMC (or EPS) degradation whenplyA (on pIJ7871) was introduced into the protein secretion mutantA408 (prsD). On the basis of these results, we conclude that PlyA,like PlyB, is secreted via the prsDE-encoded type I secretionsystem. Such a type I-dependent secretion of PlyA and PlyB isconsistent with the absence of potential N-terminal secretionsignals in PlyA or PlyB and suggests that they probably have C-terminalsecretion signals.

Secretion of an A. caulinodans endoglycanase. An endoglycanase gene (egl) was previously cloned from Azorhizobium caulinodans (17). The egl gene product shows no similarityto PlyA and PlyB or to any other proteins shown to be secretedby a type I secretion system. The cloned egl gene (on pRGC1) wastransferred to A616 (plyB) and shown to induce strong degradationof CMC (Fig. 2d). However, there was no degradation of EPS bythis strain (data not shown), demonstrating that although theegl gene product can degrade CMC, it cannot degrade the EPS fromR. leguminosarum bv. viciae.

The observation (Fig. 2d) that the cloned egl gene does not cause CMC degradation in the protein secretion mutant A408 (prsD)demonstrates that Egl secretion is prsD dependent. Geelen et al.(17) described a derivative of the egl gene that retained CMCdegradation activity even though a large part of the gene encodingthe N-terminal domain of the Egl protein was deleted. This deletedform of the Egl protein could be also secreted by R. leguminosarumbv. viciae, as observed by the strongly enhanced degradation ofCMC by R. leguminosarum bv. viciae 8401 carrying the deleted formof egl (on pGV910-C1). This demonstrates that the deleted N-terminalregion of Egl is not required for its secretion. The observedsecretion is PrsD dependent as judged by the lack of CMC degradationby the prsD mutant A408 carrying the deleted form of egl (Fig.2e).

The pattern of CMC degradation by the strain carrying the deleted egl gene was different from that observed in all of theother assays. In all the other cases, the zone of CMC degradationwas observed only directly below the colony; i.e., there was noobserved diffusion of CMC degradation activity beyond the edgeof the colony. However, with the deleted derivative of egl (onpGV910-C1), the zone of CMC degradation extended well beyond theedge of the colony (Fig. 2e). The wild-type form of Egl was shownto be cell associated in A. caulinodans (17), and this alsoseems to be the case in R. leguminosarum bv. viciae with wild-typeEgl, which does not diffuse beyond the edge of the colony (Fig.2d). It may be that this cell association is mediated via theN-terminal half of the protein and that deletion of this regionallows a more freely diffusible activity.

Analysis of culture-supernatant proteins of ply mutants. Previously we identified three proteins (other than NodO), with M_rs of 33,000, 65,000, and 110,000, which were not secretedby a prsD mutant. To determine which (if any) of these proteinswas absent from plyA or plyB mutants, culture supernatant proteinsfrom 8401 (wild type), A616 (plyB1::Tn5), A632 (plyA2::Tn5), andA633 (plyA1::Tn5) were concentrated, separated by SDS-PAGE, andstained with Coomassie blue (Fig. 3). No bands were absent fromthe culture supernatants of the plyA mutants; the bands previouslyidentified as being secreted via PrsDE were all present, indicatingthat none of these is encoded by plyA. A band running at about65 kDa was absent from (or significantly reduced in amount in)the culture supernatant of the plyB mutant A616 (Fig. 3, laneg). This band corresponds to one of the proteins previously observedto be missing from the culture supernatant of a prsD mutant (Fig.3). However, the predicted molecular mass of PlyB (51.5 kDa) issignificantly lower than the apparent molecular mass of the missingprotein band (65 kDa). The only other difference compared withthe control concerns a protein of 30 kDa, whose was reduced inthe supernatant of the plyB mutant (Fig. 3, lane g), but thisdecrease was more variable between different preparations. Weconsidered it possible that the PlyB protein migrated aberrantlyon SDS-PAGE. plyB was expressed in E. coli by using a T7 expressionsystem in which expressed proteins were labelled with [³⁵S]methionine (40). A plyB-specific band of 52 kDa was detectedfollowing SDS-PAGE and autoradiography (data not shown). Therefore,we conclude that PlyB migrates normally on SDS-PAGE and that weare unable to detect its absence in the culture supernatant ofthe plyB mutant. The absence of the 65-kDa protein from the Coomassieblue-stained gel of the plyB mutant may be due to a secondaryeffect (such as lack of expression of a downstream gene) in theplyB mutant.

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FIG. 3. Two Coomassie blue-stained SDS-PAGE gels showing secreted proteins from R. leguminosarum bv. viciae mutants. Culture supernatant proteins were precipitated from the prsD mutant A412 (lane b), wild-type (WT) 8401(pRL1JI) (lanes c and d), the plyA mutants A501 (lane e) and A503 (lane f), and the plyB mutant A617 (lane g). Molecular size markers (94, 67, 43, and 30 kDa) are shown in lanes a and h. The strains were grown in the absence of the nod gene inducer hesperetin. Proteins present in 8401(pRL1JI) but absent from the secretion mutant A412 are indicated in lanes c and d. One of these proteins (arrowhead) is apparently also absent from A617 (lane g). The gel containing lanes a, b, and c was run slightly differently from the other gel; the lines highlight the positions of the proteins that were absent from the supernatant of prsD mutants.

Analysis of EPSs of ply mutants. The prsD mutant was found to have an increased ratio of total to reducing sugars in culture supernatants and an increase inculture viscosity over the wild-type strain (16). We analyzedthe effects of the plyA and plyB mutations on the EPS by usingthe same methods that we previously used to characterize the EPSof the prsD mutant. Parallel experiments were done with the mutantscontaining or lacking the symbiotic plasmid pRL1JI, which wasfound to have no effect on the results. Therefore, for simplicityand to enable a direct comparison with our previous data (whichwas obtained with pRL1JI-containing strains), we present onlythe results of the analysis of EPS in the plyA and plyB mutantscarrying pRL1JI.

The amount of EPS (determined by measuring the total sugar content by the anthrone method) made by the plyA mutant (A501)was similar to that observed with the control strain [8401(pRL1JI)],and there was also no observed difference in the concentrationof reducing sugars (an estimate of the numbers of free ends ofEPS) (Table 2). Therefore, the calculated ratio of EPS repeatsto reducing sugars is similar to that in the control, 8401(pRL1JI).The viscosity of cultures of A501 (plyA) was not increased. Theseobservations indicate that the plyA mutation does not greatlyaffect EPS processing, at least under the growth conditions used.The plyB mutant had a slightly higher level of EPS, since thetotal sugar content was slightly higher than that of the control[8401(pRL1JI)] (Table 2), but the concentration of reducing sugarswas below the limits of sensitivity of the assay. Under the conditionsused, the assay could detect reducing sugars at concentrationsabove 0.2 µg ml¹. Therefore, the level of reducing sugars found with the plyBmutant (A617) was less than 1/10 of the level seen with the control[8401(pRL1JI)]. On this basis, the ratio of EPS repeats to reducingends in the plyB mutant was calculated to be more than 100 timesthat observed with the wild-type. The measurements of viscositysupported these results; A617 (plyB) cultures were twice as viscousas control [8401(pRL1JI)] cultures after 5 days of growth (Table2), indicating that the EPS of the mutant is longer than normal.Even when the culture supernatants were adjusted to have similarcarbohydrate concentrations, the viscosity of the plyB mutantwas much higher (about 1.8- to 2-fold) than that of the wild type.There is a theoretical possibility that these altered characteristicsof the plyB mutant are due to the formation of a new EPS. However,gas chromatography analysis of alditol acetate derivatives ofculture supernatant polysaccharides from the plyB mutant (andthe plyA mutant) demonstrated that the ratio and amount of neutralmonosaccharides were the same as in the wild-type control (datanot shown). Therefore, the increase in culture viscosity and estimatedpolysaccharide length observed in the plyB mutant is unlikelyto be due to the formation of a novel high-molecular-weight polysaccharide.

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TABLE 2. Analysis of EPSs

Analysis of the role of plyA and plyB in the symbiosis. The protein secretion mutant A412 (prsD), which cannot secrete NodO, PlyB, PlyA, or other proteins, induces Fix nodules on peas. As is typical of Fix mutants, this was accompanied by an increase in nodule numberfrom an average of about 80 to about 120 nodules/plant (16).This phenotype cannot be explained by the absence of secretedNodO, since nodules induced by a strain lacking nodO are Fix⁺ (14). One or more proteins that are secreted via the PrsDEsystem are presumably required for the development of an effectivesymbiosis. The number of nodules induced on peas by A638 (plyA)and A617 (plyB) was normal (an average of about 80 nodules perplant after 24 days of growth), and this correlated with normallevels of nitrogen fixation (based on measurements of acetylenereduction). The possibility remained that plyA and plyB were fulfillinga similar function and that either one of them was sufficientfor nitrogen fixation; therefore, a double mutant was constructed.The plyA plyB double mutant (A640) was also normal with respectto the number of nodules formed and levels of symbiotic nitrogenfixation, demonstrating that PlyA and PlyB are not required toestablish a nitrogen-fixing symbiosis. The rate of nodulationof the various mutants on vetch was measured (Fig. 4). A640 (plyAplyB) induced slightly fewer nodules than did the control [8401(pRL1JI)],A638 (plyA), and A617 (plyB). This indicates that plyA and plyBhave little influence on the efficiency of nodulation.

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FIG. 4. Nodulation of vetch by 8401 pRLIJI ( $black-square$ ), the plyA mutant A638 ( $diamond$ ), the plyB mutant A617 ( $black-lozenge$ ), and the double mutant A640 (plyA plyB) ( $triangle$ ). Standard errors are shown.

Since plyB mutants retain a small residual activity on CMC plates and EPS plates, another enzyme which is able to degradeCMC and EPS may be present. Mutant strains lacking both plyA andplyB retained the same level of residual activity seen with theplyB mutant on CMC agar and EPS agar. The residual activity inthe plyB mutant is therefore not dependent on PlyA and may bedue to an additional polysaccharide-degrading enzyme(s) secretedby R. leguminosarum bv. viciae. The plyA plyB double mutant wasalso indistinguishable from the plyB mutant in terms of cultureviscosity and supernatant polysaccharides (data not shown).

Structural characteristics of PlyA and PlyB. Our data suggest that PlyA and PlyB cleave EPS and depend on the prsDE genes for their secretion. The C-terminal 70 aminoacids of PlyA and PlyB are very similar and are expected to containa secretion signal. NodO, PlyA, PlyB, and Egl, all proposed tobe secreted by PrsDE, have a characteristic motif at the extremeC terminus. This is made up of a negatively charged residue followedby several hydrophobic residues and is often present in proteinssecreted via type I secretion systems (18).

Another characteristic shared by most of the proteins secreted via type I secretion systems is the presence of glycine- andaspartate-rich nonapeptide RTX repeats (46), which form a Ca²⁺-binding $beta$ -roll structure (3, 4). NodO (30 kDa) contains12 such RTX repeats (13). PlyA and PlyB do not contain an RTXdomain, and there is no sequence similarity between NodO and PlyAor PlyB, which are secreted via the same (PrsDE) secretion system.However, we noted that PlyA and PlyB each contain 10 repeats ofa novel motif with the approximate consensus N(I/V)X(I/V)X(D/E)N(Fig. 5a). Predictions of secondary structure for PlyA and PlyBsuggest that they are composed predominantly of $beta$ -strand, particularlyin the regions containing the proposed novel repeats (Fig. 5b).Six similar repeats are present in SpsR (Fig. 5a), which has about20% identity to PlyA and PlyB.

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FIG. 5. (a) Repeat motifs found in PlyA, PlyB, and SpsR. The position in the sequence of the first amino acid in each repeat is indicated. A rough consensus sequence is shown. PlyA and PlyB each contain 10 copies of the motif; SpsR contains 6 copies. (b) Sequence alignment of PelC from E. chrysanthemi with PlyA and PlyB from R. leguminosarum bv. viciae, showing conservation of secondary structure. The mature form of PelC (lacking the N-terminal signal peptide) was used for the alignment. Residues that are conserved in all three proteins ( $open circle$ ) and between PelC and either PlyA or PlyB (·) are indicated beneath the alignment. Structural elements are indicated in boldface type, with $alpha$ -helices in italics and $beta$ -strands underlined. The secondary structure of PelC is known from the crystal structure (49). The $beta$ -strands that form the PB2 $beta$ -sheet in PelC are indicated. The residues which form stacks stabilizing the parallel $beta$ -helix of PelC are indicated by asterisks above the sequence. The stacks are composed mainly of Asn residues, which occur as the second residue after the end of the PB2 $beta$ -strands. The secondary structure of PlyA and PlyB was predicted by PHDsec (34) and aligns well with the known structure of PelC, suggesting that these proteins may have a similar fold.

The crystal structures of PelC and PelE from E. chrysanthemi (which are similar to PlyA and PlyB) have been solved (50,51). Both form a parallel $beta$ -helix, with three $beta$ -sheets, PB1,PB2, and PB3, stabilized by specific stacking interactions betweenamino acid side chains in the core of the helix. The predictionof secondary structure for PlyA and PlyB was obtained with PHDsec(34) and was superimposed onto a sequence alignment of PlyAand PlyB with PelC. The predicted secondary structure alignedwell with the known PelC structure (Fig. 5b). The repeat motifstended to align with the $beta$ -strands forming the PB2 $beta$ -sheet. Inparticular, the Asn residues involved in the formation of a distinctive"asparagine ladder" between PB2 and PB3 in pectate lyases areconserved in PlyA and PlyB (Fig. 5b). These conserved asparaginesoften correspond to the last residue of the repeat motif describedabove. Another feature of the PelC structure is the presence ofan N-terminal $alpha$ -helix that caps the $beta$ -helix. PlyA and PlyB arepredicted to form an $alpha$ -helix in a similar position (around residue30). Therefore, rather than forming a $beta$ -roll structure based onRTX repeats like other proteins previously shown to be secretedby type I systems, PlyA and PlyB may share a similar fold withthe superfamily of extracellular pectate lyases.

In view of the apparent structural similarities between PlyA or PlyB and pectate lyases, we checked for hydrolysis of polygalacturonicacid, which has been seen previously in R. leguminosarum bv. trifolii(30). R. leguminosarum bv. viciae produced clearings on agarplates that contained polygalacturonic acid, but this activitywas not dependent on plyA or plyB, since isogenic strains carryingmutations in either or both genes had similar clearings to thecontrol strain, 8401 (data not shown). Therefore, although PlyAand PlyB are suggested to form a similar structure to the familyof pectate lyases, they apparently do not have the same substratespecificity as this family.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Two genes, plyA and plyB, which are very similar to each other and encode products that are similar to polysaccharide lyaseshave been identified. PlyA and PlyB are secreted by the Prs proteinsecretion system encoded by prsDE and cleave EPS and CMC. Thelack of secreted PlyB can account for the increase in the lengthof EPS chains observed in the prsD mutant.

Some of the proteins secreted via the prsDE system may remain cell associated. Cellulase and endoglycanase activities in R.leguminosarum bv. trifolii and A. caulinodans were found to becell associated (17, 30). Our results also suggest that Eglis secreted via the PrsDE type I secretion system but may remainassociated with the cell surface. Such an association could accountfor the lack of diffusion of CMC-degrading activity from coloniesand could be somewhat different from the secretion of solubleproteins such as NodO, proteases, and alpha-hemolysin secretedvia type I exporters. R. leguminosarum bv. trifolii, which hada cell-associated extracellular cellulase activity, had no cellulaseactivity in culture supernatants (30). Similarly, the Egl endoglycanasefrom A. caulinodans was also concluded to be a cell-associatedextracellular enzyme (17). The diffusion of enzyme activityfrom colonies carrying the truncated form of Egl may indicatethat this protein does not remain cell associated and might suggesta role for the N-terminal part of the protein in surface association.It is possible that the activities encoded by plyA and plyB arealso predominantly cell associated, since the areas of clearingformed by R. leguminosarum bv. viciae on CMC and EPS agar arevisible only directly underneath the colonies. If a freely diffusibleactivity were present, more diffuse clearing around the colonieswould be expected. The small amount of 65-kDa protein in culturesupernatants that is thought to correspond to PlyB may be dueto the release of a relatively low proportion of the PlyB proteinfrom the cell surface.

It was previously proposed that at least one of the proteins secreted via the Prs system was required for symbiotic nitrogenfixation. The evidence presented here demonstrates that PlyA andPlyB are not required for nitrogen fixation and that they do nothave a strong effect on nodulation. Work with R. meliloti hasdemonstrated that a particular size range of EPS produced by thebacterium is required for activity in nodulation (2, 43).So far, two enzymes, encoded by exoK and exsH, that cleave thebacterial EPS have been identified in R. meliloti (5, 52).ExoK is thought to be secreted in a sec-dependent manner sinceit has a potential N-terminal transit peptide, and ExsH (whichcontains four RTX repeats) is thought to be a glycosyl hydrolasethat is secreted via the R. meliloti PrsDE type I secretion system(52). These glycosyl hydrolases are not homologous to PlyA andPlyB.

The residual low level of degradation of CMC and EPS by the plyA plyB double mutant suggests that an additional polysaccharidasemay be produced by R. leguminosarum bv. viciae. To demonstratea requirement for these enzymes in the symbiosis, it may thereforebe necessary to mutate additional genes. Although plyA mutantsare apparently unaffected in the ability to degrade CMC and EPS,we have demonstrated, by placing plyA under the control of a constitutivepromoter, that PlyA has glycanase activity. Our results suggestthat under free-living conditions, plyA is not highly expressed,and they imply that plyA and plyB may be under different regulatorycontrols. An in situ analysis (with appropriate gene fusions)of plyA and plyB gene expression during legume nodulation wouldreveal if either gene is expressed during legume infection.

Four gene products have been identified so far that require prs genes for secretion from R. leguminosarum bv. viciae: NodO,PlyA, PlyB, and Egl (from A. caulinodans). Analysis of extracellularproteins indicates that other proteins are also secreted via thesame system. SpsR from Sphingomonas may also be secreted via atype I secretion system. Like PlyA, it is encoded in a clusterof EPS-biosynthetic genes and is expected to be a secreted proteininvolved in EPS processing. SpsR has no N-terminal signal sequence(49) but does have a negatively charged residue followed byseveral hydrophobic residues at its extreme C terminus, a motifoften present in proteins secreted via type I secretion systems(18). Two genes, atrB and atrD, encoding a type I secretionsystem are also present within the sps gene cluster (49), andthese genes may be required for the secretion of SpsR.

PlyA, PlyB, and SpsR share a novel repeat motif. These repeats may be involved in the formation of a similar structure tothe parallel $beta$ -helix formed by the pectate lyase superfamily,on the basis of conservation of significant structural features.The repeat sequences align with the PB2 $beta$ -strands of PelC (50),and the terminal asparagines in the repeats align with the residuesin PelC that form the asparagine ladder stabilizing a tight turnbetween PB2 and PB3. The conservation of these asparagines isparticularly significant in view of the otherwise low overallsequence similarity. These features suggest the existence of afamily of bacterial proteins involved in polysaccharide processing,including PlyA, PlyB, and SpsR, that are secreted by type I secretionsystems.

The Egl protein shows no similarity to PlyA, PlyB, or any of the RTX family of proteins. Therefore, Egl lacks the RTX repeats,and we found no evidence for the PlyA-type heptapeptide repeat.However, Egl does contain several copies of a large (150-amino-acid)repeat that is similar to Ca²⁺-binding domains of some proteins (17). Thus, Egl may be a memberof a different class of polysaccharide degrading enzymes thatare secreted via a type I system. It remains to be determinedif the repeat domains in PlyA and PlyB or Egl play any role intheir secretion. However, the observation that there are threeclasses of secreted proteins, each with a different type of internal-repeatstructure, suggests that repeated domains may be important forthe secretion or folding of these proteins in the extracellularenvironment.

	ACKNOWLEDGMENTS

We thank M. Sutton and J. Peart for the gift of NodO-specific monoclonal antibodies, M. Holsters and D. Geelen for pRGC1 andpGU910-C1, P. Bovill and A. Wilkinson for help with DNA sequencing,A. Marry and M. McCann for help with analysis of sugar derivatives,E. Brown for help with screening mutants, O. Mayans and L. LoLeggio for informed and helpful discussions about the parallel $beta$ -helix protein structure analysis, M. Dow for critical commentson the manuscript, and G. Sawyers and M. Wexler for help with³⁵S labelling of proteins.

This work was supported by the BBSRC. A.Z. is supported by CONICET Argentina.

	FOOTNOTES

^* Corresponding author. Mailing address: John Innes Centre, Norwich Research Park, Norwich NR7 4UH, United Kingdom. Phone: 1603452571. Fax: 1603 456844. E-mail: downie{at}bbsrc.ac.uk.

Present address: Department of Plant Biology, Royal Vetinary and Agricultural University, 1871 Frederiksberg C, Copenhagen,Denmark.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
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