Serological and conductimetric assays for the detection of Pseudomonas syringae pathovar pisi in pea seeds

Test protocols for detecting Pseudomonas syringae pv. pisi , the causal agent of bacterial blight, in pea seeds are generally based on dilution-plating assays. These assays are usually very specific and reliable, but are time-consuming and laborious. Tests suited for large scale screening of seed lots are therefore needed. Conductimetric assays, immunofluorescence microscopy (IF) and an enzyme-linked immunosorbent assay (ELISA) for detecting Ps. syr. pv. pisi in pea seed extracts were compared with dilution-plating by two extraction methods, viz. 6 h soaking of seeds and 2 h soaking of flour of ground pea seeds in water. In general, the detection of Ps. syr. pv. pisi with conductimetric, IF and dilution-plating assays in the suspension water of the ground and 2 h-soaked pea samples was less sensitive than detection in suspension water of the 6 h-soaked pea seeds. The detection threshold of these assays varied per seed lot between 0 and 4.08 log cfu ml^-1 for the 6 h soaking procedure. The detection threshold of ELISA varied for both extraction methods generally between 4.08 and 6.08 log cfu ml^-1. Detection times recorded in conductimetric assays correlated well (— 0.89 < r < —0.98) with the log colony-forming units of Ps. syr. pv. pisi added to seed extracts at 27 as well as 17°. However, confirmation of results by isolation on semi-selective media after conductimetry was more successful at 17° than at 27°, because of the relatively lower activity of saprophytic Pseudomonas spp. at this temperature.     

Protein and enzymatic criteria for the characterization of phytopathogenic Pseudomonas fluorescens

Polyacrylamide gel electrophoresis of proteins was carried out to characterize eight bacterial strains belonging to the genus Pseudomonas. The sampling included three species (P. cichorii, P. viridiflava and P. syringae), with three pathovars for this last species (pv. pisi, pv. syringae, pv. tomato). Several molecular markers were evaluated: native proteins, denatured proteins, esterases, superoxide dismutases (SOD) and polyphenoloxidases (PPO). Each species or pathovar of Pseudomonas was clearly differentiated by esterase patterns. SOD, PPO and native protein patterns allowed strains of P. cichorii, P. viridiflava and P.s. pv. tomato also to be distinguished. Strains of P.s. pv. pisi and P.s. pv. syringae were identical for these criteria. Denatured protein patterns of these two pathovars and P. viridiflava were similar.     

Evaluation of determinative tests for pathovars of Pseudomonas syringae van Hall 1902

The utility of 36 presumptive determinative tests for 32 pathovars of Pseudomonas syringae was investigated. A total of 395 strains was examined. Most strains of 12 of these pathovars ( Ps. syringae pv. cannabina, Ps. syr. delphinii, Ps. syr. glycinea, Ps. syr. helianthi, Ps. syr. lachrymans, Ps. syr. mori, Ps. syr. morsprunorum, Ps. syr. phaseolicola, Ps. syr. 'porri', Ps. syr. papulans, Ps. syr. savastanoi and Ps. syr. tabaci ) formed clusters when test data were compared by centroid analysis. Pseudomonas syr. syringae, Ps. syr. aptata, Ps. syr. atrofaciens, Ps. syr. dysoxyli and Ps. syr. japonica formed a single cluster, indicating their possible synonymy. Strains of Ps. syr. antirrhini and Ps. syr. tomato were indistinguishable, as were those of Ps. syr. garcae and Ps. syr. oryzae. Strains of Ps. syr. berberidis, Ps. syr. coronafaciens, Ps. syr. eriobotryae, Ps. syr. maculicola, Ps. syr. passiflorae, Ps. syr. pisi and Ps. syr. striafaciens and Ps. syr. tagetis did not form distinguishable clusters.
The tests which reliably differentiated pathovars are recorded in a determinative scheme.     

Plasmid analysis and variation in Pseudomonas syringae

Total plasmid DNA was successfully isolated from 46 of 55 strains of Pseudomonas syringae . Electrophoretic separation after digestion with restriction endonuclease Eco RI gave reproducible banding patterns. Cluster analysis of banding data grouped all strains of pathovar (pv.) pisi separately from pv. glycinea , pv. phaseolicola and pv. syringae . Pathovars glycinea and phaseolicola were more similar to each other than to pv. pisi. A relationship between fragment banding patterns and race structure within pv. pisi was observed.     

A Note: Serological study of four pathovars of Pseudomonas syringae: Ps. syr. aptata, Ps. syr. tabaci, Ps. syr. mors-prunorum and Ps. syr. phaseolicola

The antigenic reactions of 35 strains of four pathovars of Pseudomonas syringae (Ps. syr. aptata, Ps. syr. tabaci, Ps. syr. mors-prunorum and Ps. syr. phaseolicola ) were studied by double diffusion and indirect immunofluorescent staining, and anti-whole-cell and anti-LPS-extract sera. It had already been shown that the precipitating lines in Ouchterlony double-diffusion tests, due to bacterial LPS, were suitable for the distinction of O-serogroups. The investigation of serological cross-reactions between the 35 strains and 20 antisera revealed that three pathovars were serologically homogeneous: Ps. syr. aptata, Ps. syr. tabaci and Ps. syr. phaseolicola. They could fit into three O-serogroups formerly described: namely APTPIS, TAB and PHA. The O-serogroups APTPIS and TAB showed some common antigens. The 10 strains of Ps. syr. mors-prunorum studied were distributed into two O-serogroups (eight strains belonging to the O-serogroup MOP1, one strain to MOP2, and the last strain failed to react with any of the serogroups).     

Interaction between Pseudomonas syringae pv. Pisi and Isolated Pea Mesophyll Protoplasts

The interaction between five races of Pseudomonas syringae pv. pisi (PSP) and isolated mesophyll protoplasts obtained from five pea cultivars was studied. There was no trend in the attachment of bacterial cells to surfaces of compatible and incompatible host protoplasts. The viability of protoplasts from compatible and incompatible host-pathogen interactions did not differ significantly; however, changes in the viability of cultivar Kelvedon Wonder protoplasts, compatible with all five races, was relatively more stable following inoculation with bacteria than those of cultivar Fortune, incompatible with all of the five races. Protoplast cell wall regeneration did not take place until 24–48 h after isolation. It is concluded that the use of pea protoplasts as a model system for studying the pea-PSP interaction appears to have considerable potential for the future, but more basic research is required.     

Relatedness of Pseudomonas syringae pv. tomato, Pseudomonas syringae pv. maculicola and Pseudomonas syringae pv. antirrhini

The relationships among strains of Pseudomonas syringae pv. tomato, Ps. syr. antirrhini, Ps. syr. maculicola, Ps. syr. apii and a strain isolated from squash were examined by restriction fragment length polymorphism (RFLP) patterns, nutritional characteristics, host of origin and host ranges. All strains tested except for Ps. syr. maculicola 4326 isolated from radish ( Raphanus sativus L.) constitute a closely related group. No polymorphism was seen among strains probed with the 5.7 and 2.3 kb Eco RI fragments which lie adjacent to the hrp cluster of Ps. syr. tomato and the 8.6 kb Eco RI insert of pBG2, a plasmid carrying the β-glucosidase gene(s). All strains tested had overlapping host ranges. In contrast to this, comparison of strains by RFLP patterns of sequences homologous to the 4.5 kb Hind III fragment of pRut2 and nutritional properties distinguished four groups. Group 1, consisting of strains of pathovars maculicola, tomato and apii , had similar RFLP patterns and used homoserine but not sorbitol as carbon sources. Group 2, consisting of strains of pathovars maculicola and tomato , differed from Group 1 in RFLP patterns and did not use either homoserine or sorbitol. Group 3 was similar to Group 2 in RFLP patterns but utilized homoserine and sorbitol. This group included strains of the pathovars tomato and antirrhini , and a strain isolated from squash. Group 4, a single strain of Ps. syr. maculicola isolated from radish, had unique RFLP patterns and resembled Group 3 nutritionally. The evolutionary relationships of these strains are discussed.     

Production of monoclonal antibodies to Pseudomonas syringae pv. phaseolicola and Xanthomonas campestris pv. phaseoli

The production of monoclonal antibodies (MAbs) to ethylenediamine tetraacetic acid (sodium salt) soluble antigens of Pseudomonas syringae pv. phaseolicola and Xanthomonas campestris pv. phaseoli (fuscans strain) is described. MAbs A6-1 and A6-2 produced to Ps. syringae pv. phaseolicola are pathovar specific. Although MAb XP2 produced to X. campestris pv. phaseoli recognized surface antigens of all strains of this pathovar (including fuscans strains) it cross-reacted specifically with X. campestris pv. malvacearum; it did not react with any other known bacteria or unidentified epiphytes from navy bean seed or leaves. The isotype of both MAbs XP2 and A6-1 is IgG3 whereas that of MAb A6-2 is IgG2a. The reactive antigens are thermostable, but their chemical nature has not been determined.     

Misidentification of Pseudomonas strain NCPPB 1498 (ATCC 19875) and proposal for a rejection of the name Pseudomonas syringae pv. panici (Elliott 1923) Young et al. 1978

Pseudomonas syringae pv. panici should be considered invalid because the pathovar epithet panici refers to a xanthomonad. Pseudomonas strain NCPPB 1498 (ATCC 19875) should be listed as an unknown strain belonging to the Ps. syringae group of organisms.     

Variation within Pseudomonas syringae pv. philadelphi, the cause of a leaf spot of Philadelphus spp.

R oberts , S.J. 1985. Variation within Pseudomonas syringae pv. philadelphi , the cause of a leaf spot of Philadelphius spp. Journal of Applied Bacteriology 59 , 283–290
In pathogenicity tests on Philadelphus and other plant species, belonging to ten genera in seven families, isolates of Pseudomonas syringae from leaf spots on Philadelphus spp. in England did not produce symptoms on any plants other than Philadelphus . It is therefore proposed that these isolates should be designated a distinct pathovar of Ps. syringae with the name Pseudomonas syringae pv. philadelphi . Isolates of this new pathovar varied in their reactions to 6 of 57 biochemical tests. In phage typing tests isolates also varied in their sensitivity to five of seven bacteriophage strains. Four of the six biochemical tests (aesculin hydrolysis, utilization of DL-homoserine L-leucine and sorbitol) and all five of the phages (P11, Pls, P2, A15, and A26) were used to separate the isolates into seven groups. These groups had some relation to their geographical origin, species of Philadelphus from which they were originally isolated, and relative virulence on P. coronarius and P. x purpureo-maculatus . They may represent ecotypes of this new pathovar.     

Ethylene Production by Pseudomonas syringae Pathovars In Vitro and In Planta

Significant amounts of ethylene were produced by Pseudomonas syringae pv. glycinea, pv. phaseolicola (which had been isolated from viny weed Pueraria lobata [Willd.] Ohwi [common name, kudzu]), and pv. pisi in synthetic medium. On the other hand, the bean strains of P. syringae pv. phaseolicola and strains of 17 other pathovars did not produce ethylene. P. syringae pv. glycinea and P. syringae pv. phaseolicola produced nearly identical levels of ethylene (about 5 x 10(sup-7) nl h(sup-1) cell(sup-1)), which were about 10 times higher than the ethylene level of P. syringae pv. pisi. Two 22-bp oligonucleotide primers derived from the ethylene-forming enzyme (efe) gene of P. syringae pv. phaseolicola PK2 were investigated for their ability to detect ethylene-producing P. syringae strains by PCR analysis. PCR amplification with this primer set resulted in a specific 0.99-kb fragment in all ethylene-producing strains with the exception of the P. syringae pv. pisi strains. Therefore, P. syringae pv. pisi may use a different biosynthetic pathway for ethylene production or the sequence of the efe gene is less conserved in this bacterium. P. syringae pv. phaseolicola isolated from kudzu and P. syringae pv. glycinea also produced ethylene in planta. It could be shown that the enhanced ethylene production in diseased tissue was due to the production of ethylene by the inoculated bacteria. Ethylene production in vitro and in planta was strictly growth associated.     

Preliminary description of biocidal (syringomycin) activity in fluorescent plant pathogenic Pseudomonas species

Strains representing the fluorescent plant pathogenic Pseudomonas spp., Ps. agarici , Ps. asplenii , Ps. avellanae , Ps. beteli , Ps. caricapapayae , Ps. cichorii , Ps. corrugata , Ps. ficuserectae , Ps. flectens , Ps. fuscovaginae , Ps. marginalis , Ps. meliae , Ps. savastanoi , Ps. syringae , Ps. tolaasii and Ps. viridiflava were tested for biocidal activity using Aspergillus niger as assay organism. Inhibitory behaviour was found in strains of Ps. asplenii , Ps. blatchfordae , Ps. cichorii , Ps. corrugata , Ps. fuscovaginae , Ps. marginalis , Ps. marginalis pv. pastinacea , Ps. syringae pv. syringae , Ps. syringae pv. aptata , Ps. syringae pv. atrofaciens , Ps. syringae pv. lapsa , Ps. tolaasii , and strains of a Pseudomonas sp. pathogenic to Actinidia , in the Ps. savastanoi genomic sp. Antifungal activity could be identified with the production of members of the syringomycin family of toxins by strains in Ps. syringae , Ps. asplenii and Ps. fuscovaginae . These toxin reactions support suggestions made elsewhere of the synonymy of the latter two species. In a preliminary characterization using tests for stability to heat, protease, acid and alkaline treatments, unknown toxins consistent with syringomycin-like toxins the strains from Actinidia speciesColour RGB 0,0,128. The toxins from Ps. cichorii and from Ps. corrugata differed in their reactions from all other agents. Pseudomonas tolaasii produces the antifungal compound tolaasin. The white line reaction with ' Ps. reactans ', a test for tolaasin production by strains of Ps. tolaasii , was confirmed as specific for this compound. Some of these low molecular weight toxins may be produced by some of these plant pathogenic strains.     

Functional homologs of the Arabidopsis RPM1 disease resistance gene in bean and pea.

We showed that a bacterial avirulence (avr) gene function, avrPpiA1, from the pea pathogen Pseudomonas syringae pv pisi, is recognized by some, but not all, genotypes of Arabidopsis. Thus, an avr gene functionally defined on a crop species is also an avr gene on Arabidopsis. The activity of avrPpiA1 on a series of Arabidopsis genotypes is identical to that of the avrRpm1 gene from P.s. pv maculicola previously defined using Arabidopsis. The two avr genes are homologous and encode nearly identical predicted products. Moreover, this conserved avr function is also recognized by some bean and pea cultivars in what has been shown to be a gene-for-gene manner. We further demonstrated that the Arabidopsis disease resistance locus, RPM1, conditioning resistance to avrRpm1, also conditions resistance to bacterial strains carrying avrPpiA1. Therefore, bean, pea, and conceivably other crop species contain functional and potentially molecular homologs of RPM1.     

Pseudomonas syringae pv. japonica (Mukoo 1955) Dye et al. 1980 is a junior synonym of Ps. syringae pv. syringae van Hall 1902

An investigation of the biochemical, nutritional and pathogenic reactions of strains of Pseudomonas syringae pv. japonica and Ps. syringae pv. syringae showed them to be indistinguishable. Pseudomonas syringae pv. japonica is a junior synonym of Ps. syringae pv. syringae.     

Detection of tabtoxin-producing strains of Pseudomonas syringae by PCR

AIMS: The present study describes a system based on PCR to distinguish tabtoxin-producing strains of Pseudomonas syringae from other Ps. syringae plant pathogens that produce chlorosis-inducing phytotoxins. METHODS AND RESULTS: Thirty-two strains of Ps. syringae and related species were examined. Two sets of PCR primers were developed to amplify genes (tblA and tabA) required for tabtoxin production. Only a PCR product of 829 bp or 1020 bp was produced in PCR reactions with the tblA or tabA primer sets, respectively, and cells from tabtoxin-producing pathovars of Pseudomonas syringae. All known non-tabtoxin producing bacterial species failed to produce an amplification product with either primer set. CONCLUSIONS: PCR of genes required for tabtoxin production is a simple, rapid and reliable method for identifying tabtoxin-producing strains of Ps. syringae. SIGNIFICANCE AND IMPACT OF THE STUDY: The protocol can effectively distinguish tabtoxin-producing strains of Ps. syringae from other Ps. syringae pathovars and Ps. syringae pv. tabaci strains from other tabtoxin-producing Ps. syringae pathovars.     

Sequence diversity of rulA among natural isolates of Pseudomonas syringae and effect on function of rulAB-mediated UV radiation tolerance

The rulAB locus confers tolerance to UV radiation and is borne on plasmids of the pPT23A family in Pseudomonas syringae. We sequenced 14 rulA alleles from P. syringae strains representing seven pathovars and found sequence differences of 1 to 12% within pathovar syringae, and up to 15% differences between pathovars. Since the sequence variation within rulA was similar to that of P. syringae chromosomal alleles, we hypothesized that rulAB has evolved over a long time period in P. syringae. A phylogenetic analysis of the deduced amino acid sequences of rulA resulted in seven clusters. Strains from the same plant host grouped together in three cases; however, strains from different pathovars grouped together in two cases. In particular, the rulA alleles from P. syringae pv. lachrymans and P. syringae pv. pisi were grouped but were clearly distinct from the other sequenced alleles, suggesting the possibility of a recent interpathovar transfer. We constructed chimeric rulAB expression clones and found that the observed sequence differences resulted in significant differences in UV (wavelength) radiation sensitivity. Our results suggest that specific amino acid changes in RulA could alter UV radiation tolerance and the competitiveness of the P. syringae host in the phyllosphere.     

Certain aspects of resistance of plum trees to bacterial canker Part I. Some biochemical characteristics of Pseudomonas morsprunorum (Wormald) and related phytopathogenic bacteria

Several strains of Pseudomonas mors-prunorum (Wormald) and Ps. prunicola (Wormald) isolated from pathological lesions of plum and cherry were studied together with the causal organism of bacterial canker of stone-fruits in California (Ps. syringae from apricot) and other phytopathogenic bacteria obtained from pear and syringa. Comparison was also made with pseudomonas forms pathogenic to pea, bean, lettuce, and tobacco, and with the common saprophytes Ps. fluorescens and Ps. pyocyaneus. With the exception of two yellow organisms (B. pruni and the Pear 8 strain—the latter, however, very occasionally showing fluorescence), all belong to the green-fluorescent group of Pseudomonas (Dowson's Group II). On the basis of their dissimilation of C and N compounds a very close relationship has been established between these fruit-tree and syringa pathogens of the green-fluorescent group. Ps. mors-prunorum is not highly specialized in its nutrient requirements but can satisfy its fundamental C and N requirements from a very large variety of simple substances. The only consistent biochemical differentiation shown by Ps. mors-prunorum (including some of the syringa strains) in comparison with Ps. prunicola (including Ps. syringae from apricot and most of the pear strains) is its more rapid production of add from sucrose. Both the mors-prunorum and prunicola varieties produce a levan from sucrose, which causes a raised gummy growth on solid sucrose-containing media. This applies also to Ps. pisi, Ps. tabaci, and Ps. phaseolicola , but is not the case with the weakly pathogenic forms— Ps. marginalis, cerasi (= trifoliorum , from bean), and the saprophytes— Ps. fluorescens and Ps. pyocyaneus.
On the basis of biochemical characteristics, considered apart from host pathogenicity, there is no justification for erecting to specific rank these various levan-forming. green-fluorescent, phytopathogenic pseudomonads.     

Housekeeping gene sequencing and multilocus variable-number tandem-repeat analysis to identify subpopulations within Pseudomonas syringae pv. maculicola and Pseudomonas syringae pv. tomato that correlate with host specificity

Pseudomonas syringae pv. maculicola causes bacterial spot on Brassicaceae worldwide, and for the last 10 years severe outbreaks have been reported in the Loire Valley, France. P. syringae pv. maculicola resembles P. syringae pv. tomato in that it is also pathogenic for tomato and causes the same types of symptoms. We used a collection of 106 strains of P. syringae to characterize the relationships between P. syringae pv. maculicola and related pathovars, paying special attention to P. syringae pv. tomato. Phylogenetic analysis of gyrB and rpoD gene sequences showed that P. syringae pv. maculicola, which causes diseases in Brassicaceae, forms six genetic lineages within genomospecies 3 of P. syringae strains as defined by L. Gardan et al. (Int. J. Syst. Bacteriol. 49[Pt 2]:469-478, 1999), whereas P. syringae pv. tomato forms two distinct genetic lineages. A multilocus variable-number tandem-repeat (VNTR) analysis (MLVA) conducted with eight minisatellite loci confirmed the genetic structure obtained with rpoD and gyrB sequence analyses. These results provide promising tools for fine-scale epidemiological studies on diseases caused by P. syringae pv. maculicola and P. syringae pv. tomato. The two pathovars had distinct host ranges; only P. syringae pv. maculicola strains were pathogenic for Brassicaceae. A subpopulation of P. syringae pv. maculicola strains that are pathogenic for Pto-expressing tomato plants were shown to lack avrPto1 and avrPtoB or to contain a disrupted avrPtoB homolog. Taking phylogenetic and pathological features into account, our data suggest that the DC3000 strain belongs to P. syringae pv. maculicola. This study shows that P. syringae pv. maculicola and P. syringae pv. tomato appear multiclonal, as they did not diverge from a single common ancestral group within the ancestral P. syringae genomospecies 3, and suggests that pathovar specificity within P. syringae may be due to independent genetic events.     

Whole-genome sequence analysis of Pseudomonas syringae pv. phaseolicola 1448A reveals divergence among pathovars in genes involved in virulence and transposition

Pseudomonas syringae pv. phaseolicola, a gram-negative bacterial plant pathogen, is the causal agent of halo blight of bean. In this study, we report on the genome sequence of P. syringae pv. phaseolicola isolate 1448A, which encodes 5,353 open reading frames (ORFs) on one circular chromosome (5,928,787 bp) and two plasmids (131,950 bp and 51,711 bp). Comparative analyses with a phylogenetically divergent pathovar, P. syringae pv. tomato DC3000, revealed a strong degree of conservation at the gene and genome levels. In total, 4,133 ORFs were identified as putative orthologs in these two pathovars using a reciprocal best-hit method, with 3,941 ORFs present in conserved, syntenic blocks. Although these two pathovars are highly similar at the physiological level, they have distinct host ranges; 1448A causes disease in beans, and DC3000 is pathogenic on tomato and Arabidopsis. Examination of the complement of ORFs encoding virulence, fitness, and survival factors revealed a substantial, but not complete, overlap between these two pathovars. Another distinguishing feature between the two pathovars is their distinctive sets of transposable elements. With access to a fifth complete pseudomonad genome sequence, we were able to identify 3,567 ORFs that likely comprise the core Pseudomonas genome and 365 ORFs that are P. syringae specific.     

Pathovar-specific requirement for the Pseudomonas syringae lemA gene in disease lesion formation.

The lemA gene is conserved among strains and pathovars of Pseudomonas syringae. In P. syringae pv. syringae B728a, a causal agent of bacterial brown spot disese of bean, the lemA gene is required for lesion formation on leaves and pods. Using lemA-containing DNA as a probe, we determined that 80 P. syringae pv. syringae strains isolated from bean leaves could be grouped into seven classes based on restriction fragment length polymorphism. Marker exchange mutagenesis showed that the lemA gene was required for lesion formation by representative strains from each restriction fragment length polymorphism class. Hybridization to the lemA locus was detected within six different P. syringae pathovars and within Pseudomonas aeruginosa. Interestingly, a lemA homolog was present and functional within the nonpathogenic strain P. syringae Cit7. We cloned a lemA homolog from a genomic library of P. syringae pv. phaseolicola NPS3121, a causal agent of halo blight of bean, that restored lesion formation to a P. syringae pv. syringae lemA mutant. However, a lemA mutant P. syringae pv. phaseolicola strain retained the ability to produce halo blight disease symptoms on bean plants. Therefore, the lemA gene played an essential role in disease lesion formation by P. syringae pv. syringae isolates, but was not required for pathogenicity of a P. syringae pv. phaseolicola strain.