Genetic Differences between Blight-Causing Erwinia Species with Differing Host Specificities, Identified by Suppression Subtractive Hybridization

PCR-based subtractive hybridization was used to isolate sequences from Erwinia amylovora strain Ea110, which is pathogenic on apples and pears, that were not present in three closely related strains with differing host specificities: E. amylovora MR1, which is pathogenic only on Rubus spp.; Erwinia pyrifoliae Ep1/96, the causal agent of shoot blight of Asian pears; and Erwinia sp. strain Ejp556, the causal agent of bacterial shoot blight of pear in Japan. In total, six subtractive libraries were constructed and analyzed. Recovered sequences included type III secretion components, hypothetical membrane proteins, and ATP-binding proteins. In addition, we identified an Ea110-specific sequence with homology to a type III secretion apparatus component of the insect endosymbiont Sodalis glossinidius, as well as an Ep1/96-specific sequence with homology to the Yersinia pestis effector protein tyrosine phosphatase YopH.     

Relatedness of chromosomal and plasmid DNAs of Erwinia pyrifoliae and Erwinia amylovora

The plant pathogen Erwinia pyrifoliae has been classified as a separate species from Erwinia amylovora based in part on differences in molecular properties. In this study, these and other molecular properties were examined for E. pyrifoliae and for additional strains of E. amylovora, including strains from brambles (Rubus spp.). The nucleotide composition of the internal transcribed spacer (ITS) region was determined for six of the seven 16S-23S rRNA operons detected in these species with a 16S rRNA gene probe. Each species contained four operons with a tRNA(Glu) gene and two with tRNA(Ile) and tRNA(Ala) genes, and analysis of the operons from five strains of E. amylovora indicated a high degree of ITS variability among them. One tRNA(Glu)-containing operon from E. pyrifoliae Ep1/96 was identical to one in E. amylovora Ea110, but three tRNA(Glu) operons and two tRNA(Ile) and tRNA(Ala) operons from E. pyrifoliae contained unique nucleotide changes. When groEL sequences were used for species-specific identification, E. pyrifoliae and E. amylovora were the closest phylogenetic relatives among a set of 12 bacterial species. The placement of E. pyrifoliae distinct from E. amylovora corroborated molecular hybridization data indicating low DNA-DNA similarity between them. Determination of the nucleotide sequence of plasmid pEP36 from E. pyrifoliae Ep1/96 revealed a number of presumptive genes that matched genes previously found in pEA29 from E. amylovora and similar organization for the genes and origins of replication. Also, pEP36 and pEA29 were incompatible with clones containing the reciprocal origin regions. Finally, the ColE1-like plasmid pEP2.6 from strain Ep1/96 contained sequences found in small plasmids in E. amylovora strains IL-5 and IH3-1.     

Analyses of the secretomes of Erwinia amylovora and selected hrp mutants reveal novel type III secreted proteins and an effect of HrpJ on extracellular harpin levels

Erwinia amylovora is a plant pathogenic enterobacterium that causes fire blight disease of apple, pear and other rosaceous plants. A type III (T3) secretion system, encoded by clustered, chromosomal hrp genes (hypersensitive response and pathogenicity), is essential for infection, but only a few proteins are known that are secreted through this pathway (the T3 'secretome'). We developed an efficient protocol for purification and concentration of extracellular proteins and used it to characterize the T3 secretome of E. amylovora Ea273 by comparing preparations from the wild-type strain with those from mutants defective in hrp secretion, regulation, or in genes encoding putative T3-secreted proteins. Proteins were resolved by gel electrophoresis and identified using mass spectrometry and a draft sequence of the E. amylovora genome. Twelve T3-secreted proteins were identified, including homologues of known effector and helper proteins, and HrpJ, a homologue of YopN of Yersinia pestis . Several previously uncharacterized T3-secreted proteins were designated as Eops for Erwinia outer proteins. Analysis of the secretome of a non-polar hrpJ mutant demonstrated that HrpJ is required for accumulation of wild-type levels of secreted harpins. HrpJ was found to be essential for pathogenesis, and to play a major role in elicitation of the hypersensitive reaction in tobacco.     

HrpN of Erwinia amylovora functions in the translocation of DspA/E into plant cells

The type III secretion system (T3SS) is required by plant pathogenic bacteria for the translocation of certain bacterial proteins to the cytoplasm of plant cells or secretion of some proteins to the apoplast. The T3SS of Erwinia amylovora, which causes fire blight of pear, apple and other rosaceous plants, secretes DspA/E, which is an indispensable pathogenicity factor. Several other proteins, including HrpN, a critical virulence factor, are also secreted by the T3SS. Using a CyaA reporter system, we demonstrated that DspA/E is translocated into the cells of Nicotiana tabacum'Xanthi'. To determine if other T3-secreted proteins are needed for translocation of DspA/E, we examined its translocation in several mutants of E. amylovora strain Ea321. DspA/E was translocated by both hrpW and hrpK mutants, although with some delay, indicating that these two proteins are dispensable in the translocation of DspA/E. Remarkably, translocation of DspA/E was essentially abolished in both hrpN and hrpJ mutants; however, secretion of DspA/E into medium was not affected in any of the mentioned mutants. In contrast to the more virulent strain Ea273, secretion of HrpN was abolished in a hrpJ mutant of strain Ea321. In addition, HrpN was weakly translocated into plant cytoplasm. These results suggest that HrpN plays a significant role in the translocation of DspA/E, and HrpJ affects the translocation of DspA/E by affecting secretion or stability of HrpN. Taken together, these results explain the critical importance of HrpN and HrpJ to the development of fire blight.     

HopX1 in Erwinia amylovora functions as an avirulence protein in apple and is regulated by HrpL

Fire blight is a devastating disease of rosaceous plants caused by the Gram-negative bacterium Erwinia amylovora. This pathogen delivers virulence proteins into host cells utilizing the type III secretion system (T3SS). Expression of the T3SS and of translocated and secreted substrates is activated by the alternative sigma factor HrpL, which recognizes hrp box promoters upstream of regulated genes. A collection of hidden Markov model (HMM) profiles was used to identify putative hrp boxes in the genome sequence of Ea273, a highly virulent strain of E. amylovora. Among potential virulence factors preceded by putative hrp boxes, two genes previously known as Eop3 and Eop2 were characterized. The presence of functionally active hrp boxes upstream of these two genes was confirmed by β-glucuronidase (GUS) assays. Deletion mutants of the latter candidate genes, renamed hopX1(Ea) and hopAK1(Ea), respectively, did not differ in virulence from the wild-type strain when assayed in pear fruit and apple shoots. The hopX1(Ea) deletion mutant of Ea273, complemented with a plasmid overexpressing hopX1(E)(a), suppressed the development of the hypersensitivity response (HR) when inoculated into Nicotiana benthamiana; however, it contributed to HR in Nicotiana tabacum and significantly reduced the progress of disease in apple shoots, suggesting that HopX1(Ea) may act as an avirulence protein in apple shoots.     

Modulation of defense responses of Malus spp. during compatible and incompatible interactions with Erwinia amylovora

Erwinia amylovora is the causal agent of fire blight, a disease affecting members of subfamily Maloideae. In order to analyze mechanisms leading to compatible or incompatible interactions, early plant molecular events were investigated in two genotypes of Malus with contrasting susceptibility to fire blight, after confrontation with either E. amylovora or the incompatible tobacco pathogen Pseudomonas syringae pv. tabaci. Many defense mechanisms, including generation of an oxidative burst and accumulation of pathogenesis-related proteins, were elicited in both resistant and susceptible genotypes by the two pathogens at similar rates and according to an equivalent time course. This elicitation was linked with the functional hypersensitive reaction and pathogenicity (hrp) cluster of E. amylovora, because an hrp secretion mutant did not induce such responses. However, a delayed induction of several genes of various branch pathways of the phenylpropanoid metabolism was recorded in tissues of the susceptible genotype challenged with the wild-type strain of E. amylovora, whereas these genes were quickly induced in every other plant-bacteria interaction, including interactions with the hrp secretion mutant. This suggests the existence of hrp-independent elicitors of defense in the fire blight pathogen as well as hrp-dependant mechanisms of suppression of these nonspecific inductions.     

Complete genome sequence of Japanese erwinia strain ejp617, a bacterial shoot blight pathogen of pear

The Japanese Erwinia strain Ejp617 is a plant pathogen that causes bacterial shoot blight of pear in Japan. Here, we report the complete genome sequence of strain Ejp617 isolated from Nashi pears in Japan to provide further valuable insight among related Erwinia species.     

Genes of Erwinia amylovora involved in yellow color formation and release of a low-molecular-weight compound during growth in the presence of copper ions

Most Erwinia amylovora strains form yellow mucoid colonies on solid minimal medium containing asparagine and copper sulfate (MM2Cu). One exception is the strain Ea25/82, which produces white colonies on MM2Cu agar. This strain was transformed with a genomic library of E. amylovora and yellow colonies were recovered. A 1.5-kb fragment was found to complement strain Ea25/82 for color formation, and subsequent sequencing revealed two ORFs. The smaller ORF132(ycfB) overlapped with the end of the larger ORF253(ycfA). The putative protein YcfA shows low homology with K+/Na+ channel transporter ATPases. Resistance genes were inserted in both ORFs, and the E. amylovora strains Ea1/79-YA and Ea1/79-YB were created by site-directed mutagenesis. The mutation in ycfB did not affect color formation, whereas the ycfA mutant formed white colonies on MM2Cu. Sequence analysis of the ycf region in strain Ea25/82 revealed a 1-bp alteration in ycfA and no change in ycfB. Stable complementation of Ea25/82 and Ea1/79-YA, however, required both genes. Carotenoids were not detected in E. amylovora grown in the presence of copper ions. On the other hand, copper-independent secretion of a low-molecular-weight compound with an absorption maximum at 340 nm (CP340) was found for strain Ea1/79, but not for Ea25/82 or the mutant Ea1/79-YA. CP340 formed a complex with copper ions, and complementation with plasmids carrying both ycfA and ycfB restored its release from mutant strains. The compound may be connected with the yellow pigment or function in sensing bacterial population densities.     

Characterization of serracin P,a phage-tail-like bacteriocin,and its activity against Erwinia amylovora,the fire blight pathogen

Serratia plymithicum J7 culture supernatant displayed activity against many pathogenic strains of Erwinia amylovora, the causal agent of the most serious bacterial disease of apple and pear trees, fire blight, and against Klebsiella pneumoniae, Serratia liquefaciens, Serratia marcescens, and Pseudomonas fluorescens. This activity increased significantly upon induction with mitomycin C. A phage-tail-like bacteriocin, named serracin P, was purified from an induced culture supernatant of S. plymithicum J7. It was found to be the only compound involved in the antibacterial activity against sensitive strains. The N-terminal amino acid sequence analysis of the two major subunits (23 and 43 kDa) of serracin P revealed high homology with the Fels-2 prophage of Salmonella enterica, the coliphages P2 and 168, the phiCTX prophage of Pseudomonas aeruginosa, and a prophage of Yersinia pestis. This strongly suggests a common ancestry for serracin P and these bacteriophages.     

Complete genome sequences of three Erwinia amylovora phages isolated in north america and a bacteriophage induced from an Erwinia tasmaniensis strain

Fire blight, a plant disease of economic importance caused by Erwinia amylovora, may be controlled by the application of bacteriophages. Here, we provide the complete genome sequences and the annotation of three E. amylovora-specific phages isolated in North America and genomic information about a bacteriophage induced by mitomycin C treatment of an Erwinia tasmaniensis strain that is antagonistic for E. amylovora. The American phages resemble two already-described viral genomes, whereas the E. tasmaniensis phage displays a singular genomic sequence in BLAST searches.     

Isolation and characterization of five Erwinia amylovora bacteriophages and assessment of phage resistance in strains of Erwinia amylovora

Phages able to infect the fire blight pathogen Erwinia amylovora were isolated from apple, pear, and raspberry tissues and from soil samples collected at sites displaying fire blight symptoms. Among a collection of 50 phage isolates, 5 distinct phages, including relatives of the previously described phages phiEa1 and phiEa7 and 3 novel phages named phiEa100, phiEa125, and phiEa116C, were identified based on differences in genome size and restriction fragment pattern. phiEa1, the phage distributed most widely, had an approximately 46-kb genome which exhibited some restriction site variability between isolates. Phages phiEa100, phiEa7, and phiEa125 each had genomes of approximately 35 kb and could be distinguished by their EcoRI restriction fragment patterns. phiEa116C contained an approximately 75-kb genome. phiEa1, phiEa7, phiEa100, phiEa125, and phiEa116C were able to infect 39, 36, 16, 20, and 40, respectively, of 40 E. amylovora strains isolated from apple orchards in Michigan and 8, 12, 10, 10, and 12, respectively, of 12 E. amylovora strains isolated from raspberry fields (Rubus spp.) in Michigan. Only 22 of 52 strains were sensitive to all five phages, and 23 strains exhibited resistance to more than one phage. phiEa116C was more effective than the other phages at lysing E. amylovora strain Ea110 in liquid culture, reducing the final titer of Ea110 by >95% when added at a ratio of 1 PFU per 10 CFU and by 58 to 90% at 1 PFU per 10(5) CFU.     

First Report of Erwinia amylovora Fire Blight in Belarus

Erwinia amylovora is a phytopathogenic bacterium that causes fire blight, an economically important disease of Rosaceae . Several isolates from pears and apples with fire blight symptoms from Belarus were identified as E. amylovora . All tested isolates were yellow and mucoid on MM2Cu medium, positive in levan production and showed pathogenicity in immature pear fruits. These isolates have identical total protein patterns with E. amylovora 1/79. The PCR with specific primers for E. amylovora harpin gene also gave positive results.     

Expression of lysozymes from Erwinia amylovora phages and Erwinia genomes and inhibition by a bacterial protein

Genes coding for lysozyme-inhibiting proteins (Ivy) were cloned from the chromosomes of the plant pathogens Erwinia amylovora and Erwinia pyrifoliae. The product interfered not only with activity of hen egg white lysozyme, but also with an enzyme from E. amylovora phage ΦEa1h. We have expressed lysozyme genes from the genomes of three Erwinia species in Escherichia coli. The lysozymes expressed from genes of the E. amylovora phages ΦEa104 and ΦEa116, Erwinia chromosomes and Arabidopsis thaliana were not affected by Ivy. The enzyme from bacteriophage ΦEa1h was fused at the N- or C-terminus to other peptides. Compared to the intact lysozyme, a His-tag reduced its lytic activity about 10-fold and larger fusion proteins abolished activity completely. Specific protease cleavage restored lysozyme activity of a GST-fusion. The bacteriophage-encoded lysozymes were more active than the enzymes from bacterial chromosomes. Viral lyz genes were inserted into a broad-host range vector, and transfer to E. amylovora inhibited cell growth. Inserted in the yeast Pichia pastoris, the ΦEa1h-lysozyme was secreted and also inhibited by Ivy. Here we describe expression of unrelated cloned 'silent' lyz genes from Erwinia chromosomes and a novel interference of bacterial Ivy proteins with a viral lysozyme.     

The genome of Erwinia tasmaniensis strain Et1/99, a non-pathogenic bacterium in the genus Erwinia

The complete genome of the bacterium Erwinia tasmaniensis strain Et1/99 consisting of a 3.9 Mb circular chromosome and five plasmids was sequenced . Strain Et1/99 represents an epiphytic plant bacterium related to Erwinia amylovora and E. pyrifoliae , which are responsible for the important plant diseases fire blight and Asian pear shoot blight, respectively. Strain Et1/99 is a non-pathogenic bacterium and is thought to compete with these and other bacteria when occupying the same habitat during initial colonization. Genome analysis revealed tools for colonization, cellular communication and defence modulation, as well as genes coding for the synthesis of levan and a not detected capsular exopolysaccharide. Strain Et1/99 may secrete indole-3-acetic acid to increase availability of nutrients provided on plant surfaces. These nutrients are subsequently accessed and metabolized. Secretion systems include the hypersensitive response type III pathway present in many pathogens. Differences or missing parts within the virulence-related factors distinguish strain Et1/99 from pathogens such as Pectobacterium atrosepticum and the related Erwinia spp. Strain Et1/99 completely lacks the sorbitol operon, which may also affect its inability to invade fire blight host plants. Erwinia amylovora in contrast depends for virulence on utilization of sorbitol, the dominant carbohydrate in rosaceous plants. The presence of other virulence-associated factors in strain Et1/99 indicates the ancestral genomic background of many plant-associated bacteria.     

Mechanisms of inhibition of Erwinia amylovora by Erw. herbicola in vitro and in vivo

The mechanisms by which Erwinia herbicola inhibits Erwinia amylovora , the fire blight pathogen, were investigated. The optimum pH for growth of Erw. amylovora strain Ea273 in nutrient-yeast extract-glucose broth (NYGB) was 7.0 and growth was markedly reduced at pH values below 6.0. In contrast, the growth rates of Erw. herbicola strains Eh141 and Eh112Y were only slightly reduced at pH levels as low as 4.5, relative to pH 6-8. When Ea273 was grown in NYGB in the presence of Eh141 or Eh112Y, the media became acidic and lower populations of Ea273 were recovered, compared with populations from buffered NYGB. Acidification of plant tissue as a consequence of growth of Erw. herbicola did not occur, however, and thus acid-based inhibition of growth in planta is unlikely. The growth rates of nine strains of Erw. herbicola and their abilities to reduce the pH of NYGB did not correlate with their different abilities to prevent development of fire blight incited by Ea273 in a research apple orchard. When grown in mixed culture, Eh114 and Eh112Y grew to higher populations than Ea273 due to depletion of a nitrogen source needed by Ea273. The ability of 12 strains of Erw. herbicola to produce antibiotics inhibitory to Ea273 on a glucose-asparagine medium correlated with the effectiveness of the strains in suppressing fire blight. A crude preparation of the Eh318 antibiotic delayed development of disease in immature pear fruits incited by Ea273 but not by strain Ea273R318, which is resistant in vitro to the Eh318 antibiotic. Cells of Eh318 protected immature pear fruits more effectively from infection by Ea273 than from the resistant strain Ea273R318.     

Role of antibiotic production by Erwinia herbicola Eh252 in biological control of Erwinia amylovora.

Erwinia herbicola Eh252 is a nonpathogenic epiphytic bacterium that reduces fire blight incidence when sprayed onto apple blossoms before inoculation with Erwinia amylovora, the causal agent of fire blight. Eh252 was found to produce on minimal medium an antibiotic that inhibited the growth of E. amylovora. This antibiotic was inactivated by histidine but not by Fe(II), was sensitive to proteolytic enzymes, and showed a narrow host range of activity. To determine the role of this antibiotic in the control of fire blight, two prototrophic Tn5-induced mutants, 10:12 and 17:12, that had lost their ability to inhibit E. amylovora on plates (Ant- mutants) were compared with the wild-type strain for their ability to suppress fire blight in immature pear fruits. The two mutants had single Tn5 insertions in the chromosome; although they grew in immature pear fruits at a rate similar to that of the wild-type strain, neither of these mutants suppressed fire blight as well as Eh252 did. The Tn5-containing fragment isolated from 10:12 was used to mutagenize Eh252 by marker exchange. Derivatives that acquired the Tn5-containing fragment by homologous recombination lost the ability to inhibit E. amylovora on minimal medium. Furthermore, the three Ant- derivatives tested were also affected in their ability to inhibit E. amylovora in immature pear fruits. The results obtained suggest that antibiotic production is a determinant of the biological control of E. amylovora by Eh252, but that another mechanism(s) is involved.     

DspA/E, a type III effector essential for Erwinia amylovora pathogenicity and growth in planta, induces cell death in host apple and nonhost tobacco plants

Erwinia amylovora is responsible for fire blight, a necrotic disease of apples and pears. E. amylovora relies on a type III secretion system (TTSS) to induce disease on hosts and hypersensitive response (HR) on nonhost plants. The DspA/E protein is essential for E. amylovora pathogenicity and is secreted via the TTSS in vitro. DspA/E belongs to a type III effector family that is conserved in several phytopathogenic bacteria. In E. amylovora, DspA/E has been implicated in the generation of an oxidative stress during disease and the suppression of callose deposition. We investigated the fate of DspA/E in planta. DspA/E delivered artificially to apple or tobacco cells by agroinfection induced necrotic symptoms, indicating that DspA/E was probably injected via the TTSS. We confirmed that DspA/E acts as a major cell-death inducer during disease and HR, because the dspA/E mutant is severely impaired in its ability to induce electrolyte leakage in apple and tobacco leaves. Expression of the defense marker gene PR1 was delayed when dspA/E was transiently expressed in tobacco, suggesting that DspA/E-mediated necrosis may be associated with an alteration of defense responses.     

Identification of Erwinia amylovora genes induced during infection of immature pear tissue

The enterobacterium Erwinia amylovora is a devastating plant pathogen causing necrotrophic fire blight disease of apple, pear, and other rosaceous plants. In this study, we used a modified in vivo expression technology system to identify E. amylovora genes that are activated during infection of immature pear tissue, a process that requires the major pathogenicity factors of this organism. We identified 394 unique pear fruit-induced (pfi) genes on the basis of sequence similarity to known genes and separated them into nine putative function groups including host-microbe interactions (3.8%), stress response (5.3%), regulation (11.9%), cell surface (8.9%), transport (13.5%), mobile elements (1.0%), metabolism (20.3%), nutrient acquisition and synthesis (15.5%), and unknown or hypothetical proteins (19.8%). Known virulence genes, including hrp/hrc components of the type III secretion system, the major effector gene dspE, type II secretion, levansucrase (lsc), and regulators of levansucrase and amylovoran biosynthesis, were upregulated during pear tissue infection. Known virulence factors previously identified in E. (Pectobacterium) carotovora and Pseudomonas syringae were identified for the first time in E. amylovora and included HecA hemagglutinin family adhesion, Peh polygalacturonase, new effector HopPtoC(EA), and membrane-bound lytic murein transglycosylase MltE(EA). An insertional mutation within hopPtoC(EA) did not result in reduced virulence; however, an mltE(EA) knockout mutant was reduced in virulence and growth in immature pears. This study suggests that E. amylovora utilizes a variety of strategies during plant infection and to overcome the stressful and poor nutritional environment of its plant hosts.