Yuichi Takikawa

The hrpZ and hrpA genes are variable, and useful for grouping Pseudomonas syringae bacteria

The hrpS to hrpB regions from strains of Pseudomonas syringae were amplified by polymerase chain reaction (PCR) and the DNA sequence determined. The order of hrpS, hrpA, hrpZ, and hrpB was consistent among P. syringae strains. The sequence of hrpS was highly conserved. In a cluster analysis with the hrpS sequence, P. syringae strains were divided into four groups (I, II, III, and IV) and one undetermined strain, in agreement with previous studies. In contrast, the hrpZ sequences contained insertions, deletions, and base substitutions followed by changes in amino acids. Based on cluster analysis of hrpA, hrpZ, and hrpB, P. syringae strains could be divided into five groups. One of the four groups (group I) in the cluster analysis of hrpS could be further divided into two subgroups (groups IA and IB). Groups II, III, and IV were the same in the two analyses. Group-specific primers were designed, based on the DNA sequences of hrpZ, that could differentiate the groups of P. syringae strains.

Identification of Non-Pathogenic Xanthomonas Strains Associated with Plants

Summary A total of 70 presumptive non-pathogenic yellow-pigmented strains from different origins were identified to the genus Xanthomonas with the genus-specific monoclonal antibodies (XI and XII), and fatty acid methyl ester (FAME) and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) protein databases. On the basis of FAME profiles and SDS-PAGE protein patterns, these non-pathogenic xanth- omonads formed a heterogeneous population. Fourty-two strains were identified as the same species by both methods, whereas five strains were identified as different species. Only eight strains remained unidentified by both methods, whereas in 15 cases the identification was ambiguous. The identification at pathovar level was usually ambiguous and not concordant, which indicated that the non-pathogenic xanthomonads cannot be classified in the described pathovars. None of the non-pathogenic xanth- omonads was identified as belonging to the pathovars of the plant from which they were isolated.

Molecular typing of Japanese strains of Ralstonia solanacearum in relation to the ability to induce a hypersensitive reaction in tobacco

The genetic diversity of 120 Ralstonia solanacearum strains isolated from a variety of host plants across Japan was assessed on the basis of hypersensitive response (HR) in tobacco leaves and phylogenetic analyses of endoglucanase gene egl, hrpB, and gyrB. Phylogenetic analysis of egl revealed that only three strains belonged to phylotype IV, and 117 strains belonged to phylotype I. Partial sequences of HrpB were identical among phylotype I strains except for one strain. Analyses using the partial nucleotide sequences of the gyrB and egl gene fragments grouped phylotype I strains into 11 gyrB and 8 egl types, respectively, whereas analyses using the partial amino acid sequences of GyrB and Egl grouped phylotype I strains into 4 GyrB and 5 Egl types, respectively. Using multilocus sequence typing of GyrB and Egl, we identified 10 unique sequence types within the Japanese phylotype I strains. Strains belonging to the GyrB42 or GyrB66 type caused wilt in tobacco, and strains belonging to GyrB2 or GyrB9 type elicited HR, demonstrating that HR induction in tobacco is genetically differentiated in the Japanese strains of R. solanacearum.

Internal fruit rot of netted melon caused by Pantoea ananatis (=Erwinia ananas) in Japan

An internal fruit rot with a malodor was found in netted melons (Cucumis melo L.) in commercial greenhouses in Kochi Prefecture, Japan, in 1998, despite their healthy appearance and lack of water-soaking or brown spots on the surface. A yellow bacterium was consistently isolated from the affected fruits. To confirm the pathogenicity of eight representative isolates of the yellow bacterium, we stub-inoculated ovaries (immature-fruits) 5–7 days after artificial pollination, with a pin smeared with bacteria. After the melon fruits had grown for 60 more days, an internal fruit rot resembling the natural infection appeared, and the inoculated bacterium was reisolated. The melon isolates had properties identical with Pantoea ananatis, such as gram-negative staining, facultative anaerobic growth, indole production, phenylalanine deaminase absence, and acid production from melibiose, sorbitol, glycerol, and inositol. Phylogenetic analysis based on 16S rDNA sequences showed that the melon bacterium positioned closely with known P. ananatis strains. The melon bacterium had indole acetic acid (IAA) biosynthesis genes (iaaM and iaaH) and a cytokinin biosynthesis gene (etz). The bacterium could be distinguished from the other ‘Pantoea’ group strains by rep-PCR genomic fingerprinting. From these results, the causal agent of internal fruit rot was identified as a strain of P.ananatis [Serrano in (Philipp J Sci 36:271–305, 1928); Mergaert et al. in (Int J Syst Bacteriol 43:162–173, 1993)].

Occurrence of blood disease of banana in Sumatra, Indonesia

Since 1991, the sudden death of cultivated banana plants has been widely observed in the southern region of Sumatra Island, Indonesia. Wilting from loss of petiole and midrib turgidity, yellowing, and necrosis of leaves was followed by death of the whole plant. Reddish brown bacterial ooze exuded from the cut surface of infected pseudostems and fruits. The colony appearance of the isolated bacterium was similar to that of Ralstonia solanacearum. The bacterium was pathogenic to banana plants but not to tomato. Its bacteriological properties agreed with those of blood disease bacterium (BDB) of banana described previously. The 16S rDNA sequence of strain Banana E had conserved bases characteristic of BDB. Based on these results, the causal agent was identified as BDB, which is a close relative of Ralstonia. The isolates have resistance against antibiotics, such as chloramphenicol and tetracycline.

Pseudomonas syringae Strains Are Classified into Five Groups by Comparing DMA Homology at the hrp Neighboring Regions

Previously, we classified Pseudomonas syringae strains into at least three groups (I, II and U) by comparing DNA homology at the hrp cluster and its neighboring regions (Inoue and Takikawa 1999). However, heterogeneous strains remained in the undetermined group (group U). We further classify group U, using pvs. syringae and coronafaciens as references. Comparison of restriction sites for regions of each pathovar revealed distinct differences. By using probes from the two pathovars, comparisons of DNA homology at the regions separated two additional distinct groups (III and IV) from group U. Therefore, P. syringae strains are classified into at least five groups.

Occurrence of bacterial rot of onion bulbs caused by Burkholderia cepacia in Japan

In 2001, a bacterial rot of onion (Allium cepa L.) bulbs was observed in Japan. The causal agent was identified as Bukholderia cepacia (Palleroni & Holmes 1981 ex Burhkolder 1950) Yabuuchi, Kosako, Oyaizu, Yano, Hotta, Ezaki, and Arakawa 1993. The identified bacteria were divided into two groups (Y and W) based on colony colors, and several phenotypic and genetic characteristics. Based on recA polymerase chain reaction assays, the strains of the Y and W groups belong to genomovar I (B. cepacia sensu stricto) and genomovar III (B. cenocepacia), respectively.

Bacterial leaf spot of ivy caused by Xanthomonas campestris pv. hederae

A bacterial leaf spot disease was observed on Hedera helix (English ivy) and H. canariensis (Algerian ivy) in Japan. The causal agent was identified as Xanthomonas campestris pv. hederae (Arnaud 1920) Dye 1978.

Phylogenetic study of Japanese Dickeya spp. and development of new rapid identification methods using PCR–RFLP

Forty-one representative Japanese Dickeya spp. (Erwinia chrysanthemi) strains isolated from 24 plants in Japan were investigated using multilocus sequence analysis of recA, dnaX, rpoD, gyrB and 16S rDNA; PCR–RFLP (restriction fragment length polymorphism) of recA, rpoD and gyrB genes; PCR genomic fingerprinting; and biochemical tests. Based on the recA, dnaX, rpoD, gyrB and 16S rDNA sequences and PCR genomic fingerprinting, the strains were essentially divided into six groups (I–VI). Group I corresponded to D. chrysanthemi, group II corresponded to D. dadantii, group III to D. dianthicola and group IV to D. zeae. Meanwhile, group V and group VI could not be assigned to any existing Dickeya species, and they were deduced to be two putative new species. The PCR–RFLP analysis of gyrB, rpoD and recA clearly differentiated the six groups of Dickeya strains. From the results of the biochemical tests, the strains were assigned to biovars 1, 3, 5, 8 and 9; only one strain (SUPP 2525) was not assignable to the existing biovars. We also showed that the PCR–RFLP analysis of rpoD, gyrB and recA can be used as a rapid technique to identify Japanese Dickeya strains.

Analysis of the gacS-gacA regulatory genes of spontaneous mutants of Pseudomonas fluorescens biocontrol strain PfG32R

Pseudomonas fluorescens strain PfG32R, a potential biocontrol agent against soilborne pathogens, frequently loses its antifungal activity and ability to produce enzymes. To characterize genetically the instability of these bacterial functions, we analyzed gacS and gacA genes of PfG32R and three spontaneous mutants of PfG32R (NR1, NR9, and ASW6), which had lost their ability to produce proteases and antifungal activities. The gacS and gacA sequences of PfG32R had 77%–89% and 78%–87% homology, respectively, with several known gacS and gacA homologues. All three spontaneous mutants were subjected to complementation analysis. Introduction of clones containing an intact gacS of PfG32R and another P. fluorescens strain Pf-5 as well as strain tea632 of P. syringae pv. theae complemented all three mutants restoring protease and antifungal activities, indicating a mutation in gacS. In sequencing analysis, the mutants had a deletion or change in amino acids in the conserved sensor kinase domains of GacS. The three mutants maintained both their antibacterial activity against Ralstonia solanacearum and Clavibacter michiganensis ssp. michiganensis and siderophore production, indicating that they are not controlled by the GacS/GacA system.