Reclassification of Xanthomonas gardneri (ex Sutic 1957) Jones et al. 2006 as a later heterotypic synonym of Xanthomonas cynarae Trébaol et al. 2000 and description of X. cynarae pv. cynarae and X. cynarae pv. gardneri based on whole genome analyses.

Multilocus sequence analysis of Xanthomonas species revealed a very close relationship between Xanthomonas cynarae, an artichoke pathogen and Xanthomonas gardneri, a tomato and pepper pathogen. Results of whole genome sequence comparisons using average nucleotide identity between representative strains of X. gardneri and X. cynarae were well above the threshold of 95-96 %. Inoculations of X. gardneri strains in artichoke leaves caused mild disease symptoms, but only weak symptoms were observed in the bracts. Both X. cynarae and X. gardneri grew equally and caused typical bacterial spot symptoms in pepper after artificial inoculation. However, X. cynarae induced a hypersensitive reaction in tomato, while X. gardneri strains were virulent. Pathogenicity-associated gene clusters, including the protein secretion systems, type III effector profiles, and lipopolysaccharide cluster were nearly identical between the two species. Based on our results from whole genome sequence comparison, X. gardneri and X. cynarae belong to the same species. The name X. cynarae has priority and X. gardneri should be considered as a later heterotypic synonym. An emended description of X. cynarae (type strain=CFBP 4188T, =DSM 16794T) is given. However, due to the host specificity in artichoke and tomato, two pathovars, X. cynarae pv. cynarae and X. cynarae pv. gardneri, are proposed.

A multilocus sequence analysis of Xanthomonas campestris reveals a complex structure within crucifer-attacking pathovars of this species.

Previous classification of Xanthomonas campestris has defined six pathovars (aberrans, armoraciae, barbareae, campestris, incanae, and raphani) that cause diseases on cruciferous plants. However, pathogenicity assays with a range of strains and different hosts identifies only three types of symptom: black rot, leaf spot and bacterial blight. These findings raise the question of the genetic relatedness between strains assigned to different pathovars or symptom phenotypes. Here we have addressed this issue by multilocus sequence analysis of 42 strains. The X. campestris species was polymorphic at the 8 loci analysed and had a high genetic diversity; 23 sequence types were identified of which 16 were unique. All strains that induce black rot (pathovars aberrans and campestris) were genetically close but split in two groups. Only three clonal complexes were found, all within pathovar campestris. The assignment of the genome-sequenced strain 756C to pathovar raphani suggested from disease symptoms was confirmed, although this group of strains was particularly polymorphic. Strains belonging to pathovars barbareae and incanae were closely related, but distinct from pathovar campestris. There is evidence of genetic exchanges of housekeeping genes within this species as deduced from a clear incongruence between individual gene phylogenies and from network structures from SplitsTree analysis. Overall this study showed that the high genetic diversity derived equally from recombination and point mutation accumulation. However, X. campestris remains a species with a clonal evolution driven by a differential adaptation to cruciferous hosts.

Polyphasic classification of the genus Photorhabdus and proposal of new taxa: P. luminescens subsp. luminescens subsp. nov., P. luminescens subsp. akhurstii subsp. nov., P. luminescens subsp. laumondii subsp. nov., P. temperata sp. nov., P. temperata subsp. temperata subsp. nov. and P. asymbiotica sp. nov.

The taxonomic position of Photorhabdus strains was examined through the results of DNA relatedness (S1 nuclease method) studies associated with the determination of delta Tm, 16S rRNA phylogenetic inferences and phenotypic characterization, including morphological, auxanographic, biochemical and physiological properties. Three genomic species were delineated on a consensus assessment. One of these species corresponded to Photorhabdus luminescens, since strains were at least 50% related to the type strain of this species with delta Tm less than 7 degrees C. The two other species were novel genomic species II and III, which were less than 40% related to each other with delta Tm higher than 9 degrees C. A comparison of the complete 16S rDNA sequences of several representatives of genomic species II and genomic species III revealed that each of them formed a stable lineage independent of the cluster generated by P. luminescens strains. The genomic species differed in their maximum temperatures for growth. A correlation with the ecological origin of the bacterial samples was noticed. The heat-tolerant group I (maximum growth temperature 35-39 degrees C) corresponded to the symbionts of Heterorhabditis bacteriophora groups Brecon and HP88 and Heterorhabditis indica, nematodes living in warm and tropical countries, respectively. Group II (maximum growth temperature 33-35 degrees C) encompassed symbionts from Heterorhabditis megidis, Heterorhabditis zealandica and group NC1 of H. bacteriophora, nematodes isolated in temperate climates. Group III were bacteria isolated from human specimens. Two new species, Photorhabdus temperata sp. nov. (type strain CIP 105563T) and Photorhabdus asymbiotica sp. nov. (type strain ATCC 43950T), are proposed for genomic species II and III, respectively. Species I and II can be separated into sub-groups on the basis of high DNA-DNA relatedness (more than 80% DNA binding with delta Tm < 1.5 degrees C), 16S rDNA branching and phenotypic characters. Therefore, we propose that the two species P. luminescens and P. temperata should be subdivided into subspecies as follows: P. luminescens subsp. luminescens subsp. nov. (type strain ATCC 29999T), P. luminescens subsp. akhurstii subsp. nov. (type strain CIP 105564T), P. luminescens subsp. laumondii subsp. nov. (type strain CIP 105565T) and P. temperata subsp. temperata subsp. nov.

Gnotobiological study of infective juveniles and symbionts of Steinernema scapterisci: A model to clarify the concept of the natural occurrence of monoxenic associations in entomopathogenic nematodes.

Gnotobiology of Steinernema scapterisci and bacteriological study of its symbiont confirmed that this nematode harbors a symbiotic species of Xenorhabdus, as do other Steinermena species. Based on phenotypic and 16S rDNA data, this Xenorhabdus strain UY61 could be distinguished from other Xenorhabdus species. Bacteria reported previously as being associated with this nematode and belonging to several other genera were probably contaminating bacteria located in the intercuticular space of the infective juveniles (IJs). These bacteria were detrimental to nematode reproduction in Galleria mellonella. Axenic S. scapterisci and its symbiont Xenorhabdus strain UY61 alone were not pathogenic to G. mellonella. The combination of both partners reestablished the pathogenicity of the complex toward G. mellonella. This combination also gave the best yields of IJs when produced in this insect and in vitro production on artificial diet.

PCR-ribotyping of Xenorhabdus and Photorhabdus isolates from the Caribbean region in relation to the taxonomy and geographic distribution of their nematode hosts.

The genetic diversity of symbiotic Xenorhabdus and Photorhabdus bacteria associated with entomopathogenic nematodes was examined by a restriction fragment length polymorphism analysis of PCR-amplified 16S rRNA genes (rDNAs). A total of 117 strains were studied, most of which were isolated from the Caribbean basin after an exhaustive soil sampling. The collection consisted of 77 isolates recovered from entomopathogenic nematodes in 14 Caribbean islands and of 40 reference strains belonging to Xenorhabdus and Photorhabdus spp. collected at various localities worldwide. Thirty distinctive 16S rDNA genotypes were identified, and cluster analysis was used to distinguish the genus Xenorhabdus from the genus Photorhabdus. The genus Xenorhabdus appears more diverse than the genus Photorhabdus, and for both genera the bacterial genotype diversity is in congruence with the host-nematode taxonomy. The occurrence of symbiotic bacterial genotypes was related to the ecological distribution of host nematodes.