Neoaplectana species: Specificity of association with bacteria of the genus Xenorhabdus

Each of five Neoaplectana (Nematoda: Steinernematidae) species was cultured monoxenically with various Xenorhabdus (Eubacteriales: Enterobacteriaceae) isolates. The nematodes were usually able to reproduce when cultured with the bacterial symbiont of any one of the five Neoaplectana spp. but never with Xenorhabdus luminescens, symbiotic with Heterorhabditis spp., or with the Xenorhabdus sp. isolated from an undescribed steinernematid species. Only Neoaplectana bibionis could be cultured with the Xenorhabdus symbiont of Steinernema kraussei. A high proportion of infectives were able to carry within their intestine X. nematophilus isolated from other strains of the same nematode species; a small proportion of infectives were able to carry X. nematophilus isolated from other nematode species.     

Phase Variation in Xenorhabdus nematophilus and Photorhabdus luminescens: Differences in Respiratory Activity and Membrane Energization

Phase variation in Xenorhabdus and Photorhabdus spp. has a significant impact on their symbiotic relationship with entomopathogenic nematodes by altering the metabolic by-products upon which the nematodes feed. The preferential retention of the phase I variant by the infective-stage nematode and its better support for nematode reproduction than phase II indicates its importance in the bacterial-nematode interactions. However, there is no obvious role for phase II in these interactions. This study has revealed differences in the respiratory activity between the two phases of Xenorhabdus nematophilus A24 and Photorhabdus luminescens Hm. After experiencing periods of starvation, phase II cells recommenced growth within 2 to 4 h from the addition of nutrients, compared with 14 h for phase I cells, indicating a more efficient nutrient uptake ability in the former. The levels of activity of major respiratory enzymes were 15 to 100% higher in phase II cells from stationary cultures in complex media than in phase I cells. Transmembrane proton motive force measurements were also higher by 20% in phase II under the same conditions. The increased membrane potentials reflect upon the ability of the phase II variant to respond to nutrients, both through growth and nutrient uptake. It is postulated that while phase I cells are better adapted to conditions in the insect and the nematode, phase II cells may be better adapted to conditions in soil as free-living organisms.     

Isolation and identification of a symbiotic bacterium fromSteinernema carpocapsae

Xenorhabdus nematophilus sp., an insect-pathogenic bacterium, was newly isolated from Korean entomopathogenic nematode ofSteinernema carpocapsae, which can be used as a useful bioinsecticide. Primary and secondary form variants ofXenorhabdus nematophilus were observed when culturedin vitro. Primary form variants adsorbed bromothymol blue, while secondary form did not. However, many other characters of two variants were very similar. The variants were all rod-shaped and cell size was highly variable ranging from 0.5 by 2.0 μm to 1.0 by 5.0 μm. Both produced highly toxic substances and killed the insect larva within 20–38 hr, indicating that insect pathogenicity ofXenorhabdus is not directly associated with its phase variation. In addition, cell-free culture supernatant ofXenorhabdus was sufficient to kill the insect larva by injecting it into insect hemolymph; however, cell-harboring culture broth was more effective for killing the insect. The use ofXenorhabdus nematophilus may provide a potential alternative toBacillus thuringiensis (Bt) toxins.     

Biochemical and physiological characteristics of Xenorhabdus species,symbiotically associated with entomopathogenic nematodes including Steinernema kushidai and their pathogenicity against Spodoptera litura (Lepidoptera: Noctuidae)

The symbiotic bacterium strain, SK-1 isolated from Steinernema kushidai, a new species of entomopathogenic nematode, was compared with other strains of Xenorhabdus species. Like other Xenorhabdus nematophilus strains, this new strain is gram-negative, facultatively anaerobic, peritrichously flagellated rod and negative for catalase and nitrate reduction. It can be distinguished from the other Xenorhabdus spp. by differences in reactions to phenylalanine deaminase, no acid production from myo-inositol and utilizations of inosine, dl-malate, formate and methanol. Intra-haemocoelic injection of actual cells or liquid culture supernatant into sixth instar larvae of Spodoptera litura for either Phase I or II variants were not pathogenic. Other strains of X. nematophilus showed pathogenicity for whole cell injections. The supernatants of strain D-1 and ATCC 19061, which are symbionts of Steinernema carpocapsae were pathogenic, however pathogenicity decreased and then terminated by increases in temperature.     

Two Distinct Hemolytic Activities in Xenorhabdus nematophila Are Active against Immunocompetent Insect Cells

Xenorhabdus spp. and Photorhabdus spp. are major insect bacterial pathogens symbiotically associated with nematodes. These bacteria are transported by their nematode hosts into the hemocoel of the insect prey, where they proliferate within hemolymph. In this work we report that wild strains belonging to different species of both genera are able to produce hemolysin activity on blood agar plates. Using a hemocyte monolayer bioassay, cytolytic activity against immunocompetent cells from the hemolymph of Spodoptera littoralis (Lepidoptera: Noctuidae) was found only in supernatants of Xenorhabdus; none was detected in supernatants of various strains of Photorhabdus. During in vitro bacterial growth of Xenorhabdus nematophila F1, two successive bursts of cytolytic activity were detected. The first extracellular cytolytic activity occurred when bacterial cells reached the stationary phase. It also displayed a hemolytic activity on sheep red blood cells, and it was heat labile. Among insect hemocyte types, granulocytes were the preferred target. Lysis of hemocytes by necrosis was preceded by a dramatic vacuolization of the cells. In contrast the second burst of cytolytic activity occurred late during stationary phase and caused hemolysis of rabbit red blood cells, and insect plasmatocytes were the preferred target. This second activity is heat resistant and produced shrinkage and necrosis of hemocytes. Insertional inactivation of flhD gene in X. nematophila leads to the loss of hemolysis activity on sheep red blood cells and an attenuated virulence phenotype in S. littoralis (A. Givaudan and A. Lanois, J. Bacteriol. 182:107–115, 2000). This mutant was unable to produce the early cytolytic activity, but it always displayed the late cytolytic effect, preferably active on plasmatocytes. Thus, X. nematophila produced two independent cytolytic activities against different insect cell targets known for their major role in cellular immunity.     

Diversity of Xenorhabdus and Photorhabdus spp. and Their Symbiotic Entomopathogenic Nematodes from Thailand

Xenorhabdus and Photorhabdus spp. are bacterial symbionts of entomopathogenic nematodes (EPNs). In this study, we isolated and characterized Xenorhabdus and Photorhabdus spp. from across Thailand together with their associated nematode symbionts, and characterized their phylogenetic diversity. EPNs were isolated from soil samples using a Galleria-baiting technique. Bacteria from EPNs were cultured and genotyped based on recA sequence. The nematodes were identified based on sequences of 28S rDNA and internal transcribed spacer regions. A total of 795 soil samples were collected from 159 sites in 13 provinces across Thailand. A total of 126 EPNs isolated from samples taken from 10 provinces were positive for Xenorhabdus (n = 69) or Photorhabdus spp. (n = 57). Phylogenetic analysis separated the 69 Xenorhabdus isolates into 4 groups. Groups 1, 2 and 3 consisting of 52, 13 and 1 isolates related to X. stockiae, and group 4 consisting of 3 isolates related to X. miraniensis. The EPN host for isolates related to X. stockiae was S. websteri, and for X. miraniensis was S. khoisanae. The Photorhabdus species were identified as P. luminescens (n = 56) and P. asymbiotica (n = 1). Phylogenenic analysis divided P. luminescens into five groups. Groups 1 and 2 consisted of 45 and 8 isolates defined as subspecies hainanensis and akhurstii, respectively. One isolate was related to hainanensis and akhurstii, two isolates were related to laumondii, and one isolate was the pathogenic species P. asymbiotica subsp. australis. H. indica was the major EPN host for Photorhabdus. This study reveals the genetic diversity of Xenorhabdus and Photorhabdus spp. and describes new associations between EPNs and their bacterial symbionts in Thailand.     

Bacteriocinogenesis in cells of Xenorhabdus nematophilus and Photorhabdus luminescens: Enterobacteriaceae associated with entomopathogenic nematodes

Summary— Xenorhabdus nematophilus FI strain and Photorhabdus luminescens NC19 strain produced bacteriocins after mitomycin C treatment and under natural conditions respectively. The ultrastructure of these two strains was described and compared to the ultrastructure of untreated or normal cells. After image processing of purified bacteriocins we found morphological homology in infected cells with protoplasmic rods in longitudinal section and hexagonal aggregates in transversal section. We concluded that these particular structures, so-called ‘lattice structures’ and previously interpreted as ‘photosomes’, are in fact the early stages of in situ production of bacteriocins in these two bacterial genera. Natural occurrence of Photorhabdus spp bacteriocinogenesis was observed in other strains, while other lysogenic strains of Xenorhabdus spp are lysed after a mitomycin C treatment.     

Proteolytic Enzyme Production by Strains of the Insect Pathogen Xenorhabdus and Characterization of an Early-Log-Phase-Secreted Protease as a Potential Virulence Factor

As a comparison to a similar study on Photorhabdus strains, 15 Xenorhabdus bacterial strains and secondary phenotypic variants of two strains were screened for proteolytic activity by five detection methods. Although the number and intensity of proteolytic activities were different, every strain was positive for proteolytic activity by several tests. Zymography following native PAGE detected two groups of activities with different substrate affinities and a higher and lower electrophoretic mobility that were distinguished as activity 1 and 2, respectively. Zymography following SDS-PAGE resolved three activities, which were provisionally named proteases A, B, and C. Only protease B, an ∼55-kDa enzyme, was produced by every strain. This enzyme exhibited higher affinity to the gelatin substrate than to the casein substrate. Of the chromogenic substrates used, three were hydrolyzed: furylacryloyl-Ala-Leu-Val-Tyr (Fua-ALVY), Fua-LGPA (LGPA is Leu-Gly-Pro-Ala) (a substrate for collagen peptidases), and succinyl-Ala-Ala-Pro-Phe-thiobenzyl (Succ-AAPF-SBzl). All but the Fua-LGPA-ase activity seemed to be from secreted enzymes. According to their substrate preference profiles and inhibitor sensitivities, at least six such proteolytic enzymes could be distinguished in the culture medium of Xenorhabdus strains. The proteolytic enzyme that was secreted the earliest, protease B and the Succ-AAPF-SBzl-hydrolyzing enzyme, appeared from the early logarithmic phase of growth. Protease B could also be detected in the hemolymph of Xenorhabdus-infected Galleria mellonella larvae from 15 h postinfection. The purified protease B hydrolyzed in vitro seven proteins in the hemolymph of Manduca sexta that were also cleaved by PrtA peptidase from Photorhabdus. The N-terminal sequence of protease B showed similarity to a 55-kDa serralysin type metalloprotease in Xenorhabdus nematophila, which had been identified as an orthologue of Photorhabdus PrtA peptidase.Xenorhabdus and Photorhabdus bacteria are highly virulent, fatal pathogens for insects. Phylogenetically, they are sister genera in the family Enterobacteriaceae (3, 4). There are some differences between Xenorhabdus and Photorhabdus in their biology (e.g., light production), and they also differ in their interaction with their symbiotic nematode partners, which are in the Steinernematidae and Heterorhabditidae genera, respectively (8, 9). At the same time, they also have several properties in common. For example, due to their similar strategy of infection, their entrance into the hemocoel is absolutely dependent on the invasion of insects by their symbiotic nematode partners. An interesting feature of both genera is that they have two phenotypic (form) variants, primary and secondary (9). The primary form is natural, while the secondary form can be observed (generated) mostly in the laboratory. They differ in, for example, antibiotic production, outer membrane proteins, and cell surface structures (fimbriae and flagellae [23], symbiotic capabilities with nematode partners, and exoenzyme production [9]). The secondary form variants were found, with nonbiochemical detection methods, to produce less or no proteolytic activity compared to the primary phenotypic variants (see references 9 and 23 and references therein). The high pathogenicity makes Xenorhabdus and Photorhabdus good model organisms of infection, which can be exploited—by studying the function of their virulence factors—for the investigation of the immune system of insects and the mechanisms the pathogens use to cope with the immune defense of hosts. The comparative analysis of these bacterial partners provides an opportunity to study the question of how similar the infection mechanisms can be at the molecular level of two evolutionarily different insect pathogen bacterium-nematode complexes that, at the same time, have similar infection strategies.Of the virulence factors, we have been interested in secreted proteases that may be used by the pathogens during the first stage of infection in the penetration of the tissues of host or in the suppression of its immune response. The secretion and biochemistry of these enzymes are better studied in Photorhabdus, where four secreted proteases could be detected in a screen of 20 strains by a combination of five methods (15). The earliest secreted Photorhabdus protease is PrtA peptidase, a metzincin in the M10B family of serralysins. The others are PhpC (Photorhabdus protease C), which belongs to the M4 metallopeptidase family of thermolysin-like proteases, OpdA, a collagen peptidase in the family of thimet oligopeptidases and PhpD, a furylacryloyl-Ala-Leu-Val-Tyr (Fua-ALVY)-cleaving enzyme, the identity of which is still unknown. In contrast, although a number of Xenorhabdus strains were tested for proteolytic activity with simple bacteriological plate assays (2, 25), only one (Xenorhabdus nematophila) was investigated by a biochemical detection method of protease activities, zymography. Two activities have been found by this method, and one of these activities has been partially characterized (5).As an approach to establish the similarity between Xenorhabdus and Photorhabdus in the mechanism of infection regarding the type and role of proteolytic enzymes, we investigated 15 Xenorhabdus strains for the secretion of proteases employing the same five detection methods that we had previously used for Photorhabdus strains. Two of the strains (Xenorhabdus nematophila AN6 and Xenorhabdus cabanillassii RIO-HU) were represented with their phenotypic variant pairs.     

Suppression of pecan and peach pathogens on different substrates using Xenorhabdus bovienii and Photorhabdus luminescens

Prior research indicated the ability of concentrated metabolites from Xenorhabdus spp. and Photorhabdus spp. to suppress a variety of peach and pecan diseases in vitro, and on detached pecan leaves or terminals. In the current study, our objectives were to (1) determine if bacterial broths (in addition to concentrated metabolites tested previously) have suppressive ability and (2) determine if metabolites or bacterial broths are active in a soil medium. In laboratory studies, two pathogens of pecan (Fusicladium effusum and Phytophthora cactorum) and one peach pathogen (Armillaria tabescens) were tested for susceptibility to Xenorhabdus bovienii (SN) and Photorhabdus luminescens (VS) bacterial broths or concentrated metabolites on three different substrates. Treatments were applied to lesions of F. effusum on terminals to ascertain any suppressive effect on sporulation, to A. tabescens in soil to determine effect on survival of mycelia, and to lesions caused by P. cactorum on pecan leaf surfaces to assess any reduction in lesion development. Acetone (the metabolite solvent), un-inoculated media (tryptic soy broth) and water were included as controls. The X. bovienii metabolite treatment was as efficacious as a commercial fungicide (fenbuconazole) in reducing sporulation of F. effusum on pecan terminals. The P. luminescens metabolite treatment also caused reduced sporulation relative to water and acetone controls but bacterial broths had no effect. In contrast, all bacterial broth and metabolite treatments suppressed lesion growth caused by P. cactorum (measured on detached leaves maintained on agar). However, in soil, only the P. luminescens metabolite treatment was suppressive to A. tabescens (this is the first report of Photorhabdus or Xenorhabdus toxicity to Armillaria spp.). This study provides a basis for further research on the use of Xenorhabdus and Photorhabdus metabolites or bacterial broth for suppression of pecan and peach diseases.     

Suppressive effects of metabolites from Photorhabdus and Xenorhabdus spp. on phytopathogens of peach and pecan

Abstract

Our objective was to determine the suppressive abilities of bacterial metabolites derived from Xenorhabdus and Photorhabdus spp. on Glomerella cingulata, Phomopsis sp., Phytophthora cactorum, and Fusicladosporium effusum, which are fungal or oomycete pathogens of pecan, and Monilinia fructicola, a fungal pathogen of peach. In the first set of in vitro assays, when metabolites were compared based on initial bacterial cell count, X. bovienii (SN) metabolites generally exhibited the greatest suppression of phytopathogens and Xenorhabdus sp. (355) the least with Photorhabdus luminescens (Hb) and Xenorhabdus nematophila (All) being intermediate. In a second set of in vitro assays, in which metabolites were compared at 50 mg per ml acetone, P. luminescens (VS) exhibited greater suppression than P. luminescens (Hb), Photorhabdus sp. (MX4), X. bovienii (SN), and Xenorhabdus sp. (3 – 8b). In in vivo tests, 6 or 12% dilutions of X. bovienii (SN) or P. luminescens (Hb) metabolites caused 90 – 100% suppression of P. cactorum lesions on pecan leaves with only slight phytotoxicity. No phytotoxic effects were observed in detached peach leaves at dilutions up to 25%. Metabolite treatments, derived from X. bovienii (SN) and P. luminescens (Hb), were also tested for suppression of F. effusum sporulation in detached pecan shoots. Reductions in sporulation caused by bacterial metabolites were similar to those following treatment with two chemical fungicides, dodine and fenbuconazole; a third chemical triphenyltin hydroxide had no effect. Further research is warranted to determine if fungal or oomycete incited diseases in pecan and peach can be controlled with metabolites of Xenorhabdus spp. and Photorhabdus spp.     

Genetic and phenotypic characterizations of <Emphasis Type="Italic">Xenorhabdus</Emphasis> species (Enterobacteriales: Enterobacteriaceae) isolated from steinernematid nematodes (Rhabditida: Steinernematidae) in Japan

The bacterial species of the genus Xenorhabdus in the family Enterobacteriaceae have a mutualistic association with steinernematid entomopathogenic nematodes (EPNs), which have been used as biological control agents against soil insect pests. In this study we present the genetic and phenotypic characterizations of the Xenorhabdus species isolated from steinernematid nematodes in Japan. The 18 Japanese Xenorhabdus isolates were classified into five bacterial species based on 16S ribosomal RNA (16S rRNA) gene sequences: Xenorhabdus bovienii, Xenorhabdus hominickii, Xenorhabdus indica, Xenorhabdus ishibashii, and Xenorhabdus japonica. There was no genetic variation between the 16S RNA sequences among the three X. ishibashii isolates, 0–0.1% variation among the five X. hominickii isolates, and 0–0.5% among the eight X. bovienii isolates. Phenotypic characterization demonstrated that representative isolates of the five bacterial species shared common characteristics of the genus Xenorhabdus, and only X. hominickii isolates produced indole. Symbiotic association and co-speciation of Xenorhabdus bacteria with Steinernema nematodes from Japan are discussed.     

Stability and Activities of Antibiotics Produced during Infection of the Insect Galleria mellonella by Two Isolates of Xenorhabdus nematophilus

Xenorhabdus nematophilus subsp. dutki, an entomopathogenic bacterium, is vectored by steinernematid nematodes into insects, where it produces broad-spectrum antibiotics. The use of the nematode-bacterium complex against soil-dwelling pest insects could introduce antibiotics into the soil via the dead insect fragments during the emergence phase of the nematodes. Studies on the stability and activities of these antibiotics produced in the insect Galleria mellonella may contribute to assessing the possible impact of antibiotics on soil bacteria. Two isolates of X. nematophilus subsp. dutki (isolates GI and SFU) produced xenocoumacins 1 and 2 in cadavers of G. mellonella larvae in a 1:1 ratio. Total xenocoumacin 1 and 2 production was 800 ng/200 mg (wet weight) of insect tissue for the GI isolate. Antibiotic activity of water extracts from insects that had been infected with X. nematophilus was stable at 60°C for 1 h and after repeated freeze-thaw cycles. The antibiotic titer of extracts held at 27°C declined by day 10. The spectrum of bacterial species killed by antibiotics produced in insect cadavers varied with the isolate of X. nematophilus. Levels of antibiotic activity were greater in vivo than in tryptic soy broth, which may represent a nutrient effect. The bacterial isolate, culture condition, and presence of nematodes influenced the total antibiotic production in vivo. However, the levels of activity were not correlated with bacterial levels in the different growth environments. Insect cadavers with antibiotic activity transiently lowered the numbers of the bacteria in the soil, the extent of decline varying with the strain of X. nematophilus and the time of sampling.     

Biochemical Characterization and Agglutinating Properties of Xenorhabdus nematophilus F1 Fimbriae

Xenorhabdus spp., entomopathogenic bacteria symbiotically associated with nematodes of the family Steinernematidae, occur spontaneously in two phases. Only the phase I variants of Xenorhabdus nematophilus F1 expressed fimbriae when the bacteria were grown on a solid medium (nutrient agar; 24 and 48 h of growth). These appendages were purified and characterized. They were rigid, with a diameter of 6.4 (plusmn) 0.3 nm, and were composed of 16-kDa pilin subunits. The latter were synthesized and assembled during the first 24 h of growth. Phase II variants of X. nematophilus did not possess fimbriae and apparently did not synthesize pilin. Phase I variants of X. nematophilus have an agglutinating activity with sheep, rabbit, and human erythrocytes and with hemocytes of the insect Galleria mellonella. The purified fimbriae agglutinated sheep and rabbit erythrocytes. The hemagglutination by bacteria and purified fimbriae was mannose resistant and was inhibited by porcine gastric mucin and N-acetyl-lactosamine. The last sugar seems to be a specific inhibitor of hemagglutination by X. nematophilus.     

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.     

Inactivation of a Novel Gene Produces a Phenotypic Variant Cell and Affects the Symbiotic Behavior of Xenorhabdus nematophilus

Xenorhabdus nematophilus is an insect pathogen that lives in a symbiotic association with a specific entomopathogenic nematode. During prolonged culturing, variant cells arise that are deficient in numerous properties. To understand the genetic mechanism underlying variant cell formation, a transposon mutagenesis approach was taken. Three phenotypically similar variant strains of X. nematophilus, each of which contained a single transposon insertion, were isolated. The insertions occurred at different locations in the chromosome. The variant strain, ANV2, was further characterized. It was deficient in several properties, including the ability to produce antibiotics and the stationary-phase-induced outer membrane protein, OpnB. Unlike wild-type cells, ANV2 produced lecithinase. The emergence of ANV2 from the nematode host was delayed relative to the emergence of the parental strain. The transposon in ANV2 had inserted in a gene designated var1, which encodes a novel protein composed of 121 amino acid residues. Complementation analysis confirmed that the pleiotropic phenotype of the ANV2 strain was produced by inactivation of var1. Other variant strains were not complemented by var1. These results indicate that inactivation of a single gene was sufficient to promote variant cell formation in X. nematophilus and that disruption of genetic loci other than var1 can result in the same pleiotropic phenotype.     

Growth and Virulence of Steinernema glaseri Influenced by Different Subspecies of Xenorhabdus nematophilus

Three Xenorhabdus nematophilus subspecies influenced Steinernema glaseri growth profiles and growth rates, but this was not necessarily because of different bacterial growth rates. Virulence of dauer nematodes in larval Galleria mellonella varied with the number of dauers retaining bacteria and the bacterial subspecies. Virulence was least for dauers grown on X. nematophilus subsp. bovienii because of the lack of retained bacteria. Virulence was subsequently restored by culturing these nematodes on X. nematophilus subsp. poinari.     

Xenorhabdus japonicus sp. nov. associated with the nematode Steinernema kushidai

A new species, Xenorhabdus japonicus, is proposed as the bacterial symbiont of Steinernema kushidai isolated from field soil in Shizuoka Prefecture, Japan. Xenorhabdus japonicus could be distinguished phenotypically and genetically from other Xenorhabdus spp. The type strain of the species, SK-1, a Gram-negative, facultative anaerobe and peritrichously flagellated rod, has colonies with primary and secondary forms. The strain can be differentiated from the type strain of Xenorhabdus nematophilus by several characters, including the formation of arginine dehydrolase, phenylalanine deaminase and lysine decarboxylase, the assimilation of inosine and L-proline and acid production from inositol. The major cellular fatty acids are 16:0, cyclo 17:0 and 18:1. The ubiquinone system is Q-8. The G+C content of DNA is 45.9 mol%. The DNA of strain SK-1 has 20 to 58% homology with that of the type strains of other Xenorhabdus spp.Y. Nishimura, A. Hagiwara and T. Suzuki are with the Department of Applied Biological Science, Science University of Tokyo, Noda 278, Japan, and SDS Biotech K.K., Tsukuba Technology Centre, Tsukuba 300-26, Japan     

Txp40, a Ubiquitous Insecticidal Toxin Protein from Xenorhabdus and Photorhabdus Bacteria

Xenorhabdus and Photorhabdus are gram-negative bacteria that produce a range of proteins that are toxic to insects. We recently identified a novel 42-kDa protein from Xenorhabdus nematophila that was lethal to the larvae of insects such as Galleria mellonella and Helicoverpa armigera when it was injected at doses of 30 to 40 ng/g larvae. In the present work, the toxin gene txp40 was identified in another 59 strains of Xenorhabdus and Photorhabdus, indicating that it is both highly conserved and widespread among these bacteria. Recombinant toxin protein was shown to be active against a variety of insect species by direct injection into the larvae of the lepidopteran species G. mellonella, H. armigera, and Plodia interpunctella and the dipteran species Lucilia cuprina. The protein exhibited significant cytotoxicity against two dipteran cell lines and two lepidopteran cell lines but not against a mammalian cell line. Histological data from H. armigera larvae into which the toxin was injected suggested that the primary site of action of the toxin is the midgut, although some damage to the fat body was also observed.     

Swarming and Swimming Changes Concomitant with Phase Variation in Xenorhabdus nematophilus

Xenorhabdus spp., entomopathogenic bacteria symbiotically associated with nematodes of the family Steinernematidae, occur spontaneously in two phases. Phase I, the variant naturally isolated from the infective-stage nematode, provides better conditions than the phase II variant for nematode reproduction. This study has shown that Xenorhabdus phase I variants displayed a swarming motility when they were grown on a suitable solid medium (0.6 to 1.2% agar). Whereas most of the phase I variants from different Xenorhabdus spp. were able to undergo cycle of rapid and coordinately population migration over the surface, phase II variants were unable to swarm and even to swim in semisolid agar, particularly in X. nematophilus. Optical and electron microscopic observations showed nonmotile cells with phase II variants of X. nematophilus F1 which lost their flagella. Flagellar filaments from strain F1 phase I variants were purified, and the molecular mass of the flagellar structural subunit was estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis to be 36.5 kDa. Flagellin from cellular extracts or culture medium of phase II was undetectable with antiserum against the denatured flagellin by immunoblotting analysis. This suggests that the lack of flagella in phase II cells is due to a defect during flagellin synthesis. The importance of such a difference of motility between both phases is discussed in regard to adaptation of these bacteria to the insect prey and the nematode host.     

Entomopathogenic symbiotic bacteria,Xenorhabdus and Photorhabdus of nematodes

Xenorhabdus and Photorhabdus species are entomopathogenic bacteria with a wide insect host range, that belong to the family Enterobacteriaceae. Xenorhabdus and Photorhabdus species symbiotically associate with nematodes of the families Steinernematidae and Heterorhabditidae respectively. The factor(s) determining the symbiotic interaction between nematodes and bacteria are yet to be identified. Xenorhabdus and Photorhabdus species exist in two main phenotypic forms, a phenomenon known as phase variation. The phase I (or primary form) varies from phase II (or secondary form) in certain physiological and morphological characteristics. There is no variation in the DNA integrity of phase I and phase II and this supports epigenetic regulatory mechanism in phase variation. Certain pathogenic determinants such as pili, lipopolysaccharides and toxins contribute to the pathogenicity of Xenorhabdus and Photorhabdus species, and both appear to be equally pathogenic to insects. The observed similarity in their virulence to insect hosts may reflect possible in vivo conversion of phase II to phase I, however the host cellular invasion and virulence is yet to be properly understood. The virulence of Xenorhabdus variants varies among insects apparently due to factors which include the feeding habits of the insects. The molecular mechanism and biological significance of phase variation are presently unknown.