Pyrimidine nucleoside salvage confers an advantage to Xenorhabdus nematophila in its host interactions

Xenorhabdus nematophila is a mutualist of entomopathogenic nematodes and a pathogen of insects. To begin to examine the role of pyrimidine salvage in nutrient exchange between X. nematophila and its hosts, we identified and mutated an X. nematophila tdk homologue. X. nematophila tdk mutant strains had reduced virulence toward Manduca sexta insects and a competitive defect for nematode colonization in plate-based assays. Provision of a wild-type tdk allele in trans corrected the defects of the mutant strain. As in Escherichia coli, X. nematophila tdk encodes a deoxythymidine kinase, which converts salvaged deoxythymidine and deoxyuridine nucleosides to their respective nucleotide forms. Thus, nucleoside salvage may confer a competitive advantage to X. nematophila in the nematode intestine and be important for normal entomopathogenicity.     

An encoded N-terminal extension results in low levels of heterologous protein production in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Background  

The tdk gene (encoding deoxythymidine kinase) of the gamma-proteobacterium Xenorhabdus nematophila has two potential translation start sites. The promoter-distal start site was predicted to be functional based on amino acid sequence alignment with closely related Tdk proteins. However, to experimentally determine if either of the two possible start codons allows production of a functional Tdk, we expressed the "long-form" (using the promoter-proximal start codon) and "short-form" (using the promoter-distal start codon) X. nematophila tdk genes from the T7 promoter of the pET-28a(+) vector. We assessed Tdk production and activity using a functional assay in an Escherichia coli tdk mutant, which, since it lacks functional Tdk, is able to grow in 5-fluorodeoxyuridine (FUdR)-containing medium.     

Iron contributes to the antibacterial functions of the haemolymph of Galleria mellonella

Studies with Galleria mellonella larvae and the iron chelating agent EDDA showed that iron was essential for the removal of dead Xenorhabdas nematophila and Bacillus subtilis from the haemolymph. The delay in removal of the bacteria from the iron-restricted haemolymph was attributed to reduced adhesiveness of the haemocytes and prophenoloxidase activity. Iron augmentation returned these activities to control levels. Whereas dead B. subtilis had no effect on the concentration of ferrozine-detectable iron (henceforth iron) in the haemolymph, dead X. nematophila was associated with substantially lower levels of iron as the number of damaged haemocytes increased. Haemocyte lysate lowered the concentrations of iron in both FeCl₃ solutions and deproteinized larval serum independent of serum lipids. Haemocyte lysate added to tryptic soybroth lowered the level of iron and limited the growth of X. nematophila. X. nematophila limited iron availability in the plasma by releasing lipopolysaccharides; such a mechanism may be a means of impairing the antimicrobial defences of the insects.     

Identification and Functional Characterization of a Xenorhabdus nematophila Oligopeptide Permease

The bacterium Xenorhabdus nematophila is a mutualist of Steinernema carpocapsae nematodes and a pathogen of insects. Presently, it is not known what nutrients the bacterium uses to thrive in these host environments. In other symbiotic bacteria, oligopeptide permeases have been shown to be important in host interactions, and we therefore sought to determine if oligopeptide uptake is essential for growth or symbiotic functions of X. nematophila in laboratory or host environments. We identified an X. nematophila oligopeptide permease (opp) operon of two sequential oppA genes, predicted to encode oligopeptide-binding proteins, and putative permease-encoding genes oppB, oppC, oppD, and oppF. Peptide-feeding studies indicated that this opp operon encodes a functional oligopeptide permease. We constructed strains with mutations in oppA₁, oppA₂, or oppB and examined the ability of each mutant strain to grow in a peptide-rich laboratory medium and to interact with the two hosts. We found that the opp mutant strains had altered growth phenotypes in the laboratory medium and in hemolymph isolated from larval insects. However, the opp mutant strains were capable of initiating and maintaining both mutualistic and pathogenic host interactions. These data demonstrate that the opp genes allow X. nematophila to utilize peptides as a nutrient source but that this function is not essential for the existence of X. nematophila in either of its host niches. To our knowledge, this study represents the first experimental analysis of the role of oligopeptide transport in mediating a mutualistic invertebrate-bacterium interaction.     

Role of Secondary Metabolites in Establishment of the Mutualistic Partnership between Xenorhabdus nematophila and the Entomopathogenic Nematode Steinernema carpocapsae

Xenorhabdus nematophila engages in a mutualistic partnership with the nematode Steinernema carpocapsae, which invades insects, migrates through the gut, and penetrates into the hemocoel (body cavity). We showed previously that during invasion of Manduca sexta, the gut microbe Staphylococcus saprophyticus appeared transiently in the hemocoel, while Enterococcus faecalis proliferated as X. nematophila became dominant. X. nematophila produces diverse secondary metabolites, including the major water-soluble antimicrobial xenocoumacin. Here, we study the role of X. nematophila antimicrobials in interspecies competition under biologically relevant conditions using strains lacking either xenocoumacin (ΔxcnKL strain), xenocoumacin and the newly discovered antibiotic F (ΔxcnKL:F strain), or all ngrA-derived secondary metabolites (ngrA strain). Competition experiments were performed in Grace''s insect medium, which is based on lepidopteran hemolymph. S. saprophyticus was eliminated when inoculated into growing cultures of either the ΔxcnKL strain or ΔxcnKL:F strain but grew in the presence of the ngrA strain, indicating that ngrA-derived antimicrobials, excluding xenocoumacin or antibiotic F, were required to eliminate the competitor. In contrast, S. saprophyticus was eliminated when coinjected into M. sexta with either the ΔxcnKL or ngrA strain, indicating that ngrA-derived antimicrobials were not required to eliminate the competitor in vivo. E. faecalis growth was facilitated when coinjected with either of the mutant strains. Furthermore, nematode reproduction in M. sexta naturally infected with infective juveniles colonized with the ngrA strain was markedly reduced relative to the level of reproduction when infective juveniles were colonized with the wild-type strain. These findings provide new insights into interspecies competition in a host environment and suggest that ngrA-derived compounds serve as signals for in vivo nematode reproduction.     

Role of Mrx fimbriae of Xenorhabdus nematophila in competitive colonization of the nematode host

Xenorhabdus nematophila engages in mutualistic associations with the infective juvenile (IJ) stage of specific entomopathogenic nematodes. Mannose-resistant (Mrx) chaperone-usher-type fimbriae are produced when the bacteria are grown on nutrient broth agar (NB agar). The role of Mrx fimbriae in the colonization of the nematode host has remained unresolved. We show that X. nematophila grown on LB agar produced flagella rather than fimbriae. IJs propagated on X. nematophila grown on LB agar were colonized to the same extent as those propagated on NB agar. Further, progeny IJs were normally colonized by mrx mutant strains that lacked fimbriae both when bacteria were grown on NB agar and when coinjected into the insect host with aposymbiotic nematodes. The mrx strains were not competitively defective for colonization when grown in the presence of wild-type cells on NB agar. In addition, a phenotypic variant strain that lacked fimbriae colonized as well as the wild-type strain. In contrast, the mrx strains displayed a competitive colonization defect in vivo. IJ progeny obtained from insects injected with comixtures of nematodes carrying either the wild-type or the mrx strain were colonized almost exclusively with the wild-type strain. Likewise, when insects were coinjected with aposymbiotic IJs together with a comixture of the wild-type and mrx strains, the resulting IJ progeny were predominantly colonized with the wild-type strain. These results revealed that Mrx fimbriae confer a competitive advantage during colonization in vivo and provide new insights into the role of chaperone-usher fimbriae in the life cycle of X. nematophila.     

In-silico analysis of genomic distribution and functional association of hipBA toxin-antitoxin (TA) homologs in entomopathogen Xenorhabdus nematophila

Bacteria have a particular strategy to invade the host immune system by forming an undetectable dormant state that may resuscitate and cause disease even after inhabiting for years in a host body. Several mechanisms are known to be responsible for bacterial dormancy, among them the hipBA toxin-antitoxin (TA) system which was initially identified in Escherichia coli. Here we explore the genomic distribution and functional association of hipBA TA homologs from an entomopathogenic bacterium Xenorhabdus nematophila. This bacterium is a symbiotic model with the nematode Steinernema carpocapsae. We found that HipA toxin homologs are more closely related than HipB antitoxins and have satisfactory adenine (for HipA homologs) and nucleic acid (for HipB homologs) ligand partners with a typical TA interaction network that may promote the X. nematophila towards a stringent response to form the dormant state. Such homologs distribution is an inclusion in the current TA repertoire of X. nematophila.     

The hmsHFRS operon of Xenorhabdus nematophila is required for biofilm attachment to Caenorhabditis elegans

The bacterium Xenorhabdus nematophila is an insect pathogen and an obligate symbiont of the nematode Steinernema carpocapsae. X. nematophila makes a biofilm that adheres to the head of the model nematode Caenorhabditis elegans, a capability X. nematophila shares with the biofilms made by Yersinia pestis and Yersinia pseudotuberculosis. As in Yersinia spp., the X. nematophila biofilm requires a 4-gene operon, hmsHFRS. Also like its Yersinia counterparts, the X. nematophila biofilm is bound by the lectin wheat germ agglutinin, suggesting that beta-linked N-acetyl-D-glucosamine or N-acetylneuraminic acid is a component of the extracellular matrix. C. elegans mutants with aberrant surfaces that do not permit Yersinia biofilm attachment also are resistant to X. nematophila biofilms. An X. nematophila hmsH mutant that failed to make biofilms on C. elegans had no detectable defect in symbiotic association with S. carpocapsae, nor was virulence reduced against the insect Manduca sexta.     

The global regulator Lrp contributes to mutualism, pathogenesis and phenotypic variation in the bacterium Xenorhabdus nematophila

Xenorhabdus nematophila is a Gram-negative bacterium that leads both pathogenic and mutualistic lifestyles. In this study, we examine the role of Lrp, the leucine-responsive regulatory protein, in regulating both of these lifestyles. lrp mutants have attenuated virulence towards Manduca sexta insects and are defective in suppression of both cellular and humoral insect immunity. In addition, an lrp mutant is deficient in initiating colonization of and growth within mutualistic host nematodes. Furthermore, nematodes reared on lrp mutant lawns exhibit decreased overall numbers of nematode progeny. To our knowledge, this is the first demonstration of virulence attenuation associated with an lrp mutation in any bacterium, as well as the first report of a factor involved in both X. nematophila symbioses. Protein profiles of wild-type and mutant cells indicate that Lrp is a global regulator of expression in X. nematophila, affecting approximately 65% of 290 proteins. We show that Lrp binds to the promoter regions of genes known to be involved in basic metabolism, mutualism and pathogenesis, demonstrating that the regulation of at least some host interaction factors is likely direct. Finally, we demonstrate that Lrp influences aspects of X. nematophila phenotypic variation, a spontaneous process that occurs during prolonged growth in stationary phase.     

NilD CRISPR RNA contributes to Xenorhabdus nematophila colonization of symbiotic host nematodes

The bacterium Xenorhabdus nematophila is a mutualist of entomopathogenic Steinernema carpocapsae nematodes and facilitates infection of insect hosts. X. nematophila colonizes the intestine of S. carpocapsae which carries it between insects. In the X. nematophila colonization‐defective mutant nilD6::Tn5, the transposon is inserted in a region lacking obvious coding potential. We demonstrate that the transposon disrupts expression of a single CRISPR RNA, NilD RNA. A variant NilD RNA also is expressed by X. nematophila strains from S. anatoliense and S. websteri nematodes. Only nilD from the S. carpocapsae strain of X. nematophila rescued the colonization defect of the nilD6::Tn5 mutant, and this mutant was defective in colonizing all three nematode host species. NilD expression depends on the presence of the associated Cas6e but not Cas3, components of the Type I‐E CRISPR‐associated machinery. While cas6e deletion in the complemented strain abolished nematode colonization, its disruption in the wild‐type parent did not. Likewise, nilD deletion in the parental strain did not impact colonization of the nematode, revealing that the requirement for NilD is evident only in certain genetic backgrounds. Our data demonstrate that NilD RNA is conditionally necessary for mutualistic host colonization and suggest that it functions to regulate endogenous gene expression.     

Stages of Infection during the Tripartite Interaction between Xenorhabdus nematophila, Its Nematode Vector, and Insect Hosts

Bacteria of the genus Xenorhabdus are mutually associated with entomopathogenic nematodes of the genus Steinernema and are pathogenic to a broad spectrum of insects. The nematodes act as vectors, transmitting the bacteria to insect larvae, which die within a few days of infection. We characterized the early stages of bacterial infection in the insects by constructing a constitutive green fluorescent protein (GFP)-labeled Xenorhabdus nematophila strain. We injected the GFP-labeled bacteria into insects and monitored infection. We found that the bacteria had an extracellular life cycle in the hemolymph and rapidly colonized the anterior midgut region in Spodoptera littoralis larvae. Electron microscopy showed that the bacteria occupied the extracellular matrix of connective tissues within the muscle layers of the Spodoptera midgut. We confirmed the existence of such a specific infection site in the natural route of infection by infesting Spodoptera littoralis larvae with nematodes harboring GFP-labeled Xenorhabdus. When the infective juvenile (IJ) nematodes reached the insect gut, the bacterial cells were rapidly released from the intestinal vesicle into the nematode intestine. Xenorhabdus began to escape from the anus of the nematodes when IJs were wedged in the insect intestinal wall toward the insect hemolymph. Following their release into the insect hemocoel, GFP-labeled bacteria were found only in the anterior midgut region and hemolymph of Spodoptera larvae. Comparative infection assays conducted with another insect, Locusta migratoria, also showed early bacterial colonization of connective tissues. This work shows that the extracellular matrix acts as a particular colonization site for X. nematophila within insects.     

The xnp1 P2-like tail synthesis gene cluster encodes xenorhabdicin and is required for interspecies competition

Xenorhabdus nematophila, the mutualistic bacterium of the nematode Steinernema carpocapsae, produces the R-type bacteriocin called xenorhabdicin, which is thought to confer a competitive advantage for growth in the insect host. We have identified a P2-like tail synthesis gene cluster (xnp1) that is required for xenorhabdicin production. The xnp1 genes were expressed constitutively during growth and were induced by mitomycin C. Deletion of either the sheath (xnpS1) or fiber (xnpH1) genes eliminated xenorhabdicin production. Production of R-type bacteriocins in a host organism had not been shown previously. We show that xenorhabdicin is produced in the hemocoel of insects infected with the wild type but not with the ΔxnpS1 deletion strain. Xenorhabdicin prepared from the wild-type strain killed the potential competitor Photorhabdus luminescens TT01. P. luminescens was eliminated during coculture with wild-type X. nematophila but not with the ΔxnpS1 strain. Furthermore, P. luminescens inhibited reproduction of S. carpocapsae in insect larvae, while coinjection with wild-type X. nematophila, but not the ΔxnpS1, strain restored normal reproduction, demonstrating that xenorhabdicin was required for killing P. luminescens and protecting the nematode partner. Xenorhabdicin killed X. nematophila from Steinernema anatoliense, demonstrating for the first time that it possesses intraspecies activity. In addition, activity was variable against diverse strains of Xenorhabdus and Photorhabdus and was not correlated with phylogenetic distance. These findings are discussed in the context of the role of xenorhabdicin in the life cycle of the mutualistic bacterium X. nematophila.     

OpnS,an Outer Membrane Porin of Xenorhabdus nematophila,Confers a Competitive Advantage for Growth in the Insect Host

The gammaproteobacterium Xenorhabdus nematophila engages in a mutualistic association with an entomopathogenic nematode and also functions as a pathogen toward different insect hosts. We studied the role of the growth-phase-regulated outer membrane protein OpnS in host interactions. OpnS was shown to be a 16-stranded β-barrel porin. opnS was expressed during growth in insect hemolymph and expression was elevated as the cell density increased. When wild-type and opnS deletion strains were coinjected into insects, the wild-type strain was predominantly recovered from the insect cadaver. Similarly, an opnS-complemented strain outcompeted the ΔopnS strain. Coinjection of the wild-type and ΔopnS strains together with uncolonized nematodes into insects resulted in nematode progeny that were almost exclusively colonized with the wild-type strain. Likewise, nematode progeny recovered after coinjection of a mixture of nematodes carrying either the wild-type or ΔopnS strain were colonized by the wild-type strain. In addition, the ΔopnS strain displayed a competitive growth defect when grown together with the wild-type strain in insect hemolymph but not in defined culture medium. The ΔopnS strain displayed increased sensitivity to antimicrobial compounds, suggesting that deletion of OpnS affected the integrity of the outer membrane. These findings show that the OpnS porin confers a competitive advantage for the growth and/or the survival of X. nematophila in the insect host and provides a new model for studying the biological relevance of differential regulation of porins in a natural host environment.The bacterium Xenorhabdus nematophila forms a mutualistic association with the entomopathogenic nematode Steinernema carpocapsae (2). The nonfeeding infective juvenile form of the nematode (IJ) exists in the soil and carries the bacteria in a specialized receptacle region in the anterior intestine (4, 39). The IJ invades susceptible insect species and enters the hemocoel, where exposure to insect hemolymph stimulates the movement of bacteria down the intestine and out of the anus (36, 39). Together, the nematode and bacteria kill the insect host. X. nematophila not only helps to kill the insect but also promotes bioconversion of host macromolecules and tissues to provide nutrients for nematode reproduction and secretes diverse antimicrobial products to suppress competition for the nutrient resources of the insect cadaver (11, 13, 18, 19, 38). In turn, the nematode vectors X. nematophila to new insect hosts and protects it from the competitive environment of the soil. Colonization of the nematode receptacle is predominantly a monoculture process that is initiated by a single cell followed by bacterial proliferation (24, 39). The level of colonization varies from a few cells to several hundreds per nematode and is higher in nematodes reproducing in insects than on bacterial lawns, suggesting that the insect environment provides additional nutrients for bacterial growth (16, 39).Hydrophilic nutrients and antibiotics passively diffuse across the outer membrane of gram-negative bacteria through general porins and substrate-specific channels (17, 29). The most extensively studied general porins, OmpF and OmpC of Escherichia coli (30), are 16-stranded β-barrel proteins that are reciprocally regulated by changes in external osmolarity (12, 21, 41). Although the flow rate through OmpF is greater than OmpC (28), comparison of the resolved crystal structures does not reveal significant physiochemical differences between the two porins (3). The biological significance of the differential regulation of porins with distinct functional properties remains unclear. The major outer membrane protein of X. nematophila, OpnP, was shown to be produced at high levels in exponentially growing cells and is a homologue of OmpF and OmpC (14). OpnP production was not affected by changes in medium osmolarity, and the flow rate measured for the OpnP porin was more similar to the restrictive porin OmpC than to the more permissive OmpF porin (3). As cells transitioned to stationary phase, de novo synthesis of OpnP decreased, while the synthesis of the outer membrane protein, designated OpnS, increased (15, 22).Porin function and regulation have been studied in both pathogenic and symbiotic bacteria. In Vibrio cholerae two well-studied porins, OmpU and OmpT, that possess distinct functional properties have been shown to be differentially regulated (37). OmpU confers resistance to sodium deoxycholate (DC), a major component of bile, as well as polymixin B, detergents, and antimicrobial peptides, while the expression of OmpT alone sensitizes the cell to DC (26, 33). OmpU was thought to be expressed when V. cholerae colonizes the intestine, suggesting that it was required for host colonization (33); however, subsequent findings indicated that neither OmpU nor OmpT were essential for intestinal colonization (34). Recent findings indicated that OmpU may sense membrane perturbations and activate DegS which in turn modulates σ^E activity (25, 26). In the symbiotic bacterium Vibrio fischeri the deletion of ompU was shown to reduce the efficiency of colonization of the light organ of the Euprymna scolopes squid and increase sensitivity to bile, antimicrobial peptides, and detergent (1). Interestingly, the ompU strain did not display a competitive defect for colonization in the presence of the wild-type strain.In the present study the growth-phase-regulated outer membrane protein OpnS of X. nematophila was identified as a general porin that conferred a competitive advantage for growth in the insect host. OpnP and OpnS were the only general porins identified in the genome of X. nematophila. The reciprocal expression of OpnP and OpnS suggest that they serve distinct biological roles.