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. 2012 Aug 17;7(8):e43114. doi: 10.1371/journal.pone.0043114

Genetic and Proteomic Characterization of rpoB Mutations and Their Effect on Nematicidal Activity in Photorhabdus luminescens LN2

Xuehong Qiu 1, Xun Yan 1, Mingxing Liu 1, Richou Han 1,*
Editor: Vladimir N Uversky2
PMCID: PMC3422287  PMID: 22912803

Abstract

Rifampin resistant (RifR) mutants of the insect pathogenic bacterium Photorhabdus luminescens LN2 from entomopathogenic nematode Heterorhabditis indica LN2 were genetically and proteomically characterized. The RifR mutants showed typical phase one characters of Photorhabdus bacteria, and insecticidal activity against Galleria mellonella larvae, but surprisingly influenced their nematicidal activity against axenic infective juveniles (IJs) of H. bacteriophora H06, an incompatible nematode host. 13 out of 34 RifR mutants lost their nematicidal activity against H06 IJs but supported the reproduction of H06 nematodes. 7 nematicidal-producing and 7 non-nematicidal-producing RifR mutants were respectively selected for rpoB sequence analysis. rpoB mutations were found in all 14 RifR mutants. The rpoB (P564L) mutation was found in all 7 mutants which produced nematicidal activity against H06 nematodes, but not in the mutants which supported H06 nematode production. Allelic exchange assays confirmed that the Rif-resistance and the impact on nematicidal activity of LN2 bacteria were conferred by rpoB mutation(s). The non-nematicidal-producing RifR mutant was unable to colonize in the intestines of H06 IJs, but able to colonize in the intestines of its indigenous LN2 IJs. Proteomic analysis revealed different protein expression between wild-type strain and RifR mutants, or between nematicidal-producing and non nematicidal-producing mutants. At least 7 putative proteins including DsbA, HlpA, RhlE, RplC, NamB (a protein from T3SS), and 2 hypothetical proteins (similar to unknown protein YgdH and YggE of Escherichia coli respectively) were probably involved in the nematicidal activity of LN2 bacteria against H06 nematodes. This hypothesis was further confirmed by creating insertion-deletion mutants of three selected corresponding genes (the downregulated rhlE and namB, and upregualted dsbA). These results indicate that the rpoB mutations greatly influence the symbiotic association between the symbionts and their entomopathogenic nematode hosts.

Introduction

Rifampin (Rif), first introduced in 1972 as an antitubercular drug, was initially extremely effective against Mycobacterium tuberculosis, and other bacteria [1][2]. With its widespread and extended use, the number of bacterial isolates resistant to Rif has increased. Most Rif-resistance mutations in M. tuberculosis as well as in Escherichia coli and Staphylococcus aureus were conferred by a set of restrictive mutations in the rpoB gene, which encoded the β-subunit of RNA polymerase (RNAP) in bacteria [3][4]. DNA-dependent RNAP, which contains an essential catalystic core enzyme (α2ββ’ω) and one of the sigma (δ) factors, is the central enzyme for expression of genomic information in all organisms. Rif inhibits transcription initiation by blocking the rpoB of bacterial RNAP [5][6]. E. coli rpoB mutations that suppress the auxotrophy due to lack of stringent response were demonstrated to affect the transcription of stringently controlled genes by destabilizing the RNAP-stable RNA promoter complex [7]. The Rif resistant (RifR) M. tuberculosis mutations of the rpoB gene were found in nearly 95% of clinical isolates [4]. Most of the mutations were located from nucleotides 1276 to 1356 (codon 432–458 in M. tuberculosis rpoB gene and codon 507–533 in E. coli rpoB gene). An 81 bp core region was called the Rif resistance determining region (RRDR) of rpoB [8][10]. However, a significant number of RifR mycobacteria with no mutations in the rpoB gene have been isolated from different clinical samples [11][14]. A 191A/C mutation in the Rv2629 gene was reported to be significantly associated with Rif-resistance in M. tuberculosis [15]. Recently, it was reported that the K1 uptake regulator TrkA played an important role in intrinsic and acquired antibiotic resistance in mycobacteria [16]. Besides Rif-resistance, the rpoB mutation (A621E) conferred dual heteroresistance to daptomycin and vancomycin in Staphylococcus aureus [17], but most rpoB mutations were involved in reduced vancomycin susceptibility [18]. It suggested that different rpoB mutations may have different effect on bacteria.

Photorhabdus and Xenorhabdus bacteria belonging to the Enterobacteriaceae are symbiotically associated respectively with entomopathogenic Heterorhabditis and Steinernema nematodes, which are used as a commercial bioinsecticide for many economically important insect pests [19]. The association between the nematodes and their symbiotic bacteria plays an important role in the pathogenicity and production of these nematode-bacterium complexes. The infective juveniles (IJs) of these nematodes are a developmentally arrested non-feeding form, ensheathed in the second stage cuticle and harbor Photorhabdus or Xenorhabdus cells as symbionts in their intestines. The IJ nematodes properly maintain and carry the bacteria needed for killing insects and providing a suitable environment for the reproduction of new vectors [20][22]. Different Photorhabdus or Xenorhabdus bacterial isolates differ in their ability to support in vitro monoxenic cultures of non-host nematodes [23][30] and to retain the bacterial cells in the IJ intestines [22][23], [26], [28], [31].

Strains of Photorhabdus and Xenorhabdus not only show insecticidal activities towards different insects [32][36] but also exhibit nematicidal activities against some plant nematodes, such as Meloidogyne incognita [37], the free-living soil nematode Caenorhabditis elegans [38], and for Steinernema nematodes [39].

The trans-specific nematicidal activity of P. luminescens subsp. akhurstii LN2, a normal symbiont of H. indica LN2, against H. bacteriohora H06 nematodes was previously observed [40]. These bacteria secrete unidentified toxic factors lethal for H06 nematodes although the bacteria produce signals which trigger the recovery of H06 IJ nematodes [30]. A novel P. luminescens LN2 gene involved in the nematicidal activity against H. bacteriophora H06 IJs was identified [41].

Xenorhabdus and Photorhabdus bacterial isolates resistant to Rif were used in several references [42][46]. When different RifR mutants of P. luminescens LN2 were monoxenically combined respectively with the axenic IJs of a Chinese isolate H. bacteriophora H06, the involvement of rpoB mutation in the nematicidal activity (incompatible symbiosis) was discovered.

To achieve an overall view of phenotypic, genetic and metabolic modifications associated with different RifR mutants, the experiments were conducted to determine: (1) the effects of different RifR mutants of P. luminescens LN2 on the growth of their corresponding incompatible nematode hosts, H. bacteriophora H06; (2) the phenotypic and biochemical characters of the RifR mutants; (3) the rpoB mutations in the RifR mutants; (4) the effects of rpoB mutations in the RifR mutants on the nematode growth; (5) the mutualistic colonization of H06 IJs by the RifR mutants; (6) the proteomic analysis of the mutants and wild-type bacterial strain; (7) the effects of differentially expressed proteins detected from proteomic analysis on nematicidal activity.

Materials and Methods

Nematode Species, Bacterial Strains, Plasmids and Culture Conditions

Bacterial strains and plasmids used in this study are listed in Table 1. P. luminescens subsp. akhurstii LN2 isolated from its host nematode H. indica LN2 was used for the isolation of spontaneous RifR mutants. P. luminescens H06 or HNA were used for the mass production of H. bacteriophora H06. The bacterial strains were cultured in LB1 broth (1% tryptone, 0.5% yeast Extract, 0.5% NaCl) or on LB1 agar at 25°C. The primary form (phase one) of these bacteria was obtained by selecting green or blue-green colonies on NBTA or red colonies on MacConkey agar, and repeated subculturing [47]. Stock cultures were maintained in 15% glycerol (v/v) in LB1 at −80°C. E. coli strains were grown in LB2 broth (1% tryptone, 0.5% yeast Extract, 1% NaCl) or on LB2 agar at 37°C.

Table 1. Bacterial strains and plasmids used in this study.

Strain/plasmid Description, relevant characteristics Reference or source
Photorhabdus luminescens strains
LN2/LN2-W Wild-type isolate from host nematode H. indica LN2 Ralf-Udo Ehlers
LN2-R1∼LN2-R34 Spontaneous RifR mutant of wild-type strain LN2; RifR This study
LN2-A Spontaneous AmpR mutant of wild-type strain LN2; AmpR This study
LN2-M1 Tn5 insertion mutant of LN2; AmpR, KmR [41]
H06 Wild-type isolate from host nematode H. bacteriophora H06 Laboratory stock
HNA Wild-type isolate from host nematode H. megidis HNA Dr Wim Wouts
LN2-WΔrpoB-LR31 LN2-W containing the mutant rpoB allele from LN2-R31 This study
LN2-R31ΔrpoB-LW LN2-R31containing the wild-type rpoB allele from LN2-W This study
LN2ΔrhlE LN2-A rhlE::Cm This study
LN2ΔnamB LN2-A namB::Cm This study
LN2ΔdsbA LN2-A dsbA::Cm This study
Escherichia coli strains
DH5a Host of plasmids TaKaRa
S17-1 (λpir) E. coli lysogenized with λpir, replication of ori R6K [51]
TOP10 Cloning strain Invitrogen
Plasmids
pMini-Tn5 oriT, oriR6K, delivery plasmid for mini-Tn5; KmR [52]
pCR4-TOPO Cloning vector; AmpR, KmR Invitrogen
pMD-18T Cloning vector; AmpR TaKaRa
pMD-19T Cloning vector; AmpR TaKaRa
pUC19-egfp pUC19 carrying egfp; AmpR Laboratory stock
pMD-egfp pMD-18T carrying ribosome binding site and egfp gene; AmpR This study
pMD-lac-egfp pMD-19T carrying ribosome binding site, lacZ promoter and egfp gene; AmpR This study
pMini-lac-egfp pMini-Tn5 carrying a NotI fragment containing ribosome binding site, lacZ promoter and egfp gene; KmR This study
pPHU281 lacZ’ mob(RP4), TcR derivative of pUC18 with oriT [50]
pPHU281-rpoB-LW pPHU281 carrying a BamHI-PstI fragment containing rpoB gene from wild-type strain of P. luminescens LN2 This study
pPHU281-rpoB-LR31 pPHU281 carrying a BamHI-PstI fragment containing rpoB gene from RifR mutant of P. luminescens LN2-R31 This study
pKNG101 R6K Ori, sacB, SmR [56]
pKNG101-rhlE::Cm pKNG101 carrying a rhlE::Cm fragment, SmR, CmR This study
pKNG101- namB::Cm pKNG101 carrying a namB::Cm fragment, SmR, CmR This study
pKNG101- dsbA::Cm pKNG101 carrying a dsbA::Cm fragment, SmR, CmR This study

When required, antibiotics were added to the medium with the following concentrations: ampicillin (Amp), 100 µg/mL; kanamycin (Km), 50 µg/mL; rifampin (Rif), 50 µg/mL; and tetracycline (Tc), 25 µg/mL; chloramphenicol (Cm), 25 µg/mL. All the antibiotics used in this study were purchased from Sigma Chemical Company and all medium components from Oxoid Company, England.

Production of Axenic Heterorhabditis IJs

Axenic H. bacteriophora H06 IJs for the monoxenic nematode-bacterium recombinations were obtained according to the method as previously described [30]. Briefly, IJs of H06 were grown monoxenically on nonspecific P. luminescens HNA on a sponge medium consisting of 1% yeast extract, 5% egg yolk, 15% soya flour, 5% corn oil, 8% polyether polyurethane sponge and 50% distilled water [30]. The IJs were collected by centrifugation and migration through a 30 µm nylon cloth sieve under sterile conditions, surface-sterilized in 0.5% streptomycin-sulfate (Merck, Germany) for 6 h and then rinsed three times in sterile distilled water. The axenicity of these surface-sterilized IJs was checked as previously described [30]. Because these IJs can be reared with the provided bacterial isolates, and are not able to contain the bacteria in their intestines, they are free of bacteria after surface sterilization.

Nematicidal Bioassay of the RifR Mutants

The RifR mutants from LB1 agar with Rif were screened for their nematicidal activities against H. bacteriophora H06 IJs according to the method as previously described [30]. Approximately 100 axenic H06 IJs were introduced to the 2-day old lawn of wild-type strain or RifR mutants of P. luminescens LN2 grown on LB1 agar in 96-well tissue culture plate (Corning, New York, USA). Mortality and growth of the IJs were observed daily and recorded until 15 days. A lawn of wild-type P. luminescens H06 was used as a control. A mutant was considered positive for nematode growth if the tested nematodes were able to survive at least 7 days and produce the next generation of juveniles from the hermaphrodites. If the mutants were unable to support the survival of nematodes, the introduced IJs died after 7 days. The effect of the RifR mutants on H06 IJs were verified by repeating the nematode survival and growth experiments three times, each with 12 replicates. Among the 34 tested RifR mutants, 13 mutants were identified positive, and 21 mutants negative for the growth of H. bacteriophora H06. 7 positive (LN2-R2, LN2-R6, LN2-R12, LN2-R15, LN2-R28, LN2-R31, LN2-R33) and 7 negative mutants (LN2-R3, LN2-R5, LN2-R7, LN2-R8, LN2-R11, LN2-R16, LN2-R25) were selected for further study (Table 2).

Table 2. rpoB mutations of the RifR mutants and their effect on H06 nematode growth.

Bacterial mutants Nucleotide change Amino acid change Effect on the growth of H06 nematodes
LN2-R2 G436T V146F +
LN2-R6
LN2-R15
LN2-R12 C938A A313D +
C1585T R529C
LN2-R28 C1535T S512F +
LN2-R33
LN2-R31 C1537A Q513K +
LN2-R3 C1691T P564L
LN2-R7
LN2-R11
LN2-R16
LN2-R25
LN2-R5 C521T A174V
C1691T P564L
LN2-R8 C826T Q276*
C1691T P564L
A2475G No change
LN2-A No change No change
LN2-M1 No change No change +
+

Nematode production;

No nematode production and nematode died after 7 days;

*

stop code.

Colonial Characterization of the Mutants and Wild-type Bacterial Strain

Colony pigmentation was determined on LB1 agar, NBTA, and MacConkey agar plates. pH-sensitive pigment production in LB1 was determined by addition of 1 M NaOH or 1 M HCl. Tests for the production of antibiotic substances were conducted as previously described [48], using Bacillus subtilis as test organism, and scored positive when a growth inhibition zone of >3 mm was measured around the P. luminescens colonies at 96 h after inoculation of the overlay culture. Bioluminescence was observed by dark-adapted eyes in a dark room. Cell morphology was observed microscopically. Catalase activity was tested by introducing 0.1 ml 3% hydrogen peroxide into the bacterial cultures and observing the release of oxygen. For all assays, both wide-type and mutant colonies were characterized on the same agar plate ad positive and negative controls. At least three plates for each medium were established.

DNA Manipulation

Plasmid DNA preparation, extraction of genomic DNA, restriction enzyme digestions, and ligations were carried out as previously described [49]. Restriction enzymes (Promega, USA) and T4 ligase (Novagen, Germany) were used according to the manufacturer’s instructions. Plasmids were extracted from E. coli with QIAprep Spin Miniprep kit (Qiagen, Netherlands). When required, DNA fragments were extracted and purified from agarose gels using E.Z.N.A.™ Gel Extractio kit (Omega, USA). The genomic DNA was isolated from P. luminescens bacteria using E.Z.N.A.™ Bacterial DNA Kit (Omega).

Mutation Analysis of the rpoB Gene from Different Strains

To examine the rpoB sequence from the RifR mutants and wild-type strain (LN2-W), together with a spontaneous AmpR mutant LN2-A and the namA mutant LN2-M1 [41], the gene was amplified from the genomic DNA of different strains, by PCR with PfuUltra™ II Fusion HS DNA Polymerase (Stratagene, Germany), using the primers rpoB-BamHI-F (5′-GCTGGATCCATGGTTTACTCCTATACCGAG-3′) and rpoB-PstI-R (5′-GCACTGCAGTTATTCGTCTTCCAGCTCGATG-3′). The amplified gene was cloned into pCR4-TOPO vector (Invitrogen, USA), and transformed into E. coli TOP10 (Invitrogen). DNA sequencing was performed by Invitrogen Trading (Shanghai) Co. Ltd. All strains were sequenced at least twice. The sequence data of the rpoB gene were assembled and analyzed with DNAstar and CLUSTAL W program. The rpoB sequence data from wild-type strain of P. luminescens LN2 has been submitted to the GenBank database under accession number (JN177303).

Allelic Exchange Mutagenesis of the rpoB Gene

The plasmids of pCR4-TOPO-rpoB-LW and pCR4-TOPO-rpoB-LR31 containing corresponding rpoB genes from LN2-W and LN2-R31, were digested with BamHI (GGATCC) and PstI (CTGCAG), respectively. The resulting rpoB fragments were purified and ligated into the suicide vector pPHU281 [50] digested with BamHI and PstI to yield plasmids pPHU281-rpoB-LW and pPHU281-rpoB-LR31. The resulting plasmids were transferred into E. coli S17-1 (λpir) [51]. Strains LN2-WΔrpoB-LR31 (LN2-W containing the mutant rpoB allele from LN2-R31) and LN2-R31ΔrpoB-LW (LN2-R31containing the wild type rpoB allele from LN2-W) were created by allelic exchange with pPHU281-rpoB-LR31 and pPHU281-rpoB-LW, respectively, using biparental mating method. RifR.AmpR.TcS exconjugants of LN2-WΔrpoB-LR31 and RifS.AmpR.TcS exconjugants of LN2-R31ΔrpoB-LW were selected on LB1 agar plates with appropriate antibiotics. The exconjugants had undergone allelic exchange and lost the wild-type or mutated copy of rpoB and the plasmid vehicle. The mutants were verified for the presence of the appropriate rpoB allele by sequencing rpoB gene as described above. The resulting confirmed allelic exchange mutants were determined for the nematicidal activities against the IJs of H06 as described above.

Insecticidal Injection Assays

To check the insecticidal activity of the RifR mutants, the wild-type strain and RifR mutants of P. luminescens LN2 were grown overnight in LB1 broth without antibiotics, subcultured into fresh LB1 broth with 1% of bacterial culture, and incubated at 25°C for 24 h prior to injection. These cultures were washed and diluted to concentrations of 10, 100, 1000 CFU/µL in sterile phosphate buffered saline (PBS; 137 mM NaCl, 2.7 mM KCl, 10 mM NaHPO4, 2 mM KH2PO4, pH 7.4). Last instar larvae of greater wax moth Galleria mellonella were incubated on ice for approximately 5 min. 10 µL of the diluted cultures or sterile PBS were injected into the first proleg of each of 10 insect larvae using a 30-gauge syringe (Hamilton, Reno, NV). Three replicates with 10 insect larvae per replicate were established. Insects were monitored every 6 h for 120 h post injection. Dead insects were observed to confirm the presence of red color and bioluminescence.

Colonizations of H06 IJs by the GFP-labelled Mutants

To observe the colonization of IJ nematodes by the RifR mutant bacteria, the RifR mutant LN2-R31 positive for the growth of H06 nematodes was labeled with GFP by transposon mutagenesis of a pMini-Tn5 [52] containing an expressed egfp gene (pMini-lac-egfp). The pMini-lac-egfp was constructed as follows. A fragment containing an egfp gene and ribosome binding site (GAAGGTTTAGAC) was obtained from pUC19-egfp with primers egfp-SD2 (5′-GAAGGTTTAGACATGGGCAAAGGAGA-3′) and egfp-rev (5′-TAGCGGCCGCTTATTTGTATAGTTCATC-3′) (NotI). The amplified 750 bp PCR product was cloned into the pMD-18T vector (TaKaRa, Japan) and transformed into E. coli DH5α. Green clone on LB2 plates with ampicillin was selected to extract the plasmid pMD-egfp. A NotI-NotI fragment containing the lac promoter and egfp gene from pMD-egfp was cloned into pMD-19T Simple vector (TaKaRa) to generate pMD-lac-egfp, with primers lac-F (5′-AGCGGCCGCGAGCGCAGCGAGTCAGTGAGC-3) (NotI) and egfp-rev (NotI ). After transformed into E. coli DH5α, clones (AmpR) expressing GFP were detected using epifluorescence microscope (Nikon Eclipse 80i). To construct a transposon delivery vector pMini-lac-egfp, the NotI-NotI fragment carrying ribosome binding site, lacZ promoter and egfp gene from pMD-lac-egfp was inserted into the NotI site of pMini-Tn5. The ligation product was transformed into E. coli S17-1 (λpir). Clones (KmR) with green fluorescence were used to deliver the egfp gene into the chromosome of the RifR mutant LN2-R31 by diparent conjugation. Conjugants (KmR.RifR) were selected on LB1 plates at 25°C. GFP-labeled LN2-R31 was observed to express stable green fluorescence, even in the absence of antibiotic selection.

To check the colonization of H06 IJs by the RifR mutant LN2-R31, the nematodes were cultured on sponge medium [30] inoculated with GFP-labeled LN2-R31 as described above respectively. The IJs were extracted from the sponge and observed for GFP-labeled bacteria. The IJs were also homogenized with a sterile glass homogenizer after surface sterilization with 0.1% merthiolate and 5-time rinse with sterile distilled water. The presence of the GFP-labeled bacteria retained in the IJs intestines was determined by plating dilutions of surface-sterilized and homogenized nematodes on LB1 agar plates.

2-DE Analysis and Protein Identification by MALDI-TOF-MS

The 48 h old bacterial cells of the wild-type strain and RifR mutants (one negative mutant LN2-R16 and three positive mutants LN2-R2, LN2-R31 and LN2-R33, for H06 growth) grown on LB1 plates at 25°C were harvested and washed three times with cold PBS by centrifugation (6000 g, 10 min, 4°C). The cell pellets were resuspended in lysis buffer (8 M urea, 0.2% w/v Bio-Lyte 3/10 Ampholyte (Bio-Rad, USA), 4% CHAPS, 65 mM DTT) containing Protease Inhibitor Cocktail (Calbiochem, Germany) and Benzonase (Novagen, Germany) and disrupted by liquid nitrogen freezing-thawing three times. Cell debris was removed by centrifugation (20000 g, 60 min, 4°C). The supernatant (total cell protein) was divided into aliquots and stored at −80°C until use. Protein concentrations were determined by the Bradford method using Modified Bradford Protein Assay Kit (Sangon, China).

The 2-DE was performed according to the methods described previously [53] and the manufacturer’s instruction. The first dimension (isoelectric focusing) was conducted using the IPGphor IEF system (Bio-Rad) at 20°C. For analytical gels, 350 µg protein was solubilized in 400 µL rehydration solution (8M urea, 0.2% w/v Bio-Lyte 3/10 Ampholyte, 4% CHAPS, 65 mM DTT, 0.001% w/v bromophenol blue), and loaded onto a 17 cm pH 3–10 NL IPG strip (Bio-Rad). Focusing was performed for 13 h at 50V, 1 h at 500 V, 1 h at 1000 V, and 5 h and 30 min at 8000 V (total  = 45 kVh). The IPG strips were equilibrated as previously described [53]. The second dimension was performed with 12% (w/v) SDS-polyacrylamide gels using the Protean II xi 2D Multicell system (Bio-Rad). Proteins were stained with silver nitrate, and gels were digitized using Image ScannerII (Amersham Biosciences). Digitized 2-DE gel patterns were edited and matched using the PDQUEST software package (PDI, Humington Station). Triplicate experiments were run to confirm the reproducibility of results.

Spots of interest in gels staining with silver nitrate were cut out, washed, reduced, S-alkylated with iodoacetamide and in-gel digested at 37°C overnight with sequencing grade porcine trypsin (Promega, USA). After extraction in extractant of 50% ACN (Fisher) and 2.5% TFA (Sigma), peptide mixtures were analyzed using a saturated solution of 5 mg/mL α-cyano-4-hydroxycinnamic acid (CHCA, Sigma) in ACN containing 0.1% TFA (Sigma) (50/50 v/v) using a 4800 Proteomics Analyzer equipped with matrix assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) (Applied Biosystems, Framingham, MA, USA). For MS calibration, the trypsin autolysis peptides were used as internal calibrants. Monoisotopic peak masses were automatically determined within the mass range of 800–4000 Da, with a minimum S/N of 50. Five of the most intense ion signals were selected as precursors for MS/MS acquisition. Combined MS and MS/MS queries were performed with the MASCOT search engine (V2.1, Matrix Science, UK) embedded in GPS-Explorer Software (V3.6, Applied Biosystems), using the P. luminescens database (Gene DB). MASCOT protein scores (based on combined MS and MS/MS spectra) of greater than 61 were considered statistically significant (p≤0.05). The individual MS/MS spectrum with statistically significant (confidence interval >95%) best ion score (based on MS/MS spectra) were also accepted.

Insertion-deletion Mutations of the Corresponding Genes from Differentially Expressed Proteins

Compared with the nematicidal-producing mutant LN2-R16 and wild type strain, four proteins including RplC, RhlE, NamB (a putative transport and binding protein from type III secretion system), and a hypothetical protein similar to unknown protein YggE of E. coli were downregulated; three proteins including DsbA, HlpA, and a hypothetical protein highly similar to unknown protein YgdH of E. coli were upregulated in the non-nematicidal-producing mutants (LN2-R2, LN2-R31 and LN2-R33) (Table 34, Figure S1, S2, S3, S4, S5). At least these 7 putative proteins were probably involved in the nematicidal activity of LN2 bacteria against H06 nematodes.

Table 3. Total proteins with altered level of synthesis in the nematicidal-producing and non nematicidal-producing mutants.

Spot No. Protein Name/plu Organism Gene Function Protein PI Protein MW Ratio
W/W R2/W R16/W R31/W R33/W
Ribosomal protein
6 30S ribosomal protein S8 P. luminescens TT01 rpsH Binds directly to 16S rRNA central domain where it helps coordinate assembly of the platform of the 30S subunit 9.35 14205.6 1 0.7 0.8 0.27 1.03
15 50S ribosomal protein L17, plu4701 P. luminescens TT01 rplQ A component of the macrolide binding site in the peptidyl transferase cente 11.04 14708.8 1 0.5 1.27 0.69 1.34
26 50S ribosomal protein L3, plu4726 P. luminescens TT01 rplC Binds directly near the 3′ end of the 23S rRNA, where it nucleates assembly of the 50S subunit; essential for peptidyltransferase activity; mutations in this gene confer resistance to tiamulin 9.87 22328.9 1 0 0.41 0 0
44 50S ribosomal protein L9 plu4570 P. luminescens TT01 rplI In E. coli this protein is wrapped around the base of the L1 stalk 6.13 15872.5 1 2.38 2.23 0.92 1.37
45 50S ribosomal protein, L9 plu4570 P. luminescens TT01 rplI In E. coli this protein is wrapped around the base of the L1 stalk 6.13 15872.5 1 1.82 3.29 0.51 1.23
Adaptations conditions
7 Hypothetical protein, plu2032 P. luminescens TT01 Similar to Unknown protein YbdQ of E. coli; Similar to universal stress protein (pfam00582: Usp) 6.19 15907.4 1 3.79 2.9 1.46 4.83
9 Hypothetical protein, plu2030 P. luminescens TT01 Similar to Unknown protein YbdQ of E. coli, Similar to universal stress protein (pfam00582: Usp) 5.76 15283.2 1 1.71 1.21 0.2 0.45
48 Alkyl hydroperoxide reductase, small subunit (antioxidant), plu3907 P. luminescens TT01 ahpC Alkyl hydroperoxide reductase, small subunit (antioxidant) 5.98 22259.3 1 0.8 0.82 0.9 0.47
Secondary metabolites
12 Crystalline inclusion protein CipB P. luminescens TT01 cipB Unknown, similar to crystalline inclusion protein type II 6.08 11281.6 1 0.12 0 0.51 0
25 Crystalline inclusion protein CipA, plu1576 P. luminescens TT01 cipA Crystalline inclusion protein CipA 6.06 11710.9 1 0 0.08 0.74 0
32 Unknown P. luminescen Similar to hemolysin from Fusobacterium nucleatum clinical isolate found in GenBank, Accession Number AF525507 5.61 39995.2 1 0.9 1.7 0.44 0.8
62 Hypothetical protein, plu4211 P. luminescens TT01 Highly similar to Hcp protein 6.29 18482.5 1 11.43 14.91 19.98 3.24
Metabolism of amino acids and related molecules
30 Ethanolamine ammonia-lyase small subunit, plu2971 P. luminescens TT01 eutC Catalyzes the formation of acetaldehyde from ethanolamine 6.37 31188.4 1 4.17 0.5 1.1 1.2
36 Tryptophan synthase subunit beta, plu2466 P. luminescens TT01 trpB Catalyzes the formation of L-tryptophan from L-serine and 1-(indol-3-yl)glycerol 3-phosphate 6.2 43098 1 1.22 0.25 0.41 0.58
46 Serine/arginine repetitive matrix protein 2 Srrm2 12.02 294500.8 1 0.72 1.7 0.89 0.9
50 2,3-dihydroxy-2,3-dihy drophenylpropionate dehydrogenase, plu2207 P. luminescens TT01 hcaB Converts cis-3-(3-carboxyethyl) -3,5-cyclohexadiene-1,2-diol (PP-dihydrodiol) into 3-(2,3-dihydroxylphenyl) propionate 5.43 29519.1 1 0.37 0.3 0.49 0.9
51 Hypothetical protein, plu4676 P. luminescens TT01 Similar to 3-oxoacyl-[acyl-carrier-protein] synthase II (beta-ketoacyl-ACP synthase II) (KAS II) 5.58 45407.3 1 3.29 3.0 0.01 <0.01
52 Serine hydroxymethyltransferase, plu3291 P. luminescens TT01 glyA Catalyzes the reaction of glycine with 5,10-methylenetetrahydrofolate to form L-serine and tetrahydrofolate” 5.92 45229.8 1 3.74 4.55 2.93 5.6
53 Urease accessory protein, plu2176 P. luminescens TT01 ureG Urease accessory protein 5.04 22868.1 1 4.42 2.98 5.17 6.66
54 Hypothetical protein, plu2040 P. luminescens TT01 Similar to vibrio bactin utilization protein ViuB 5.51 31363 1 2.36 3.61 1.83 6.57
55 3-oxoacyl-(acyl carrier protein) synthase III, plu2835 P. luminescens TT01 fabH FabH; beta-ketoacyl-acyl carrier protein synthase III; catalyzes the condensation of acetyl-CoA with malonyl-ACP to initiate cycles of fatty acid elongation; differs from 3-oxoacyl-(acyl carrier protein) synthase I and II in that it utilizes CoA thioesters as primers rather than acyl-ACPs” 5.33 34189.6 1 5.12 6.14 3.85 6.77
Nucleosides and nucleotides biosynthesis and metabolism
1 Hypothetical protein, plu3994 P. luminescens TT01 Similar to putative membrane protein YqjD (carboxyl transferase) of E. coli 7.93 11042 1 4.03 0.57 2.91 1.2
3 IS630 family transposase, plu0720 P. luminescens TT01 ISPlu3Y Transposase, IS630 family 9.35 39771.5 1 0.38 0.17 0.02 0.11
47 IS630 family transposase, plu0468 P. luminescens TT01 ISPlu10J Transposase 9.59 39687.9 1 0.85 0.6 0.71 0.25
4 ATP-dependent RNA helicase RhlE, plu1511 P. luminescens TT01 rhlE This helicase is not essential cell growth 10.01 48258.8 1 0.05 0.52 0.04 0.02
19 ATP-dependent RNA helicase RhlE, plu1511 P. luminescens TT01 rhlE This helicase is not essential cell growth 10.01 48258.8 1 0 1.43 0.2 0
18 Nucleoside diphosphate kinase, plu1372 P. luminescens TT01 ndk Catalyzes the formation of nucleoside triphosphate from ATP and nucleoside diphosphate 5.35 15591.8 1 1.43 1.96 2.48 2.53
57 Uracil phosphoribosyl transferase, plu2759 P. luminescens TT01 upp Catalyzes the formation of uracil and 5-phospho-alpha-D-ribosy 1-diphosphate from UMP and diphosphate 5.46 22489 1 1.59 2.81 1.83 4.95
58 Reverse gyrase Leptospirillum sp. Group II UBA 9.31 56458 1 0 4.93 6.32 0.41
Cell wall/membrane biogenesis
8 Karst CG12008-PA, isoform A Drosophila melanogaster kst Kst-PA; spectrin beta-heavy chain; beta-H spectrin; 5.93 471351.1 1 2.20 1.8 1.33 1.16
43 hypothetical protein, plu3994 P. luminescens TT01 Similar to putative membrane protein YqjD of E. coli 7.93 11042 1 0.21 0.05 0.1 0.08
5 Periplasmic chaperone, plu0681 P. luminescens TT01 hlpA Histone-like protein HLP-1 precursor 9.43 18476.8 1 2.63 0.81 2.11 2.64
Transport and binding proteins
10 Unknown P. luminescens W14 From (type III secretion system, partial sequence) GI:27550090 6.1 16883.6 1 0 1.53 0 0
64 Unknown P. luminescens w14 From (type III secretion system, partial sequence) GI:27550090 6.1 16883.6 1 0.1 0.91 0.11 0.15
65 Unknown P. luminescens w14 From (type III secretion system, partial sequence) GI:27550090 6.1 16883.6 1 0.11 0.93 0.11 0.16
11 Hypothetical protein, plu1886 P. luminescens TT01 Hypothetical transmembrane protein 5.88 15588.6 1 1.53 2.83 1.57 0.43
13 Macrolide transporter subunit MacA, plu1590 P. luminescens TT01 macA Probable macrolide-specific ABC transporter; confers macrolide resistance via active drug efflux 6.95 40743.2 1 0 0 0 0
17 Sec-independent protein translocase protein, plu4410 P. luminescens TT01 tatA Sec-independent protein translocase protein 6.18 9289.9 1 0.76 0.81 0.72 0.23
42 Na-binding protein HU-alpha (NS2) (HU-2), plu0492 P. luminescens TT01 dbhA Na-binding protein HU-alpha (NS2) (HU-2) 9.1 9407 1 2.1 2.3 0.59 0.99
Information and regulatory pathways
14 DNA-binding transcriptional regulator HexR, plu2121 P. luminescens TT01 hexR Represses the expression of the zwf, eda, glp and gap 6.97 31694.5 1 2.2 1.96 1.92 0.91
16 DnaK transcriptional regulator DksA, plu0876 P. luminescens TT01 dksA DnaK transcriptional regulator DksA 5.04 17415.8 1 0 0.05 0.65 0
20 Nucleotide-binding protein, plu3881 P. luminescens TT01 Similar to Unknown protein YajQ of E. coli 5.77 18311.4 1 1.47 0.89 1.48 1.09
22 Transcriptional repressor MprA, plu1277 P. luminescens TT01 mprA DNA-binding transcriptional repressor of microcin B17 synthesis and multidrug efflux; negative regulator of the multidrug operon emrAB 7.01 20365.5 1 1.67 1.18 1.38 1.09
27 Hypothetical protein, plu0318 P. luminescens TT01 Similar to AidA protein of Ralstonia solanacearum 5.7 22068.3 1 1.03 1.68 0.86 0.87
49 Periplasmic protein disulfide isomerase I, plu0381 P. luminescens TT01 dsbA Disulfide interchange protein DsbA precursor 7.7 22954.8 1 3.8 1.57 3.49 3.62
37 Protease precursor DegQ, plu4018 P. luminescens TT01 degQ Protease precursor DegQ 9.12 48028.9 1 0 0 0 0
38 Protease precursor DegQ, plu4018 P. luminescens TT01 degQ Protease precursor DegQ 9.12 48028.9 1 0 0 0 0
Energy production and conversion
24 GD22749 Drosophilia simulans Dism\GD22749 Chromosome segregation ATPases [Cell division and chromosome partitioning]; COG1196 5.23 76326.8 1 1.39 0 <0.01 <0.01
23 Hypothetical protein, plu2075 P. luminescens TT01 Similar to 3-oxoacyl-[acyl-carrier protein] reductase 8.55 25032.6 1 0.12 0.31 0.45 0.33
35 WblA protein, plu4796 P. luminescens TT01 wblA Probable lipopolysaccharide biosynthesis protein; Similar to putative UDP-glucose/GDP-mannose dehydrogenase 5.86 48484 1 2.1 0 2.07 0.05
40 Catalase, plu3068 P. luminescens TT01 katE Catalase 6.92 55509.5 1 0 0 0 0
41 Catalase plu3068 P. luminescens TT01 katE Catalase 6.92 55509.5 1 0 0 0 0
56 Phosphoglycero mutase, plu1471 P. luminescens TT01 gpmA Catalyzes the interconversion of 2-phosphoglycerate to 3-phosphoglycerate 5.62 28396.7 1 1.64 2.88 2.02 3.5
Phage-related proteins
28 Hypothetical protein, plu3012 P. luminescens TT01 Probable phage protein; Similar to tail fiber assembly protein from bacteriophage 4.67 21467.8 1 0.68 0.88 2.36 0.44
29 Hypothetical protein, plu2035 P. luminescens TT01 Some similarities with putative tail fiber protein of prophage 4.23 23641.5 1 0 3 0.42 0.88
39 Hypothetical protein, plu3803 P. luminescens TT01 Some similarities with prophage tail fiber protein 6.37 66850.4 1 0.23 0.5 0.1 0
60 Hypothetical protein, plu3032 P. luminescens TT01 Putative bacteriophage protein; Some similarities with Unknown protein of Photorhabdus 6.08 22021.6 1 1.93 2.55 2.14 4.66
63 Hypothetical protein, plu3012 P. luminescens TT01 Probable phage protein; Similar to tail fiber assembly protein from bacteriophage 4.67 21467.8 1 1.66 1.72 5.27 0.48
Flagellin
31 Flagellin, plu1954 P. luminescens TT01 fliC Structural flagella protein 5.19 38183.6 1 0 0.1 0.87 0
Post-translational modification
61 PTS system, N-acetyl- galactosamine-specific IIB component 2 (EIIB-AGA’) (N-acetyl- galactosamine-perme, plu0835 P. luminescens TT01 agaV Probable PTS system; Highly similar to PTS system, cytoplasmic, N-acetylgalactosamine-specific 6.51 17774.4 1 3.87 2.18 4.31 1.5
Uknown
2 Hypothetical protein, plu0661 P. luminescens TT01 Highly similar to Unknown protein YgdH of E. coli 5.95 51257.2 1 2.74 0.81 2.51 1.76
21 Unknown Fanconi anemia group D1 protein LOC725687 Similar to Breast cancer type 2 susceptibility protein 8.75 82829.5 1 0.05 0 0 0
33 Hypothetical protein, plu3611 P. luminescens TT01 Similar to Unknown protein YggE of E. coli 5.97 25893.5 1 0 2.33 0.2 0.4
34 Hypothetical protein MHP7448_0445 Mycoplasma hyopneumoniae 7448 GI:72080777 9.17 275940.9 1 0.39 0.19 0.1 0.05
59 Hypothetical protein UM02446.1 Ustilago maydis 521 GI:124514614 8.96 130494.3 1 11.46 2.78 6.42 6.6

Table 4. Total proteins with altered level of synthesis in the nematicidal-producing and non nematicidal-producing mutants.

Spot No. Protein Name/plu Organism Gene Function Ratio
nematicidal-producing strains non nematicidal-producing strains
W/W R16/W R2/W R31/W R33/W
26 50S ribosomal protein L3, plu4726 P. luminescens TT01 rplC Binds directly near the 3′ end of the 23S rRNA, where it nucleates assembly of the 50S subunit; essential for peptidyltransferase activity; mutations in this gene confer resistance to tiamulin 1 0.41 0 0 0
4 ATP-dependent RNA helicase RhlE, plu1511 P. luminescens TT01 rhlE This helicase is not essential cell growth 1 0.52 0.05 0.04 0.02
19 ATP-dependent RNA helicase RhlE, plu1511 P. luminescens TT01 rhlE This helicase is not essential cell growth 1 1.43 0 0.2 0
5 Periplasmic chaperone, plu0681 P. luminescens TT01 hlpA Histone-like protein HLP-1 precursor 1 0.81 2.63 2.11 2.64
10 Unknown P. luminescens W14 From (type III secretion system, partial sequence) GI:27550090 1 1.53 0 0 0
64 Unknown P. luminescens w14 From (type III secretion system, partial sequence) GI:27550090 1 0.91 0.1 0.11 0.15
65 Unknown P. luminescens w14 From (type III secretion system, partial sequence) GI:27550090 1 0.93 0.11 0.11 0.16
49 Periplasmic protein disulfide isomerase I, plu0381 P. luminescens TT01 dsbA Disulfide interchange protein DsbA precursor 1 1.57 3.8 3.49 3.62
2 Hypothetical protein, plu0661 P. luminescens TT01 Highly similar to Unknown protein YgdH of E. coli 1 0.81 2.74 2.51 1.76
33 Hypothetical protein, plu3611 P. luminescens TT01 Similar to Unknown protein YggE of E. coli 1 2.33 0 0.2 0.4

To confirm these results, the downregulated rhlE and namB, and upregualted dsbA (GenBank accession number JX274431, JX274430 and JX274432 respectively) from the differentially expressed proteins were selected for construction of insertion-deletion mutations to determine the effects of the knock-out genes on the nematicial activity. Three P. luminescens LN2 mutants termed as LN2ΔrhlE, LN2ΔnamB and LN2ΔdsbA were created. Insertion-deletion mutations in these three genes were constructed using fusion PCR strategy as previously described [54]. For each gene, three fragments F1 (the upstream of the target gene), camR (Chloramphenicol cassette) and F2 (the downstream of the target gene) were generated using primer pairs of P1 and P2, P3 and P4, and P5 and P6 (Table S1), respectively. The camR gene was amplified from the plasmid pSZ21 [55] and the F1 and F2 gene fragments were amplified from P. luminescens LN2 genomic DNA. Approximately equal amounts of the three purified fragments F1, camR and F2 were mixed, and used as a template to generate a new DNA fragment by a second PCR performed with the primers P1 and P6. Three resulting fragments, which corresponded to rhlE::Cm, namB::Cm and dsbA::Cm, respectively, were separately cloned into a pMD-19T Simple vector. Then the resulting plasmids of pMD-rhlE::Cm, pMD-namB::Cm and pMD-dsbA::Cm were separately ligated to the same enzyme digested suicide vector pKNG101 [56] to generate pKNG101-rhlE::Cm, pKNG101- namB::Cm and pKNG101-dsbA::Cm. P. luminescens LN2 mutants termed as LN2ΔrhlE, LN2ΔnamB and LN2ΔdsbA were created by allelic exchange with pKNG101-rhlE::Cm, pKNG101- namB::Cm and pKNG101-dsbA::Cm, respectively, as previously described [54]. The phenotypic characterization, rpoB sequence and effects on nematicidal activity of three resulting mutants were determined as described above.

Results

Isolation and Characterization of the RifR Mutants of P. luminescens LN2

Several hundreds of the RifR mutants of P. luminescens LN2 were isolated and 34 mutants were randomly selected for further study. The wild type strain and the selected mutants showed the typical characteristics of phase one bacteria as described: uptake of dye from NBTA and MacConkey agar, production of pH-sensitive pigments, occurrence of inclusion bodies, antibiotic activity, and bioluminescence.

The Effects of the RifR Mutants on the Growth of H06 Nematodes

13 of 34 RifR P. luminescens LN2 mutants were able to support the growth of H06 IJs, with hermaphrodites containing living juveniles inside and outside after 12 days on the agar plates, while 21 of them were negative for the growth of H06 nematodes. On the bacterial lawns with those mutants or the wild-type, which did not support the nematode production, all the nematodes did not grow beyond adults and died after 7 days.

The Mutation Loci of rpoB Gene in the RifR Mutants

7 positive mutants (LN2-R2, LN2-R6, LN2-R12, LN2-R15, LN2-R28, LN2-R31 and LN2-R33) and 7 negative mutants (LN2-R3, LN2-R5, LN2-R7, LN2-R8, LN2-R11, LN2-R16 and LN2-R25) for H06 nematode growth (Table 2) were randomly selected for rpoB gene sequencing. The entire rpoB sequences of 14 selected RifR mutants, wild type strain, LN2-A and LN2-M1 were sequenced at least twice. The rpoB gene from all colonies was 4029 bp in length, the same to that of P. luminescens subsp. laumondii TT01 [57]. The identity of rpoB genes between the wild-type strain of LN2 and TT01 was 96.13%. All of the 14 RifR mutants carried mutations in the rpoB gene. 10 mutants showed a single nucleotide mutation resulting in an amino acid substitution, and 2 mutants presented two nucleotide mutations resulting in two amino acid substitutions, but only one mutant displayed three nucleotide mutations resulting in two amino acid substitutions (Table 2). No mutation was observed in the rpoB gene of AmpR mutant LN2-A and namA mutant LN2-M1.

The rpoB (P564L) mutation was found in all 7 mutants which produced nematicidal activity against H06 nematodes, but not in the mutants which supported H06 nematode production. While the single mutations of V146F, S512F, Q513K and double mutations of A313D and R529C were detected respectively in the mutants which supported H06 nematode production (Table 2). The single and double mutations resulted in loss of nematicidal activity against H06 nematodes and ability to supported H06 nematode production.

Allelic Exchange Assays

The recombinant LN2-WΔrpoB-LR31 (LN2-W strain containing the mutant rpoB allele from LN2-R31) and the LN2-R31ΔrpoB-LW (LN2-R31 containing the wild type rpoB allele from LN2-W) were selected on AmR RifR Tcs and AmR RifS Tcs LB1 agar plates, respectively.

Successful homologous recombination of rpoB gene in the recipient strains was verified by randomly selecting three colonies from each recipient and checking their rpoB gene sequences by PCR and DNA sequencing. The sequences of rpoB gene from three colonies of each recipient were 100% identical.

The recombinant LN2-WΔrpoB-LR31 showed Rif resistance and lost the nematicidal activity against H06 IJs, while LN2-R31ΔrpoB-LW was sensitive to Rif and restored the nematicidal activity. These results clearly indicated that rpoB mutation was responsible for the Rif-resistance and the absence of nematicidal activity of LN2-R31.

Insecticidal Activity

The RifR mutants, including nematicidal-producing LN2-R16 and non nematicidal-producing LN2-R2, LN2-R31 and LN2-R33, together with wild-type of P. luminescens LN2 caused 100% mortality of G. mellonella at the concentrations of 1000 CFU/µL after 24 h, 100 CFU/µL after 30 h, and 10 CFU/µL after 36 h. No insect mortality was recorded in the control after 120 h. It appeared that the mutant bacteria also displayed insecticidal activity against G. mellonella larvae.

IJ Colonization of the GFP-labelled Mutants

No H06 IJs from the culture with GFP-labeled LN2-R31 mutant contained GFP-labeled bacteria in their intestines. No GFP-labeled bacteria were also observed from the mechanically disrupted H06 IJs. However, the IJs of H. indica LN2 from GFP-labeled LN2-R31 mutant contained GFP-labeled bacteria in their intestines. Bacterial colonization of the intestines of IJs is an important process in the nematode-bacterium symbiosis. The present result demonstrated that the mutation of rpoB gene restored the nutrient suitability of the LN2 bacteria for the reproduction of H06 nematodes by silencing the nematicidal activity of the bacteria, but did not establish the environment for bacterial colonization of the IJs.

The Proteomic Analysis of the Mutants and Wild-type

The effects of rpoB mutations on the nematicidal activity of LN2 bacteria were further investigated by identifying the differentially expressed proteins by 2-DE. The parental and selected rpoB mutant strains grown on LB1 agar plates were collected after 48 h. Cells were disrupted and whole cell proteins were separated on 2-DE gels spanning the pH 3–10, silver stained, and analyzed by MS. Protein levels were expressed as percentage volume, which corresponds to the percentage ratio between the volume of a single spot and the total volume of all spots present in a gel. The mean values of spot intensity were calculated using at least three gels. Spots showing more than 15% variation were not considered (Student’s test, with 7 degrees of freedom, p<0.05). Little deviation was observed in the patterns on replica gels.

Approximately 900 spots were revealed on the silver-stained 2-DE patterns of the whole cell proteins from wild type strain LN2-W and the mutant strains of LN2-R16, LN2-R2, LN2-R31 and LN2-R33 (Figure S1, S2, S3, S4, S5). Protein spots were distributed over the 3–10 pH range, with most spots in the 4–7 pH range.

Major differences were detected from different rpoB mutants (Figure S1, S2, S3, S4, S5, Table 3). Comparing to the wild type strain, 19, 12 and 13 spots were differentially upregulated, downregulated or missing, respectively, by a factor of at least two in the rpoB mutant LN2-R2; 19, 12 and 9 spots in the LN2-R16; 17, 19 and 8 spots in the LN2-R31; and 13, 19 and 14 spots in the LN2-R33.

The spots with intensity changes by a factor of at least two were selected for MALDI-TOF-MS analysis (Table 3), using NCBI website and the PhotoList database (http://genolist.pasteur.fr/PhotoList/).

The proteins identified could be classified into thirteen categories based on functions: (1) ribosomal protein, (2) adaptation conditions, (3) secondary metabolities, (4) metabolisim of amino acids and related molecules, (5) nucleosides and nucleotides biosynthesis and metabolism, (6) cell wall/membrane biogenesis, (7) transport and binding proteins, (8) information and regulation pathways, (9) energy production and conversion, (10) phage-related proteins, (11) flagellin, (12) post-translational modification, and (13) other functions and unknown. A list of the proteins affected by rpoB mutation was shown in Table 3.

Proteomic analysis revealed major difference between wild-type strain and RifR mutants, and between nematicidal-producing and non nematicidal-producing mutants. In all the analyzed rpoB mutants, 15 putative proteins (YbdQ, Hcp, GlyA, UreG, ViuB, FabH, Ndk, Upp, Kst, MprA, DsbA, GpmA, AgaV, one bacteriophage protein and one unknown protein) were upregulated, and 11 (AhpC, CipA, cipB, HcaB, ISPPlu3Y, ISPlu10J, YqjD, TatA, DksA, FliC, and three hypothetical proteins) were downregulated. In particular, the following putative proteins were not detected from all the analyzed rpoB mutants: MacA (probable macrolide-specific ABC transporter, spot 13); DegQ (protease precursor, spot 37, 38); and KatE (catalase, spot 40, 41). Interestingly, an unknown function protein Brca2 (similar to breast cancer type 2 susceptibility protein, spot 21) was not present in the mutants, but present in the wild type strain. It appeared that the absence of these proteins was due to the rpoB mutation rather than the antibiotic pressure, because they were absent also from a namA disruption mutant of LN2 [41] without rpoB mutation in the culture without any rifampin (unpublished data).

Compared with the nematicidal-producing mutant LN2-R16 and wild type strain, four proteins in the non-nematicidal-producing mutants (LN2-R2, LN2-R31 and LN2-R33) were downregulated at least a 2-fold difference in expression, including RplC (putative ribosomal protein, spot 26), RhlE (putative nucleosides and nucleotides biosynthesis and metabolism protein, spot 4, 19), NamB (a putative transport and binding protein from type III secretion system, part of T3SS, spot 10, 64, 65) and a hypothetical protein (similar to unknown protein YggE of E. coli, spot 33); three proteins including DsbA (periplasmic protein disulfide isomerase I involved in information and regulatory pathways, spot 49), HlpA (periplasmic chaperone involved in cell wall/membrane biogenesis, spot 5), and a hypothetical protein(highly similar to unknown protein YgdH of E. coli, spot 2) were upregulated in the non-nematicidal-producing mutants(LN2-R2, LN2-R31 and LN2-R33) (Table 4, Figure S1, S2, S3, S4, S5). It was suggested that at least these 7 proteins were involved in the nematicidal activity of LN2 bacteria against H06 nematodes.

Genetic Confirmation of Differentially Expressed Proteins

LN2ΔrhlE, LN2ΔnamB and LN2ΔdsbA mutants showed the typical characteristics of phase one bacteria as the wild type strain. No mutation in rpoB gene was observed in these mutants. LN2ΔrhlE and LN2ΔnamB mutants were able to support the growth of H06 IJs, with hermaphrodites containing living juveniles inside and outside after 12 days on the agar plates, while LN2ΔdsbA mutant was negative for the growth of H06 nematodes as the wild type strain. The results confirmed the involvement of these selected genes in the nematicidal activity against H06 nematodes.

Discussion

In this study, a similar mechanism determining Rif-resistance in E. coli and M. tuberculosis [3], [11], [58] was verified in Photorhabdus bacteria. Surprisingly, the RifR mutants influenced the nematicidal activity of P. luminescens LN2 bacteria against a different nematode, H. bacteriophora H06. Furthermore, some but not all rpoB mutants of LN2 bacteria lost nematicidal activity against H06 IJs. The rpoB mutation was demonstrated to be responsible for the Rif-resistance and the effect on the nematicidal activity in the RifR mutants of LN2. There are fundamental connections between rifampin resistance, RNA polymerase structure and function and global gene expression in the literatures. Rif mutations in E. coli affected a wide variety of phenotypes, including altered growth properties and stimulated secondary metabolism [59]. A novel rpoB mutation in B. subtilis showed a unique spectrum of effects on growth and various developmental events [60]. An rpoB mutation in Streptomyces lividans activated antibiotic production and reduced growth rate [61]. A spontaneous RifR mutation isolated from Saccharopolyspora erythraea stimulated bacterial secondary metabolism and was severely impaired in erythromycin production [62]. To the best of our knowledge, this is the first report that rpoB mutations influenced the nematicidal activitity of a nematode symbiont on a non-cognate nematode partner. The symbiosis between the entomopathogenic nematodes and their associated bacteria will be also influenced by the rpoB mutations. However, how rpoB mutations affect this nematicidal activity needs to be further explored.

The mutants exhibited several phenotypes of phase one variant as previously described [47], e.g. absorption of the dye from NBTA and MacConkey agar, production of bioluminescence and occurrence of crystalline inclusion proteins in the cells. It was reported that the nematicidal activity occurred only in phase one of P. luminescens LN2 [31]. Apparently, the loss of nematicidal activity in the LN2 mutants against H06 nematodes was not the result of a typical phase variation. The physiological status of symbiotic Photorhabdus and Xenorhabdus bacteria (such as phase variation, mutants) may influence their fitness for nematode production. As rpoB mutations were associated with the nematode growth, screening of rpoB mutants of symbiotic bacteria of entomopathogenic nematodes may provide a way to select beneficial rpoB mutants by Rif for effective mass production of the nematodes.

One of the important characters in Photorhabdus bacteria is their insecticidal activities towards different insects [32][33], [35]. The present result indicated that the rpoB mutations did not change the expression of the toxin genes, at least in the tested mutants, for the mutants also displayed the insecticidal activity against G. mellonella larvae.

Different rpoB mutations were associated with their ability to support H06 nematode production. However, the P564L mutation was not associated with the loss of nematicidal activity. The reasons why the mutations affect the physiology and metabolism of the bacterial mutants are not known. The RNA polymerase complex may contact every promoter in the genome, thus any change in critical portions of the enzyme can lead to global changes in gene transcription. Mutations within the Rif binding pocket of rpoB gene may alter the structure of RNA polymerase and hence its regulated interaction with specific promoters, and hence physiology and metabolism [63].

Proteomic analysis revealed at least 7 putative proteins including DsbA, RhlE, NamB (a protein from T3SS), HlpA, RplC and 2 hypothetical proteins YggE and YgdH might be involved in the nematicidal activity. All these proteins may play different roles in different organisms (64–71). In the present study, it was hard to establish the functional relationship among these proteins in the nematicidal activity of LN2 bacteria. However, the insertion-deletion method confirmed the involvement of the selected corresponding genes (such as rhlE, namB and dsbA) from the differentially expressed proteins in the nematicidal activity against H06 nematodes. It seems that a big network system is involved in this nematicidal acitivity. Further work is needed to explore this system to understand the molecular mechanism on the trans-specific nematicidal activity of incompatible symbionts.

Supporting Information

Figure S1

2-DE map of total cell proteins from P. luminescens LN2 wild type strain. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S2

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R2. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S3

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R16. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S4

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R31. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S5

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R33. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Table S1

Oligonucleotide sequences used to generate Photorhabdus luminescens LN2 mutant constructs in this study.

(DOC)

Acknowledgments

We would like to thank Li Cao and Xiuling Liu for help in nematode culture.

Funding Statement

This work was supported by National Natural Science Foundation of China (No: 31010103912, No: 31000879 and No: 31101494), Natural Science Foundation of Guangdong Province, China (No: 10151026001000010) and Guangzhou Science & Technology Project (No: 2011J2200032). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

References

  • 1. Woodley CL, Kilburn JO, David HL, Silcox VA (1972) Susceptibility of mycobacteria to rifampin. Antimicrob Agents Chemother (2): 245–249. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 2. Mitchison DA (1985) Mechanism of drug action in short-course chemotherapy. Bull Int Union Against Tuber 65: 30–37. [PubMed] [Google Scholar]
  • 3. Telenti A, Imboden P, Marchesi F, Lowrie D, Cole S, et al. (1993) Detection of rifampicin resistance mutations in Mycobacterium tuberculosis . Lancet 341: 647–650. [DOI] [PubMed] [Google Scholar]
  • 4. Musser JM (1995) Antimicrobial agent resistance in mycobacteria - molecular-genetic insights. Clin Microbiol Rev 8: 496. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 5. Zhang GY, Campbell EA, Minakhin L, Richter C, Severinov K, et al. (1999) Crystal structure of Thermus aquaticus core RNA polymerase at 3.3 angstrom resolution. Cell 98: 811–824. [DOI] [PubMed] [Google Scholar]
  • 6. Campbell EA, Korzheva N, Mustaev A, Murakami K, Nair S, et al. (2001) Structural mechanism for rifampicin inhibition of bacterial RNA polymerase. Cell 104: 901–912. [DOI] [PubMed] [Google Scholar]
  • 7. Zhou YN, Jin DJ (1998) The rpoB mutants destabilizing initiation complexes at stringently controlled promoters behave like “stringent” RNA polymerases in Escherichia coli . Proc Natl Acad Sci U S A 95: 2908–2913. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8. Miller N, Hernandez SG, Cleary TJ (1994) Evaluation of gen-probe amplified mycobacterium-tuberculosis direct test and pcr for direct-detection of mycobacterium-tuberculosis in clinical specimens. J Clin Microbiol 32: 393–397. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 9. Ramaswamy S, Musser JM (1998) Molecular genetic basis of antimicrobial agent resistance in Mycobacterium tuberculosis: update. Tuber Lung Dis 79: 3–29. [DOI] [PubMed] [Google Scholar]
  • 10.Zhang Y, Telenti A (2000) Molecular genetics of mycobacteria; Washington DC: ASM Press. 235–254.
  • 11. Yuen LK, Leslie D, Coloe PJ (1999) Bacteriological and molecular analysis of rifampin-resistant Mycobacterium tuberculosis strains isolated in Australia. J Clin Microbiol 37: 3844–3850. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12. Riska PF, Jacobs WR Jr, Alland D (2000) Molecular determinants of drug resistance in tuberculosis. Int J Tuberc Lung Dis 4: S4–10. [PubMed] [Google Scholar]
  • 13. Herrera L, Jiménez S, Valverde A, García-Aranda MA, Sáez-Nieto JA (2003) Molecular analysis of rifampicin-resistant Mycobacterium tuberculosis isolated in Spain (1996–2001). Description of new mutations in the rpoB gene and review of the literature. Int J Antimicrob Agents 21: 403–408. [DOI] [PubMed] [Google Scholar]
  • 14. Zhang Y, Yew WW (2009) Mechanisms of drug resistance in Mycobacterium tuberculosis . Int J Tuberc Lung Dis 13: 1320–1330. [PubMed] [Google Scholar]
  • 15. Wang Q, Yue J, Zhang L, Xu Y, Chen J, et al. (2007) A Newly identified 191A/C mutation in the Rv2629 gene that was significantly associated with rifampin resistance in Mycobacterium tuberculosis . J Proteome Res 6: 4564–4571. [DOI] [PubMed] [Google Scholar]
  • 16. Castañeda-García A, Do TT, Blázquez J (2011) The K+ uptake regulator TrkA controls membrane potential, pH homeostasis and multidrug susceptibility in Mycobacterium smegmatis . J Antimicrob Chemother 66: 1489–1498. [DOI] [PubMed] [Google Scholar]
  • 17. Cui L, Isii T, Fukuda M, Ochiai T, Neoh HM, et al. (2010) An RpoB mutation confers dual heteroresistance to daptomycin and vancomycin in Staphylococcus aureus . Antimicrob Agents Chemother 54: 5222–5233. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 18. Watanabe Y, Cui L, Katayama Y, Kozue K, Hiramatsu K (2011) Impact of rpoB Mutations on Reduced Vancomycin Susceptibility in Staphylococcus aureus . J Clin Microbiol 49: 2680–2684. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 19. Georgis R, Koppenhofer AM, Lacey LA, Belair G, Duncan LW, et al. (2006) Successes and failures in the use of parasitic nematodes for pest control. Biol Control 38: 103–123. [Google Scholar]
  • 20. Poinar GO Jr, Thomas GM (1966) Significance of Achromobacter nematophilus Poinar and Thomas (Achromobacteriaceae: Eubacteriales) in the development of the nematode DD-136 (Neoplectana sp., Steinernematidae). Parasitol 56: 385–390. [DOI] [PubMed] [Google Scholar]
  • 21. Ciche TA, Darby C, Ehlers R-U, Forst S, Goodrich-Blair H (2006) Dangerous liaisons: the symbiosis of entomopathogenic nematodes and bacteria. Biol Control 38: 22–46. [Google Scholar]
  • 22. Goodrich-Blair H, Clarke DJ (2007) Mutualism and pathogenesis in Xenorhabdus and Photorhabdus: two roads to the same destination. Mol Microbiol 64: 260–268. [DOI] [PubMed] [Google Scholar]
  • 23. Akhurst RJ (1983) Neoaplectana species: specificity of association with bacteria of the genus Xenorhabdus . Exp Parasitol 55: 258–263. [DOI] [PubMed] [Google Scholar]
  • 24.Akhurst RJ, Boemare NE (1990) Biology and taxonomy of Xenorhabdus. In: Gaugler R, Kaya HK, editors. Entomopathogenic Nematodes in Biological Control. Florida: CRC press. 75–90.
  • 25. Ehlers R-U, Stoessel S, Wyss U (1990) The influence of phase variants of Xenorhabdus spp. and Escherichia coli (Enterobacteriaceae) on the propagation of entomopathogenic nematodes of the genera Steinernema and Heterorhabditis. . Revue de Nematologie 13: 417–424. [Google Scholar]
  • 26. Han RC, Wouts WM, Li LY (1990) Development of Heterorhabditis spp. strains as characteristic of possible Xenorhabdus luminescens subspecies. Revue de Nematologie 13: 411–415. [Google Scholar]
  • 27. Han RC, Wouts WM, Li LY (1991) Development and virulence of Heterorhabditis spp. strains associated with different Xenorhabdus luminescens isolates. J Invertebr Pathol 58: 27–32. [Google Scholar]
  • 28. Gerritsen LJM, Smits PH (1993) Variation in pathogenicity of recombinations of Heterorhabditis and Xenorhabdus luminescens strains. Fund Appl Nematol 16: 367–373. [Google Scholar]
  • 29. Gerritsen LJM, Smits PH (1997) The influence of Photorhabdus luminescens strains and form variants on the reproduction and bacterial retention of Heterorhabditis megidis . Fund Appl Nematol 20: 317–322. [Google Scholar]
  • 30. Han RC, Ehlers R-U (1998) Cultivation of axenic Heterorhabditis spp. dauer juveniles and their response to non-specific Photorhabdus luminescens food signals. Nematologica 44: 425–435. [Google Scholar]
  • 31. Han RC, Ehlers R-U (2001) Effect of Photorhabdus luminescens phase variants on the in vivo and in vitro development and reproduction of the entomopathogenic nematodes Heterorhabditis bacteriophora and Steinernema carpocapsae . FEMS Microbiol Ecol 35: 239–247. [DOI] [PubMed] [Google Scholar]
  • 32. Bowen DJ, Ensign JC (1998) Purification and characterization of a high-molecular-weight insecticidal protein complex produced by the entomopathogenic bacterium Photorhabdus luminescens . Appl Environ Microbiol 64: 3029–3035. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 33. Bowen D, Rocheleau TA, Blackburn M, Andreev O, Golubeva E, et al. (1998) Insecticidal toxins from the bacterium Photorhabdus luminescens . Science 280: 2129–2132. [DOI] [PubMed] [Google Scholar]
  • 34.Ensign JC, Bowen DJ, Tenor J, Petell JK, Orr GL, et al. (2002) Insecticidal protein toxins from Xenorhabdus. PCT Patent, No. US6379946 B1.
  • 35. Yang G, Dowling AJ, Gerike U, ffrench-Constant RH, Waterfield NR (2006) Photorhabdus virulence cassettes confer injectable insecticidal activity against the wax moth. J Bacteriol 188: 2254–2261. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 36. Ffrench-Constant RH, Dowling A, Waterfield NR (2007) Insecticidal toxins from Photorhabdus bacteria and their potential use in agriculture. Toxicon 49: 436–451. [DOI] [PubMed] [Google Scholar]
  • 37. Hu K, Li J, Webster JM (1995) Mortality of plant-parasitic nematodes caused by bacterial (Xenorhabdus spp. and Photorhabdus luminescens) culture media. J Nematol 27: 502–503. [Google Scholar]
  • 38. Sicard M, Hering S, Schulte R, Gaudriault S, Schulenburg H (2007) The effect of Photorhabdus luminescens (Enterobacteriaceae) on the survival, development, reproduction and behaviour of Caenorhabditis elegans (Nematoda: Rhabditidae) Environ Microbiol. 9: 12–25. [DOI] [PubMed] [Google Scholar]
  • 39. Sicard M, Ferdy JB, Pagès S, Le Brun N, Godelle B, et al. (2004) When mutualists are pathogens: an experimental study of the symbioses between Steinernema (entomopathogenic nematodes) and Xenorhabdus (bacteria). J Evol Biol 17: 985–993. [DOI] [PubMed] [Google Scholar]
  • 40. Han RC, Ehlers R-U (1999) Trans-specific nematicidal activity of Photorhabdus luminescens . Nematology 1: 687–693. [Google Scholar]
  • 41. Qiu XH, Han RC, Yan X, Liu MX, Li C, et al. (2009) Identification and characterization of a novel gene involved in the trans-specific nematicidal activity of Photorhabdus luminescens LN2. Appl Environ Microb 75: 4221–4223. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 42. Heungens K, Cowles CE, Goodrich-Blair H (2002) Identification of Xenorhabdus nematophila genes required for mutualistic colonization of Steinernema carpocapsae nematodes. Mol Microbiol 45: 1337–1353. [DOI] [PubMed] [Google Scholar]
  • 43. Joyce SA, Clarke DJ (2003) A hexA homologue from Photorhabdus regulates pathogenicity, symbiosis and phenotypic variation. Mol Microbiol 47: 1445–1457. [DOI] [PubMed] [Google Scholar]
  • 44. Cowles CE, Goodrich-Blair H (2004) Characterization of a lipoprotein, NilC, required by Xenorhabdus nematophila for mutualism with its nematode host. Mol Microbiol 54: 464–477. [DOI] [PubMed] [Google Scholar]
  • 45. Martens E, Goodrich-Blair H (2005) The Steinernema carpocapsae intestinal vesicle contains a subcellular structure with which Xenorhabdus nematophila associates during colonization initiation. Cell Microbiol 7: 1723–1735. [DOI] [PubMed] [Google Scholar]
  • 46. Chalabaev S, Turlin E, Charles JF, Namane A, Pagès S, et al. (2007) The HcaR regulatory protein of Photorhabdus luminescens affects the production of proteins involved in oxidative stress and toxemia. Proteomics 7: 4499–4510. [DOI] [PubMed] [Google Scholar]
  • 47. Akhurst RJ (1980) Morphological and functional dimorphism in Xenorhabdus spp., bacteria symbiotically associated with the insect pathogenic nematodes Neoaplectana and Heterorhabditis . J Gen Microbiol 121: 303–309. [DOI] [PubMed] [Google Scholar]
  • 48. Akhurst RJ (1982) Antibiotic activity of Xenorhabdus spp., bacteria symbiotically associated with insect pathogenic nematodes of the families Heterorhabditidae and Steinernematidae. J Gen Microbiol 128: 3061–3065. [DOI] [PubMed] [Google Scholar]
  • 49.Sambrook J, Russell DW (2001) Molecular Cloning: A Laboratory Manual, 3rd ed. NewYork: Cold Spring Harbor Laboratory Pres. 2344 p.
  • 50. Hübner P, Masepohl B, Klipp W, Bickle TA (1993) nif gene expression studies in Rhodobacter capsulatus: ntrC-independent repression by high ammonium concentrations. Mol Microbiol 10: 123–132. [DOI] [PubMed] [Google Scholar]
  • 51. Simon R, Priefer U, Pühler A (1983) A broad host range mobilization system for in vivo genetic engineering: transposon mutagenesis in gram negative bacteria. Biotechnology 1: 784–791. [Google Scholar]
  • 52. Herrero M, de Lorenzo V, Timmis KN (1990) Transposon vectors containing non-antibiotic resistance selection markers for cloning and stable chromosomal insertion of foreign genes in gram-negative bacteria. J Bacteriol 172: 6557–6567. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 53. Gorg A, Postel W, Domscheit A, Günther S (1988) Two-dimensional electrophoresis with immobilized pH gradients of leaf proteins from barley (Hordeum vulgare): method, reproducibility and genetic aspects. Electrophoresis. 9: 681–692. [DOI] [PubMed] [Google Scholar]
  • 54. An R, Grewal PS (2010) Molecular mechanisms of persistence of mutualistic bacteria Photorhabdus in the entomopathogenic nematode host. PLoS One 5: e13154. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 55. Jiang QY, Zhou ZH, Shen SE, Jin RZ, Huang YD, et al. (1990) Construction of recombinant plasmid of Tn5-nifA having conjugal mobilization of broad host range. Chinese Science Bulletin (in Chinese) 35: 302–305. [Google Scholar]
  • 56. Kaniga K, Delor I, Cornelis GR (1991) A wide-host-range suicide vector for improving reverse genetics in Gram-negative bacteria: inactivation of the blaA gene of Yersinia enterocolitica . Gene 109: 137–141. [DOI] [PubMed] [Google Scholar]
  • 57. Duchaud E, Rusniok C, Frangeul L, Buchrieser C, Givaudan A, et al. (2003) The genome sequence of the entomopathogenic bacterium Photorhabdus luminescens. Nat Biotechnol 21: 1307–1313. [DOI] [PubMed] [Google Scholar]
  • 58. Jin D, Gross C (1988) Mapping and sequencing of mutations in the Escherichia coli rpoB gene that leads to rifampicin resistance. J Mol Biol 202: 45–58. [DOI] [PubMed] [Google Scholar]
  • 59. Jin DJ, Gross CA (1989) Characterization of the pleiotropic phenotypes of rifampin-resistant rpoB mutants of Escherichia coli . J Bacteriol 171: 5229–5231. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 60. Maughan H, Galeano B, Nicholson WL (2004) Novel rpoB mutations conferring rifampin resistance on Bacillus subtilis: global effects on growth, competence, sporulation, and germination. J Bacteriol 186: 2481–2486. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 61. Lai C, Xu J, Tozawa Y, Okamoto-Hosoya Y, Yao X, et al. (2002) Genetic and physiological characterization of rpoB mutations that activate antibiotic production in Streptomyces lividans. . Microbiology 148: 3365–3373. [DOI] [PubMed] [Google Scholar]
  • 62. Carata E, Peano C, Tredici SM, Ferrari F, Talà A, et al. (2009) Phenotypes and gene expression profiles of Saccharopolyspora erythraea rifampicin-resistant (rif) mutants affected in erythromycin production. Microbial Cell Factories 8: 18. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 63. Perkins AE, Nicholson WL (2008) Uncovering new metabolic capabilities of Bacillus subtilis using phenotype profiling of rifampin-resistant rpoB mutants. J Bacteriol 190: 807–814. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 64. Shouldice SR, Heras B, Walden PM, Totsika M, Schembri MA, et al. (2011) Structure and function of DsbA, a key bacterial oxidative folding catalyst. Antioxid Redox Signal 14: 1729–1760. [DOI] [PubMed] [Google Scholar]
  • 65. Jain C (2008) The E. coli RhlE RNA helicase regulates the function of related RNA helicases during ribosome assembly. RNA 14: 381–389. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 66. Cartier G, Lorieux F, Allemand F, Dreyfus M, Bizebard T (2010) Cold adaptation in DEAD-box proteins. Biochemistry 49: 2636–2646. [DOI] [PubMed] [Google Scholar]
  • 67. Gentry DR, Rittenhouse SF, McCloskey L, Holmes DJ (2007) Stepwise exposure of Staphylococcus aureus to pleuromutilins is associated with stepwise acquisition of mutations in rplC and minimally affects susceptibility to retapamulin. Antimicrob Agents Chemother 51: 2048–2052. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 68. Brugirard-Ricaud K, Duchaud E, Givaudan A, Girard PA, Kunst F, et al. (2005) Site-specific antiphagocytic function of the Photorhabdus luminescens type III secretion system during insect colonization. Cell Microbiol 7: 363–371. [DOI] [PubMed] [Google Scholar]
  • 69. Schmidt MA, Balsanelli E, Faoro H, Cruz LM, Wassem R, et al. (2012) The type III secretion system is necessary for the development of a pathogenic and endophytic interaction between Herbaspirillum rubrisubalbicans and Poaceae . BMC Microbiol 12: 98. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 70. Kim SY, Nishioka M, Hayashi S, Honda H, Kobayashi T, et al. (2005) The gene yggE functions in restoring physiological defects of Escherichia coli cultivated under oxidative stress conditions. Appl Environ Microbiol 71: 2762–2765. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 71. Stinson MW, McLaughlin R, Choi SH, Juarez ZE, Barnard J (1998) Streptococcal histone-like protein: primary structure of hlpA and protein binding to lipoteichoic acid and epithelial cells. Infect Immun 66: 259–265. [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Figure S1

2-DE map of total cell proteins from P. luminescens LN2 wild type strain. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S2

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R2. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S3

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R16. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S4

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R31. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Figure S5

2-DE map of total cell proteins from P. luminescens LN2 RifR mutant LN2-R33. A representative gel shows the identified differentially expressed protein spots. 350 µg of total cell proteins was loaded onto a 17 cm pH 3–10 NL IPG strip, separated in the second dimension by SDS-polyacrylamide gel electrophoresis on a 12% gel and stained with silver nitrate.

(TIF)

Table S1

Oligonucleotide sequences used to generate Photorhabdus luminescens LN2 mutant constructs in this study.

(DOC)


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