Metagenomics revealed a quorum quenching lactonase QlcA from yet unculturable soil bacteria.

Quorum sensing (QS) is a signal mediated cell-cell communication system that couples bacterial cell density to a synchronized gene expression (Fuqua et al., 1994). Mostly, in Gram negative bacteria QS signals are N-acylhomoserine lactones (NAHLs) that coordinate important functions such as virulence and pathogenicity. QS signals or the elements involved in their production or perception could be targeted to disrupt QS, a phenomenon called Quorum quenching (QQ). QQ properties (chemicals and enzymes) are naturally found in various Living organisms, like bacteria (Rhodococcus and Commamonas), plants (carrot, soybean, pea seedling, chilli, garlic etc), and animals (human sera, pork kidney tissues). Consequently, various bacterial genes encoding for NAHL degrading enzymes, like NAHL lactonases (AiiA in Bacillus, AiiB and AttM in Agrobacterium tumefaciens) and acylase/-amidohydrolase (AiiD in Ralstonia) were identified (Givskov et al., 2006). In Pectobacterium carotovorum (causal agent of soft rot diseases) production of various virulence factors and cell wall maceration enzymes is QS dependant, and relies upon successful production, stability, emission and perception of NAHLs (C-8, oxo-C8 and C-10). Disruption of QS signalling by NAHL degrading bacteria, modified bacteria or plants expressing NAHL lactonases resulted in the reduced virulence of the pathogen (Faure et al., 2007). Until recently, investigations on QQ enzymes were carried out mostly on cultivable bacteria, that represent a tiny fraction of soil and root-associated bacteria. In this study, a metagenomics approach (Handelsman, 2004) was employed to access the hidden diversity of uncultivable soil bacteria that revealed a QQ enzyme, an NAHL lactonase, in these bacteria (Riaz et al., 2008).

[Violacein: a molecule of biological interest originating from the soil-borne bacterium Chromobacterium violaceum]. / La violacéine: une molécule d'intérêt biologique, issue de la bactérie tellurique Chromobacterium violaceum.

INTRODUCTION: Soil micro-organisms have evolved functions that allow them to withstand the strong competition for survival that characterizes most of their habitats. The production of antibiotic or antifungal compounds is one of these mechanisms. The relevant molecules often exhibit valuable therapeutic properties. EXEGESIS: Chromobacterium violaceum is a soil-borne bacterium producing a characteristic antibiotic termed violacein. It is part of a series of compounds released by C. violaceum to oppose competitors and predators in the soil and water environments. Violacein, and one of these compounds, i.e. structure FR901228, exhibit antiparasitic and antitumoral activities of potential medical interest. Genes involved in the synthesis of these compounds are available, the genome sequence of C. violaceum (strain ATCC 12472) being published. CONCLUSIONS: The above example, involving Chromobacterium, is not an exception: soil constitutes a reservoir of molecules, enzymatic activities and micro-organisms of biological interest, the study of which will undoubtedly lead to developments in fields as diverse as agronomy or animal and human therapeutics.

Physiological evidence for differently regulated tryptophan-dependent pathways for indole-3-acetic acid synthesis in Azospirillum brasilense.

Disruption of ipdC, a gene involved in indole-3-acetic acid (IAA) production by the indole pyruvate pathway in Azospirillum brasilense Sp7, resulted in a mutant strain that was not impaired in IAA production with lactate or pyruvate as the carbon source. A tryptophan auxotroph that is unable to convert indole to tryptophan produced IAA if tryptophan was present but did not synthesise IAA from indole. Similar results were obtained for a mutant strain with additional mutations in the genes ipdC and trpD. This suggests the existence of an alternative Trp-dependent route for IAA synthesis. On gluconate as a carbon source, IAA production by the ipdC mutant was inhibited, suggesting that the alternative route is regulated by catabolite repression. Using permeabilised cells we observed the enzymatic conversion of tryptamine and indole-3-acetonitrile to IAA, both in the wild-type and in the ipdC mutant. IAA production from tryptamine was strongly decreased when gluconate was the carbon source.

Control of Azospirillum brasilense NifA activity by P(II): effect of replacing Tyr residues of the NifA N-terminal domain on NifA activity.

It was previously reported that the N-terminal domain of Azospirillum brasilense NifA was a negative regulator of the NifA activity and that the P(II) protein prevented this inhibition under nitrogen fixing conditions. Here, we show that a mutation of a single Tyr residue at position 18 of the N-terminal domain of NifA led to an active NifA protein that did not require P(II) for activation under nitrogen fixation conditions.

Poly-beta-hydroxybutyrate turnover in Azorhizobium caulinodans is required for growth and affects nifA expression.

Azorhizobium caulinodans is able to fix nitrogen in the free-living state and in symbiosis with the tropical legume Sesbania rostrata. The bacteria accumulate poly-beta-hydroxybutyrate (PHB) under both conditions. The structural gene for PHB synthase, phbC, was inactivated by insertion of an interposon. The mutant strains obtained were devoid of PHB, impaired in their growth properties, totally devoid of nitrogenase activity ex planta (Nif-), and affected in nucleotide pools and induced Fix- nodules devoid of bacteria. The Nif- phenotype was the consequence of the lack of nifA transcription. Nitrogenase activity was partially restored to a phbC mutant by constitutive expression of the nifA gene. However, this constitutive nifA expression had no effect on the nucleotide content or on growth of the phbC mutant. It is suggested that PHB is required for maintaining the reducing power of the cell and therefore the bacterial growth. These observations also suggest a new control of nifA expression to adapt nitrogen fixation to the availability of carbon and reducing equivalents.

Characterisation of the glnK-amtB operon and the involvement of AmtB in methylammonium uptake in Azorhizobium caulinodans.

This work reports the characterisation of the Azorhizobium caulinodans amtB gene, the deduced protein sequence of which shares similarity to those of several ammonium transporters. amtB is located downstream from glnK, a glnB-like gene. It is cotranscribed with glnK from an NtrC- and sigma54-dependent promoter. glnK and amtB insertion mutant strains have been isolated. Methylammonium uptake was assayed in these strains and in other mutant strains in which the regulation of nitrogen metabolism is impaired. Our data suggest that the AmtB protein is an ammonium transporter, which is mainly regulated by NtrC in response to nitrogen availability.

The control of Azorhizobium caulinodans nifA expression by oxygen, ammonia and by the HF-I-like protein, NrfA.

The control of Azorhizobium caulinodans nifA expression in response to oxygen and ammonia involves FixLJ, FixK, NtrBC, NtrXY and the HF-I-like protein NrfA. The regulation is thus complex and possibly involves post-transcriptional regulation by NrfA. The coding region of nifA was determined using a translational lacZ fusion and by site-directed mutagenesis to identify which of four in frame AUG codons was used. The major NifA protein is translated from the second AUG codon and is predicted to consist of 613 amino acids. Primer extension analysis showed a major transcript starting 34 bp downstream from the anaerobox in wild-type, nifA, rpoN, ntrC and nrfA strains, but not in a fixK mutant. FixK- and oxygen-dependent transcription of nifA was confirmed by the analysis of four transcriptional nifA-lacZ fusions with fusion junctions at positions +1, +47, +110 and +181 with respect to the start site. Regulation by ammonia was independent of FixK and RpoN, NtrC being only partially required. Thus, there may be another type of nitrogen control that does not involve NtrC in A. caulinodans. NrfA is not required for the initiation of nifA transcription but, most probably, has an effect on nifA mRNA stability and/or translation. NrfA also restores the defect in rpoS translation to an Escherichia coli hfq mutant, indicating that HF-I and NrfA have similar activities in both A. caulinodans and E. coli.

A transcriptional regulator of the LuxR-UhpA family, FlcA, controls flocculation and wheat root surface colonization by Azospirillum brasilense Sp7.

Genetic complementation of a spontaneous mutant, impaired in flocculation, Congo red binding, and colonization of root surface, led to the identification of a new regulatory gene in Azospirillum brasilense Sp7, designated flcA. The deduced amino acid sequence of flcA shared high similarity with a family of transcriptional activators of the LuxR-UphA family. The most significant match was with the AgmR protein, an activator for glycerol metabolism in Pseudomonas aeruginosa. Derivatives of Sp7 resulting from site-directed Tn5 mutagenesis in the flcA coding sequence were constructed by marker exchange. Characterization of the resulting mutant strains showed that flcA controls the production of capsular polysaccharides, the flocculation process in culture, and the colonization of the root surface of wheat. This study provides new information on the genetic control of the mechanism of plant root colonization by Azospirillum.

[The construction of Alcaligenes faecalis ntrC-lacZ fusion gene and its expression during association with rice roots].

A broad host range vector pLA2917 containing ntrC gene or ntrC-lacZ fusion were constructed, namely pLAC1 and pLAC2. The plasmids pLAC1 and pLAC2 were introduced into A. faecalis wild type strain A1501 by conjugation, subsequently to abtain A15C1 and A15C2. The expression and regulation of ntrC gene of A. faecalis associated with rice roots was investigated under the condition of the associative nitrogen fixation using X-Gal decoration method, micrograph and ntrC partially deletion mutant. The blue precipitation was strongly existed in parenchyma cells as well as in the lateral root primordial. It showed that ntrC gene could express at much higher level in these sites. In the presence of ammonia, the number of multi-copy ntrC conjugatants colonized on surface of rice roots is higher than that of wild type A1501, and the colonization of ntrC mutant is weakest among these three strains. This provided an evidence that ntrC gene might be involved in procedure of colonization of A. faecalis to rice roots.

Characterization of Azorhizobium caulinodans glnB and glnA genes: involvement of the P(II) protein in symbiotic nitrogen fixation.

The nucleotide sequence and transcriptional organization of Azorhizobium caulinodans ORS571 glnA, the structural gene for glutamine synthetase (GS), and glnB, the structural gene for the P(II) protein, have been determined. glnB and glnA are organized as a single operon transcribed from the same start site, under conditions of both nitrogen limitation and nitrogen excess. This start site may be used by two different promoters since the expression of a glnB-lacZ fusion was high in the presence of ammonia and enhanced under conditions of nitrogen limitation in the wild-type strain. The increase was not observed in rpoN or ntrC mutants. In addition, this fusion was overexpressed under both growth conditions, in the glnB mutant strain, suggesting that P(II) negatively regulates its own expression. A DNA motif, similar to a sigma54-dependent promoter consensus, was found in the 5' nontranscribed region. Thus, the glnBA operon seems to be transcribed from a sigma54-dependent promoter that operates under conditions of nitrogen limitation and from another uncharacterized promoter in the presence of ammonia. Both glnB and glnBA mutant strains derepress their nitrogenase in the free-living state, but only the glnBA mutant, auxotrophic for glutamine, does not utilize molecular nitrogen for growth. The level of GS adenylylation is not affected in the glnB mutant as compared to that in the wild type. Under symbiotic conditions, the glnB and glnBA mutant strains induced Fix- nodules on Sesbania rostrata roots. P(II) is the first example in A. caulinodans of a protein required for symbiotic nitrogen fixation but dispensable in bacteria growing in the free-living state.

Modulation of NifA activity by PII in Azospirillum brasilense: evidence for a regulatory role of the NifA N-terminal domain.

Azospirillum brasilense NifA, which is synthesized under all physiological conditions, exists in an active or inactive from depending on the availability of ammonia. The activity also depends on the presence of PII, as NifA is inactive in a glnB mutant. To investigate further the mechanism that regulates NifA activity, several deletions of the nifA coding sequence covering the amino-terminal domain of NifA were constructed. The ability of these truncated NifA proteins to activate the nifH promoter in the absence or presence of ammonia was assayed in A. brasilense wild-type and mutant strains. Our results suggest that the N-terminal domain is not essential for NifA activity. This domain plays an inhibitory role which prevents NifA activity in the presence of ammonia. The truncated proteins were also able to restore nif gene expression to a glnB mutant, suggesting that PII is required to activate NifA by preventing the inhibitory effect of its N-terminal domain under conditions of nitrogen fixation. Low levels of nitrogenase activity in the presence of ammonia were also observed when the truncated gene was introduced into a strain devoid of the ADP-ribosylation control of nitrogenase. We propose a model for the regulation of NifA activity in A. brasilense.

Coexistence of two structurally similar but functionally different PII proteins in Azospirillum brasilense.

The coexistence of two different PII, proteins in Azospirillum brasilense was established by comparing proteins synthesized by the wild-type strain and two null mutants of the characterized glnB gene (encoding PII) adjacent to glnA. Strains were grown under conditions of nitrogen limitation or nitrogen excess. The proteins were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) or isoelectric focusing gel electrophoresis and revealed either by [32P]phosphate or [3H]uracil labeling or by cross-reaction with an anti-A. brasilense PII-antiserum. After SDS-PAGE, a single band of 12.5 kDa revealed by the antiserum in all conditions tested was resolved by isoelectric focusing electrophoresis into two bands in the wild-type strain, one of which was absent in the glnB null mutant strains. The second PII protein, named Pz, was uridylylated under conditions of nitrogen limitation. The amino acid sequence deduced from the nucleotide sequence of the corresponding structural gene, called glnZ, is very similar to that of PII. Null mutants in glnB were impaired in regulation of nitrogen fixation and in their swarming properties but not in glutamine synthetase adenylylation. No glnZ mutant is yet available, but it is clear that PII and Pz are not functionally equivalent, since glnB null mutant strains exhibit phenotypic characters. The two proteins are probably involved in different regulatory steps of the nitrogen metabolism in A. brasilense.

A mutant of Azospirillum brasilense Sp7 impaired in flocculation with a modified colonization pattern and superior nitrogen fixation in association with wheat.

We report here significant phenotypic and genetic differences between Azospirillum brasilense Sp7 and spontaneous mutant Sp7-S and their related properties in association with wheat. In contrast to the wild-type strain of Sp7, colonies of Sp7-S stained weakly with Congo red when grown on agar media containing the dye and did not flocculate in the presence of fructose and nitrate. Scanning and transmission electron micrographs showed clearly that the Sp7-S strain lacked surface materials present as a thick layer on the surface of the wild-type Sp7 strain. Different patterns of colonization on wheat roots between Sp7 and Sp7-S, revealed by in situ studies using nifA-lacZ as a reporter gene, were related to a large increase in nitrogenase activity (acetylene reduction) with Sp7-S in association with normal and 2,4-dichlorophenoxyacetic acid-treated wheat for assays conducted under conditions in which the nitrogenase activity of free-living Azospirillum organisms was inhibited by an excess of oxygen. Randomly amplified polymorphic DNA analysis indicated the close genetic relationship of Sp7-S to several other sources of Sp7, by comparison to other recognized strains of A. brasilense. Genetic complementation of Sp7-S was achieved with a 9.4-kb fragment of DNA cloned from wild-type Sp7, restoring Congo red staining and flocculation.

The expression of nifA in Azorhizobium caulinodans requires a gene product homologous to Escherichia coli HF-I, an RNA-binding protein involved in the replication of phage Q beta RNA.

We report the characterization of a mutant of Azorhizobium caulinodans, isolated after ethyl methanesulfonate mutagenesis. This Nod+ Nif- Fix- mutant is unable to synthesize 10 of 15 polypeptides normally induced under conditions of nitrogen fixation. By using lacZ fusions it was shown that nifA and nifA-regulated genes were not expressed in this strain. The mutation was complemented by a constitutively expressed nifA gene or by a 1.1-kb DNA fragment from the wild-type strain, whose nucleotide sequence revealed a single open reading frame of 255 bp coding for an 85-amino acid polypeptide. The deduced amino acid sequence is similar to that of HF-I, an RNA-binding protein of Escherichia coli, which is required for replication of bacteriophage Q beta RNA. The similarity can be extended to the function since hfq, the structural gene for HF-I, complemented the A. caulinodans mutant. The corresponding gene in A. caulinodans was termed nrfA (for nif regulatory factor). Inactivation of nrfA in the mutant was due to a missense mutation resulting in the replacement of a cysteine residue by arginine. A null mutant, constructed by disruption of nrfA, exhibited the same phenotype as the missense mutant. Thus, an additional factor can be added to the already complex system of nifA regulation in A. caulinodans.

Functional analysis of the fixNOQP region of Azorhizobium caulinodans.

The deduced amino acid sequences of four open reading frames identified upstream of the fixGHI region in Azorhizobium caulinodans are very similar to the putative terminal oxidase complex coded by the fixNOQP operons from Rhizobium meliloti and Bradyrhizobium japonicum. The expression of the A. caulinodans fixNOQP genes, which was maximal under microaerobiosis, was positively regulated by FixK and independent of NifA. In contrast to the Fix- phenotype of B. japonicum and R. meliloti fixN mutants, an A. caulinodans fixNO-deleted mutant strain retained 50% of the nitrogenase activity of the wild type in the symbiotic state. In addition, the nitrogenase activity was scarcely reduced under free-living conditions. Analysis of membrane fractions of A. caulinodans wild-type and mutant strains suggests that the fixNOQP region encodes two proteins with covalently bound hemes, tentatively assigned to fixO and fixP. Spectral analysis showed a large decrease in the c-type cytochrome content of the fixN mutant compared with the wild type. These results provide evidence for the involvement of FixNOQP proteins in a respiratory process. The partial impairment in nitrogen fixation of the fixN mutant in planta may be due to the activity of an alternative terminal oxidase compensating for the loss of the oxidase complex encoded by fixNOQP.

Role of the fixGHI region of Azorhizobium caulinodans in free-living and symbiotic nitrogen fixation.

A 19-kb DNA region containing genes sharing homology with Rhizobium meliloti fixNOQP and fixGHI was isolated from a genomic library of Azorhizobium caulinodans. Identity of fixG was confirmed by partial nucleotide sequencing. Mutant strains in the fixGHI region were constructed by deletion or Tn5 insertions. In contrast with the situation in R. meliloti, the mutants still displayed a significant nitrogenase activity in symbiosis.

Characterization of the ntrBC genes of Azospirillum brasilense Sp7: their involvement in the regulation of nitrogenase synthesis and activity.

A 7.1 kb EcoRI fragment from Azospirillum brasilense, that hybridized with a probe carrying the ntrBC genes from Bradyrhizobium japonicum, was cloned. The nucleotide sequence of a 3.8 kb subfragment was established. This led to the identification of two open reading frames, encoding polypeptides of 401 and 481 amino acids, that were similar to NtrB and NtrC, respectively. A broad host range plasmid containing the putative Azospirillum ntrC gene was shown to restore nitrogen fixation under free-living conditions to a ntrC-Tn5 mutant of Azorhizobium caulinodans. Several Tn5 insertion mutants were isolated in the ntrBC coding region in A brasilense. These mutants were prototrophic and Nif+. However, their nitrogenase activity was slightly lower than in the wild type and they were unable to grow on nitrate as sole nitrogen source. Under microaerobiosis and in the absence of ammonia, a nifA-lacZ fusion was expressed in the mutants at about 60% of the level in the wild type. In the presence of ammonia, the fusion was similarly expressed (60% of the maximum) both in the wild type and mutants. Addition of ammonia to a nitrogen-fixing culture of ntrBC mutants did not abolish nitrogenase activity, in contrast with the wild type. It thus appears that in Azospirillum the ntrBC genes are not essential for nitrogen fixation, although NtrC controls nifA expression to some extent. They are, however, required for the switch-off of nitrogenase activity.

Functional organization of the glnB-glnA cluster of Azospirillum brasilense.

The functional organization of the glnB-A cluster of Azospirillum brasilense, which codes for the PII protein and glutamine synthetase, respectively, was studied with the aid of lacZ fusions, deletion mapping, site-directed mutagenesis, and complementation. It was shown previously by mRNA mapping that the cluster contains two tandemly organized promoters, glnBp1 and glnBp2, of the sigma 70 and sigma 54 types, respectively, upstream of glnB and a third unidentified promoter upstream of glnA. Data obtained with lacZ fusions in the wild-type strain confirmed that cotranscription of glnBA and transcription of glnA alone were oppositely regulated by the cell N status. Quantification of promoter activities showed a high level of transcription from glnBp1p2 and a low level from glnAp under conditions of nitrogen limitation. The opposite situation prevails under conditions of nitrogen excess. As a consequence, PII polypeptide synthesis is increased under conditions of nitrogen fixation, which strongly suggests that PII plays an important role under these conditions. Null mutant strains of glnB, ntrB-ntrC, nifA, and point mutant strains in glnA were analyzed. NtrB and NtrC are not involved in the regulation of glnBA expression, in contrast to PII and glutamine synthetase. Glutamine synthetase probably acts by modulating the intracellular N status, and PII acts by modifying the properties of an unidentified regulator which might be a functional homolog of NtrC. In addition, a Nif- null mutant strain of glnB was characterized further. A Nif+ phenotype was restored to the strain by nifA from Klebsiella pneumoniae but not by nifA from A. brasilense. This mutant strain is not impaired in NifA synthesis, which is relatively independent of the growth conditions in A. brasilense. It is therefore most likely that PII is required for NifA activation under conditions of nitrogen fixation. Deletion mapping and site-directed mutagenesis showed glnAp was located within a 45-bp DNA fragment upstream of the mRNA start site, dissimiar to previously described consensus sites for sigma factors.

Regulation of nitrogen fixation in Azospirillum brasilense Sp7: involvement of nifA, glnA and glnB gene products.

The expression of nifA-, niH- and nifB-lacZ fusions was examined in different mutants of Azospirillum brasilense. Mutations in nifA, glnA and glnB severely impaired the expression of nifH- and nifB-lacZ fusions. By contrast, a nifA-lacZ fusion was not affected in a nifA or a glnB background and was only partially impaired in glnA mutants. It is proposed that in A. brasilense, the PII protein and glutamine synthetase are involved in a post-translational modification of NifA.

Nitrogenase activity in wheat seedlings bearing para-nodules induced by 2,4-dichlorophenoxyacetic acid (2,4-D) and inoculated with Azospirillum.

Nitrogenase activity (C2H2 reduction) was demonstrated in seedlings of wheat roots bearing para-nodules induced by 2,4-dichlorophenoxyacetic acid (2,4-D) and inoculated with Azospirillum brasilense. Increased nitrogenase activity was observed in inoculated para-nodulated seedlings as compared to inoculated roots not treated by 2,4-D under the conditions of assay used. 2,4-D had no stimulating effect on plant ethylene production in the absence of acetylene. When inoculation was performed with a Nif-mutant of A. brasilense, no ethylene production was detected. It was also shown that the energy source required for nitrogenase activity was supplied by the host plant.