Defining the Metabolic Functions and Roles in Virulence of the rpoN1 and rpoN2 Genes in Ralstonia solanacearum GMI1000

The alternative sigma factor RpoN is a unique regulator found among bacteria. It controls numerous processes that range from basic metabolism to more complex functions such as motility and nitrogen fixation. Our current understanding of RpoN function is largely derived from studies on prototypical bacteria such as Escherichia coli. Bacillus subtilis and Pseudomonas putida. Although the extent and necessity of RpoN-dependent functions differ radically between these model organisms, each bacterium depends on a single chromosomal rpoN gene to meet the cellular demands of RpoN regulation. The bacterium Ralstonia solanacearum is often recognized for being the causative agent of wilt disease in crops, including banana, peanut and potato. However, this plant pathogen is also one of the few bacterial species whose genome possesses dual rpoN genes. To determine if the rpoN genes in this bacterium are genetically redundant and interchangeable, we constructed and characterized ΔrpoN1, ΔrpoN2 and ΔrpoN1 ΔrpoN2 mutants of R. solanacearum GMI1000. It was found that growth on a small range of metabolites, including dicarboxylates, ethanol, nitrate, ornithine, proline and xanthine, were dependent on only the rpoN1 gene. Furthermore, the rpoN1 gene was required for wilt disease on tomato whereas rpoN2 had no observable role in virulence or metabolism in R. solanacearum GMI1000. Interestingly, plasmid-based expression of rpoN2 did not fully rescue the metabolic deficiencies of the ΔrpoN1 mutants; full recovery was specific to rpoN1. In comparison, only rpoN2 was able to genetically complement a ΔrpoN E. coli mutant. These results demonstrate that the RpoN1 and RpoN2 proteins are not functionally equivalent or interchangeable in R. solanacearum GMI1000.     

Structure and expression of the alternative sigma factor, RpoN, in Rhodobacter capsulatus; physiological relevance of an autoactivated nifU2-rpoN superoperon

The alternative sigma factor, RpoN (σ⁵⁴) is responsible for recruiting core RNA polymerase to the promoters of genes required for diverse physiological functions In a variety of eubacterial species. The RpoN protein In Rhodobacter capsulatus is a putative sigma factor specific for nitrogen fixation (nif) genes. Insertional mutagenesis was used to define regions important for the function of the R. capsulatus RpoN protein. Insertions of four amino acids in the predicted helix-turn-helix or in the highly conserved C-terminal eight amino acid residues (previously termed the RpoN box), and an in-frame deletion of the glutamine-rich M-terminus completely inactivated the R. capsulatus RpoN protein. Two separate insertions in the second hydrophobic heptad repeat, a putative leucine zipper, resulted in a partially functional RpoN protein. Eight other linkers in the rpoN open reading frame (ORF) resulted in a completeiy or partially functional RpoN protein. The rpoN gene in R capsulatus is downstream from the nifHDKU2 genes, in a nifU2-rpoN operon. Results of genetic experiments on the nifU2-rpoN locus show that the rpoN gene is organized in a nifU2-rpoN superoperon. A primary promoter directly upstream of the rpoN ORF is responsible for the initial expression of rpoN. Deletion analysis and insertional mutagenesis were used to define the primary promoter to 50 bp, between 37 and 87 nucleotides upstream of the predicted rpoN translational start site. This primary promoter is expressed constitutively with respect to nitrogen, and it is necessary and sufficient for growth under nitrogen-limiting conditions typically used in the laboratory. A secondary promoter upstream of nifU2 is autoactivated by RpoN and NifA to increase the expression of rpoN, which ultimately results in higher expression of RpoN dependent genes. Moreover. rpoN expression from this secondary promoter is physiologically beneficial under certain stressful conditions, such as nitrogen-limiting environments that contain high salt (>50mM NaCl) or low iron (<400nM FeS0₄).     

Nucleotide sequence of the rpoN (hno) gene region of Alcaligenes eutrophus: evidence for a conserved gene cluster

The nucleotide sequence of the rpoN gene, formerly designated hno, and flanking DNA regions of the aerobic hydrogen bacterium Alcaligenes eutrophus has been determined; rpoN codes for the RNA polymerase sigma factor ⁵⁴ involved in nitrogen regulation and diverse physiological functions of gram-negative bacteria. In A. eutrophus hydrogen metabolism is under control of rpoN. The Tn5-Mob insertion in a previously isolated pleiotropic mutant was mapped within the rpoN gene. The derived amino acid sequence of the A. eutrophus RpoN protein shows extensive homology to the RpoN proteins of other organisms. Sequencing revealed four other open reading frames: one upstream (ORF280) and three downstream (ORF130, ORF99 and ORF > 54) of the rpoN gene. A similar arrangement of homologous ORFs is found in the rpoN regions of other bacteria and is indicative of a conserved gene cluster.     

Role of alternative sigma factor 54 (RpoN) from Vibrio anguillarum M3 in protease secretion, exopolysaccharide production, biofilm formation, and virulence

The sigma factor σ⁵⁴ (RpoN) is an important regulator of bacterial response to environmental stresses. Here, we demonstrate the roles of RpoN in Vibrio anguillarum M3 by comparative investigation of physiological phenotypes and virulence of the wild-type, an rpoN mutant, and an rpoN complemented strain. Disruption of rpoN was found to decrease biofilm formation, production of exopolysaccharides, and production of the metalloproteases EmpA and PrtV. Injection experiments in fish showed that the M3 ΔrpoN mutant was attenuated in virulence when administrated either by intramuscular injection or by immersion challenge. Slower proliferation of the mutant in fish was also observed. Complementation of the mutant strain with rpoN restored some of the phenotypes to wild-type levels. RpoN was involved in regulation of some virulence-associated genes, as shown by real-time quantitative reverse PCR analysis. These results revealed a pleiotropic regulatory role of RpoN in biofilm formation, production of proteases and exopolysaccharides, and virulence in V. anguillarum M3.     

Cloning and characterization of Planctomyces limnophilus rpoN: complementation of a Salmonella typhimurium rpoN mutant strain

The rpoN gene, which encodes the alternative sigma factor σ⁵⁴, was cloned from the budding, peptidoglycan-less bacterium Planctomyces limnophilus. P. limnophilus rpoN complemented the Ntr⁻ phenotype of a Salmonella typhimurium rpoN mutant strain. The P. limnophilus rpoN gene encoded a predicted polypeptide that was 495 residues in length and shared a significant homology with other members of the σ⁵⁴ family. The protein sequence displayed all of the characteristic motifs found in members of this family, including the C-terminal helix–turn–helix motif and the well-conserved RpoN box. A potential σ⁵⁴-dependent activator was also identified in P. limnophilus. These findings extend the range of phylogenetic groups within the Domain Bacteria that are known to contain σ⁵⁴.     

Quorum sensing and alternative sigma factor RpoN regulate type VI secretion system I (T6SSVA1) in fish pathogen <Emphasis Type="Italic">Vibrio alginolyticus</Emphasis>

Type VI secretion system (T6SS) is a highly conserved bacterial protein secretion system and is precisely regulated in Gram-negative pathogens. In Vibrio alginolyticus, an important fish pathogen, two complete T6SS gene clusters (T6SSVA1 and T6SSVA2) were identified. In this study, expression of a hemolysin coregulated protein (Hcp1), which is one of the hallmarks of T6SS, was found to be strictly regulated in this bacterium. We showed that the expression of Hcp1 was growth phase-dependent and the production of Hcp1 reached a maximum in the exponential phase. The expression of Hcp1 was positively and negatively regulated by quorum sensing regulators LuxO and LuxR, respectively. In addition, we observed that Hcp1 expression required the alternative sigma factor RpoN and the enhancer-binding protein VasH, which is encoded in T6SSVA1 gene cluster. Moreover, LuxR, RpoN, and VasH could positively regulate the expression of other T6SS genes. Taken together, we demonstrated that the expression of T6SS in V. alginolyticus was under the regulation of quorum sensing and alternative sigma factor.     

The fire blight pathogen Erwinia amylovora requires the rpoN gene for pathogenicity in apple

RpoN is a σ⁵⁴ factor regulating essential virulence gene expression in several plant pathogenic bacteria, including Pseudomonas syringae and Pectobacterium carotovorum. In this study, we found that mutation of rpoN in the fire blight pathogen Erwinia amylovora caused a nonpathogenic phenotype. The E. amylovora rpoN Tn5 transposon mutant rpoN1250::Tn5 did not cause fire blight disease symptoms on shoots of mature apple trees. In detached immature apple fruits, the rpoN1250::Tn5 mutant failed to cause fire blight disease symptoms and grew to population levels 12 orders of magnitude lower than the wild‐type. In addition, the rpoN1250::Tn5 mutant failed to elicit a hypersensitive response when infiltrated into nonhost tobacco plant leaves, and rpoN1250::Tn5 cells failed to express HrpN protein when grown in hrp (hypersensitive response and pathogenicity)‐inducing liquid medium. A plasmid‐borne copy of the wild‐type rpoN gene complemented all the rpoN1250::Tn5 mutant phenotypes tested. The rpoN1250::Tn5 mutant was prototrophic on minimal solid and liquid media, indicating that the rpoN1250::Tn5 nonpathogenic phenotype was not caused by a defect in basic metabolism or growth. This study provides clear genetic evidence that rpoN is an essential virulence gene of E. amylovora, suggesting that rpoN has the same function in E. amylovora as in P. syringae and Pe. carotovorum.     

Cloning of a Vibrio alginolyticus rpoN gene that is required for polar flagellar formation.

A fragment of DNA was cloned which complemented a polar flagellum-defective (pof) mutation of Vibrio alginolyticus. The fragment contained two complete and two partial open reading frames (ORFs) (ORF2 and -3 and ORF1 and -4, respectively). The presumed product of ORF2 has an amino acid sequence with a high degree of similarity to that of RpoN, which is an alternative sigma factor (sigma54) for other microorganisms. The other ORFs are also homologous to the genes adjacent to other rpoN genes. Deletion analysis suggests that ORF2 complements the pof mutation. These results demonstrate that RpoN is involved in the expression of polar flagellar genes.     

Genetic analysis of two phosphodiesterases reveals cyclic diguanylate regulation of virulence factors in Dickeya dadantii

Cyclic diguanylate (c‐di‐GMP) is a second messenger implicated in the regulation of various cellular properties in several bacterial species. However, its function in phytopathogenic bacteria is not yet understood. In this study we investigated a panel of GGDEF/EAL domain proteins which have the potential to regulate c‐di‐GMP levels in the phytopathogen Dickeya dadantii 3937. Two proteins, EcpB (contains GGDEF and EAL domains) and EcpC (contains an EAL domain) were shown to regulate multiple cellular behaviours and virulence gene expression. Deletion of ecpB and/or ecpC enhanced biofilm formation but repressed swimming/swarming motility. In addition, the ecpB and ecpC mutants displayed a significant reduction in pectate lyase production, a virulence factor of this bacterium. Gene expression analysis showed that deletion of ecpB and ecpC significantly reduced expression of the type III secretion system (T3SS) and its virulence effector proteins. Expression of the T3SS genes is regulated by HrpL and possibly RpoN, two alternative sigma factors. In vitro biochemical assays showed that EcpC has phosphodiesterase activity to hydrolyse c‐di‐GMP into linear pGpG. Most of the enterobacterial pathogens encode at least one T3SS, a major virulence factor which functions to subvert host defences. The current study broadens our understanding of the interplay between c‐di‐GMP, RpoN and T3SS and the potential role of c‐di‐GMP in T3SS regulation among a wide range of bacterial pathogens.     

The Rhizobium etli rpoN Locus: DNA Sequence Analysis and Phenotypical Characterization of rpoN, ptsN, and ptsA Mutants

The rpoN region of Rhizobium etli was isolated by using the Bradyrhizobium japonicum rpoN1 gene as a probe. Nucleotide sequence analysis of a 5,600-bp DNA fragment of this region revealed the presence of four complete open reading frames (ORFs), ORF258, rpoN, ORF191, and ptsN, coding for proteins of 258, 520, 191, and 154 amino acids, respectively. The gene product of ORF258 is homologous to members of the ATP-binding cassette-type permeases. ORF191 and ptsN are homologous to conserved ORFs found downstream from rpoN genes in other bacterial species. Unlike in most other microorganisms, rpoN and ORF191 are separated by approximately 1.6 kb. The R. etli rpoN gene was shown to control in free-living conditions the production of melanin, the activation of nifH, and the metabolism of C₄-dicarboxylic acids and several nitrogen sources (ammonium, nitrate, alanine, and serine). Expression of the rpoN gene was negatively autoregulated and occurred independently of the nitrogen source. Inactivation of the ptsN gene resulted in a decrease of melanin synthesis and nifH expression. In a search for additional genes controlling the synthesis of melanin, an R. etli mutant carrying a Tn5 insertion in ptsA, a gene homologous to the Escherichia coli gene coding for enzyme I of the phosphoenolpyruvate:sugar phosphotransferase system, was obtained. The R. etli ptsA mutant also displayed reduced expression of nifH. The ptsN and ptsA mutants also displayed increased sensitivity to the toxic effects of malate and succinate. Growth of both mutants was inhibited by these C₄-dicarboxylates at 20 mM at pH 7.0, while wild-type cells grow normally under these conditions. The effect of malate occurred independently of the nitrogen source used. Growth inhibition was decreased by lowering the pH of the growth medium. These results suggest that ptsN and ptsA are part of the same regulatory cascade, the inactivation of which renders the cells sensitive to toxic effects of elevated concentrations of malate or succinate.     

Integrated bioinformatic and phenotypic analysis of RpoN-dependent traits in the plant growth-promoting bacterium Pseudomonas fluorescens SBW25

The alternative sigma factor RpoN is a key regulator in the acclimation of Pseudomonas to complex natural environments. In this study we show that RpoN is required for efficient colonization of sugar beet seedlings by the plant growth-promoting bacterium Pseudomonas fluorescens SBW25, and use phenotypic and bioinformatic approaches to profile the RpoN-dependent traits and genes of P. fluorescens SBW25. RpoN is required for flagellar biosynthesis and for assimilation of a wide variety of nutrient sources including inorganic nitrogen, amino acids, sugar alcohols and dicarboxylic acids. Chemosensitivity assays indicate that RpoN-regulated genes contribute to acid tolerance and resistance to some antibiotics, including tetracyclines and aminoglycosides. Gain of function changes associated with loss of RpoN included increased tolerance to hydroxyurea and Guanazole. Bioinformatic predictions of RpoN-regulated genes show a close correspondence with phenotypic analyses of RpoN-regulated traits and suggest novel functions for RpoN in P. fluorescens, including regulation of poly(A) polymerase. The reduced plant colonization ability observed for an rpoN mutant of P. fluorescens is therefore likely to be due to defects in multiple traits including nutrient assimilation, protein secretion and stress tolerance.     

Phenazine-1-carboxylic acid biosynthesis in <Emphasis Type="Italic">Pseudomonas Chlororaphis</Emphasis> GP72 is positively regulated by the sigma factor RpoN

The production of phenazine-1-carboxylic acid (PCA) and 2-hydroxyphenazine (2-OH-PHZ) makes Pseudomonas chlororaphis GP72 an effective biocontrol agent. In order to understand how production of PCA is regulated by RpoN, an insertional mutation in rpoN has been made in P. chlororaphis GP72. Production of PCA in the rpoN mutant strain GP72N decreased both in King’s B medium and in Pigment Producing Medium. Moreover, the expression of the translational fusion phzA′–′lacZ was reduced about 2-fold in GP72N compared to wild type strain, whatever the growth medium is. Complementation of rpoN gene in mutant GP72N restored its motility and its PCA biosynthesis ability. However, overexpression of RpoN had no major effects on the expression of the RpoN-dependent phenotypes described in this study for P. chlororaphis GP72. These results suggest that RpoN is involved as a positive regulator in the regulation of PCA biosynthesis in P. chlororaphis GP72.