Control of AlgU, a member of the sigma E-like family of stress sigma factors, by the negative regulators MucA and MucB and Pseudomonas aeruginosa conversion to mucoidy in cystic fibrosis

RseB binding to the periplasmic domain of RseA modulates the RseA:sigmaE interaction in the cytoplasm and the availability of sigmaE.RNA polymerase

The Escherichia coli sigmaE regulon has evolved to sense the presence of misfolded proteins in the bacterial envelope. Expression of periplasmic chaperones and folding catalysts is under the control of sigmaE RNA polymerase. The N-terminal domain of RseA sequesters sigmaE in the cytoplasmic membrane, preventing its association with core RNA polymerase. The C-terminal domain of RseA interacts with RseB, a periplasmic protein. The relative concentration of sigmaE:RseA:RseB is 2:5:1 and this ratio remains unaltered upon heat shock induction of the sigmaE regulon. Purification from crude cellular extracts yields cytoplasmic, soluble sigmaE RNA polymerase as well as membrane sequestered sigmaE.RseA and sigmaE.RseA.RseB. RseB binding to the C-terminal domain of RseA increases the affinity of RseA for sigmaE by 2- to 3-fold (Kd 50-100 nM). RseB binds also to the misfolded aggregates of MalE31, a variant of maltose binding protein that forms inclusion bodies in the periplasm. We discuss a model whereby the RseB-RiseA interaction represents a measure for misfolded polypeptides in the bacterial envelope, modulating the assembly of sigmaE RNA polymerase and the cellular heat shock response.

Membrane-to-cytosol redistribution of ECF sigma factor AlgU and conversion to mucoidy in Pseudomonas aeruginosa isolates from cystic fibrosis patients

The conversion to mucoid phenotype in Pseudomonas aeruginosa during chronic infections in cystic fibrosis (CF) is due to mutations in the algU mucABCD gene cluster. This cluster encodes an extreme stress response system conserved in Gram-negative bacteria. The system includes an ECF sigma factor, AlgU (sigmaE), an inner membrane protein, MucA, which inhibits AlgU activity, and MucB, a periplasmic protein that negatively controls AlgU. In this work, we investigated whether and how these factor interact to transduce signals between different cellular compartments. The mutation mucADeltaG440, which renders a large fraction of P. aeruginosa CF isolates mucoid, did not abrogate AlgU-MucA interactions, although it eliminated MucA-MucB interactions in the yeast two-hybrid system. The mucADeltaG440 truncation of the periplasmic C-terminal tail of MucA destabilized the molecule resulting in low or undetectable steady-state levels in P. aeruginosa. Somewhat reduced levels of MucA were also seen in cells with inactivated mucB or with the mucACF53 allele carrying the missense P184S mutation, which mildly affected interactions with MucB. The events downstream from MucA destabilization were also investigated. AlgU was found to associate with inner membranes in mucA+ cells. In mutants destabilizing MucA, a limited redistribution of AlgU from the membrane to the cytosol was observed. The redistribution was spontaneous in mucADeltaG440 cells, while in mucB and mucACF53 mutants it required additional signals. Despite a large reduction in MucA levels in mucADeltaG440 cells, only a small fraction of AlgU was redistributed to the cytosol and a significant portion of this sigma factor remained membrane bound and behaved as a peripheral inner membrane protein. The fraction of AlgU that depended on MucA for association with the membrane also brought RNA polymerase into this compartment. These results are consistent with a model in which MucB-MucA-AlgU-RNA polymerase interactions at the membrane allow transduction of potentially lethal stress signals with both rapid reaction times of the preassembled complexes and efficient resupply at the membrane from the prebound components.

Dual regulation of mucoidy in Pseudomonas aeruginosa and sigma factor antagonism

The conversion to mucoid, exopolysaccharide alginate-overproducing phenotype in Pseudomonas aeruginosa during chronic respiratory infections in cystic fibrosis patients occurs via mutations that activate the alternative sigma factor AlgU (sigmaE). In this study, we demonstrate that conversion to mucoidy can be caused via a second, algU-independent pathway, in which alginate production and transcription of the critical algD promoter depend on another alternative sigma factor, RpoN (sigma54). The algD promoters dependent on sigma54 and sigmaE showed a complete overlap resulting in identical mRNA 5' ends. The two pathways were not independent, as sigma54 also repressed sigmaE-dependent transcription of algD both in vitro and in vivo. The negative regulatory effect of sigma54 on sigmaE-dependent algD expression was based on sigma54 binding to the algD promoter and its interference with sigmaE-dependent transcription. This phenomenon, referred to here as sigma factor antagonism, reflects the unique properties of sigma54, which lacks an intrinsic ability to form open transcription initiation complexes. We propose that this peculiar feature of sigma54 has evolved in part to allow its recruitment as a repressor of certain promoter subsets. The repression of algD by sigma54 also depends on environmental conditions, supporting the notion that sigma factor antagonism plays a physiological role in controlling alginate production in P. aeruginosa during adaptation to different ecological sites (e.g. biofilm development, stress and other growth conditions) and unique environments in the chronically infected host.

Role of RpoS and AlgT in Pseudomonas aeruginosa biofilm resistance to hydrogen peroxide and monochloramine

The role of two sigma factors, AlgT and RpoS, in mediating Pseudomonas aeruginosa biofilm resistance to hydrogen peroxide and monochloramine was investigated. Two knock out mutant strains, SS24 (rpoS-) and PAO6852 (algT-), were compared with a wild type, PAO1, in their susceptibility to monochloramine and hydrogen peroxide. When grown as biofilms on alginate gel beads (mean untreated areal cell density 3.7 +/- 0.27 log cfu cm-2) or on glass slides (mean untreated areal cell density 7.6 +/- 0.9 log cfu cm-2), wild type bacteria exhibited reduced susceptibility to both antimicrobial agents in comparison with suspended cells. On alginate gel beads, all strains were equally resistant to monochloramine. rpoS- and algT- gel bead biofilms of 24-hour-old were more susceptible to hydrogen peroxide disinfection than were biofilms formed by PAO1. Biofilm disinfection rate coefficients for the two mutant strains were statistically indistinguishable from planktonic disinfection rate coefficients, indicating complete loss of biofilm resistance. While 48-hour-old algT- biofilm cells became resistant to hydrogen peroxide, 48-hour-old rpoS- biofilm cells remained highly susceptible. With the thicker biofilms formed on glass coupons, all strains were equally resistant to both hydrogen peroxide and monochloramine. It is concluded that while RpoS and AlgT may play a transient role in protecting thin biofilms from hydrogen peroxide, these sigma factors do not mediate resistance to monochloramine and do not contribute significantly to the hydrogen peroxide resistance of thick biofilms.

AlgT (sigma22) controls alginate production and tolerance to environmental stress in Pseudomonas syringae

Pseudomonas aeruginosa and the phytopathogen P. syringae produce the exopolysaccharide alginate, which is a copolymer of D-mannuronic and L-guluronic acids. One of the key regulatory genes controlling alginate biosynthesis in P. aeruginosa is algT, which encodes the alternate sigma factor, sigma(22). In the present study, the algT gene product from P. syringae pv. syringae showed 90% amino acid identity with its P. aeruginosa counterpart, and sequence analysis of the region flanking algT in P. syringae revealed the presence of nadB, mucA, and mucB in an arrangement virtually identical to that of P. aeruginosa. An algT mutant of P. syringae was defective in alginate production but could be complemented with wild-type algT from P. syringae or P. aeruginosa when expressed in trans. The algT mutant also displayed increased sensitivity to heat, paraquat, and hydrogen peroxide (H(2)O(2)); the latter two compounds are known to generate reactive oxygen intermediates. Signals for activation of algT gene expression in P. syringae were investigated with an algT::uidA transcriptional fusion. Like that in P. aeruginosa, algT transcription in P. syringae was activated by heat shock. However, algT expression in P. syringae was also stimulated by osmotic stress and by exposure to paraquat, H(2)O(2), and copper sulfate. The latter two compounds are frequently encountered during colonization of plant tissue and may be unique signals for algT activation in P. syringae.

The Rhodobacter sphaeroides ECF sigma factor, sigma(E), and the target promoters cycA P3 and rpoE P1

Rhodobacter sphaeroides rpoE encodes a 19.2 kDa protein, sigma(E), related to members of the extra-cytoplasmic function subfamily of eubacterial RNA polymerase sigma factors. We demonstrate that sigma(E) directs transcription from rpoE P1, the promoter for the rpoEchrR operon, and from cycA P3, a promoter for the cytochrome c2 structural gene. Comparison of these sigma(E)-dependent promoters reveals significant sequence conservation in their -35 and -10 regions; however, rpoE P1 is over 80-fold stronger than cycA P3. Both promoters contain identical -35 hexamers, (-36)TGATCC(-31), that appear to constitute the preferred sequence, since any single base mutation in this region of cycA P3 reduces promoter function. The higher activity of rpoE P1 appears to reflect a better -10 region, (-13)TAAGA(-9), as it contains four out of five of the nucleotides found to be important to sigma(E)-dependent transcription. We also propose that ChrR acts as an inhibitor of sigma(E), since these two proteins can form a complex, and DeltachrR mutations increase sigma(E)-dependent transcription. ChrR is believed to respond to a signal from tetrapyrrole biosynthesis because loss of function mutations in chrR lead to cohemin resistance. Based on our observations, we present a model in which cohemin resistance is conferred by increasing sigma(E) activity.

The Escherichia coli sigma(E)-dependent extracytoplasmic stress response is controlled by the regulated proteolysis of an anti-sigma factor

The activity of the stress-responsive sigma factor, sigma(E), is induced by the extracytoplasmic accumulation of misfolded or unfolded protein. The inner membrane protein RseA is the central regulatory molecule in this signal transduction cascade and acts as a sigma(E)-specific anti-sigma factor. Here we show that sigma(E) activity is primarily determined by the ratio of RseA to sigma(E). RseA is rapidly degraded in response to extracytoplasmic stress, leading to an increase in the free pool of sigma(E) and initiation of the stress response. We present evidence that the putative inner membrane serine protease, DegS, is responsible for this regulated degradation of RseA.

Regulation of alginate biosynthesis in Pseudomonas syringae pv. syringae

Both Pseudomonas aeruginosa and the phytopathogen P. syringae produce the exopolysaccharide alginate. However, the environmental signals that trigger alginate gene expression in P. syringae are different from those in P. aeruginosa with copper being a major signal in P. syringae. In P. aeruginosa, the alternate sigma factor encoded by algT (sigma22) and the response regulator AlgR1 are required for transcription of algD, a gene which encodes a key enzyme in the alginate biosynthetic pathway. In the present study, we cloned and characterized the gene encoding AlgR1 from P. syringae. The deduced amino acid sequence of AlgR1 from P. syringae showed 86% identity to its P. aeruginosa counterpart. Sequence analysis of the region flanking algR1 in P. syringae revealed the presence of argH, algZ, and hemC in an arrangement virtually identical to that reported in P. aeruginosa. An algR1 mutant, P. syringae FF5.32, was defective in alginate production but could be complemented when algR1 was expressed in trans. The algD promoter region in P. syringae (PsalgD) was also characterized and shown to diverge significantly from the algD promoter in P. aeruginosa. Unlike P. aeruginosa, algR1 was not required for the transcription of algD in P. syringae, and PsalgD lacked the consensus sequence recognized by AlgR1. However, both the algD and algR1 upstream regions in P. syringae contained the consensus sequence recognized by sigma22, suggesting that algT is required for transcription of both genes.

Overproduction and characterization of the Bacillus subtilis anti-sigma factor FlgM

FlgM is an anti-sigma factor of the flagellar-specific sigma (sigma) subunit of RNA polymerase in Bacillus subtilis, and it is responsible of the coupling of late flagellar gene expression to the completion of the hook-basal body structure. We have overproduced the protein in soluble form and characterized it. FlgM forms dimers as shown by gel exclusion chromatography and native polyacrylamide gel electrophoresis and interacts in vitro with the cognate sigmaD factor. The FlgM.sigmaD complex is a stable heterodimer as demonstrated by gel exclusion chromatography, chemical cross-linking, native polyacrylamide gel electrophoresis, and isoelectric focusing. sigmaD belongs to the group of sigma factors able to bind to the promoter sequence even in the absence of core RNA polymerase. The FlgM.sigmaD complex gave a shift in a DNA mobility shift assay with a probe containing a sigmaD-dependent promoter sequence. Limited proteolysis studies indicate the presence of two structural motifs, corresponding to the N- and C-terminal regions, respectively.

The sigmaE and Cpx regulatory pathways: overlapping but distinct envelope stress responses

The Cpx and sigmaE extracytoplasmic stress responses sense and respond to misfolded proteins in the bacterial envelope. Recent studies have highlighted differences between these regulatory pathways in terms of activating signals, mechanisms of signal transduction and the nature of the responses. Cumulatively, the findings suggest distinct physiological roles for these partially overlapping envelope stress responses. The sigmaE pathway is essential for survival and is primarily responsible for monitoring and responding to alterations in outer membrane protein folding. Mounting evidence suggests that the Cpx regulon may have been adapted to ensure properly timed expression and assembly of adhesive organelles.

The anti-sigma factors

A mechanism for regulating gene expression at the level of transcription utilizes an antagonist of the sigma transcription factor known as the anti-sigma (anti-sigma) factor. The cytoplasmic class of anti-sigma factors has been well characterized. The class includes AsiA form bacteriophage T4, which inhibits Escherichia coli sigma 70; FlgM, present in both gram-positive and gram-negative bacteria, which inhibits the flagella sigma factor sigma 28; SpoIIAB, which inhibits the sporulation-specific sigma factor, sigma F and sigma G, of Bacillus subtilis; RbsW of B. subtilis, which inhibits stress response sigma factor sigma B; and DnaK, a general regulator of the heat shock response, which in bacteria inhibits the heat shock sigma factor sigma 32. In addition to this class of well-characterized cytoplasmic anti-sigma factors, a new class of homologous, inner-membrane-bound anti-sigma factors has recently been discovered in a variety of eubacteria. This new class of anti-sigma factors regulates the expression of so-called extracytoplasmic functions, and hence is known as the ECF subfamily of anti-sigma factors. The range of cell processes regulated by anti-sigma factors is highly varied and includes bacteriophage phage growth, sporulation, stress response, flagellar biosynthesis, pigment production, ion transport, and virulence.

The Azotobacter vinelandii response regulator AlgR is essential for cyst formation

Azotobacter vinelandii produces the exopolysaccharide alginate, which is essential for the encystment process. In Pseudomonas aeruginosa, as well as in A. vinelandii, the sigmaE factor encoded by algU is required for transcription of algD, which encodes a key enzyme of the alginate biosynthetic pathway. The P. aeruginosa response regulator AlgR activates transcription of algD. fimS, located upstream algR, is proposed to encode the AlgR cognate sensor kinase. We have cloned and characterized the A. vinelandii algR gene; the deduced amino acid sequence of the protein encoded by this gene shows 79% identity with its P. aeruginosa homolog. Sequence analysis around the algR gene revealed the absence of a fimS homolog. Inactivation of A. vinelandii algR diminished alginate production by 50%, but did not affect algD transcription, and completely impaired the capacity to form mature cysts. Electron microscopy of the cyst structures formed by the algR mutant revealed that the encystment process is blocked at the step of exine formation. The transcriptional regulation of the A. vinelandii algR gene and the role of AlgR in alginate production differ significantly from those of its P. aeruginosa counterparts. These differences could be due to the fact that in A. vinelandii, alginate plays a role in encystment, a function not found in P. aeruginosa.

Identification of an Escherichia coli pepA homolog and its involvement in suppression of the algB phenotype in mucoid Pseudomonas aeruginosa

Strains of Pseudomonas aeruginosa isolated from the respiratory tracts of patients with cystic fibrosis often display a mucoid morphology due to high levels of expression of the exopolysaccharide alginate. The response regulator AlgB is required for full transcription of the alginate biosynthetic operon. Repeated attempts to demonstrate a direct interaction between AlgB and the promoter region of algD, the first gene in the alginate operon, have thus far been unsuccessful. The possibility that AlgB exerts its effect on algD indirectly exists. To identify putative genes under the control of AlgB which affect algD transcription, transposon mutagenesis of nonmucoid algB derivatives of the mucoid strain FRD1 was employed. Of approximately 3,000 transposon mutants screened, 6 were found to display phenotypes which were mucoid relative to the phenotype of the parental algB strain. The phenotypes of these mutants ranged from being only slightly mucoid to being indistinguishable from that of the original FRD1 strain. One of the particularly mucoid transposon mutants was chosen for further study. This strain was found to be disrupted in a previously uncharacterized open reading frame with 56% amino acid identity to PepA of Escherichia coli. PepA is classified as a leucine aminopeptidase, and homologs have been detected in a number of bacterial, plant, and animal species. This novel gene has been designated phpA (P. aeruginosa homolog of pepA). The insertional inactivation of phpA was found to correlate with the mucoid phenotype and an increase in algD transcription in the algB strain. Expression of phpA from an ectopic chromosomal locus compensated for the transposon insertion in the native phpA gene, restoring algD transcription to levels similar to those observed in the parental algB strain. While phpA expression did not appear to be under the control of AlgB at the transcriptional level, this study demonstrates that loss of phpA in an algB genetic background had a positive effect on alginate expression and, more specifically, on transcription of the alginate biosynthetic operon.

Synthesis of the A-band polysaccharide sugar D-rhamnose requires Rmd and WbpW: identification of multiple AlgA homologues, WbpW and ORF488, in Pseudomonas aeruginosa

Pseudomonas aeruginosa is capable of producing various cell-surface polysaccharides including alginate, A-band and B-band lipopolysaccharides (LPS). The D-mannuronic acid residues of alginate and the D-rhamnose (D-Rha) residues of A-band polysaccharide are both derived from the common sugar nucleotide precursor GDP-D-mannose (D-Man). Three genes, rmd, gmd and wbpW, which encode proteins involved in the synthesis of GDP-D-Rha, have been localized to the 5' end of the A-band gene cluster. In this study, WbpW was found to be homologous to phosphomannose isomerases (PMIs) and GDP-mannose pyrophosphorylases (GMPs) involved in GDP-D-Man biosynthesis. To confirm the enzymatic activity of WbpW, Escherichia coli PMI and GMP mutants deficient in the K30 capsule were complemented with wbpW, and restoration of K30 capsule production was observed. This indicates that WbpW, like AlgA, is a bifunctional enzyme that possesses both PMI and GMP activities for the synthesis of GDP-D-Man. No gene encoding a phosphomannose mutase (PMM) enzyme could be identified within the A-band gene cluster. This suggests that the PMM activity of AlgC may be essential for synthesis of the precursor pool of GDP-D-Man, which is converted to GDP-D-Rha for A-band synthesis. Gmd, a previously reported A-band enzyme, and Rmd are predicted to perform the two-step conversion of GDP-D-Man to GDP-D-Rha. Chromosomal mutants were generated in both rmd and wbpW. The Rmd mutants do not produce A-band LPS, while the WbpW mutants synthesize very low amounts of A band after 18 h of growth. The latter observation was thought to result from the presence of the functional homologue AlgA, which may compensate for the WbpW deficiency in these mutants. Thus, WbpW AlgA double mutants were constructed. These mutants also produced low levels of A-band LPS. A search of the PAO1 genome sequence identified a second AlgA homologue, designated ORF488, which may be responsible for the synthesis of GDP-D-Man in the absence of WbpW and AlgA. Polymerase chain reaction (PCR) amplification and sequence analysis of this region reveals three open reading frames (ORFs), orf477, orf488 and orf303, arranged as an operon. ORF477 is homologous to initiating enzymes that transfer glucose 1-phosphate onto undecaprenol phosphate (Und-P), while ORF303 is homologous to L-rhamnosyltransferases involved in polysaccharide assembly. Chromosomal mapping using pulsed field gel electrophoresis (PFGE) and Southern hybridization places orf477, orf488 and orf303 between 0.3 and 0.9 min on the 75 min map of PAO1, giving it a map location distinct from that of previously described polysaccharide genes. This region may represent a unique locus within P. aeruginosa responsible for the synthesis of another polysaccharide molecule.

The extracytoplasmic function sigma factors: role and regulation

Alternative sigma factors provide a means of regulating gene expression in response to various extracellular changes. One such class of sigma factors appears to control a variety of functions, including expression of heat-shock genes in Escherichia coli, biosynthesis of alginates and carotenoids in Pseudomonas aeruginosa and Myxococcus xanthus, respectively, iron uptake in E. coli and Pseudomonas spp., nickel and cobalt efflux in Alcaligenes europhus, plant pathogenicity in Pseudomonas syringae and synthesis of outer membrane proteins in Photobacterium sp. strain SS9. Most of these activities deal with extracytoplasmic functions, and such sigmas have been designated as ECF sigma factors. They have also been characterized in Mycobacteria as well as gram-positive bacteria such as Streptomyces coelicolor and Bacillus subtilus and the archaea Sulpholobus acidocaldarius. ECF factors belong to a subfamily of the sigma 70 class, based on their sequence conservation and function across bacterial species. The promoter consensus sequences recognized by the ECF factors are also highly conserved. In most of the cases, the activity of these factors is modulated by a cognate inner membrane protein that has been shown, both in E. coli and in P. aeruginosa, to act as an anti-sigma activity. This inner membrane protein is presumed to serve as a sensor and signalling molecule, allowing an adaptive response to specific environmental change. Presumably, an on-and-off switch of the anti-sigma activity leads to the release of the sigma factor and thereby to the co-ordinate transcription of the specific regulon it governs.

Role of alternative sigma factor algU in encystment of Azotobacter vinelandii

Alginate is essential for encystment in Azotobacter vinelandii. Transcription of the algD gene, which codes for GDP-mannose dehydrogenase, a key enzyme in the alginate biosynthetic pathway, is initiated at two promoters, one of which, p2, has sigmaE consensus sequences. AlgU is the A. vinelandii alternative sigmaE factor. In this study, we constructed an algU mutant (SMU88) which, as expected, is impaired in alginate production, encystment, and transcription of the algD gene from the p2 promoter. Plasmid pJMSAT1, carrying the A. vinelandii algU gene, restored alginate production and encystment to SMU88 and to strain UW136, a naturally occurring algU mutant. Plasmid pSMU865, carrying the A. vinelandii mucABCD genes coding for negative regulators of AlgU activity and previously shown to diminish alginate production in the wild-type strain, ATCC 9046, was shown here to impair encystment and transcription of the algD gene from the p2 algU-dependent promoter. Since nonencysting strain ATCC 9046/pSMU865 produced more alginate than some encysting strains, such as UW136/pJMSAT1, we propose an AlgU role in encystment, independent of the structural role that alginate plays in mature cysts.

Bacterial alginate biosynthesis--recent progress and future prospects

The extracellular polysaccharide alginate has been widely associated with chronic Pseudomonas aeruginosa infections in the cystic fibrosis lung. However, it is clear that alginate biosynthesis is a more widespread phenomenon. Alginate plays a key role as a virulence factor of plant-pathogenic pseudomonads, in the formation of biofilms and with the encystment process of Azotobacter spp.

Phosphorylation-independent activity of the response regulators AlgB and AlgR in promoting alginate biosynthesis in mucoid Pseudomonas aeruginosa

Overproduction of the capsular polysaccharide alginate appears to confer a selective advantage for Pseudomonas aeruginosa in the lungs of cystic fibrosis patients. The regulators AlgB and AlgR, which are both required as positive activators in alginate overproduction, have homology with the regulator class of two-component environmental responsive proteins which coordinate gene expression through signal transduction mechanisms. Signal transduction in this class of proteins generally occurs via autophosphorylation of the sensor kinase protein and phosphotransfer from the sensor to a conserved aspartate residue, which is present in the amino terminus of the response regulator. Recently, kinB was identified downstream of algB and was shown to encode the cognate histidine protein kinase that efficiently phosphorylates AlgB. However, we show here that a null mutation in kinB in a mucoid cystic fibrosis isolate, P. aeruginosa FRD1, did not block alginate production. The role of the conserved aspartate residue in the phosphorylation of AlgB was examined. The predicted phosphorylation site of AlgB (D59) was mutated to asparagine (N), and a derivative of an AlgB lacking the entire amino-terminal phosphorylation domain (AlgB delta1-145) was constructed. A hexahistidine tag was included at the amino terminus of the wild-type (H-AlgB), H-AlgB delta1-145, and mutant (H-AlgB.59N) AlgB proteins. These derivatives were purified by Ni2+ affinity chromatography and examined for in vitro phosphorylation by the purified sensor kinase protein, KinB. The results indicated that while KinB efficiently phosphorylated H-AlgB, no phosphorylation of H-AlgB delta1-145 or H-AlgB.D59N was apparent. An allelic exchange system was developed to transfer mutant algB alleles onto the chromosome of a P. aeruginosa algB mutant to examine the effect on alginate production. Despite the defect in AlgB phosphorylation, P. aeruginosa strains expressing AlgB.D59N or H-AlgB delta1-145 remained mucoid. The roles of the conserved aspartate residues in the phosphorylation of AlgR were also examined. As seen with AlgB, mutations in the predicted phosphorylation site of AlgR (AlgR.D54N and AlgR.D85N) did not affect alginate production. These results indicate that in vivo phosphorylation of AlgB and AlgR are not required for their roles in alginate production. Thus, the mechanism by which these response regulators activate alginate genes in mucoid P. aeruginosa appears not to be mediated by conventional phosphorylation-dependent signal transduction.

Pseudomonas aeruginosa in cystic fibrosis: role of mucC in the regulation of alginate production and stress sensitivity

Alginate production in Pseudomonas aeruginosa and the associated mucoid phenotype of isolates from cystic fibrosis patients are under the control of the algU mucABCD cluster. This group of genes encodes AlgU, the P. aeruginosa equivalent of the extreme heat shock sigma factor sigma E in Gram-negative bacteria, the AlgU-cognate anti-sigma factor MucA, the periplasmic protein MucB and a serine protease homologue, MucD. While mucA, mucB or mucD act as negative regulators of AlgU, the function of mucC is not known. In this study the role of mucC in P. aeruginosa physiology and alginate production has been addressed. Insertional inactivation of mucC in the wild-type P. aeruginosa strain PAO1 did not cause any overt effects on alginate synthesis. However, it affected growth of P. aeruginosa under conditions of combined elevated temperature and increased ionic strength or osmolarity. Inactivation of mucC in mucA or mucB mutant backgrounds resulted in a mucoid phenotype when the cells were grown under combined stress conditions of elevated temperature and osmolarity. Each of the stress factors tested separately did not cause comparable effects. The combined stress factors were not sufficient to cause phenotypically appreciable enhancement of alginate production in mucA or mucB mutants unless mucC was also inactivated. These findings support a negative regulatory role of mucC in alginate production by P. aeruginosa, indicate additive effects of muc genes in the regulation of mucoidy in this organism and suggest that multiple stress signals and recognition systems participate in the regulation of algU-dependent functions.

Evidence that rseC, a gene in the rpoE cluster, has a role in thiamine synthesis in Salmonella typhimurium

In Salmonella typhimurium, the genetic loci and biochemical reactions necessary for the conversion of aminoimidazole ribotide (AIR) to the 4-amino-5-hydroxymethyl-2-methyl pyrimidine (HMP) moiety of thiamine remain unknown. Preliminary genetic analysis indicates that there may be more than one pathway responsible for the synthesis of HMP from AIR and that the function of these pathways depends on the availability of AIR, synthesized by the purine pathway or by the purF-independent alternative pyrimidine biosynthetic (APB) pathway (L. Petersen and D. Downs, J. Bacteriol. 178:5676-5682, 1996). An insertion in rseB, the third gene in the rpoE rseABC gene cluster at 57 min, prevented HMP synthesis in a purF mutant. Complementation analysis demonstrated that the HMP requirement of the purF rseB strain was due to polarity of the insertion in rseB on the downstream rseC gene. The role of RseC in thiamine synthesis was independent of rpoE.

Mucoid Pseudomonas aeruginosa in cystic fibrosis: characterization of muc mutations in clinical isolates and analysis of clearance in a mouse model of respiratory infection

A distinguishing feature of Pseudomonas aeruginosa isolates from cystic fibrosis (CF) patients is their mucoid, exopolysaccharide alginate-overproducing phenotype. One mechanism of conversion to mucoidy is based on mutations in the algU mucABCD cluster, encoding the stress sigma factor AlgU and its regulators. However, conversion to mucoidy in laboratory strains can be achieved via mutations in other chromosomal sites. Here, we investigated mechanisms of the emergence of mucoid P. aeruginosa in CF by analyzing the status of mucA in a collection of mucoid P. aeruginosa isolates from 53 CF patients. This negative regulator of algU, when inactivated under laboratory conditions, causes conversion to mucoidy. The overall frequency of mucA alterations in mucoid CF isolates was 84%. Nucleotide sequence analyses revealed that the majority of the alterations caused premature termination of the mucA coding sequence. Comparison of paired nonmucoid and mucoid P. aeruginosa isolates from three CF patients indicated the presence of mucA mutations only in the mucoid strains. Interestingly, mucoid P. aeruginosa isolates from urinary tract infections also had mutations in the mucA gene. Clearance of CF isolates from the murine lung was investigated in an aerosol infection model with C57BL/6J, BALB/c, and DBA/2NHsd mice. Two CF strains, selected for further study based on the dependence of their alginate production on the concentration of salt in the medium, were used to examine the effects of mucoidy on pulmonary clearance. Statistically significant improvement in recovery from the murine lung of viable mucoid P. aeruginosa cells relative to the nonmucoid bacteria was observed in the majority of mouse strains tested. Collectively, the results reported here suggest that mucA is most likely the preferential site for conversion to mucoidy in CF and that alginate overproduction in mucA-mutant P. aeruginosa improves its resistance to the innate clearance mechanisms in the lung.

Posttranslational control of the algT (algU)-encoded sigma22 for expression of the alginate regulon in Pseudomonas aeruginosa and localization of its antagonist proteins MucA and MucB (AlgN)

Pseudomonas aeruginosa strains associated with cystic fibrosis are often mucoid due to the copious production of alginate, an exopolysaccharide and virulence factor. Alginate gene expression is transcriptionally controlled by a gene cluster at 68 min on the chromosome: algT (algU)-mucA-mucB (algN)-mucC (algM)-mucD (algY). The algT gene encodes a 22-kDa alternative sigma factor (sigma22) that autoregulates its own promoter (PalgT) as well as the promoters of algR, algB, and algD. The other genes in the algT cluster appear to regulate the expression or activity of sigma22. The goal of this study was to better understand the functional interactions between sigma22 and its antagonist regulators during alginate production. Nonmucoid strain PAO1 was made to overproduce alginate (indicating high algD promoter activity) through increasing sigma22 in the cell by introducing a plasmid clone containing algT from mucA22(Def) strain FRD1. However, the bacterial cells remained nonmucoid if the transcriptionally coupled mucB on the clone remained intact. This suggested that a stoichiometric relationship between sigma22 and MucB may be required to control sigma factor activity. When the transcription and translational initiation of algT were measured with lacZ fusions, alginate production correlated with only about a 1.2- to 1.7-fold increase in algT-lacZ activity, respectively. An algR-lacZ transcriptional fusion showed a 2.8-fold increase in transcription with alginate production under the same conditions. A Western blot analysis of total cell extracts showed that sigma22 was approximately 10-fold higher in strains that overproduced alginate, even though algT expression increased less than 2-fold. This suggested that a post-transcriptional mechanism may exist to destabilize sigma22 in order to control certain sigma22-dependent promoters like algD. By Western blotting and phoA fusion analyses, the MucB antagonist of sigma22 was found to localize to the periplasm of the cell. Similar experiments suggest that MucA localizes to the inner membrane via one transmembrane domain with amino- and carboxy-terminal domains in the cytoplasm and periplasm, respectively. These data were used to propose a model in which MucB-MucA-sigma22 interact via an inner membrane complex that controls the stability of sigma22 protein in order to control alginate biosynthesis.

A mycobacterial extracytoplasmic function sigma factor involved in survival following stress

The extracytoplasmic function (ECF) sigma factors constitute a diverse group of alternative sigma factors that have been demonstrated to regulate gene expression in response to environmental conditions in several bacterial species. Genes encoding an ECF sigma factor of Mycobacterium tuberculosis, Mycobacterium avium, and Mycobacterium smegmatis, designated sigE, were cloned and analyzed. Southern blot analysis demonstrated the presence of a single copy of this gene in these species and in Mycobacterium bovis BCG, Mycobacterium leprae, and Mycobacterium fortuitum. Sequence analysis showed the sigE gene to be highly conserved among M. tuberculosis, M. avium, M. smegmatis, and M. leprae. Recombinant M. tuberculosis SigE, when combined with core RNA polymerase from M. smegmatis, reconstituted specific RNA polymerase activity on sigE in vitro, demonstrating that this gene encodes a functional sigma factor. Two in vivo transcription start sites for sigE were also identified in M. smegmatis and M. bovis BCG. Comparison of wild-type M. smegmatis with a sigE mutant strain demonstrated decreased survival of the mutant under conditions of high-temperature heat shock, acidic pH, exposure to detergent, and oxidative stress. An inducible protective response to oxidative stress present in the wild type was absent in the mutant. The mycobacterial SigE protein, although nonessential for viability in vitro, appears to play a role in the ability of these organisms to withstand a variety of stresses.

The Bacillus subtilis sigma(X) protein is an extracytoplasmic function sigma factor contributing to survival at high temperature

The sigX gene, identified as part of the international effort to sequence the Bacillus subtilis genome, has been proposed to encode an alternative sigma factor of the extracytoplasmic function (ECF) subfamily. The sigX gene is cotranscribed with a downstream gene, ypuN, during logarithmic and early stationary phases of growth. We now report that strains lacking sigma(X) are impaired in the ability to survive at high temperature whereas a ypuN mutant has increased thermotolerance. We overproduced and purified sigma(X) from Escherichia coli and demonstrate that in vitro, both sigma(A) and sigma(X) holoenzymes recognize promoter elements within the sigX-ypuN control region. However, they have distinct salt optima such that sigma(A)-dependent transcription predominates at low salt while sigma(X)-dependent transcription predominates at high salt. A 54-bp region upstream of sigX suffices as a sigma(X)-dependent promoter in vivo, demonstrating that sigX is at least partially under positive autoregulatory control. Mutation of ypuN increases expression from the sigma(X)-dependent promoter in vivo, suggesting that ypuN may encode a negative regulator of sigma(X) activity.

An operon containing fumC and sodA encoding fumarase C and manganese superoxide dismutase is controlled by the ferric uptake regulator in Pseudomonas aeruginosa: fur mutants produce elevated alginate levels

The activities of fumarase- and manganese-cofactored superoxide dismutase (SOD), encoded by the fumC and sodA genes in Pseudomonas aeruginosa, are elevated in mucoid, alginate-producing bacteria and in response to iron deprivation (D. J. Hassett, M. L. Howell, P. A. Sokol, M. L. Vasil, and G. E. Dean, J. Bacteriol. 179:1442-1451, 1997). In this study, a 393-bp open reading frame, fagA (Fur-associated gene), was identified immediately upstream of fumC, in an operon with orfX and sodA. Two iron boxes or Fur (ferric uptake regulatory protein) binding sites were discovered just upstream of fagA. Purified P. aeruginosa Fur caused a gel mobility shift of a PCR product containing these iron box regions. DNA footprinting analysis revealed a 37-bp region that included the Fur binding sites and was protected by Fur. Primer extension analysis and RNase protection assays revealed that the operon is composed of at least three major iron-regulated transcripts. Four mucoid fur mutants produced 1.7- to 2.6-fold-greater fumarase activity and 1.7- to 2.3-greater amounts of alginate than wild-type organisms. A strain devoid of the alternative sigma factor AlgT(U) produced elevated levels of one major transcript and fumarase C and manganase-cofactored SOD activity, suggesting that AlgT(U) may either play a role in regulating this transcript or function in some facet of iron metabolism. These data suggest that the P. aeruginosa fagA, fumC, orfX, and sodA genes reside together on a small operon that is regulated by Fur and is transcribed in response to iron limitation in mucoid, alginate-producing bacteria.

Fumarase C activity is elevated in response to iron deprivation and in mucoid, alginate-producing Pseudomonas aeruginosa: cloning and characterization of fumC and purification of native fumC

We report the discovery of fumC, encoding a fumarase, upstream of the sodA gene, encoding manganese superoxide dismutase, in Pseudomonas aeruginosa. The fumC open reading frame, which terminates 485 bp upstream of sodA, contains 1,374 bp that encode 458 amino acids. A second 444-bp open reading frame located between fumC and sodA, called orfX, showed no homology with any genes or proteins in database searches. A fumarase activity stain revealed that P. aeruginosa possesses at least two and possibly three fumarases. Total fumarase activity was at least approximately 1.6-fold greater in mucoid, alginate-producing bacteria than in nonmucoid bacteria and decreased 84 to 95% during the first 5 h of aerobic growth, followed by a rapid rise to maximum activity in stationary phase. Bacteria exposed to the iron chelator 2,2'-dipyridyl, but not ferric chloride, demonstrated an increase in fumarase activity. Mucoid bacteria produced approximately twofold-higher levels of the siderophores pyoverdin and pyochelin than nonmucoid bacteria. Northern blot analysis revealed a transcript that included fumC, orfX, and sodA, the amount of which was increased in response to iron deprivation. A P. aeruginosa fumC mutant produced only approximately 40% the alginate of wild-type bacteria. Interestingly, a sodA mutant possessed an alginate-stable phenotype, a trait that is typically unstable in vitro. These data suggest that mucoid bacteria either are in an iron-starved state relative to nonmucoid bacteria or simply require more iron for the process of alginate biosynthesis. In addition, the iron-regulated, tricarboxylic acid cycle enzyme fumarase C is essential for optimal alginate production by P. aeruginosa.

Protein misfolding in the cell envelope of Escherichia coli: new signaling pathways

Depending on their cellular localization, misfolded proteins in Escherichia coli trigger two different heat-shock responses. Cytoplasmic proteins induce the 'classical' heat-shock regulon transcribed by the E sigma 32 polymerase. By contrast, misfolding of proteins in the cell envelope induces the newly described E sigma E-dependent regulon. This implies that there is an inducible transduction machinery in the inner membrane. The response to protein misfolding in the cell envelope is a finely tuned system regulated by a cascade of phosphorylation and dephosphorylation reactions.

Identification of the algZ gene upstream of the response regulator algR and its participation in control of alginate production in Pseudomonas aeruginosa

Alginate production in mucoid Pseudomonas aeruginosa isolates from cystic fibrosis patients is under direct control by AlgU, the P. aeruginosa equivalent of the extreme heat shock sigma factor sigma(E) in gram-negative bacteria, and AlgR, a response regulator from the superfamily of two-component signal transduction systems. In this report, we describe the identification of the algZ gene, located immediately upstream of algR, which is involved in the control of alginate production. The predicted product of the algZ gene showed similarity to a subset of sensory components from the superfamily of signal transduction systems but lacked several of the highly conserved motifs typical of histidine protein kinases. Inactivation of algZ in the wild-type standard genetic strain PAO1 did not affect its nonmucoid morphology. However, inactivation of algZ in a mucoid mutant P. aeruginosa strain, which had AlgU freed from control by the anti-sigma factor MucA, resulted in increased alginate production under growth conditions which did not permit expression of mucoidy in the parental algZ+ strain. The observed effects were abrogated when algR was inactivated in the algZ::Tc(r) background. These findings indicate that algZ plays a regulatory role in alginate production, possibly interacting with AlgR, and that it may have negative effects on expression of the mucoid phenotype under the conditions tested. The presented results suggest that elements of negative regulation exist at the levels of both the alternative sigma factor AlgU and the transcriptional activator AlgR which, once relieved from that suppression, cooperate to bring about the expression of the alginate system.

Microbial pathogenesis in cystic fibrosis: mucoid Pseudomonas aeruginosa and Burkholderia cepacia

Respiratory infections with Pseudomonas aeruginosa and Burkholderia cepacia play a major role in the pathogenesis of cystic fibrosis (CF). This review summarizes the latest advances in understanding host-pathogen interactions in CF with an emphasis on the role and control of conversion to mucoidy in P. aeruginosa, a phenomenon epitomizing the adaptation of this opportunistic pathogen to the chronic chourse of infection in CF, and on the innate resistance to antibiotics of B. cepacia, person-to-person spread, and sometimes rapidly fatal disease caused by this organism. While understanding the mechanism of conversion to mucoidy in P. aeruginosa has progressed to the point where this phenomenon has evolved into a model system for studying bacterial stress response in microbial pathogenesis, the more recent challenge with B. cepacia, which has emerged as a potent bona fide CF pathogen, is discussed in the context of clinical issues, taxonomy, transmission, and potential modes of pathogenicity.