Genome Expression Analyses Revealing the Modulation of the Salmonella Rcs Regulon by the Attenuator IgaA

Intracellular growth attenuator A (IgaA) was identified as aSalmonella enterica regulator limiting bacterial growth insidefibroblasts. Genetic evidence further linked IgaA to repressionof the RcsCDB regulatory system, which responds to envelopestress. How IgaA attenuates this system is unknown. Here, wepresent genome expression profiling data of S. enterica serovarTyphimurium igaA mutants grown at high osmolarity and displayingexacerbated Rcs responses. Transcriptome data revealed thatIgaA attenuates gene expression changes requiring phosphorylatedRcsB (RcsB $~$ P) activity. Some RcsB-regulated genes, yciGFE andSTM1862 (pagO)-STM1863-STM1864, were equally expressed in wild-typeand igaA strains, suggesting a maximal expression at low levelsof RcsB $~$ P. Other genes, such as metB, ypeC, ygaC, glnK, glnP,napA, glpA, and nirB, were shown for the first time and by independentmethods to be regulated by the RcsCDB system. Interestingly,IgaA-deficient strains with reduced RcsC or RcsD levels exhibiteddifferent Rcs responses and distinct virulence properties. spvvirulence genes were differentially expressed in most of theanalyzed strains. spvA expression required RcsB and IgaA but,unexpectedly, was also impaired upon stimulation of the RcsC $->$ RcsD $->$ RcsBphosphorelay. Overproduction of either RcsB⁺ or a nonphosphorylatableRcsB(D56Q) variant in strains displaying low spvA expressionunveiled that both dephosphorylated RcsB and RcsB $~$ P are requiredfor optimal spvA expression. Taken together, our data supporta model with IgaA attenuating the RcsCDB system by favoringthe switch of RcsB $~$ P to the dephosphorylated state. This roleof IgaA in constantly fine-tuning the RcsB $~$ P/RcsB ratio may ensurethe proper expression of important virulence factors, such asthe Spv proteins.

INTRODUCTION

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INTRODUCTION

Bacteria use two-component signaling systems to sense, respondto, and adapt to changes in the environment (38, 57). Thesesystems participate in processes such as chemotaxis, motility,biofilm formation, adaptation to stress, and virulence (1, 5,24). A sensor histidine kinase and a cytosolic response regulatorare essential elements of these systems (38, 43). In responseto the external stimulus, the histidine kinase auto-phosphorylatesa conserved histidine residue to further transfer the phosphorylgroup to a conserved aspartate residue of the response regulator.Once phosphorylated, the response regulator binds target genesto modulate their expression levels. Transfer of the phosphategroup also occurs between modules of the same protein or intermediateproteins that act as phospho-transmitters (43). A widely studiedtwo-component signaling system is the RcsCDB signaling system,first identified in Escherichia coli as a regulator of the productionof the colanic acid capsule (53). This system can be activatedby diverse envelope-related stresses (13, 14, 19, 20, 35, 36,47, 49, 52, 61) or the overproduction of proteins such as DjlA,LolA, and OmpG (11, 37).

The RcsCDB system operates with two membrane proteins, the hybridsensor RcsC and the phospho-transmitter RcsD, together withthe cytosolic response regulator RcsB (34, 39). Most genes subjectedto regulation by the RcsCDB system encode envelope proteinsand factors related to the synthesis of diverse exopolysaccharides(20, 22, 23, 27, 30, 35). It has been proposed that, upon sensingenvelope alterations, bacteria activate the RcsCDB system toremodel the envelope composition accordingly. The stimulus sensedby the system is transmitted via an RcsC $->$ RcsD $->$ RcsB phosphorelay(11). Phosphorylated RcsB (RcsB $~$ P) modulates target gene expressionby interacting with DNA through its C-terminal DNA-binding domain.RcsA is another protein playing a coregulatory role in a subsetof the RcsB-regulated genes, such as those involved in the productionof the colanic acid capsule (39). The outer membrane proteinRcsF also modulates the RcsCDB system by activating RcsC viaa yet-unknown mechanism (8, 40). RcsF-independent signalingrequiring RcsC has also been shown previously (8). Another importantregulatory mechanism is the phosphorylation of RcsB mediatedby acetyl-phosphate under conditions in which RcsC functionsmainly as phosphatase (26).

In our previous studies, we obtained genetic evidence linkingan inner membrane protein of Salmonella enterica serovar Typhimurium,named intracellular growth attenuator A (IgaA), to repressionof the RcsCDB system (6). Mutations affecting IgaA stabilityresult in strong RcsCDB responses, manifested by the inhibitionof flagellum production and the overproduction of capsule materialand cell division proteins (6, 42). Activation of the RcsCDBsystem in E. coli has been correlated in most cases to envelopestress (34, 39). However, mutations in IgaA causing partialloss of function (igaA1 allele) do not alter envelope integrityin serovar Typhimurium (17, 42). Thus, activation of the RcsCDBsystem does not necessarily impair envelope homeostasis, andsome remodeling may be tolerable without compromising basicenvelope functions. On the other hand, IgaA is an essentialprotein in serovar Typhimurium but dispensable in mutants lackingany of the three main components of the RcsCDB system (6, 15,42). Spontaneous mutations consisting of deletions leading toa diminished production of RcsC or RcsD are also known to suppressIgaA essentiality (42). Important traits of serovar Typhimurium,such as its virulence potential, depend on the fine-tuning ofthe activity of the RcsCDB system (17, 28, 45). IgaA and theRcsCDB system are present in the same genera of enteric bacteria(17, 20, 34), and this concurrence strongly supports the functionallink existing between IgaA and the RcsCDB system.

Microarray analyses performed with E. coli have been instrumentalin defining the composition of the Rcs regulon under diverseenvironmental conditions (23, 30, 46). Although common geneswere found in these studies, there were also substantial differences,probably due to the distinct growth conditions and the diversemutations used. Thus, 46 genes with altered expression wereidentified when rcsB⁺ and ${Delta}$ rcsB strains were compared (46); 32genes were identified when rcsC⁺ and ${Delta}$ rcsC strains grown at lowtemperatures, in glucose, and with high zinc concentrationswere compared (30); and 149 genes were identified when profilesof rcsC⁺ and ${Delta}$ rcsC bacteria overexpressing DjlA were compared(23). The Rcs regulon of Yersinia pseudotuberculosis has beenestimated to be formed by at least 136 genes, with 60% of thegenes encoding functions related to envelope homeostasis (31).In serovar Typhimurium, 26 RcsB-dependent but RcsA-independentgenes were reported upon exposure of bacteria to sublethal concentrationsof antimicrobial peptides (20). Recent studies performed withserovar Typhimurium expressing IgaA(T191P), a variant previouslyshown by us to be unable to repress the RcsCDB system (17),revealed that one-fifth of the genes analyzed displayed expressionchanges higher than twofold (55).

In this work, we analyzed the serovar Typhimurium Rcs regulonin bacteria exposed to high osmolarity, a condition known tostimulate the RcsCDB system (61). We also investigated the Rcsregulon in strains producing an IgaA(R188H) variant (R188H isthe first mutation characterized for this attenuator to causeoveractivation of the RcsCDB system [6, 7, 17, 27, 54]) andin recently described IgaA-deficient strains having reducedRcsC or RcsD levels (42). The study has provided new insightsinto the mode of attenuation exerted by IgaA on the RcsCDB systemand has led to the first evidence supporting a role for dephosphorylatedRcsB as a transcriptional regulator.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains, plasmids, and growth conditions. The Salmonella enterica serovar Typhimurium strains and plasmidsused in this work are listed in Table 1. All strains are isogenicderivates of the mouse-virulent strain SL1344 (33). Bacteriawere grown at 37°C in Luria-Bertani (LB) broth, on LB agarplates, or in minimal intracellular-salt medium (ISM) as indicatedpreviously (6, 58). ISM, which is of high osmolarity (403 mosmol),provides an optimal stimulus for induction of the RcsCDB systemin strains with defects in IgaA (see below). ISM has also beenshown to be suitable to assess expression of the spv virulencegenes in serovar Typhimurium (58). Unless otherwise indicated,glycerol (38 mM) was used as the carbon source in the ISM. Whenappropriate, kanamycin (30 µg ml^–1), tetracycline(10 µg ml^–1), ampicillin (100 µg ml^–1),or chloramphenicol (10 µg ml^–1) was used.

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TABLE 1. S. enterica serovar Typhimurium strains and plasmids used in this study

Generation of a nonphosphorylatable RcsB(D56Q) variant. A nonphosphorylatable RcsB(D56Q) variant was constructed usingas the template the plasmid pIZ1589, a gift of J. Casadesús(Universidad de Sevilla, Spain). pIZ1589 expresses the rcsB⁺wild-type allele under the control of the arabinose-inducibleP_BAD promoter (27). Mutagenesis of the phosphorylatable aspartateresidue at position 56 of RcsB was designed to replace codon56, GAC, with codon CAG, specific for glutamine. The mutagenesiswas performed by overlap extension PCR as described previously(32) using the following oligonucleotides: rcsB5' (5'-AGC GGAATT CAG GAG GAA TAC ATG AAC AAT ATG AAC G-3'), rcsB3'D56Q (5'-CATGGA GAG CTG AGT GAT CAA C-3'), rcsB5'D56Q (5'-GTT GAT CAC TCAGCT CTC CAT G-3'), and rcsB3' (5'-GTG AAA GCT TGT CGA CAA GCGATT TAT TCT TTG TCT G-3'). The underlined oligonucleotide sequencesare the sites changed in the mutagenesis procedure.

Construction of a ${Delta}$ rcsD nonpolar deletion mutant. To avoid any polar effect on rcsB transcription, the deletionof rcsD was designed from 155 nucleotides upstream of the startcodon (micF-rcsD intergenic region) to position 2,523 of the2,670-nucleotide open reading frame of rcsD. The deletion wascreated by following the one-step inactivation procedure describedby Datsenko and Wanner and using plasmid pKD3 as the template(16). The oligonucleotides used for this procedure were rcsD-P1(5'-AGC AAA TAA TTT CTT GAT ATT TAG TGC TAA ACA TTT ATA AGTAGT CTT TAT GTG TAG GCT GGA GCT GCT TC-3') and rcsD-P2 (5'-TAACTG CTT GCC GGG TAC CAG ATT AAG CAT GGC AAA CAC CCC TTT CAGGCG CAT ATG AAT ATC CTC CTT AGT-3'). Underlined in these sequencesare the regions that anneal to the flanking regions of the catcassette (Cm^r) present in plasmid pKD3. This allelic exchangegenerated the strain MD2022 ( ${Delta}$ rcsD69::cat). The cat cassettewas further eliminated with plasmid pCP20, expressing the FLPrecombinase, as described previously (16), and resulting instrain MD2023 ( ${Delta}$ rcsD69). Control experiments showed that rcsBtranscription is not affected in strain MD2023 (see Fig. S1in the supplemental material). Oligonucleotides specific forrcsD, rcsB, and rcsC used in these reverse transcription-PCR(RT-PCR) assays are listed in Table S1 in the supplemental material.The loss of the wild-type rcsD⁺ allele was confirmed with oligonucleotidesyojN-4D and yojN-2R (see Table S1 in the supplemental material).

Phage transductions. The transductional crosses were made using the P22 HT 105/1int201 phage (51), as described previously (41). Phage-freetransductants were screened on green plates as described previously(10) and tested for sensitivity to the clear-plaque mutant P22H5.

Microarray analyses. A 70-mer oligonucleotide microarray was constructed using thegenome sequence of S. enterica serovar Typhimurium strain SL1344,made available by the Wellcome Trust Sanger Institute (see thesupplemental material). Hybridization of nucleic acids was conductedusing cDNA as the "expression sample" of the respective strainmixed with genomic DNA (gDNA) as the internal reference. Aspreviously reported (21), this method allows transcriptome comparisonsamong different strains. RNA was purified in six independentexperiments from bacteria grown in 10 ml of ISM-glycerol mediumat exponential phase (optical density at 600 nm [OD₆₀₀], $~$ 0.2)by using the SV total RNA isolation system kit (catalog no.Z3100; Promega). These RNAs were combined in pools of threesamples and used in two independent hybridizations. Prior tothis manipulation, a 1:5 volume of a 95% ethanol-5% phenol solutionwas added to the bacterial culture (final concentration, 19%ethanol-1% phenol). As described previously, this step ensuresthe full integrity and stability of the RNA (21). The qualityof the RNA was tested using an Agilent 2100 bioanalyzer (AgilentTechnologies, Palo Alto, CA). RT of RNA was performed with SuperScriptIII reverse transcriptase (catalog no. 18080-044; Invitrogen)according to the instructions of the manufacturer. cDNA waspurified with the QIAquick ${per thousand}$ PCR purification kit (catalog no.28106; Qiagen). Reference gDNA was purified from bacteria grownin 6 ml of LB broth to stationary phase. Upon centrifugation(10,000 x g for 10 min, 4°C), the bacterial pellet was processedusing the Qiagen gDNA kit (catalog no. 19060/10243; Qiagen).DNA was finally suspended in 200 µl of deionized water,resulting in a total amount in the range of 60 to 90 µg.This DNA was further fragmented by sonication before its usein the hybridization assays. Labeling of cDNA and gDNA withAlexa Fluor 647 and Alexa Fluor 555 fluorescence molecules,respectively, was conducted as described previously (21) usingexo-Klenow enzyme and the BioPrime Plus array CGH indirect genomiclabeling system (catalog no. 18096-011; Invitrogen). LabeledcDNA and gDNA were further purified, and the amount of incorporatedlabeling was estimated in a NanoDrop ND-1000 UV-visible-lightspectrophotometer. Hybridization conditions, data acquisition,normalization, and statistical analysis are described in detailin the supplemental material.

RT-PCR assays. RT-PCR was performed using a one-step RT-PCR kit (Qiagen) aspreviously described (55). Briefly, DNase (Ambion)-treated RNAsamples were diluted to 20 ng/µl and were further normalizedagainst the RT-PCR-amplified ompA product, used as an internalcontrol. The RT-PCR was carried out with a final volume of 25µl consisting of 5 µl buffer (5x), 1 µl ofdeoxynucleoside triphosphates (10 mM), 3 µl each of theforward and reverse primers (5 µM), 1 µl of RT-PCRenzyme mix, and $~$ 20 ng of RNA and RNase-free water supplementedto 25 µl. The RT-PCR cycling conditions were as follows:50°C for 35 min and 95°C for 15 min, followed by 26cycles of 94°C for 30 s, 55°C for 30 s, and 72°Cfor 40 s and then an extra step of elongation at 72°C for10 min. Oligonucleotides used in these RT-PCR assays are listedin Table S1 in the supplemental material.

β-Galactosidase assays. The levels of β-galactosidase enzyme derived from the wcaH21::MudJand spvA103::MudJ transcriptional fusions were determined usingthe CHCl₃-sodium dodecyl sulfate permeabilization procedure,as described previously (44). Bacteria were grown overnightat 37°C in LB broth or ISM-glycerol medium under shakingconditions (180 rpm), until a final OD₆₀₀ of $~$ 3.0 (LB medium)or $~$ 1.2 to 1.4 (ISM) was reached. Cultures were further diluted1:100 in fresh medium and further incubated for 6 h, the timeat which β-galactosidase activity was measured. In thecase of RcsB variants expressed from plasmids under the arabinose-inducibleP_BAD promoter, bacteria were grown overnight in ISM-2% glucose(OD₆₀₀, $~$ 1.2 to 1.4) and later washed once in ISM with no sugaradded. These bacteria were then added to either ISM-2% glucoseor ISM-glycerol-0.05% arabinose medium (final OD₆₀₀, $~$ 0.05) andfurther incubated for 16 h, the time at which the β-galactosideactivity was measured. The experiments were repeated at leastthree times.

Virulence assays. To assess the virulence capacity of IgaA-deficient strains withdistinct levels of expression of the RcsCDB system, the protocolof Beuzón and Holden involving a 1:1 mixture of mutantand wild-type strains was used (2). Three female BALB/c mice(6 to 8 weeks old) were challenged per mixture using the intraperitonealroute. The experiment was repeated twice using 2 x 10⁵ CFU ofeach strain. The competitive index assay results were calculatedfrom the numbers of viable bacteria counted in liver and spleenat 48 h postinfection.

Statistical analysis. Data were analyzed by one-way analysis of variance using Prismversion 5.0 (GraphPad Software, Inc.). Differences in the valueswith a P of <0.05 were considered statistically significant.

Accession numbers. The characteristics and configuration of the Salgenomics microarraywere deposited in the MIAME database (http://www.ebi.ac.uk/miamexpress)under accession number A-MEXP-846. Gene expression data weredeposited in the Array Express database (http://www.ebi.ac.uk/arrayexpress)under accession number E-MEXP-1612.

RESULTS

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RESULTS

Definition of the serovar Typhimurium Rcs regulon in a high-osmolarity minimal medium. The Rcs regulon in E. coli has been extensively studied (23,30, 46). In the case of serovar Typhimurium, a recent studyreported microarray data of wild-type, rcsC, rcsD, rcsB, andrcsA strains exposed to sublethal concentrations of polymyxinB (20). The report of that study listed 26 serovar Typhimuriumgenes regulated by the RcsCDB system in an RcsA-independentmanner (21 positively and 5 negatively). However, neither theidentities of RcsB- and RcsA-coregulated genes nor the transcriptomeprofiles were provided. In another recent study, approximately20% of the serovar Typhimurium genome was claimed to be underthe control of RcsB in bacteria growing in nutrient-rich medium(55). In that study, a strain expressing an IgaA(T191P) mutantprotein was used as a control of activation of the RcsCDB system.

In our attempt to dissect the modulation exerted by IgaA onthe RcsCDB system, we performed genome expression profilingof serovar Typhimurium strains with defects in this attenuatorand grown under conditions not tested in previous studies. Weexamined the effect of the R188H change in IgaA (allele igaA1),the first-characterized mutation that revealed a functionallink between IgaA and the RcsCDB system (6, 7, 17). Bacteriawere grown in the high-osmolarity minimal medium ISM (58), inwhich the Rcs response is more pronounced when IgaA is altered.Thus, the igaA1 mutant expressed the colanic capsule gene wcaH,positively regulated by the RcsCDB system, at $~$ 15-fold higherlevels in ISM than in LB medium (Fig. 1). Our microarray studyalso included "mucoid" strains lacking IgaA which have recentlybeen characterized (42). Two of these IgaA-defective strainswith a functional RcsCDB system are MD0842-J4 (igaA2::KIXX rcsC67')and MD0855-J10 [igaA2::KIXX ${Delta}$ (ompC'-micF)], which spontaneouslysuppressed IgaA essentiality by diminishing the protein levelsof RcsC and RcsD, respectively (42). In total, the isogenicstrains used in our microarray studies included the wild type;igaA1, rcsB, rcsA, igaA1 rcsB, and igaA1 rcsA strains; MD0842-J4;and MD0855-J10 (Table 2). The microarray Salgenomics, designedon the genome sequence of the virulent serovar Typhimurium strainSL1344 (33), was constructed for this purpose (see the supplementalmaterial). Only those gene expression changes with values offourfold or higher (log₂ ratio, $≤$ –2 or $≥$ 2) were consideredsignificant.

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FIG. 1. Growth of serovar Typhimurium under high-osmolarity conditions augments the Rcs response resulting from defects in the attenuator IgaA. The expression of the colanic acid gene wcaH (gmm), positively regulated by the Rcs system, was monitored in bacteria grown in nutrient-rich LB medium (dark-gray bars) or ISM-glycerol minimal medium of high osmolarity (light-gray bars). The isogenic strains used were wild-type SV4407 (wcaH21::MudJ), MD0099 (igaA1 wcaH21::MudJ), and MD0870 (igaA1 rcsB70 wcaH21::MudJ). These strains are abbreviated in the figure as WT, igaA, and igaA1 rcsB, respectively. Bacteria were grown to an OD₆₀₀ of $~$ 2.5 to $~$ 3.0 (LB medium) or $~$ 1.2 to $~$ 1.4 (ISM-glycerol medium). β-Galactosidase activities correspond to the means and standard deviations from a minimum of three independent experiments. Mean values are also shown on top of the bars.

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TABLE 2. List of the tables in the supplemental material showing serovar Typhimurium genes with altered expression caused by mutations in igaA, components of the RcsCDB system, and/or the coregulator RcsA^a

Identification of IgaA-regulated genes. The effect of the IgaA(R188H) mutation in the Rcs regulon wasassessed in the wild-type, igaA1, rcsB, and igaA1 rcsB strains.Expression profiles were processed in the form of comparisonsof a mutant and the wild type or of two mutants (Table 2). Atotal of 71 genes displaying changes in expression from thewild-type strain of at least fourfold were identified in theigaA1 mutant. Of these, 33 were upregulated (Table 3) and 38downregulated (Table 4). Most of the upregulated genes (n =22), are involved in colanic acid capsule synthesis (wza-wzb,wcaABCDEF-gmd-wcaGHI-manC, cpsG-wcaJ, wzxC-wcaKLM, and the regulatorygene rcsA) (30, 55). The yjbEFGH operon, recently describedto be required for the synthesis of a novel exopolysaccharidein E. coli (22), was also upregulated in the serovar TyphimuriumigaA1 mutant (Table 3). So, $~$ 80% (26/33) of the genes highlyupregulated in the igaA1 mutant are involved in the synthesisof capsular exopolysaccharides. Other genes induced in the igaA1mutant and previously known to be regulated by RcsCDB are osmB,ygaC, and yebE (3, 23, 30, 55). On the other hand, metB-metF,two genes involved in methionine biosynthesis, were identifiedin our study as new genes positively regulated by the RcsCDBsystem.

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TABLE 3. Genes in the serovar Typhimurium igaA1 mutant with increased expression relative to that in the wild-type strain

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TABLE 4. Genes with decreased expression in the serovar Typhimurium igaA1 mutant versus the wild-type strain

Among the 38 downregulated genes in the igaA1 mutant, 26 wereflagellum and chemotaxis genes (Table 4). Unlike in a recentstudy that analyzed the response in LB medium of an igaA(T191P)mutant with high Rcs activity (55), no reduced expression ofvirulence genes present in Salmonella pathogenicity islands1 and 2 or of fimbrial genes was noted. Interestingly, othergenes repressed in our igaA1 mutant are related to ammonia metabolismand nitrate/nitrite respiration (glnK, glnP, napA, napD, nirB),transport of maltose (malE, lamB), and uptake/metabolism ofglycerol-3-phosphate (glpT, glpA). In addition, a pronouncedrepression of spvA and spvB, two Salmonella-specific genes requiredfor virulence (29), was detected in the igaA1 mutant with log₂ratios in the range of –4 or –5, equivalent to $~$ 15-to 30-fold changes (Table 4). A search in the literature forgenes previously assigned to Rcs regulons of different enterobacteriarevealed that among the 71 genes identified with altered expressionin the igaA1 mutant, 13 were not reported before as genes regulatedby the RcsCBD system. These include yebE, dsrB, ypeC, metB,metF, spvB, spvA, glnK, glnP, napA, napD, glpA, yhbU, and nirB(Tables 3 and 4).

The gene expression profile of the igaA1 mutant was then comparedto those of the igaA1 rcsB and rcsB strains. Among the 71 geneshaving altered expression in the igaA1 mutant compared to thatin wild-type bacteria (Tables 3 and 4), 68 of them did not displayany significant change in expression in the igaA1 rcsB and rcsBstrains (Fig. 2A and B). It is noteworthy that the yciGFE operonand the Salmonella-specific genes STM1862 (pagO), STM1863, andSTM1864 were downregulated only in the mutants lacking RcsB,irrespective of the functional status of IgaA (igaA1 rcsB andrcsB mutants) (Fig. 2B; see also Tables S3, S4, and S5 in thesupplemental material). Such observations may indicate thatthese genes are maximally expressed with low levels of RscB $~$ P.Other genes, such as spvA and spvB, were, however, downregulatedto a large extent in the three strains tested, namely, the igaA1,igaA1 rcsB, and rcsB mutants (Table 4; Fig. 2B). To furtherconfirm these observations, RT-PCR was used as an alternativemethod to monitor the expression of representative genes notdescribed before as regulated by the RcsCDB system (spvA, metB,ypeC, glnK, glnP, napA, glpA, and nirB). Control genes knownto form part of the Rcs regulon, such as wcaH and ygaC, werealso included. The results of these RT-PCR assays were in agreementwith the microarray data, with expression profiles for the igaA1mutant being clearly opposite to those of the wild-type, igaA1rcsB, and rcsB strains, except in the expression of spvA (Fig.3). Taken together, these studies demonstrated that in bacteriagrowing at high osmolarity, IgaA antagonizes the activity ofRcsB $~$ P for most genes that are targeted by this response regulator.

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FIG. 2. The attenuator IgaA controls part of the Rcs regulon. The Venn diagrams show genes induced (A) or repressed (B) in igaA1, igaA1 rcsB, and rcsB strains upon comparison of their respective gene expression profiles with that of the wild-type strain. Only genes displaying changes with a log₂ ratio that was $≤$ –2 or $≥$ 2 are shown. Some genes, such as STM1863-STM1864 or yciGFE, are downregulated when RcsB is not functional but not induced in the igaA1 mutant with a strong RcsCDB response. Other genes, such as spvAB, display a complex regulatory pattern since they are positively regulated by RcsB (repressed in the igaA rcsB and rcsB strains) but also downregulated when the RcsC $->$ RcsD $->$ RcsB phosphorelay is stimulated (igaA1 strain). The asterisk after rcsB indicates that the gene is knocked out in the two mutants (igaA1 rcsB and rcsB mutants). Genes labeled with two asterisks indicate cases in which, for some of the comparisons shown, one of the log₂ ratios of the gene duplicates was less than or equal to –2 while the other value was close to –2. Thus, STM1862 (pagO) and phoN could be assigned to the category of genes repressed by RcsB: their log₂ ratios in the comparison of the rcsB mutant with the wild type were –2.96/–1.69 and –2.4/–1.8, respectively. Likewise, spvC and spvR could be assigned to the category of genes repressed in the igaA1, igaA1 rcsB, and rcsB strains. spvC had log₂ ratios of –2.8/-1.1 and –2.7/-1.5 in the comparisons of the igaA1 mutant with the wild type and of the rcsB mutant with the wild type, respectively. spvR had log₂ ratios of –2.2/–1.4 in the comparison of the igaA1 mutant with the wild type (see Table S2 in the supplemental material for a complete list of genes).

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FIG. 3. Altered expression in the igaA1 mutant of genes not previously assigned to the RcsCDB regulatory system. Shown are the results of RT-PCR assays of representative genes that the microarray experiments identified as up- or downregulated in the igaA1 mutant (Tables 3 and 4). wcaH, required for synthesis of the colanic acid capsule, and ygaC were used as controls for genes positively regulated by the RcsCDB system. Note that, in concordance with the microarray data, spvA is downregulated in the igaA1 mutant and in strains lacking RcsB. RNA was isolated from bacteria grown in ISM-glycerol medium at an OD₆₀₀ of $~$ 1.2 to $~$ 1.4. Numbers indicate the average log₂ ratios shown in Tables 3 and 4 for each of the indicated strains (igaA1, igaA1 rcsB, and rcsB strains) and relative to values for the wild type (WT).

Identification of genes coregulated by RcsA and RcsB. RcsA coregulates with RcsB the expression of colanic acid capsulegenes and a distinct exopolysaccharide synthesized by the productsof the yjbEFGH operon (22, 39, 55). To define the effect ofigaA mutations on the contribution of RcsA in serovar Typhimurium,we monitored transcription profiles in igaA1, igaA1 rcsA, andrcsA strains. The genes displaying altered transcription weredifferentiated into two classes on the basis of the strict requirementof the coregulator RcsA for expression. The first class containedgenes that were entirely dependent on RcsA, i.e., with alteredexpression in igaA1 rcsA and igaA1 strains. This class includedthe positively regulated colanic acid genes wcaM, wza-wzb, andwcaA-wcaB-wcaC-wcaD; the yjbEFGH operon; and yebE (Table 3;see also Table S6 in the supplemental material). Within thiscategory, but negatively regulated, were glnK and glnP (Table4; see also Table S6 in the supplemental material). To our knowledge,this result represents the first evidence of RcsA being involvedin negatively regulating metabolic genes. In a second category,we classified the genes in the transcriptome of the igaA1 rcsAstrain with altered expression levels compared with those inthe wild type. Within this class, we identified upregulatedgenes, such as the operons wcaE-wcaF-gmd-wcaG-wcaH-wcaI andcpsG-wcaJ-wzxC-wcaK-wcaL, involved in colanic acid synthesis(Table 3; see also Table S7 in the supplemental material). Thisresult suggests that RcsB $~$ P alone, probably at high levels asa consequence of the igaA1 mutation, can drive the expressionof a certain proportion of colanic acid capsule genes in anRcsA-independent manner. Other conditions leading to enhancedRcsB $~$ P levels, such as the expression of the constitutive mutantallele rcsC137 or the expression of rcsB⁺ in multicopy, havepreviously been shown to render the expression of colanic genesindependent of RcsA (4). A detailed view of our expression profilesrevealed, however, that this set of colanic capsule genes (wcaE-wcaF-gmd-wcaG-wcaH-wcaIand cpsG-wcaJ-wzxC-wcaK-wcaL) are expressed in the igaA1 mutantto a higher extent than in the igaA1 rcsA strain (Table 3; seealso Table S6 in the supplemental material). Lastly, note thatsome of the RcsB-regulated genes expressed in an IgaA⁺ (wild-type)background, such as yciGFE (Fig. 2; see also Table S4 in thesupplemental material), also require RcsA for expression (seeTable S8 in the supplemental material). All together, thesedata indicate that RcsA controls part of the Rcs regulon ofserovar Typhimurium and that genes belonging to this class canbe further subdivided by their capacity to be expressed by RcsB $~$ Pin the absence of this coregulator.

A decreased amount of RcsC or RcsD results in different Rcs responses. We have recently shown that serovar Typhimurium can spontaneouslysuppress the requirement of the essential protein IgaA by acquiringdeletions affecting the integrity of the rcsCDB locus (42).Two of the characterized suppressor strains lacking IgaA, MD0842-J4and MD0855-J10, retain activity in the RcsCDB system since bothdisplay increased expression of the colanic acid gene wcaH,produce altered levels of the flagellins FliC and FljB and thecell division proteins FtsA and FtsZ, and are mucoid on plates(42). As a result of deletions affecting the regulatory regionsof rcsC and rcsD, MD0842-J4 and MD0855-J10 mutants produce smallamounts of RcsC and RcsD, respectively (42). To obtain insightsinto how the RcsCDB system could operate in the absence of IgaA,we monitored genome expression profiles in MD0842-J4 and MD0855-J10.The two mutants showed changes similar to those observed inthe igaA1 mutant and indicative of the activity of the RcsCDBsystem, including the upregulation of colanic capsule genesand repression of flagellar genes (see Tables S9 to S13 in thesupplemental material). Nonetheless, several new features differentiatedtheir Rcs responses. The IgaA-defective strain MD0842-J4, withlow levels of RcsC, showed reduced expression of colanic capsulegenes compared to that of the igaA1 mutant (see Table S11 inthe supplemental material). This result was consistent withthe higher expression of a wcaH::lacZ transcriptional fusionin the igaA1 mutant than in MD0842-J4 (42). Unlike the igaA1mutant, the MD0842-J4 mutant, however, expressed spvAB at wild-typelevels (see Table S9 in the supplemental material). In contrast,the IgaA-defective strain MD0855-J10, which has low levels ofRcsD, displayed reduced spvAB expression (see Table S10 in thesupplemental material). As expected by the pronounced mucoidydisplayed by MD0855-J10 on plates, the expression of the colaniccapsule genes in this mutant was comparable to that observedin the igaA1 mutant (see Table S12 in the supplemental material).Globally, these data indicate that a decrease in RcsC significantlyreduces the responsiveness of the RcsCDB system, even in theabsence of the attenuator IgaA. This effect is evident in thecase of colanic acid genes, which are induced only at intermediatelevels, and the spvAB genes, whose expression remains unaltered.Conversely, the RcsCDB system can reach high activation levelswith decreased amounts of RcsD, leading to high expression ofcolanic acid genes and repression of the spvAB genes.

A decreased level of RcsC or RcsD in IgaA-deficient strains has different impacts on serovar Typhimurium virulence. An inverse correlation between RcsCDB activity and the capacityof serovar Typhimurium to cause disease in the mouse acute-infectionmodel has previously been shown (17, 45). The microarray dataobtained with the IgaA-deficient strains MD0842-J4 and MD0855-J10revealed differences in spvAB expression, and as previouslymentioned, these two strains display Rcs responses of differentintensities (42). Since both MD0842-J4 and MD0855-J10 are mucoid,it was of interest to test whether these strains behave differentlyin the mouse typhoid virulence model. Intraperitoneal-challengeassays showed that the MD0855-J10 strain, with a higher Rcsresponse (42), was highly attenuated but that the MD0842-J4strain, with lower Rcs activity, was virulent (Table 5). Weincluded the MD0835-J1 mutant as a control strain, which alsolacks IgaA but harbors a deletion of the apbE'-ompC-micF-rcsD-rcsB-rscC'region (42). This MD0835-J1 mutant behaved as a virulent strain(Table 5); therefore, we discarded the possibility that theattenuation of the MD0855-J10 mutant, which harbors an ompC-micF-rcsD'deletion (42), was due to the lack of ompC and/or micF. Thesedata reinforce the idea of IgaA modulating virulence exclusivelyat the stage of controlling the responsiveness of the RcsCDBsystem. In IgaA-defective bacteria, virulence can differ significantlydepending on whether the relative amount of either RcsC or RcsDis compromised.

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TABLE 5. Virulence of IgaA-deficient mutants of serovar Typhimurium having distinct activation levels of the RcsCDB system

spvA expression is positively controlled by RcsB but affected negatively by the RcsC $->$ RcsD $->$ RcsB phosphorelay. The microarray data uncovered an unexpected complexity in theregulation of the virulence genes spvAB. These genes were downregulatedin the igaA1 mutant upon activation of the RcsCDB system butwere also repressed in bacteria lacking RcsB (Table 4; Fig.2). Furthermore, spvAB displayed altered expression in IgaA-deficientbacteria but only in the mutant having reduced levels of RcsD,MD0855-J10 (see Table S10 in the supplemental material). Basedon these observations, we hypothesized that spvAB could be subjectedto positive regulation by dephosphorylated RcsB. In this context,any increase in the RcsB $~$ P/RcsB ratio could therefore lead tospvAB repression. This postulate predicts that normal spvABexpression levels should be restored in the igaA1 mutant uponinactivation of either RcsC or RcsD. To test this hypothesis,expression of an spvA::lacZ transcriptional fusion was monitoredin the wild-type, igaA1, igaA1 rcsB, rcsB, igaA rcsC, rcsC,igaA1 rcsD, igaA1 rcsA, rcsA, rcsD, MD0842-J4, and MD0855-J10strains. All of the mutants were characterized in previous studies(6, 17, 42), except those containing the rcsD null mutation,which we generated for this work. The rcsD deletion encompassedthe entire rcsD open reading frame except the last 130 nucleotidesat the 3' end, which were left intact to preserve intact the5' regulatory region of rcsB. Control assays revealed that thisdeletion does not affect rcsB transcription (see Fig. S1 inthe supplemental material). Figure 4 shows that spvA transcriptiondecreases significantly when the level of the RcsC $->$ RcsD $->$ RcsB phosphorelayis high (igaA1, igaA1 rcsA, and MD0855-J10 strains). Interestingly,rcsC and rcsD null mutations, but not the rcsA mutation, restoredwild-type levels of expression of spvA in the igaA1 background(Fig. 4). This result suggested that the repression of spvAobserved in the igaA1 mutant requires an active RcsC $->$ RcsD $->$ RcsBphosphorelay but is independent of RcsA. Since the loss of RcsCor RcsD alone did not have any effect on spvA transcription,but RcsB was essential for such expression, we conclude thatdephosphorylated RcsB may contribute to positively regulatethis virulence gene.

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FIG. 4. Expression of the serovar Typhimurium virulence gene spvA requires RcsB but is impaired upon stimulation of the RcsCDB system. spvA expression was monitored in bacteria grown in ISM-38 mM glycerol (OD₆₀₀, $~$ 1.2 to $~$ 1.4). The following isogenic strains were used: SV4312 (spvA103::MudJ), MD1368 (igaA1 spvA103::MudJ), MD1369 (igaA1 rcsB70 spvA103::MudJ), MD1370 (rcsB70 spvA103::MudJ), MD2008 (igaA1 rcsC52 spvA103::MudJ), MD2007 (rcsC52 spvA103::MudJ), MD2028 (igaA1 ${Delta}$ rcsD69 spvA103::MudJ), MD2027 ( ${Delta}$ rcsD69 spvA103::MudJ), MD1396 (igaA1 rcsA51 spvA103::MudJ), MD1397 (rcsA51 spvA103::MudJ), MD1371-MD0842-J4 (J4) (igaA3::Cam^r rcsC67' spvA103::MudJ), and MD1372-D0855-J10 (J10) [igaA3::Cam^r ${Delta}$ (ompC'-micF) spvA103::MudJ]. The genotype of each of these strains is abbreviated in the figure. The β-galactosidase activities correspond to the means and standard deviations from a minimum of three independent experiments and are shown as relative to the wild-type level (100%). The β-galactosidase activity of the wild-type strain (WT) had a mean value of 131.6 Miller units, as determined from a total of nine independent experiments. Note that spvA expression is repressed in strains with high activity of the RcsC $->$ RcsD $->$ RcsB phosphorelay (igaA1 mutant, igaA1 rcsA mutant, and MD0855-J10) and in those lacking RcsB (igaA1 rcsB and rcsB mutants).

Production of a nonphosphorylatable RcsB(D56Q) variant enhances spvA expression. Data shown in Fig. 4 suggested that dephosphorylated RcsB couldplay a role in the positive regulation of spvA. However, otherinterpretations are also possible, such as that spvA was activatedat low RcsB $~$ P levels but repressed at high levels of RcsB $~$ P orthat RcsB was phosphorylated by other phospho-donors, such asacetyl-phosphate in the rcsC or rcsD mutant. To address thispoint, we used plasmids in which RcsB⁺ and a nonphosphorylatableRcsB(D56Q) variant were produced from the arabinose-inducibleP_BAD promoter. To confirm the activities and correct expressionof these two RcsB versions, they were first analyzed in an igaArcsB strain. As expected, RcsB⁺ but not RcsB(D56Q) restoredmucoidy in bacteria grown in medium supplemented with arabinose(Fig. 5A). RcsB⁺ or RcsB(D56Q) were then produced in wild-type,igaA1, igaA1 rcsB, and rcsB strains carrying the spvA::lacZtranscriptional fusion (Fig. 5B). When spvA expression was comparedin media containing either glucose or arabinose, two phenomenawere observed. Unlike with what was observed in bacteria grownwith glycerol as the only carbon source (Fig. 4), low spvA expressionwas detected in all of the different strains grown in glucose-containingmedium (see the legend to Fig. 5). This effect did not impairour analysis of the relative changes in spvA expression uponthe production of RcsB from plasmid (arabinose versus glucose).The expression of the nonphosphorylatable RcsB(D56Q) variant,but not of RcsB⁺, drastically increased spvA expression (Fig.5B). This effect, noticeable in strains lacking endogenous RcsB,was, however, more pronounced in strains with an rcsB⁺ background.Thus, when RcsB(D56Q) was produced in wild-type and igaA1 strains,spvA expression increased up to 22- and 90-fold, respectively(Fig. 5B). In silico analysis of the promoter regions of spvAand spvR, the latter encoding a positive regulator of the spvABCoperon (59), did not reveal any sequence close to the consensusRcsAB box (56; data not shown). Taken together, these observationsunequivocally demonstrated the capacity of dephosphorylatedRcsB to stimulate spvA expression. In addition, they indicatedthat RcsB $~$ P may also be required to achieve proper spvA expressionlevels.

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FIG. 5. Expression of a nonphosphorylatable RcsB(D56Q) variant enhances spvA expression to a higher extent than wild-type RcsB⁺. These RcsB proteins were produced from plasmids under the arabinose-inducible P_BAD promoter (Table 1). (A) Control experiment showing that the expression of wild-type RcsB⁺ but not that of the nonphosphorylatable RcsB(D56Q) variant restores the activity of the RcsCDB system, as denoted by the mucoidy displayed by bacteria on plates. (B) Expression of spvA in wild-type, igaA1, igaA1 rcsB, and rcsB strains producing either RcsB⁺ or RcsB(D56Q). For every strain, the β-galactosidase activity measured under inducing conditions (16 h in ISM-0.05% arabinose-38 mM glycerol) is relative to that obtained in glucose-containing medium (16 h in ISM-2% glucose), which was normalized to 1. The β-galactosidase activity in Miller units measured for each strain in ISM-2% glucose was 7.4 (wild-type [WT] P_BAD-rcsB⁺ strain), 6.2 (igaA1 P_BAD-rcsB⁺ strain), 3.0 (igaA1 rcsB P_BAD-rcsB⁺ strain), 17.3 (rcsB P_BAD-rcsB⁺ strain), 9.6 [wild-type P_BAD-rcsB(D56Q) strain], 4.8 [igaA1 P_BAD-rcsB(D56Q) strain], 9.3 [igaA1 rcsB P_BAD-rcsB(D56Q) strain], and 9.2 [rcsB P_BAD-rcsB(D56Q) strain]. Data correspond to the means and standard deviations from three independent experiments.

DISCUSSION

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DISCUSSION

The RcsCDB system is a complex regulatory system playing animportant role in biofilm formation, virulence, and adaptationto envelope stress (34, 39). Genome expression studies, in fact,show that most of the genes of the Rcs regulon encode proteinsrelated to envelope homeostasis (20, 23, 30, 31, 46, 55). Here,we also studied the role of IgaA as an attenuator of the RcsCDBsystem with a strategy based on genome expression profiling.On this occasion, we used a large number of serovar TyphimuriumigaA mutants and exposed the bacteria to high osmolarity, astimulus known to exacerbate the activity of the RcsCDB system.Under these particular growth conditions, 71 genes in the igaA1mutant, 60 genes in the IgaA-defective MD0842-J4 strain (lowRcsC levels), and 47 genes in the IgaA-defective MD0855-J10mutant (low RcsD levels) displayed changes in expression higherthan fourfold. The analysis of functions equally affected inthe three mutants defines an Rcs regulon of at least 89 genes,approximately 2% of the serovar Typhimurium genome.

In qualitative terms, the Rcs regulon characterized in thiswork is similar to that reported in previous studies, with mostgenes encoding envelope and motility or chemotaxis functions(23, 30, 46). However, our study uncovered new regulatory featuresand identified up to 13 novel genes regulated by the RcsCDBsystem (Tables 3 and 4). Some of these new genes encode hypotheticalproteins, while others are involved in processes related toglycerol-3-phosphate metabolism, methionine biosynthesis, ammoniametabolism, or nitrate/nitrite respiration. Some of these processes,such as those linked to the metabolism of ammonia, nitrate,and nitrite, are repressed upon activation of the RcsCDB system.These observations suggest that the role of the RcsCDB systemmight extend beyond the control of motility, chemotaxis, andenvelope components to other scenarios related to metabolicreadjustments in response to stress.

Our data also revealed that the RcsB $~$ P activity present in wild-typebacteria may be sufficient to account for maximal expressionof genes such as STM1862 (pagO)-STM1863-STM1864 and yciGFE.Other cases in which higher expression is detected in the wildtype than in the rcsB mutant are known for the gadAB genes inE. coli, required for glutamate-dependent acid resistance (9),and for srfA and siiE in serovar Typhimurium (27). More recently,STM1841, a serovar Typhimurium gene of unknown function, wasalso shown to have a 30-fold-higher induction in the wild typethan in the rcsB mutant (55). These observations reflect thatsome genes of the Rcs regulon may require only low RcsB $~$ P levelsto be maximally expressed but that the rest are gradually upregulatedas the relative RcsB $~$ P levels increase in response to stimuli.

We were also interested in dissecting the contribution of RcsAto the Rcs regulon of serovar Typhimurium. rcsA was highly expressedin the igaA1 mutant, confirming the auto-regulation proposedto act via an RcsAB box present in the rcsA promoter (18, 56).Two classes of RcsA-regulated genes, one entirely dependenton this coregulator, were identified. However, we did not observeany correlation of these two categories with the magnitude ofchanges observed in the absence/presence of RcsB or upon inductionof the RcsCDB system by mutations in IgaA. A representativeexample is that of the yciGFE genes, maximally expressed inthe wild-type strain (i.e., not induced in the igaA1 mutant),but displaying an absolute dependence on both RcsB and RcsAfor expression.

Another objective of this study was to analyze how the Rcs reguloncould be affected by a decrease in the relative levels of RcsCand RcsD. To our knowledge, no precedent exists for this typeof analysis at the genome level with reduced amounts of thesensor protein(s) of a two-component system. Colanic acid geneswere induced, albeit to different extents, in three distinctmucoid serovar Typhimurium strains having augmented Rcs responses:MD0842-J4, MD0855-J10, and the igaA1 mutant (42). Based on thisparameter, the intensity of the RcsCDB response was graded inan igaA1 mutant > MD0855-J10 > MD0842-J4 order. Interestingly,phenotypic traits performed with IgaA-deficient bacteria showedvirulence attenuation only for the MD0855-J10 strain (Table5). Since both the MD0842-J4 and MD0855-J10 strains upregulatecolanic acid capsule genes and the yjbEFGH operon, we see asunlikely a negative effect of exopolysaccharide overproductionon virulence (28, 45). On the other hand, MD0842-J4 and MD0855-J10displayed different levels of expression of the virulence genesspvAB, a change that could explain the observed phenotypes.Obviously, alterations in the expression and/or activities ofother virulence factors may also contribute to the attenuationof the MD0855-J10 mutant. Overall, the genome expression datacollected from the IgaA-deficient strains demonstrate that thestrong Rcs responses resulting from the absence of this attenuatorcan be differentiated.

The regulation exerted on the spv genes by the RcsCDB systemwas also of interest. The transcriptional activity of spvA asregistered in different genetic backgrounds revealed a positiveregulation of RcsB on this virulence gene. It is noteworthythat spvA expression was found to be normal in rscC and rcsDmutants, which indicated that an intact RcsC $->$ RcsD $->$ RcsB phosphorelaywas not required for this regulation. This observation, however,contrasted with the reduced spvA expression linked to the stimulationof the RcsCDB system. This finding prompted us to consider aninvolvement of dephosphorylated RcsB. The data obtained withthe nonphosphorylatable RcsB(D56Q) variant demonstrated thatRcsB does not need to be phosphorylated to promote spvA expression(Fig. 5B). To our knowledge, these results are the first evidencesustaining the role of dephosphorylated RcsB as a regulatorof gene expression. Precedents for response regulators thatretain activity independently of phosphorylation are nonethelessknown for NblR in Synechococcus sp. (48), HP1043 in Helicobacterpylori (50), and FrsZ in Myxococcus xanthus (25). In our model,there is, however, a feature not described in the previous cases.RcsB(D56Q) causes a more-pronounced positive effect on spvAwhen it is produced in an rcsB⁺ background, which suggests thatboth RcsB $~$ P and dephosphorylated RcsB may be required for attainingproper spvA expression. This double requirement was tentativelyintegrated into a model in which RcsB $~$ P is proposed to regulatepositively a hypothetical coregulatory protein that could acttogether with dephosphorylated RcsB on spv promoters (Fig. 6).This hypothetical RcsB-coregulator complex may act on the promoterof spvR, the spvABC operon, or both (58). Future work is requiredto discern which of these scenarios is correct. An additionalunexpected finding was the low expression of spvA registeredin glucose-containing medium compared to that under conditionsin which glycerol was the only carbon source. Although the basisof these differences is currently unknown, this new level ofregulation supports the idea of an intricate regulatory circuitoperating on the spvABC genes. Besides the control exerted onthese genes by RpoS (59), the dedicated regulator SpvR (58),polynucleotide phosphorylase (60), and the RcsCDB system (thisstudy), catabolic repression may be relevant.

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FIG. 6. Model showing the putative role of nonphosphorylated RcsB in the positive regulation of spvA expression. This regulation could be hypothetically exerted on the spvABC regulatory region or, indirectly, via the dedicated activator SpvR. The model also highlights the requirement for this process of RcsB $~$ P, probably stimulating the production of an unknown regulatory factor (X) that may act as a coregulator together with dephosphorylated RcsB. The model also includes two alternate mechanisms of attenuation of the RcsC $->$ RcsD $->$ RcsB phosphorelay by IgaA, either by inhibition of autophosphorylation in the H1 kinase domain of RcsC or stimulation of the phosphatase activity associated with the D1 receiver domain of RcsC (dotted lines). This role of IgaA may be essential to fine-tune the switch between RcsB $~$ P and nonphosphorylated RcsB and, as a consequence, to dictate the intensity at which the Rcs regulon is expressed.

In summary, the diminished spvA expression observed in the igaA1mutant can be a consequence of the high RcsB $~$ P/RcsB ratio existingupon stimulation of the RcsC $->$ RcsD $->$ RcsB phosphorelay. IgaA maythen ensure proper spvA expression by facilitating the switchof RcsB $~$ P to the dephosphorylated state. In a more general role,IgaA could be responsible for constantly adjusting the RcsB $~$ P/RcsBratio in response to the amount and/or type of signals perceivedby the bacteria. However, how could IgaA ultimately performthis hypothetical function? Given its location as an integralinner membrane protein, IgaA has the potential to interact withmembrane components of the Rcs system as the primary sensorRcsC. Following this, IgaA might attenuate the autophosphorylationtaking place in the H1 kinase domain or, alternatively, stimulatethe phosphatase activity at the receiver D1 domain of RscC (12,26, 39) (Fig. 6). The possibility of IgaA also modulating theautophosphorylation rate of RcsB in the presence other phospho-donors,such as acetyl-phosphate (26), cannot be discarded with theavailable data. Work directed to explore these diverse mechanismsis in progress.

ACKNOWLEDGMENTS

We thank Josep Casadesús (Universidad of Seville, Spain)and members of the F. García-del Portillo lab for theirvaluable comments. We are also grateful to Roberto Serrano,Marta Godoy (Genomics Unit, Centro Nacional de Biotecnología-CSIC,Madrid, Spain), and Juan Carlos Oliveros (Bioinformatics Unit,Centro Nacional de Biotecnología-CSIC, Madrid, Spain)for their assistance in the microarray experiments and dataanalyses. We also thank the Wellcome Trust Sanger Institute(Hinxton, Cambridge, United Kingdom) for the public availabilityof the serovar Typhimurium SL1344 sequences.

This work was supported by grants from the Ministry of Scienceand Innovation of Spain (GEN2003-20234-C06-01, BIO2007-67457-C02-01,and CSD2008-00013-INTERMODS). J.F.M. was supported by a fellowshipfrom the Programa de Formación de Personal Investigadorof the Ministry of Science and Innovation.

FOOTNOTES

* Corresponding author. Mailing address: Departamento de Biotecnología Microbiana, Centro Nacional de Biotecnología-Consejo Superior de Investigaciones Científicas (CSIC), Darwin 3, 28049 Madrid, Spain. Phone: (34) 91 585 4923. Fax: (34) (91) 585 4506. E-mail: fgportillo{at}cnb.csic.es

Published ahead of print on 5 January 2009.

Supplemental material for this article may be found at http://jb.asm.org/.

REFERENCES

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