Quantitative Effect of luxS Gene Inactivation on the Fitness of Helicobacter pylori

Furanone metabolites called AI-2 (autoinducer 2), used by somebacterial species for signaling and cell density-regulated changesin gene expression, are made while regenerating S-adenosyl methionine(SAM) after its use as a methyl donor. The luxS-encoded enzyme,in particular, participates in this activated methyl cycle bygenerating both a pentanedione, which is transformed chemicallyinto these AI-2 compounds, and homocysteine, a precursor ofmethionine and SAM. Helicobacter pylori seems to contain thegenes for this activated methyl cycle, including luxS, but notgenes for AI-2 uptake and transcriptional regulation. Here wereport that deletion of luxS in H. pylori reference strain SS1diminished its competitive ability in mice and motility in softagar, whereas no such effect was seen with an equivalent ${Delta}$ luxSderivative of the unrelated strain X47. These different outcomesare consistent with H. pylori's considerable genetic diversityand are reminiscent of phenotypes seen after deletion of anothernonessential metabolic gene, that encoding polyphosphate kinase1. We suggest that synthesis of AI-2 by H. pylori may be aninadvertent consequence of metabolite flux in its activatedmethyl cycle and that impairment of this cycle and/or pathwaysaffected by it, rather than loss of quorum sensing, is deleteriousfor some H. pylori strains. Also tenable is a model in whichAI-2 affects other microbes in H. pylori's gastric ecosystemand thereby modulates the gastric environment in ways to whichcertain H. pylori strains are particularly sensitive.

INTRODUCTION

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Introduction

There has been great interest in the ability of some bacterialtaxa to signal their presence and abundance by secreting specificmetabolites; to use these metabolites to monitor the densityof members of their own species and of other species; and torespond with changes in patterns of gene expression, cellularphenotypes, and interactions with other microbes or host tissues—aset of behaviors termed "quorum sensing" (6, 17, 25, 27). Quorumsensing within individual species is often achieved using acyl-homoserine lactones(collectively called autoinducer 1 or AI-1), with much of the speciesspecificity of AI-1 action stemming from differences in acyl chainlength.

Chemically distinct furanone metabolites called AI-2 are alsoused by some species as signals for sensing cell density, bothof unrelated taxa and of the same species. These furanones are by-productsof a cyclic pathway that uses S-adenosyl methionine (SAM) asa methyl donor and then regenerates it (Fig. 1). In this pathway,methyl group transfer from SAM generates S-adenosyl homocysteine(SAH), a potentially toxic methyltransferase inhibitor. SAHis then deadenylated by a nucleosidase (Pfs) to generate S-ribosylhomocysteine (SRH). In the final enzymatic step in AI-2 synthesis,SRH is cleaved by the LuxS enzyme to generate 4,5-dihydroyxl-2,3-pentanedione,which undergoes chemical rearrangement and in some cases additionof boron or other substituents to generate a variety of furanones,some of which have AI-2 signaling activity (6, 25). The othercleavage product, homocysteine, serves as a precursor for methionineand then SAM synthesis. Despite use of AI-2 for quorum sensingby some taxa, AI-2s synthesized in other taxa could be simpleby-products of the activated methyl cycle and of no regulatorysignificance (20, 25). It is not known if LuxS-mediated SRHconsumption contributes importantly to depletion of the potentiallytoxic SAH intermediate and thus to fitness, or if Pfs-catalyzedconversion of SAH to SRH is sufficient, in any species in whichAI-2 synthesis has been studied.

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FIG. 1. AI-2 synthesis as a by-product of metabolic flux in the activated methyl cycle. For simplicity, only those metabolites and enzymes most relevant to the present studies are presented. More-detailed descriptions of this cycle, including structures of intermediates, are presented elsewhere (20, 25).

Helicobacter pylori, the genetically diverse pathogen implicatedin peptic ulcer disease and gastric cancer (4, 15), containsa luxS gene and exhibits luxS-dependent AI-2 synthesis but seemsto lack close homologs of genes known to be involved in AI-2 uptakeor AI-2-responsive transcriptional regulation (2, 20, 25). Furthermore,no effect of luxS gene inactivation on overall growth in culture, VacAtoxin synthesis, protein profiles in two-dimensional gels, or motilityin liquid cultures was detected for the H. pylori strains tested(10, 12). Additional studies indicated that a functional luxSgene diminishes the capacity of H. pylori to form a biofilmat air-liquid-glass interfaces (9) and that a functional luxSgene contributes to a cell density-dependent induction of expressionof flaA-lacZ and flaA-cat reporter constructs (14). However, flaAexpression was less stimulated by conditioned medium than wastypical of responses to AI-2 in well-established models. These studieswere carried out using pure cultures of H. pylori, however,whereas H. pylori's natural habitat consists primarily of gastricepithelial cell surfaces and overlying mucin, a niche that alsocan contain numerous other microbial species (3). Thus, if AI-2 signalingwere important for H. pylori at all, this might be most evidentin vivo, where AI-2 might affect coexisting microbes in waysthat, in turn, impact on receptivity of the gastric mucosal environmentto H. pylori.

Here we studied effects of luxS inactivation on colonizationusing two unrelated mouse-colonizing H. pylori strains, SS1and X47. These two strains were chosen because they differ intheir preferred sites of gastric colonization (antrum versuscorpus, respectively [1]) and in their need for another geneof central metabolism, that encoding polyphosphate kinase 1(PPK1) (responsible for inorganic polyphosphate synthesis [23]).

MATERIALS AND METHODS

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Materials and Methods

H. pylori strains SS1 and X47-2AL (for simplicity, here calledX47) and derivatives diagrammed in Fig. 2 were used in theseexperiments. Standard growth conditions were used, includingculture on brain heart infusion or brucella agar (supplementedwith 7% blood or 7% serum) in microaerobic atmospheres (5% O₂,10% CO₂, or simply 5% CO₂, at Washington and Vanderbilt universities,respectively) (1, 14, 22, 23). These media were supplementedwith 0.4% Isovitalex and the antibiotics amphotericin B (8 µg/ml),trimethoprim (5 µg/ml), and vancomycin (6 µg/ml).Nalidixic acid (10 µg/ml), polymyxin B (10 µg/ml),and bacitracin (200 µg/ml) were added to this medium whenculturing H. pylori from mouse stomachs (referred to as H. pyloriselective agar), thereby ensuring that all colonies recoveredare H. pylori (1). Motility was assayed by inoculating patchesof H. pylori growth into plates containing brucella serum mediumsolidified with 0.35% agar, as described previously (22). Deletionof most of the luxS gene and its replacement with a nonpolarcat (resistance) cassette, as well as insertion of a nonpolarerm resistance cassette just downstream of both ${Delta}$ luxS-cat andluxS wild-type alleles (Fig. 2), was done by PCR without cloning(7, 22), using primers listed in Table 1. The structures oftransformants made with PCR products diagrammed in Fig. 2 weretested by PCR (as in reference 23); all transformants had theexpected allele replacements. Inoculation of 8- to 10-week-oldBALB/cJ and C57BL/6J mice, their sacrifice 2 weeks later, culturingof H. pylori from them, and testing for bacterial genotype werecarried out according to Washington Animal Studies Committee-approvedprotocols, as described previously (1, 23).

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FIG. 2. Structures of luxS-cat deletions and erm-marked insertions used in these studies. Alleles were constructed by assembly of separate PCR products using primers 1 through 12 diagrammed here, with sequences given in Table 1. Downward tails indicate extensions at 5' ends of primers that overlap with and are complementary to other specific primers used here and allow assembly of alleles from individual PCR products, as diagrammed in reference 22. The extensions on primers 2 and 5 overlap with primers 3 and 4, respectively, and extensions on primers 8 and 11 overlap with primers 9 and 10, respectively.

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TABLE 1. PCR primers^a

Two precautions were taken to guard against inadvertent attenuationof mouse-colonizing ability. First, cultures used for transformationwith DNA containing the ${Delta}$ luxS allele were derived from poolsof about 10 colonies that had been recovered by culture on H. pyloriselective agar from infected mice. Second, cells from pools ofabout 10 ${Delta}$ luxS transformant colonies were then used to infectmice, and another set of pools of 10 colonies recovered by culture2 weeks later (all carrying the ${Delta}$ luxS allele, as expected) wasthen tested for ability to compete with isogenic mouse-passagedluxS wild-type (luxS_wt) strains. No effect of mouse passageon the chloramphenicol or erythromycin resistance phenotypeof the various transformants used here was detected. This useof pooled colonies and frequent mouse passage avoided the riskof inadvertently using a single colony that might have lostcolonization ability due to mutation at loci unrelated to theluxS gene under study (see also reference 23).

The ability of conditioned medium from H. pylori cultures toinduce luminescence was tested with the Vibrio harveyi reporter strainBB170 (10, 21). H. pylori cells were grown overnight in a 24-welldish (1 ml per well) and then subcultured into fresh brucellabroth (20 ml) with shaking for various lengths of time. At eachtime point, aliquots of culture were collected, most cells wereremoved by centrifugation, and the supernatant-conditioned mediumwas sterilized by passage through a 0.22-µm filter. Supernatantswere then stored until assayed at –80°C.

To detect AI-2-type compounds produced by H. pylori, V. harveyiBB170 was grown overnight in autoinducer bioassay (AB) medium (10),washed with fresh AB medium, and inoculated (1:5,000) into freshAB medium containing 10% (vol/vol) of either H. pylori conditionedmedium or, as a control, sterile brucella broth or medium conditionedby growth of this same V. harveyi strain. The V. harveyi reporter cultureswere then grown at room temperature with shaking (150 rpm) for 6h, and luminescence was measured using a Monolight 3010 luminometer.n-fold luminescence induction values were calculated as valuesobtained after adding conditioned medium versus values obtainedafter adding sterile brucella broth. The analysis was done fivetimes with conditioned medium prepared on four different occasions.

RESULTS

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Results

To test if luxS is important in vivo, we constructed a PCR productcontaining a deletion of the luxS gene marked with a nonpolarcat resistance marker (Fig. 2). Wild-type strains were thentransformed with the DNA containing this ${Delta}$ luxS allele, and chloramphenicol-resistant( ${Delta}$ luxS) transformant colonies were selected. Initial tests indicatedthat deletion of luxS from SS1 or X47 did not severely impairthe ability of either strain to colonize mice: H. pylori densities werein the range of $~$ 10⁶ CFU/stomach 2 weeks after inoculation ineach of five mice tested with each H. pylori strain, which issimilar to results obtained with isogenic wild-type parents (1).

Competition tests were used to examine more critically the possibilityof an effect of luxS inactivation on colonization ability. Micewere each inoculated with 1:1 mixtures of ${Delta}$ luxS mutant and isogenicluxS_wt parent strains and then sacrificed 2 weeks later. H.pylori was cultured from separated antrum and corpus tissues,and at least 20 separate colonies from each tissue from eachmouse were tested for chloramphenicol resistance ( ${Delta}$ luxS) versussusceptibility (luxS_wt). In the case of X47, the ${Delta}$ luxS derivativecomprised on average $~$ 63% of H. pylori from the antrum and corpusof each mouse line (Fig. 3A; see legend for details). In nocase was there any indication that the ${Delta}$ luxS allele decreasedX47 fitness. Indeed, the X47 ${Delta}$ luxS strain was slightly more abundantthan its wild-type parent in the corpus of BALB/c mice (68%[±17%]; significantly greater than 50% [P = 0.01], one-sample signtest).

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FIG. 3. Competition tests of the importance of a functional luxS gene for mouse colonization. Mice of two different inbred lines (C57BL/6J and BALB/cJ) were inoculated with 1:1 mixtures of isogenic luxS_wt and ${Delta}$ luxS derivative strains (chloramphenicol sensitive and resistant, respectively) shown in Fig. 2. Mice were sacrificed 2 weeks later, antrum and corpus were separated, and H. pylori was recovered from each tissue by colony formation (see Materials and Methods). At least 20 single colonies from each tissue from each mouse were scored as resistant ( ${Delta}$ luxS) or susceptible (luxS_wt) to chloramphenicol. Each point represents the ratio of two types from a different mouse. Horizontal lines depict mean ratios. Panel A. Strain X47 derivatives diagrammed in Fig. 2, lines A and B. Panel B. Strain SS1 derivatives diagrammed in Fig. 2, lines A and B. Panel C. Derivatives of the SS1 ${Delta}$ luxS strain used in panel B that had been transformed with DNA containing a luxS_wt allele linked to a downstream erm (resistance) insertion or with DNA containing the original ${Delta}$ luxS allele linked to this erm cassette at the same site (see Fig. 2, lines C and D).

With SS1, in contrast, the ${Delta}$ luxS mutant comprised, on average,only 2% (±7%) and 6% (±11%) of colonies from theantrum of 23 BALB/cJ mice and 24 C57BL/6J mice, respectively,and only 9% (±13%) and 20% (±13%) of coloniesfrom the corpus of 23 BALB/cJ mice and 24 C57BL/6J mice, respectively(Fig. 3B). These yields were, in each case, far less than the50% expected if ${Delta}$ luxS had been neutral in the SS1 genetic background(P < 0.001).

Restoration of wild-type luxS.
In principle the lower fitness of SS1 ${Delta}$ luxS could have been dueto secondary mutations, selected if luxS inactivation had decreasedbacterial fitness in culture, rather than to an effect of lossof luxS function itself. To test such a possibility, we firstmade PCR products in which a selectable erythromycin resistance marker(erm) had been inserted in the intergenic space just downstreamof luxS_wt and also at the same site downstream of a ${Delta}$ luxS allele(Fig. 2C and D). These DNAs were each used to transform theSS1 ${Delta}$ luxS strain (Fig. 2B) that had competed poorly with itsluxS_wt parent. This generated a new pair of isogenic luxS_wtand ${Delta}$ luxS derivatives of strain SS1, each marked with the ermgene just downstream of the luxS locus but again distinguishableby chloramphenicol susceptibility versus resistance. Preliminarytests indicated that each type of Erm^r transformant colonizedmice efficiently when inoculated alone, as expected. A mixtureof these new isogenic luxS_wt and ${Delta}$ luxS strains was then usedto inoculate 10 C57BL/6J mice and 10 BALB/cJ mice, as describedabove. Analyses of colonies recovered 2 weeks later showed thatthe strain that had retained the ${Delta}$ luxS allele was less fit thanits sibling, in which luxS_wt had been restored (Fig. 3C). Indeed,it seemed that the cost of the ${Delta}$ luxS mutation was more severein the strain carrying the erm insertion than in a strain withoutthe erm gene (compare Fig. 3B and C). One possible explanationinvokes perturbation by erm in expression of downstream genes,which putatively encode a cyclic-nucleotide phosphodiesteraseand a methyl-accepting chemotaxis protein (2, 24), despite this cassettehaving been engineered to remove likely transcription terminationsequences (23). This model would invoke synergism between effectsof the erm insertion on downstream genes and those caused bythe ${Delta}$ luxS allele. The ${Delta}$ luxS allele is marked with cat, but studiesusing other chromosomal loci had indicated that this resistance determinantitself does not decrease strain SS1's fitness in mice (23).Hence, we conclude that SS1 ${Delta}$ luxS's lower fitness in vivo stemsprimarily from loss of luxS activity per se, not the resistancemarker used for selection.

Motility.
No effect of inactivation of luxS on H. pylori motility in brothwas found by light microscopy (as in reference 12), althoughother studies using different strains had indicated that luxS inactivationdecreased expression of flaA (14), which encodes one of thetwo H. pylori flagellins. We tested for effects of ${Delta}$ luxS on motilitywith strains SS1 and X47, using a soft agar assay that detectschanges in the strength of flagellum-driven swimming in a viscousenvironment, and also in chemotaxis along gradients that ariseas nutrients are depleted by growth of bacterial colonies (18, 19).Figure 4A shows that ${Delta}$ luxS mutant strains did indeed produce ever-expandinghalos of growth, indicative of motility, although the SS1 ${Delta}$ luxShalos were smaller than those of the isogenic SS1 wild type.In contrast, the halo sizes of X47 ${Delta}$ luxS and isogenic X47 wild-typestrains were not distinguishable either early or late duringthis growth period (Fig. 4A). Further tests showed that normalmotility was restored if the ${Delta}$ luxS allele was replaced with luxS_wtlinked to the erm resistance marker, whereas it was not restoredin cells that had received the ${Delta}$ luxS allele linked to this same erminsertion (Fig. 2C and D and 4B).

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FIG. 4. Motility assays. Panel A. Colonies of SS1 luxS_wt, X47 luxS_wt, or ${Delta}$ luxS derivatives of these two strains were stabbed once into soft agar and incubated for 4, 7, or 12 days, as indicated on the left. Panel B. Derivatives of strain SS1 ${Delta}$ luxS used in panel A that had been transformed with DNA containing an erm insertion downstream of either the ${Delta}$ luxS or luxS_wt allele (see Fig. 2, lines C and D) were tested. Two single colonies (sci #1 and sci #2) and also a pool from each transformation (separated by white vertical line) were tested by stabbing in duplicate into soft agar and incubation for 7 days.

To test for possible intercellular "complementation" of the ${Delta}$ luxSstrain's motility defect by AI-2 or any other metabolite producedby SS1 luxS_wt, the ${Delta}$ luxS-cat and luxS_wt SS1 strains were mixedin a ratio of 1:10, 1:1, or 10:1, and these strain mixtures wereinoculated in soft agar as for Fig. 4 and incubated for 7 days.Cell populations from the edges and centers of halos of growth werestreaked to form single colonies, and these colonies were tested onchloramphenicol agar to estimate ratios of ${Delta}$ luxS versus luxS_wtstrain types at each site. Both strain types were found at thecenters of halos after 7 days in ratios equivalent to thoseused in the original inoculations (data not shown). In contrast,the ${Delta}$ luxS strain was found at the halo edge only when ${Delta}$ luxS hadbeen in a 10-fold excess in the original inoculum, and thenit comprised 27% of isolates on average. In contrast, the ${Delta}$ luxSstrain comprised <0.01% of bacteria found at the halo edgewhen the starting inoculum consisted of a 1:1 or 1:10 ( ${Delta}$ luxS:luxS_wt)mixture (each of two separate trials). This indicated that thedefect caused by luxS inactivation was not restored by metabolitesfrom the wild-type strain. Based on transmission electron microscopy(as described in reference 23), SS1 luxS_wt and SS1 ${Delta}$ luxS cellsdid not seem to be different morphologically: most cells ofeach type were slightly curved and rod shaped and typicallybore several flagella of similar lengths at one pole (data not shown).

luxS integrity and AI-2 synthesis.
Given the reproducible quantitative effects of luxS inactivationon fitness in vivo and motility in strain SS1, one class ofexplanations for the lack of effect of the ${Delta}$ luxS allele in strain X47invokes a naturally occurring mutation in luxS or elsewherethat prevents AI-2 synthesis or speeds its removal. PCR amplificationand DNA sequence analysis of the X47's luxS gene revealed acomplete 155-codon open reading frame (GenBank accession no. DQ777750),with 96% amino acid sequence identity to luxS genes in referencestrains 26695 and J99 (2, 24). This suggested that luxS shouldbe functional.

More critically, we bioassayed AI-2 levels in filter-sterilizedculture supernatants by testing the abilities of these supernatantsto induce luminescence in the Vibrio harveyi reporter strainBB170. Figure 5A and B show that the inducing activity fromX47 wild type increased severalfold as cells grew from mid-to late log phase, ultimately attaining levels that were about12-fold higher than the nonspecific background seen with mediafrom cultures of the isogenic ${Delta}$ luxS mutant. This level was about30% of that seen using conditioned media from the canonicalAI-2-producing Vibrio harveyi grown in parallel (J. T. Loh andT. L. Cover, unpublished data). The level of AI-2 activity inH. pylori-conditioned media decreased sharply after prolonged (> $~$ 22h) incubation, much as had been seen previously with an unrelatedH. pylori strain (10). This might reflect intrinsic instabilityor degradation of AI-2 in culture. Data similar to those shownhere were obtained in three other experiments, involving aliquotstaken from fewer points in the growth curve (data not shown). Itwas also noteworthy that the maximum levels of AI-2-type activity producedby strain SS1 (in which the vigor of colonization is affected byluxS status) were substantially lower than those produced bystrain X47 (Fig. 5A and C). Thus, the lack of effect of luxSon motility or colonization by X47 is not likely to be due toa defect in AI-2 accumulation.

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FIG. 5. Representative analyses of AI-2 production. AI-2 activity in H. pylori broth supernatants (i.e., conditioned medium) was measured in a bioluminescence assay using V. harveyi BB170 as an AI-2 reporter strain (Materials and Methods). Panels A and C show induction by conditioned brucella broth medium relative to results with sterile brucella broth. Panels B and D show optical densities at 600 nm (OD₆₀₀) of the corresponding H. pylori cultures at the times when aliquots were withdrawn. The ${Delta}$ luxS allele used was marked with a cat (resistance) gene (see Fig. 2). luxS status, when not specified in graph caption, implies a wild-type allele.

DISCUSSION

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Discussion

We found that deletion of luxS from H. pylori reference strainSS1 caused quantitative decreases in halo size (motility) in softagar and in the ability to compete with isogenic SS1 wild type duringmouse infection. Restoration of luxS_wt by cotransformation withan erm resistance determinant inserted just downstream of luxSrestored full motility and vigor in vivo relative to its isogenic ${Delta}$ luxS sibling, also carrying erm at the same site. Thus, the ${Delta}$ luxS-associateddecrease in SS1 fitness likely stems from loss of luxS itself,not altered expression of downstream genes (predicted to encodea cyclic phosphodiesterase and a methyl-accepting chemotaxisprotein [2, 24]) or mutation elsewhere in the genome. With theunrelated strain X47, in contrast, deletion of luxS did notsignificantly affect motility or vigor in vivo. DNA sequencingrevealed a complete luxS open reading frame in this strain,and bioassays revealed normal luxS-dependent AI-2 production.Thus, the lack of effect of the ${Delta}$ luxS allele on X47 phenotypesstems from this strain's tolerance of luxS inactivation, ratherthan a preexisting luxS deficiency in X47 wild type.

The decrease in SS1 halo size caused by the ${Delta}$ luxS allele in softagar is in accord with the previously reported $~$ 2- to $~$ 10-folddecrease in expression of flaA-lacZ or flaA-cat transcriptionfusions after luxS inactivation in other H. pylori strains (14).However, transmission electron microscopy (as described in reference 23)indicated that most cells in SS1 ${Delta}$ luxS cultures carried severalflagella of apparently normal length, as did their SS1 wild-typeparents (data not shown). Alternatively, this decrease in halosize might reflect altered chemotaxis, a bacterial behaviorlinked to the activated methyl cycle via methylation of keychemotactic regulators (5, 16). In either case, it will be interestingto test if the thicker biofilms at a glass-broth-air interfacefound after luxS inactivation truly stem from direct suppressionof biofilm formation by AI-2 (9) or less-efficient swimmingor chemotaxis away from the biofilms into planktonic phase. Thatothers had not noticed an effect of luxS inactivation on motility(12) could be ascribed to methodologic differences in assays(liquid culture versus soft agar) or a feature of backgroundgenotype in the "Aston" strain they used that could have resultedin tolerance of a luxS deficiency, much as invoked here with strainX47.

In terms of possible fitness mechanisms, the in vivo cost ofdeleting luxS in SS1 could be ascribed to a lack of AI-2-directedsignaling in this strain when at high density. We do not favorthis explanation, however, because (i) the sequenced H. pylorigenomes each seemed to lack homologs of genes that in other systemsparticipate in responses to AI-2 signals (2, 20, 24) (although,given diversity in gene content in H. pylori, the possibilityof unrecognized AI-2 response genes in certain strains, SS1included, is not completely excluded); and (ii) density-dependentflaA gene transcription, one of the few events affected by luxS inactivation,was only weakly stimulated by adding conditioned medium to aculture of a luxS-null strain (14). Alternatively, the decreasedfitness of SS1 ${Delta}$ luxS might stem from metabolic disturbances causedby the loss of luxS, specifically disruption of the cycle ofSRH consumption and homocysteine synthesis (Fig. 1): e.g., ifrates of homocysteine synthesis were limiting or SRH consumptionwas needed to deplete SAH, its potentially toxic precursor (Fig. 1) (8).The possibility of less-direct metabolic network explanationsis well illustrated by the finding with Escherichia coli ofa third quorum sensing signal, AI-3, that is chemically distinctfrom AI-2 but whose synthesis is also luxS dependent (26). AI-3'ssynthesis was traced to oxaloacetate, a metabolite also usedin a second luxS-independent path for homocysteine biosynthesis.AI-3's luxS dependence was ascribed to siphoning of substratesfrom its synthesis into the alternative homocysteine biosynthesispathway in ${Delta}$ luxS strains (23). Although the types of metabolicconnections and their relative importances vary among species,this study emphasizes the significance of network architecture andthe potential of seemingly indirect effects to shape quantitative strain-variablephenotypes.

In summary, although previous reports of luxS-mutant-associatedH. pylori phenotypes had tended to favor AI-2 signaling-basedexplanations, alternative physiologic explanations, such asthose just outlined, seem more parsimonious to us at present.Further studies will be needed to define mechanisms underlyingthe differences in effects of ${Delta}$ luxS alleles in strains X47 andSS1. Possibilities include differences between them in resistanceto SAH and/or SRH intermediates, in LuxS-independent pathwaysfor disposing of these intermediates, or in luxS-influencedpathways for generating other important metabolites. Also notexcluded are models in which differences in dependence on AI-2(if such metabolites are ever used by H. pylori) reflect interactionswith coexisting bacterial species, some of which are AI-2 responsiveand whose own activities affect host permissiveness for particularH. pylori strains. Formally, these luxS results are reminiscentof our finding that consequences of a polyphosphate kinase 1deficiency varied with H. pylori genetic background. However,a functional polyphosphate kinase 1 gene was more importantin vivo for X47 than for SS1 (23), the reverse of the luxS dependenceseen here. Such contrasting outcomes illustrate that the spectraof potentially limiting metabolic factors vary among H. pyloristrains and that no one strain is fully representative of thisgenetically diverse species. This consideration will becomeincreasingly important as more H. pylori genomes are sequencedand as metabolic reconstructions and the discipline of systemsbiology (11, 13) become more refined.

ACKNOWLEDGMENTS

We thank Mark Forsyth for stimulating discussions.

This work was supported by a fellowship from the Sankyo Foundationof Science (K. Ogura); by grants RO1 DK063041, P30 DK52574,and RO1 DK53623 from the National Institutes of Health; andby a grant from the Department of Veterans Affairs (T. L. Cover).

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Microbiology, Campus Box 8230, 4940 Parkview Place, Washington University Medical School, St. Louis, MO 63110. Phone: (314) 362- 2772. Fax: (314) 362-1232. E-mail: berg{at}borcim.wustl.edu.

Published ahead of print on 25 August 2006.

Present address: Department of Microbiology, Gyeongsang NationalUniversity School of Medicine, Jinju, Republic of Korea.

Present address: Department of Gastroenterology, Universityof Tokyo, Tokyo, Japan.

REFERENCES

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