Respiration of Escherichia coli in the Mouse Intestine

Mammals are aerobes that harbor an intestinal ecosystem dominatedby large numbers of anaerobic microorganisms. However, the roleof oxygen in the intestinal ecosystem is largely unexplored.We used systematic mutational analysis to determine the roleof respiratory metabolism in the streptomycin-treated mousemodel of intestinal colonization. Here we provide evidence thataerobic respiration is required for commensal and pathogenicEscherichia coli to colonize mice. Our results showed that mutantslacking ATP synthase, which is required for all respiratoryenergy-conserving metabolism, were eliminated by competitionwith respiratory-competent wild-type strains. Mutants lackingthe high-affinity cytochrome bd oxidase, which is used whenoxygen tensions are low, also failed to colonize. However, thelow-affinity cytochrome bo₃ oxidase, which is used when oxygentension is high, was found not to be necessary for colonization.Mutants lacking either nitrate reductase or fumarate reductasealso had major colonization defects. The results showed thatthe entire E. coli population was dependent on both microaerobicand anaerobic respiration, consistent with the hypothesis thatthe E. coli niche is alternately microaerobic and anaerobic,rather than static. The results indicate that success of thefacultative anaerobes in the intestine depends on their respiratoryflexibility. Despite competition for relatively scarce carbonsources, the energy efficiency provided by respiration may contributeto the widespread distribution (i.e., success) of E. coli strainsas commensal inhabitants of the mammalian intestine.

INTRODUCTION

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INTRODUCTION

The intestinal microflora is dominated by diverse anaerobes,providing both a health benefit to the host (15) and a barrierto infection (16, 21). Despite being present in substantiallylower numbers, facultative anaerobes, primarily Escherichiacoli and Enterococcus faecalis, are ubiquitous in mammalianintestines (40). While the intestine is commonly thought tobe anaerobic (4), the tissues surrounding the lumen are oxygenrich and oxygen diffuses into the intestine at appreciable levels(20). Furthermore, oxygen from swallowed air is present in flatus(29). Oxygen in the intestine apparently has minimal impacton persistence of anaerobes, and it was recently shown thatat least one predominant anaerobe, Bacteroides fragilis, respiresoxygen at low concentrations (5). In contrast to obligate anaerobes,facultative anaerobes (e.g., E. coli) grow most rapidly whenrespiring oxygen and switch to anaerobic respiration in theabsence of oxygen or to fermentation in the absence of alternativeelectron acceptors (17). However, the extent to which facultativeanaerobes utilize oxygen to maximize their growth rate in theintestine is not known.

Nutrients consumed for growth of the microflora are thoughtprimarily to be fermentable carbohydrates, the bulk of whichare in the form of polysaccharides (37). E. coli colonizes themouse intestine by growing within the polysaccharide-rich mucuslayer covering the epithelium but is unable to degrade polysaccharides.Apparently, E. coli consumes the mono- and disaccharides releasedduring degradation of mucosal polysaccharides and dietary fiber(8) by polysaccharide hydrolase enzymes secreted by membersof the anaerobic microflora (11) and, perhaps, host colonicepithelial cells (6). Recent studies from our laboratory demonstratethat seven mucus-derived sugars contribute to E. coli colonizationof the mouse intestine, suggesting that biochemical flexibilityis key to its competitiveness in vivo (8). E. coli is nearlyequally flexible in its respiratory metabolism (17), but nothingis known about the role of bacterial respiration for couplingATP generation to carbohydrate oxidation in vivo. Thus, it isimportant to test the hypothesis that respiration confers acompetitive advantage to E. coli in the intestine.

Enterohemorrhagic E. coli (EHEC), has an infectious dose forhumans as low as 10 microorganisms and, following ingestion,grows rapidly to a population approaching a billion bacteriaper gram of feces (24). Since colonization is the first stepin the infection process, it is crucial to understand how EHECcolonizes the intestine because low numbers can survive transportto consumers in foodstuffs such as leafy vegetables, which havecaused recent outbreaks in the United States (36). It is notknown how EHEC acquires nutrients and generates energy for growthin vivo. While respiration is not a virulence factor per se,our experiments seek to establish the fundamental importanceof housekeeping functions, such as energy metabolism, for pathogenesis.Since most mucosal pathogens are facultative anaerobes, thesestudies of E. coli may be extended to include many diseases.

Here we report the results of a systematic mutational analysisdesigned to identify which respiratory pathways contribute tothe ability of commensal and pathogenic E. coli to colonizethe streptomycin-treated mouse intestine. Our findings leadus to conclude that respiration provides an enormous competitiveadvantage to E. coli in vivo. The results challenge the traditionalview that the intestine is strictly anaerobic (4). Instead,we obtained evidence that E. coli colonization of the mouseintestine is maximized by the ability to respire oxygen.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains and growth conditions. The bacterial strains used in this study were derived from E.coli MG1655 Str^r (streptomycin resistant), a K-12 strain (33),and E. coli EDL933 Str^r, the prototypical O157:H7 strain (31).Cultures were grown at 37°C in Luria-Bertani (LB) mediumwith gyratory shaking at 250 rpm. Null alleles were constructedby using the allelic replacement method of Datsenko and Wanner(14), as described previously (8), such that target genes weredeleted and replaced with kanamycin or chloramphenicol resistancecassettes (used as selectable markers in mouse colonizationassays, as described below). The null allele strains are identifiedin the text by the genes that were deleted; single gene deletionsbegan with the start codon and ended with the stop codon, andmultiple gene deletions began with the start codon of the firstgene deleted and ended with the stop codon of the last genedeleted. Strains containing multiple mutations were constructedby sequential allelic replacement; the first inserted cassettewas removed with FLP recombinase (14), followed by subsequentallelic replacement(s) and removal of the insertion as necessary,leaving the selected marker in the last mutation made. Mutantstrains were verified by phenotype analysis and DNA sequencing.

Phenotypic analysis. MOPS [3-(N-morpholino) propanesulfonic acid] defined mediumwas used to grow cultures for growth curves, as described previously(8). Anaerobic cultures were grown in culture tubes filled tothe top with N₂-sparged medium, sealed, and incubated in Balchtubes. To test for nitrate or fumarate reductase activity, mutantstrains were grown anaerobically overnight in MOPS medium withglycerol (1.6%) as the carbon source and either 50 mM nitrateor fumarate as the electron acceptor. Cell growth was monitoredspectrophotometrically by the optical density at 600 nm.

High-performance liquid chromatography analysis. A Dionex DX-500-Microbore system was used with an IonPac AS11column for anion analysis of mucus. Standards and blanks wereanalyzed, and standard curves were developed for a 1-mg sampleof cecal mucus. Mouse cecal mucus was isolated from the cecumof CD-1 male mice and lyophilized as described previously (50).Regression coefficients for standard curves were calculatedand used to demonstrate the linearity of the peak area withrespect to concentration.

Mouse colonization experiments. The streptomycin-treated mouse model has been used extensivelyto study colonization of the mouse large intestine by E. coliand Salmonella enterica serovar Typhimurium (8, 12, 22, 50).Briefly, three CD-1 male mice, 6 weeks of age, were given drinkingwater containing streptomycin sulfate (5 g/liter) for 24 h toremove the existing resident facultative microflora and thenstarved for food and water for 18 to 24 h. The mice were thenfed approximately 10⁵ CFU of both the wild-type and mutant strainsin 1 ml of 20% sucrose. The wild-type strains were E. coli MG1655Str^r Nal^r (nalidixic acid resistance) (33) and E. coli EDL933Str^r Nal^r (31); Nal^r was used to distinguish the wild-type (referencestrain) from the null allele mutants in fecal plate counts.After the bacterial suspension was ingested, food and streptomycin-waterwere restored and fecal plate counts were determined at 5 h,24 h, and on every other day thereafter for 15 days. Fecal sampleswere homogenized and diluted in 1% tryptone broth and platedon MacConkey agar containing either streptomycin (100 µg/ml)and nalidixic acid (50 µg/ml) to count the wild type orstreptomycin and kanamycin (40 µg/ml) or chloramphenicol(30 µg/ml) to count the null allele mutants. Each colonizationexperiment was repeated on separate occasions, and the plottedvalues (in figures) represent the average for six mice. Thelog₁₀ mean number of CFU per gram of feces ± the standarderror for each strain in the mice was calculated for each timepoint. In all experiments, a difference between two strainsof $≥$ 10 CFU/g feces was statistically significant (i.e., P <0.005 in Student's t test [two tailed with unequal variance]).The limit of detection in fecal plate counts was 10² CFU/g feces.To determine the role of strains during the maintenance stageof colonization, mice were colonized for 10 days with a mutantstrain of E. coli EDL933, starved for food and streptomycin-waterovernight, and fed 10¹⁰ CFU of the wild-type strain E. coliEDL933 Str^r Nal^r, after which food and streptomycin-water werereplaced.

RESULTS

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RESULTS

Colonization assays. The preferred animal model for measuring the relative fitnessof two bacterial strains for intestinal colonization is thestreptomycin-treated mouse. Streptomycin treatment selectivelyremoves facultative anaerobes while leaving the anaerobic microfloraessentially intact; this opens a previously unavailable niche,which can then be colonized by newly introduced microorganismssuch as E. coli (12, 27, 50). In this model, competing wild-typeand mutant strains are fed together to mice and their populationsare monitored in fecal plate counts. Previously we showed thatcolonization involves an initiation stage (5 h to 3 days postfeeding),in which nutrients are not limiting and the population increasesfrom low to high numbers, and a maintenance stage (7 days post-feedingand beyond), in which nutrients are limiting and the populationpersists at a level correlated with the mutant strain's relativefitness for colonization (8). For this reason, the colonizationdata shown in Table 1 are given for day 1 (initiation) and day9 (maintenance) of the 15-day-long experiments. To compare thebioenergetics of a commensal strain to those of a pathogenicstrain, each of the respiratory mutations described in thisreport was constructed in E. coli MG1655 (3), derived from thehuman isolate E. coli K-12, and E. coli EDL933 (34), the prototypicalstrain of E. coli O157:H7. Please note that the streptomycin-treatedmouse serves as a colonization model for EHEC strains, whichdo not cause disease in CD-1 mice (49). We found that each ofthe mutations tested in the commensal and pathogenic strainshad a nearly identical impact on colonization. For this reason,colonization curves are shown for E. coli EDL933 experimentsonly.

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TABLE 1. Competitive colonization between respiratory mutants and wild-type E. coli strains^a

ATP synthase is necessary for colonization. Since respiratory energy conservation, i.e., ATP generation,requires ATP synthase (32), we tested mutants that lack ATPasefor their ability to compete with the wild type in the streptomycin-treatedmouse colonization model. The ATPase mutant constructions deletedthe atpA and atpG genes, which encode the F₁ alpha and gammasubunits, respectively, resulting in strains capable only offermentative energy metabolism (13). In competition with theirrespective wild-types, E. coli EDL933 ${Delta}$ (atpA-atpG)::cat and E.coli MG1655 ${Delta}$ (atpA-atpG)::cat mutants were eliminated from micewithin 5 days (Table 1 and Fig. 1A). It is formally possiblethat mutations inadvertently introduced elsewhere on the genomecaused the observed colonization phenotype. However, we wouldargue that this was not the case, for the following reasons.First, each of the allelic replacements described here and elsewhere(8, 28, 31, 33) was obtained with a frequency that varied lessthan 1 order of magnitude. Second, half of the mutants testedhere and in similar studies (8) had no colonization defects.Third, the results were essentially identical in two differentgenetic backgrounds (EDL933 and MG1655). The failure of the ${Delta}$ (atpA-atpG)::cat mutants to initiate colonization could be dueto a general inability to grow in the intestine rather thanan inability to compete with the wild type. To distinguish thesepossibilities, the mutants were fed alone to mice and foundto colonize at wild-type levels (Fig. 1B) (data not shown).The ability of the respiratory-defective mutants to colonizealone indicates that fermentation is sufficient for growth ofE. coli in the mouse intestine, but oxidative phosphorylationis essential for competition with respiratory-competent strains.This finding led us to consider whether one or more modes ofrespiration are crucial to occupation of intestinal niches formedby electron acceptor availability.

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FIG. 1. Respiratory mutants exhibited colonization defects in competitive colonization assays. E. coli EDL933 ${Delta}$ (atpA-atpG) (A) and E. coli EDL933 ${Delta}$ (cydA-cydB) (C) mutants were eliminated during competition with wild-type E. coli EDL933 but were able to colonize when fed alone to mice (B and D, respectively).

Respiration of oxygen is necessary for colonization. Proof that aerobic respiration is essential for colonizationby E. coli was obtained by competing mutants lacking the high-affinitycytochrome bd oxidase with their respective wild types. The ${Delta}$ (cydA-cydB)::cat mutant constructions deleted genes encodingboth subunits (I and II) of cytochrome bd oxidase, as shownpreviously (19). The E. coli EDL933 ${Delta}$ (cydA-cydB)::cat and E.coli MG1655 ${Delta}$ (cydA-cydB)::cat strains were eliminated by day11 during competition with their wild-type parents (Table 1and Fig. 1C). The fitness defect observed for the ${Delta}$ (cydA-cydB)::catstrains was not merely a growth defect, since the mutants colonizedwhen fed alone to mice (Fig. 1D) (data not shown). To confirmthe requirement for high-affinity oxygen respiration, ${Delta}$ (cydD-cydC)::catmutants, which cannot assemble cytochrome bd oxidase in themembrane (39), were tested and found to have similar colonizationdefects (Table 1 and Fig. 2A). The ${Delta}$ (cydD-cydC)::cat mutantswere able to colonize when fed to mice alone (Fig. 2B) (datanot shown). We note that in addition to CydDC being requiredfor cytochrome bd oxidase assembly and activity (39), cydDCencodes a glutathione transport system (38), which if relevantmight also be required for colonization. Since the ${Delta}$ (cydA-cydB)::catand ${Delta}$ (cydD-cydC)::cat mutants failed to initiate colonization(i.e., 24 h), it was necessary to determine if they were alsodefective in the maintenance stage (beyond 7 days). Therefore,mice were precolonized (for 10 days) with E. coli EDL933 ${Delta}$ (cydD-cydC)::catand then challenged with the E. coli EDL933 wild type; the mutantwas eliminated by the wild type in 7 days, confirming that functionalcytochrome bd was important for maintenance of colonization(Fig. 2C).

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FIG. 2. Cytochrome bd oxidase assembly mutants of E. coli EDL933 exhibited colonization defects in competitive colonization assays. E. coli EDL933 ${Delta}$ (cydD-cydC) was defective in competition with wild-type E. coli EDL933 (A) but colonized at wild-type levels when fed alone (B). The ${Delta}$ (cydD-cydC) mutant exhibited a maintenance defect when mice were precolonized with E. coli EDL933 ${Delta}$ (cydD-cydC) and challenged with wild-type E. coli EDL933 at day 10 (C).

We also examined the importance of the low-affinity cytochromebo₃ oxidase for colonization. The construction of ${Delta}$ (cyoA-cyoB)::catmutants deleted the genes encoding subunits I and II of thecytochrome bo₃ oxidase, as shown previously (2). The resultsshowed that E. coli EDL933 ${Delta}$ (cyoA-cyoB)::cat and E. coli MG1655 ${Delta}$ (cyoA-cyoB)::cat strains cocolonized with their respective wild-typeparents, indicating that respiration of high oxygen levels wasnot necessary for colonization (Table 1). In summary, the colonizationdefects of the cytochrome bd oxidase mutants challenge the traditionalview that the intestine is anaerobic (4). Instead, the resultssupport the hypothesis that a microaerobic niche is criticalfor both establishing and maintaining E. coli in the intestine.Thus, a competitive advantage in vivo is conferred on strainsthat respire oxygen.

Aerobic respiratory control is necessary for colonization. E. coli governs respiratory flexibility via the global regulatorsArcA and Fnr. ArcA is a two-component regulator of several hundredgenes (30) that responds to the oxidation state of the quinonepool, which is sensed by ArcB (18). Under high oxygen tension,E. coli expresses the low-affinity oxidase cytochrome bo₃ (encodedby cyoABCDE) and the high-affinity oxidase cytochrome bd (encodedby cydAB) is repressed. Under microaerobic conditions, whereoxygen scavenging may play an important role for growth andsurvival, ArcB phosphorylates ArcA, which represses the cyoABCDEoperon and activates the cydAB and cydDC operons (1). Sincethe experiments described above indicated the importance ofcytochrome bd, we reasoned that arcA mutants would have colonizationdefects. The construction of E. coli EDL933 ${Delta}$ arcA::cat and E.coli MG1655 ${Delta}$ arcA::kan deleted the gene encoding the responseregulator of the ArcAB two-component system, as previously described(23). Although ${Delta}$ arcA mutants colonized when fed alone (Fig. 3B)(data not shown), they could not compete with their respectivewild types and were eliminated from mice within 3 days (Table1 and Fig. 3A). While it is tempting to speculate that the colonizationdefect of the ${Delta}$ arcA mutants resulted solely from failure to inducecydAB, the pleiotropic phenotype of the ${Delta}$ arcA strain makes anumber of alternative explanations possible. What is clear fromthis experiment is that appropriate regulation of aerobic respiratorygenes is necessary for E. coli to be competitive in vivo.

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FIG. 3. Aerobic respiratory and anaerobic global regulatory mutants exhibited colonization defects in competitive colonization assays. E. coli EDL933 ${Delta}$ arcA was eliminated during competition with wild-type E. coli EDL933 (A) but was able to colonize when fed alone (B). E. coli EDL933 ${Delta}$ fnr was eliminated during competition with wild-type E. coli EDL933 (C) but was able to colonize when fed alone (D).

Anaerobic control is necessary for colonization. Induction of anaerobic processes in E. coli is controlled byFnr, an oxygen-labile transcription factor, which activatestranscription of hundreds of genes, including genes that encoderespiratory pathways for nitrate and fumarate (25, 35). Sinceinduction of anaerobic respiratory pathways requires Fnr, weconstructed ${Delta}$ fnr::kan mutants to test the contribution of thisglobal regulator during colonization. The E. coli EDL933 ${Delta}$ fnr::kanand E. coli MG1655 ${Delta}$ fnr::kan mutants were fed together with therespective wild types and found to initiate colonization (althoughnot as well as the wild type), and then they were eliminatedby day 5 (Table 1 and Fig. 3C). The defect was not an inabilityto grow in the intestine, since the ${Delta}$ fnr::kan mutants colonizedwhen fed alone to mice (Fig. 3D) (data not shown). Since the ${Delta}$ fnr::kan mutants exhibit colonization defects in competitionwith the wild type, this implies that E. coli experiences conditionsin the intestine that are required for Fnr function (7): i.e.,anaerobic or nearly anaerobic conditions. Thus, we concludethat Fnr-dependent genes contribute to colonization success.While these results indicate that appropriate regulation ofanaerobic respiration is important for colonization, the specificroles of the alternative pathways were unclear.

Nitrate reductase is necessary for colonization. To determine which anaerobic respiratory pathways were usedduring colonization, we considered the in vivo role of nitratereduction. Since E. coli has three systems for nitrate respiration,it was necessary to consider strains with mutations that eliminatedeach individually and in combination (17). Mutation of the primarynitrate reductase was accomplished by deleting narG (47) tocreate E. coli EDL933 ${Delta}$ narG::kan and E. coli MG1655 ${Delta}$ narG::kan.When ${Delta}$ narG::kan strains were fed together with their respectiveparent strains, they initiated colonization but then declinednumerically (2.3 logs; P < 0.003) (Table 1 and Fig. 4A).To test the involvement in colonization of the secondary nitratereductase, mutants were constructed in which narZ was deleted,the phenotype of which was described previously (46). Likewise,the involvement of the periplasmic nitrate reductase was testedwith a construction that deleted napD and napA, which encodethe assembly protein and large subunit of the reductase, respectively(46). In colonization assays, E. coli EDL933 ${Delta}$ narZ::cat, E. coliMG1655 ${Delta}$ narZ::cat, E. coli EDL933 ${Delta}$ (napD-napA)::cat, and E. coliMG1655 ${Delta}$ (napD-napA)::cat cocolonized with their wild-type parents,indicating that strains with these individual mutations hadno phenotype in the intestine (Table 1).

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FIG. 4. Anaerobic respiration mutants exhibited colonization defects in competitive colonization assays. E. coli EDL933 ${Delta}$ narG (A), E. coli EDL933 ${Delta}$ narG ${Delta}$ narZ (B), E. coli EDL933 ${Delta}$ narG ${Delta}$ narZ ${Delta}$ (napD-napA) (C), and E. coli EDL933 ${Delta}$ frdA (D) mutants were defective in competition with wild-type E. coli EDL933.

Although the individual ${Delta}$ narZ::cat and ${Delta}$ (napD-napA)::cat mutantsdid not exhibit colonization defects, there is reason to believethese gene systems should be expressed in the wild types underthe conditions present in the intestine. First, the intestinecontains regions that are microaerobic and others that are anaerobic(20), yet apparently is sufficiently anaerobic overall for Fnrcontrol to be a factor in success of the entire E. coli population(Fig. 3). Second, we measured a concentration of 2.62 ±0.21 mM nitrate in mouse cecal mucus (data not shown), a concentrationwhich is physiologically relevant for controlling expressionof the two nitrate-inducible systems (52). Third, E. coli cellsisolated from the intestine show both logarithmic and stationary-phasecharacteristics (26). The narZYWV operon that encodes the secondarynitrate reductase is not regulated by anaerobiosis or nitratebut instead is RpoS dependent and induced in stationary phase(9). The napFDAGHBC operon that encodes the periplasmic nitratereductase is maximally induced at 1 mM nitrate and is expressedat one-half of the maximal level at 2.5 mM (52). Thus, it isreasonable to expect that both the periplasmic and secondarynitrate reductases are expressed in the intestine. To investigatethe phenotypes of these nitrate reductase mutations in the absenceof the primary nitrate reductase, we constructed ${Delta}$ narG ${Delta}$ narZ::catand ${Delta}$ narG ${Delta}$ narZ ${Delta}$ (napD-napA)::cat mutants. In colonization assays,E. coli EDL933 ${Delta}$ narG ${Delta}$ narZ::cat and E. coli MG1655 ${Delta}$ narG ${Delta}$ narZ::catmutants declined 3.2 log units (P < 0.000006) relative tothe wild-type strain by day 15 (Table 1 and Fig. 4B). Also,the E. coli EDL933 ${Delta}$ narG ${Delta}$ narZ ${Delta}$ (napD-napA)::cat and E. coli MG1655 ${Delta}$ narG ${Delta}$ narZ ${Delta}$ (napD-napA)::cat mutants declined by 5 log units (P< 9 x 10^–15) to populations just above the limit ofdetection (<10³ CFU/g feces) by the conclusion of the experiments(Table 1 and Fig. 4D). The additive effect of the sequentialnitrate reductase mutations in competition with the wild-typeE. coli EDL933 in these experiments is statistically significantbetween the ${Delta}$ narG::kan and ${Delta}$ narG ${Delta}$ narZ::cat mutants (P < 0.003)and between the ${Delta}$ narG ${Delta}$ narZ::cat and ${Delta}$ narG ${Delta}$ narZ ${Delta}$ (napD-napA)::catmutants (P < 0.004). From these results, we conclude theprimary nitrate reductase plays the larger role of the threesystems in the mouse intestine. In contrast, the ${Delta}$ narZ and ${Delta}$ (napD-napA)mutations affected colonization only in the ${Delta}$ narG background,suggesting a synergy, rather than mere redundancy, between theprimary nitrate reductase and the other two systems. Apparently,conditions in the intestine signal induction of the three nitratereductase gene systems, which together confer a competitiveadvantage to E. coli.

Fumarate reductase is necessary for colonization. To test the importance of fumarate as an alternative electronacceptor in vivo, we constructed mutants with frdA, which areknown to inactivate fumarate reductase (43). E. coli EDL933 ${Delta}$ frdA::kan and E. coli MG1655 ${Delta}$ frdA::kan mutants were fed togetherwith their respective parent strains and found to initiate colonizationbut then declined by approximately 4 logs relative to the wildtype (Table 1 and Fig. 4D). Thus, fumarate reductase mutantscompeted poorly, indicating that fumarate is used in the intestineas an alternative electron acceptor. Since fumarate was notdetected in intestinal mucus (data not shown), it most likelywas generated endogenously, giving rise to succinate as a fermentationproduct during anaerobiosis (41).

DISCUSSION

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DISCUSSION

Figure 5 shows a model of the respiratory pathways that arecritical for successful colonization by both EHEC and commensalE. coli. The results indicate that the gut is not strictly anaerobic,because the high-affinity cytochrome bd oxidase is requiredto successfully compete with the wild-type for colonization(Fig. 1 and 2). Also, anaerobic respiration of nitrate and fumarateis essential for E. coli in vivo (Fig. 4). We therefore concludethat success of E. coli in the gastrointestinal tract demandsrespiratory flexibility and use of the best available electronacceptor. The results allow us to deduce the intestinal environmentas it is perceived by E. coli. Accordingly, the niches definedby mutational analysis of respiratory pathways should correspondwith in vivo availability of exogenous electron acceptors (i.e.,oxygen and nitrate) but not necessarily fumarate, which is generatedendogenously by sugar degradation via central metabolism. Theserespiratory niches could be open to the entire population, whereineach bacterium simultaneously uses both oxygen and nitrate,or individual cells and microcolonies could each use differentelectron acceptors. If distinct microaerobic and anaerobic nicheswere to exist in the intestine, then mutants in the respectiverespiratory pathways would be maintained at populations correspondingto availability of the cogent electron acceptor when in competitionwith respiratory-competent wild types. However, since the lossof the high-affinity oxygen, nitrate, or fumarate respiratorypathways leads to the near or complete elimination of the entirepopulation in competition with respiratory-competent strains(Fig. 1C and 4C and D), the data give us reason to think thatboth aerobic and anaerobic niches are equally crucial. Thus,the behavior of the E. coli respiratory mutants implies thatthe intestinal habitat is at one time microaerobic and at anothertime anaerobic. Indeed, oxygen tension in the intestine mayfluctuate due to dynamic cycles of oxygen diffusion and respiratoryconsumption by facultative anaerobes.

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FIG. 5. Model of E. coli respiratory pathways. Respiratory oxidases and reductases used by E. coli in vivo are shown in black. The oxidase not affecting colonization is shown in gray. The environmental conditions affecting the key regulators of the genes encoding the oxido-reductases are shown. Activation is shown with arrowheads, and repression is shown with diamond heads.

Cole (10) postulated that the redundancy of respiratory systemsand complexities of their regulation ready bacteria for changesin electron acceptor availability: when respiring nitrate, E.coli can respond rapidly to the "arrival" of oxygen or copewhen nitrate is exhausted. Thus, the physiology, biochemistry,and genetic control of respiratory pathways provide flexibilitythat is thought to be essential for survival in a changing environment(10). It would appear this strategy is singularly importantduring animal colonization. We summarize these factors in Fig.5. For E. coli to colonize the intestine, appropriate aerobicrespiratory control (ArcA) and anaerobic control (Fnr) are required(Fig. 3). ArcA is most active under microaerobic conditions(i.e., oxygen tension of 2 to 15% of air saturation) (1), andFnr is most active during transition to anaerobic conditions(i.e., oxygen tension of less than 2% of air saturation) (7).Whole-animal measurements indicated oxygen tensions in the 2to 7% air saturation range for the mouse colon (20). The measurednitrate concentration in intestinal mucus (2.6 mM [see results])is near that which results in maximal expression of both nitratereductase systems (i.e., 1 mM for the periplasmic nitrate reductaseand 7 mM for the primary nitrate reductase) (52). Regulationof the periplasmic nitrate reductase genes requires both NarLand NarP (45), while regulation of the primary reductase genesrequires NarL only (44). Since NarP exerts its control at lownitrate levels (<4 mM) and NarL control dominates at highernitrate levels (51), and since both the primary and periplasmicnitrate reductases are necessary for efficient colonization,this suggests that nitrate availability might fluctuate in theintestine. Thus, if the intestinal oxygen tension fluctuatesin the anaerobic to microaerobic range and the nitrate concentrationfluctuates in the 1 to 7 mM range, then cytochrome bd oxidase,the primary nitrate reductase, the periplasmic nitrate reductase,and fumarate reductase all will be expressed in vivo. Indeed,regulation of these gene systems is poised to be most responsiveto changes in oxygen and nitrate availability in these concentrationranges (48).

The inference that oxygen availability fluctuates because itis consumed by bacterial respiration suggests the interestingpossibility that facultative anaerobes may make the intestinalenvironment more anaerobic. Indeed, this conclusion is supportedby previous studies of the effect of streptomycin treatmenton the mouse anaerobic microflora, which selectively removesfacultative anaerobes (i.e., E. coli, enterococci, streptococci,and lactobacilli). Following administration of streptomycin,populations of strict anaerobes (e.g., bifidobacteria and clostridia)decreased, while populations of so-called "nanaerobes" wereunchanged (22): e.g., Bacteroides fragilis, which respires oxygenwhen available in low concentrations (5). Thus, comparisonsof the populations of anaerobes in mice with or without facultativeanaerobes present support the hypothesis that oxygen-scavengingfacultative anaerobes (e.g., E. coli) promote the stabilityof the predominantly anaerobic microflora, exemplifying howa minor member can have a large impact on an ecosystem.

Despite the apparent competitive advantage gained by oxygenrespiration, the E. coli population is limited to between 10⁸and 10⁹ CFU/g feces: i.e., E. coli represents between 1 in 1,000and 1 in 10,000 bacteria in the intestine. The nutrient-nichehypothesis states that to be successful each species of theintestinal microflora must use at least one carbon source betterthan all other species (16). Corollary to this hypothesis, thepopulation size of any member of the microflora is determinedby the concentration of its preferred nutrient(s). The availableconcentrations of the seven sugars that contribute to colonizationby E. coli MG1655 are quite low (12, 37). Since E. coli doesnot secrete polysaccharide-degrading enzymes, its preferredsubstrates are most likely provided by anaerobes, which degrademucosal polysaccharides and dietary fiber and are thought torelease the breakdown products for use by the host and othermicrobes (11). These facts lead to the conclusion that E. colimaximizes its growth yield by coupling oxidation of low nutrientconcentrations to respiration in the intestine. This may bea general strategy of facultative anaerobes, which generallygrow well on simple sugars but do not secrete polysaccharide-degradingenzymes. Thus, high-efficiency respiration may ensure the successof facultative anaerobes in the intestine, albeit always inlower numbers, by allowing them to maximize cell yield on scarceresources.

Since most mucosal pathogens are facultative anaerobes, ourconclusions may extend to other mucosal pathogens. In supportof this idea, Mycobacterium tuberculosis genes encoding cytochromebd oxidase and the nitrate transporter were induced during mouselung infection; a cytochrome bd oxidase mutant was attenuatedduring transition to chronic infection in mice (42). Likewise,Shigella flexneri cytochrome bd mutants showed decreased intracellularsurvival and attenuated virulence in mouse infections (53).These examples demonstrate the importance of respiration duringinfection by particular mucosal pathogens and support the ideathat oxygen stimulates infectious disease by providing a competitiveadvantage for pathogens. Since there appears to be no distinctionbetween enterohemorrhagic and commensal E. coli with respectto the respiratory pathways used in vivo, we suggest cautionin targeting respiratory metabolism for combating EHEC infectionsbecause of potential collateral damage to commensal facultativeanaerobes and the resulting instability of the intestinal microbiota(16).

In summary, we have shown that E. coli uses both aerobic andanaerobic respiratory pathways during colonization. The resultspresented in this study support the conclusion that the intestineis microaerobic and that aerobic bacterial respiration in theintestine is essential for competition and therefore successfulcolonization. Apparently, E. coli respires oxygen to optimizeits reproduction in animals despite the low availability ofits preferred carbon sources, which maximizes its colonizationefficiency.

ACKNOWLEDGMENTS

We thank Bruce Roe and David Laux for helpful comments.

This work was supported by grant AI48945 from the National Institutesof Health.

FOOTNOTES

* Corresponding author. Mailing address: Department of Botany and Microbiology, The University of Oklahoma, 101 David L. Boren Blvd., Norman, OK 73019-0245. Phone: (405) 325-1683. Fax: (405) 325-3442. E-mail: tconway{at}ou.edu

Published ahead of print on 13 August 2007.

Editor: V. J. DiRita

REFERENCES

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