Streptomycin-treated Mouse Large Intestine Research Articles

Anaerobic Respiration of Escherichia coli in the Mouse Intestine

The intestine is inhabited by a large microbial community consisting primarily of anaerobes and, to a lesser extent, facultative anaerobes, such as Escherichia coli, which we have shown requires aerobic respiration to compete successfully in the mouse intestine (S. A. Jones et al., Infect. Immun. 75:4891-4899, 2007). If facultative anaerobes efficiently lower oxygen availability in the intestine, then their sustained growth must also depend on anaerobic metabolism. In support of this idea, mutants lacking nitrate reductase or fumarate reductase have extreme colonization defects. Here, we further explore the role of anaerobic respiration in colonization using the streptomycin-treated mouse model. We found that respiratory electron flow is primarily via the naphthoquinones, which pass electrons to cytochrome bd oxidase and the anaerobic terminal reductases. We found that E. coli uses nitrate and fumarate in the intestine, but not nitrite, dimethyl sulfoxide, or trimethylamine N-oxide. Competitive colonizations revealed that cytochrome bd oxidase is more advantageous than nitrate reductase or fumarate reductase. Strains lacking nitrate reductase outcompeted fumarate reductase mutants once the nitrate concentration in cecal mucus reached submillimolar levels, indicating that fumarate is the more important anaerobic electron acceptor in the intestine because nitrate is limiting. Since nitrate is highest in the absence of E. coli, we conclude that E. coli is the only bacterium in the streptomycin-treated mouse large intestine that respires nitrate. Lastly, we demonstrated that a mutant lacking the NarXL regulator (activator of the NarG system), but not a mutant lacking the NarP-NarQ regulator, has a colonization defect, consistent with the advantage provided by NarG. The emerging picture is one in which gene regulation is tuned to balance expression of the terminal reductases that E. coli uses to maximize its competitiveness and achieve the highest possible population in the intestine.

An Escherichia coli aer mutant exhibits a reduced ability to colonize the streptomycin-treated mouse large intestine

The oxygen sensor Aer of Escherichia coli affects the expression level of genes that are involved in sugar acid degradation. Phenotypes of Aer mediated gene regulation, namely growth on sugar acids was tested 'in vitro' with Phenotype MicroArrays and colonization of the mouse large intestine was tested 'in vivo'. The aer mutant did not grow on the sugar acids D: -gluconate, D: -glucuronate, D: -galacturonate, as well as the sugar alcohol D: -mannitol. Since sugar acids are the predominant carbon source for E. coli in the intestinal mucosa, the ability of the aer mutant to colonize the streptomycin-treated mouse large intestine was tested. The mutant exhibited a decreased ability to colonize the intestine when compared to wild-type cells. This effect was more pronounced under competitive conditions. The colonization phenotype of the aer mutant was complemented with either of two plasmids. One of them expressed the Aer protein, whereas the other one expressed the sugar acid degradation enzymes that are encoded by edd and eda. The data support the interpretation that decreased expression of edd and eda along with the decreased ability to grow on sugar acids may contribute to the reduced capacity of the aer mutant to colonize the mouse intestine. While Aer seems to be important during the initiation phase of colonization, FlhD/FlhC appears to be of disadvantage during maintenance phase. FlhD/FlhC is the master regulator of all flagellar genes and required for Aer expression. Mutants in flhD exhibited an initial competitive disadvantage during the first 3 days of colonization, but recovered lateron.

Mouse Intestine Selects Nonmotile flhDC Mutants of Escherichia coli MG1655 with Increased Colonizing Ability and Better Utilization of Carbon Sources

D-gluconate which is primarily catabolized via the Entner-Doudoroff (ED) pathway, has been implicated as being important for colonization of the streptomycin-treated mouse large intestine by Escherichia coli MG1655, a human commensal strain. In the present study, we report that an MG1655 Deltaedd mutant defective in the ED pathway grows poorly not only on gluconate as a sole carbon source but on a number of other sugars previously implicated as being important for colonization, including L-fucose, D-gluconate, D-glucuronate, N-acetyl-D-glucosamine, D-mannose, and D-ribose. Furthermore, we show that the mouse intestine selects mutants of MG1655 Deltaedd and wild-type MG1655 that have improved mouse intestine-colonizing ability and grow 15 to 30% faster on the aforementioned sugars. The mutants of MG1655 Deltaedd and wild-type MG1655 selected by the intestine are shown to be nonmotile and to have deletions in the flhDC operon, which encodes the master regulator of flagellar biosynthesis. Finally, we show that DeltaflhDC mutants of wild-type MG1655 and MG1655 Deltaedd constructed in the laboratory act identically to those selected by the intestine; i.e., they grow better than their respective parents on sugars as sole carbon sources and are better colonizers of the mouse intestine.

RpoS gene function is a disadvantage for Escherichia coli BJ4 during competitive colonization of the mouse large intestine.

The ability of Escherichia coli to survive stress during growth in different environments is, in large part, dependent on rpoS and the genes that comprise the rpoS regulon. E. coli BJ4 and an isogenic BJ4 rpoS mutant were used to examine the influence of the rpoS gene on E. coli colonization of the streptomycin-treated mouse large intestine. Colonization experiments in which the wild-type E. coli BJ4 and its rpoS mutant were fed individually as well as simultaneously to mice suggested that E. coli BJ4 does not face prolonged periods of nutrient starvation in the mouse large intestine and that the rpoS regulon is not expressed during long-term colonization after adaptation of the bacteria to the gut environment.

Escherichia coli F-18 and E. coli K-12 eda mutants do not colonize the streptomycin-treated mouse large intestine.

The Escherichia coli human fecal isolates F-18 and K-12 are excellent colonizers of the streptomycin-treated mouse intestine. E. coli F-18 and E. coli K-12 eda mutants (unable to utilize glucuronate, galacturonate, and gluconate) were constructed by insertional mutagenesis. Neither the E. coli F-18 eda nor the E. coli K-12 eda mutant was able to colonize the streptomycin-treated mouse intestine, whether they were fed to mice together with their respective parental strains or alone. Complementation of the eda mutants with pTC190 (containing a functional E. coli K-12 eda gene) completely restored the colonization ability of both eda mutants. Relative to their parental strains, the E. coli F-18 eda mutant and the E. coli K-12 eda mutant grew poorly in cecal mucus isolated from mice fed either normal mouse chow or a synthetic diet containing sucrose as the sole carbon source, yet the mutants and parental strains demonstrated identical growth rates in minimal medium with glucose as the carbon source. E. coli F-18 edd eda and E. coli K-12 edd eda double mutants colonized the streptomycin-treated intestine when fed to mice alone; however, when fed simultaneously with their respective parental strains, they were poor colonizers. Since the edd gene is involved only in gluconate metabolism via the Entner-Doudoroff pathway, these results implicate the utilization of gluconate and the Entner-Doudoroff pathway as important elements in E. coli colonization of the streptomycin-treated mouse large intestine.

The Escherichia coli K-12 gntP gene allows E. coli F-18 to occupy a distinct nutritional niche in the streptomycin-treated mouse large intestine.

Escherichia coli F-18 is a human fecal isolate that makes type 1 fimbriae, encoded by the fim gene cluster, and is an excellent colonizer of the streptomycin-treated mouse intestine. E. coli F-18 fimA::tet, lacking type 1 fimbriae, was constructed by bacteriophage P1 transduction of the fim region of the E. coli K-12 strain ORN151, containing the tetracycline resistance gene from Tn10 inserted in the fimA gene, into E. coli F-18. E. coli F-18 fimA::tet was found to occupy a distinct niche in the streptomycin-treated mouse intestine when fed in small numbers (10(4) CFU) to mice, along with large numbers (10(10) CFU) of E. coli F-18, as defined by the ability of the E. coli F-18 fimA::tet strain to grow and colonize only 1 order of magnitude below E. coli F-18. The same effect was observed when mice already colonized with E. coli F-18 were fed small numbers of E. coli F-18 fimA::tet. Experiments which show that the E. coli K-12 gene responsible for this effect is not fim::tet but gntP, which maps immediately downstream of the fim gene cluster, are presented. gntP encodes a high-affinity gluconate permease, suggesting that the distinct niche in the mouse large intestine is defined by the presence of gluconate. The data presented here support the idea that small numbers of an ingested microorganism can colonize the intestine as long as it can utilize an available nutrient better than any of the other resident species can.

Role of leuX in Escherichia coli colonization of the streptomycin-treated mouse large intestine

Escherichia coli F-18, a normal human fecal isolate, is an excellent colonizer of the streptomycin-treated mouse large intestine. E. coli F-18 Col-, a derivative of E. coli F-18 that no longer makes the E. coli F-18 colicin, colonizes the mouse large intestine as well as E. coli F18 when fed alone, but is eliminated when fed together with E. coli F-18. Recently, a random bank of E. coli F-18 DNA was transformed into E. coli F-18 Col-, the resultant population was fed to streptomycin-treated mice, and the intestine was used to select the best colonizer. In this fashion, a 6.5 kb E. coli F-18 DNA fragment was isolated. This fragment was shown to enhance E. coli F-18 Col- mouse large intestinal colonizing ability and survival during stationary phase in intestinal mucus in vitro, as well as stimulate the synthesis of type-1 fimbriae. Here, we present evidence that the gene responsible for the enhanced E. coli F-18 Col- colonizing ability and survival during stationary phase in vitro is leuX. This gene encodes a rare leucine tRNA specific for the UUG codon. In addition, we show that the presence of a functional leuX gene is necessary for E. coli K-12 intestinal colonization and for survival in stationary phase.

Stimulation ofEscherichia coliF-18Col−type-1 fimbriae synthesis byleuX

Escherichia coli F-18, a normal human fecal isolate, is an excellent colonizer of the streptomycin-treated mouse large intestine. E. coli F-18Col-, a derivative of E. coli F-18 which no longer makes the E. coli F-18 colicin, colonizes the large intestine as well as E. coli F-18 when fed to mice alone but is eliminated when fed together with E. coli F-18. Recently we randomly cloned E. coli F-18 DNA into E. coli F-18Col- and let the mouse intestine select the best colonizer. In this way, we isolated a 6.5-kb E. coli F-18 DNA sequence that simultaneously stimulated synthesis of type 1 fimbriae and enhanced E. coli F-18Col- colonizing ability. In the present investigation we show that the gene responsible for stimulation of type 1 fimbriae synthesis appears to be leuX, which encodes a tRNA specific for the rare leucine codon UUG. Moreover, it appears that expression of leuX may be regulated by two proteins (22 kDa and 26 kDa) encoded by genes immediately adjacent to leuX.

Stimulation of Escherichia coli F-18Col- type-1 fimbriae synthesis by leuX.

Escherichia coli F-18, a normal human fecal isolate, is an excellent colonizer of the streptomycin-treated mouse large intestine. E. coli F-18Col-, a derivative of E. coli F-18 which no longer makes the E. coli F-18 colicin, colonizes the large intestine as well as E. coli F-18 when fed to mice alone but is eliminated when fed together with E. coli F-18. Recently we randomly cloned E. coli F-18 DNA into E. coli F-18Col- and let the mouse intestine select the best colonizer. In this way, we isolated a 6.5-kb E. coli F-18 DNA sequence that simultaneously stimulated synthesis of type 1 fimbriae and enhanced E. coli F-18Col- colonizing ability. In the present investigation we show that the gene responsible for stimulation of type 1 fimbriae synthesis appears to be leuX, which encodes a tRNA specific for the rare leucine codon UUG. Moreover, it appears that expression of leuX may be regulated by two proteins (22 kDa and 26 kDa) encoded by genes immediately adjacent to leuX.

Utilization of the mouse large intestine to select an Escherichia coli F-18 DNA sequence that enhances colonizing ability and stimulates synthesis of type 1 fimbriae.

Escherichia coli F-18, a normal human fecal isolate, is an excellent colonizer of the streptomycin-treated mouse large intestine. E. coli F-18 Col-, a derivative of E. coli F-18 which no longer makes the E. coli F-18 colicin, colonizes the large intestine as well as E. coli F-18 when fed to mice alone but is eliminated when fed together with E. coli F-18. Random sequences of E. coli F-18 DNA were cloned into pRLB2, a par-B-stabilized derivative of pHC79. The entire gene library was transformed into E. coli F-18 Col- and fed to streptomycin-treated mice. The mouse large intestine selected a predominant clone which contained a recombinant plasmid (pRLB7) that enhanced E. coli F-18 Col- colonizing ability 100-fold but did not stimulate colicin synthesis. Moreover, pRLB7 simultaneously improved the survival of E. coli F-18 Col- in stationary phase in vitro, utilizing nutrients derived from mouse cecal mucus, and stimulated synthesis of both type 1 fimbriae and three E. coli F-18 Col- outer membrane proteins (74, 71, and 69 kDa). The 6.5-kb E. coli F-18 DNA sequence in pRLB7 does not contain either the fim operon or pilG (hns), both known to be involved in type 1 fimbrial synthesis. The sequence encodes six proteins, all smaller than the three E. coli F-18 Col- outer membrane proteins whose synthesis it stimulates. Collectively, the results suggest that the cloned E. coli F-18 DNA sequence contains one or more regulators of E. coli F-18 Col- operons expressed in the mouse large intestine in vivo and in isolated mouse cecal mucus in vitro.

Escherichia coli F-18 phase locked 'on' for expression of type 1 fimbriae is a poor colonizer of the streptomycin-treated mouse large intestine

Escherichia coli F-18, a human fecal isolate, makes type 1 fimbriae in vitro and in the streptomycin-treated mouse large intestine in vivo, and is an excellent colonizer of the cecal mucus layer in the streptomycin-treated mouse large intestine. E. coli F-18(pPKL91) harbors an extra fimB gene on a parB stabilized pPBR322 plasmid and is therefore phase-locked 'on' such that all cells express type 1 fimbriae. E. coli F-18(pPR633) contains essentially the same plasmid minus the fim B gene and in L-broth about 30% of the cells express type 1 fimbriae. When fed alone to streptomycin-treated mice, E. coli F-18(pPKL91) colonized the large intestine at about 107 cfu/g of feces. However, when simultaneously fed with E. coli F-18(pPR633) at either high (1010 cfu), or low doses (104 cfu), E. coli F-18(pPKL91) was a poor colonizer dropping to a level of between 102 and 103 cfu/g of feces. When given enough time to establish the state of colonization (10 days), E. coli F-18(pPKL91 ) persisted in feces in high numbers despite subsequent challenge by E. coli F-18(pPR633). Moreover, although both E. coli F-18(pPR633) and E. coli F-18(pPKL91) grew equally well in cecal mucus in vitro, E. coli F-18(pPR633) traveled through a layer of cecal mucus in vitro much faster than E. coli F-18(pPKL91). Together, the data suggest that type 1 fimbriated cells are at a disadvantage in initiating the colonization state because they have difficulty entering the mucus layer of the intestine as rapidly as non-fimbriated cells. The data also point to the possible biological significance of type 1 fimbrial phase-variation in the mouse large intestine.

Expression of Escherichia coli F-18 type 1 fimbriae in the streptomycin-treated mouse large intestine.

Escherichia coli F-18, isolated from the feces of a healthy human, makes type 1 fimbriae and is an excellent colonizer of the streptomycin-treated mouse large intestine. Recently, it was shown that the inability to produce type 1 fimbriae had no effect on the ability of E. coli F-18 to colonize the streptomycin-treated mouse large intestine, suggesting the possibility that E. coli F-18 does not express type 1 fimbriae in vivo. However, we show here that E. coli F-18 does express type 1 fimbriae in mouse cecal mucus in vivo and, in fact, appears to express substantially more type 1 fimbriae in cecal mucus in vivo than in L broth in vitro.

Growth of Salmonella typhimurium SL5319 and Escherichia coli F-18 in mouse cecal mucus: role of peptides and iron

Escherichia coli F-18, a normal human fecal isolate, and Salmonella typhimurium SL5319, an avirulent strain, are known to colonize the streptomycin-treated CD-1 mouse large intestine by utilizing nutrients present in intestinal mucus for growth. Moreover, previous experiments suggested the possibility that E. coli F-18 and S. typhimurium SL5319 utilized different mucus nutrients. Therefore, mouse cecal mucus was fractionated into high and low molecular weight components, and each fraction was inoculated either simultaneously or separately with E. coli F-18 and S. typhimurium SL5319. A 50 kd fraction was found in which the growth of S. typhimurium SL5319 suppressed growth of E. coli F-18. Evidence is presented that in this fraction S. typhimurium SL5319 utilizes peptides, presumably generated by mucus proteases, as a source of amino acids for growth. Furthermore, it is shown that S. typhimurium SL5319 grows in this 50 kd fraction with a generation time of 27 min in the presence of at most 7 μg of carbohydrate per ml and 2.2 μg of peptide per ml, and that S. typhimurium SL5319 suppresses E. coli F-18 growth in this fraction by sequestering iron. The data are discussed with respect to the role of peptide utilization and iron sequestration in the ability of S. typhimurium SL5319 to colonize the mouse large intestine.

Growth ofSalmonella typhimuriumSL5319 andEscherichia coliF-18 in mouse cecal mucus: role of peptides and iron

Escherichia coli F-18, a normal human fecal isolate, and Salmonella typhimurium SL5319, an avirulent strain, are known to colonize the streptomycin-treated CD-1 mouse large intestine by utilizing nutrients present in intestinal mucus for growth. Moreover, previous experiments suggested the possibility that E. coli F-18 and S. typhimurium SL5319 utilized different mucus nutrients. Therefore, mouse cecal mucus was fractionated into high and low molecular weight components, and each fraction was inoculated either simultaneously or separately with E. coli F-18 and S. typhimurium SL5319. A 50 kd fraction was found in which the growth of S. typhimurium SL5319 suppressed growth of E. coli F-18. Evidence is presented that in this fraction S. typhimurium SL5319 utilizes peptides, presumably generated by mucus proteases, as a source of amino acids for growth. Furthermore, it is shown that S. typhimurium SL5319 grows in this 50 kd fraction with a generation time of 27 min in the presence of at most 7 μg of carbohydrate per ml and 2.2 μg of peptide per ml, and that S. typhimurium SL5319 suppresses E. coli F-18 growth in this fraction by sequestering iron. The data are discussed with respect to the role of peptide utilization and iron sequestration in the ability of S. typhimurium SL5319 to colonize the mouse large intestine.

Neither motility nor chemotaxis plays a role in the ability of Escherichia coli F-18 to colonize the streptomycin-treated mouse large intestine

Escherichia coli F-18, isolated from the feces of a healthy human in 1977, is an excellent colonizer of the streptomycin-treated mouse large intestine and displays normal motility and chemotaxis ability. A chemotaxis-defective derivative of E. coli F-18, E, coli F-18 CheA-, and a nonflagellated derivative, E. coli F-18 Fla-, were constructed. These strains were found to colonize the streptomycin-treated mouse large intestine as well as E. coli F-18 when mice were fed both E. coli F-18 and either the CheA- or Fla- derivative at high levels (10(10) CFU of each strain per mouse) or low levels (10(4) CFU of each strain per mouse). Furthermore, E. coli F-18 lost motility and chemotaxis ability when grown in colonic or cecal mucus in vitro despite retaining the ability to synthesize flagella. Thus, it appears that neither motility nor chemotaxis plays a role in the ability of E. coli F-18 to colonize because this strain becomes functionally nonmotile upon growth in the streptomycin-treated mouse large intestine.

Escherichia coli F-18 makes a streptomycin-treated mouse large intestine colonization factor when grown in nutrient broth containing glucose

Escherichia coli F-18 FimA-, a type 1 fimbria-less derivative of a normal human fecal isolate, E. coli F-18, has previously been shown to be as good a colonizer of streptomycin-treated mouse large intestine as its parent, suggesting that type 1 fimbriae are not necessary in this process. In this study it was found that when E. coli F-18 FimA- was grown standing overnight at 37 degrees C in nutrient broth, it remained uniformly suspended; however, when grown in nutrient broth containing 1% (wt/wt) D-glucose, it settled to the bottom of culture tubes. Settling was associated with the formation of clumps (microcolonies) of more than 10 cells each. The effect of glucose could be partially reversed by growing E. coli F-18 FimA- in nutrient broth containing 1% D-glucose supplemented with cyclic AMP (greater than or equal to 1 mM). A reduced-settling mutant of E. coli F-18 FimA-, E. coli F-18 FimA- Set-, selected after Tn5 mutagenesis, was found to be a poor colonizer of streptomycin-treated mouse large intestine when fed to mice simultaneously with the parent strain. These results suggest that glucose-induced settling is, at least in part, regulated in a way related to catabolite repression and that the ability of E. coli F-18 FimA- to form microcolonies plays an important role in its ability to colonize streptomycin-treated mouse large intestine.

Construction of stable cloning vectors that do not segregate from a human fecal Escherichia coli strain in the streptomycin-treated mouse large intestine

Escherichia coli F-18 Col- was previously shown to be a poor colonizer of the streptomycin-treated mouse large intestine, relative to its parent, E. coli F-18. Prior to attempting to clone genes responsible for the colonization phenotype of E. coli F-18 into E. coli F-18 Col-, a suitable cloning vector had to be found. In this investigation, we report that the commonly used cloning vectors pBR322, pHC79, and pBR329 all segregate from E. coli F-18 Col- both when grown in L broth under conditions of nonselection (i.e., in vitro) and when fed to streptomycin-treated mice (i.e., in vivo). Insertion of the cer region (which promotes resolution of replicating plasmids into monomeric forms) into pHC79 stabilized this plasmid in E. coli F-18 Col- in vitro and in vivo. In contrast, two independent cer insertions into pBR329 did not stabilize the plasmid completely in E. coli F-18 Col- in vitro, and feeding the strain to streptomycin-treated mice resulted in rapid segregation of the plasmids in vivo. Also, stability of all three plasmids in E. coli F-18 Col- in vitro was achieved by insertion of the parB region of plasmid R1, which encodes a cell-killing protein, Hok, that is active only postsegregationally. However, as with cer, complete in vitro and in vivo stabilization was achieved only in parB constructs of pBR322 and pHC79.

Type 1 Pili Are Not Necessary for Colonization of the Streptomycin-Treated Mouse Large Intestine by Type 1-Piliated Escherichia coli F-18 and E. coli K-12

Type 1 Pili Are Not Necessary for Colonization of the Streptomycin-Treated Mouse Large Intestine by Type 1-Piliated <i>Escherichia coli</i> F-18 and <i>E. coli</i> K-12

Type 1 pili are not necessary for colonization of the streptomycin-treated mouse large intestine by type 1-piliated Escherichia coli F-18 and E. coli K-12

Escherichia coli F-18, an excellent colonizer of the streptomycin-treated mouse large intestine, produces type 1 pili. E. coli F-18 FimA-, type 1 pilus negative, and E. coli F-18 FimH-, type 1 pilus positive but adhesin negative, were constructed by bacteriophage P1 transduction of defective fimA and fimH genes from the E. coli K-12 strains ORN151 and ORN133, respectively, into E. coli F-18. Adhesion of E. coli F-18 to an immobilized mannose-bovine serum albumin glycoconjugate was about sixfold greater than that of either E. coli F-18 FimA- or E. coli F-18 FimH-, and adhesion of E. coli F-18 to immobilized cecal epithelial cell brush border membranes was between two- and threefold greater than that of E. coli F-18 FimA- or E. coli F-18 FimH-. When either E. coli F-18 FimA- or E. coli FimH- was fed to streptomycin-treated mice together with E. coli F-18, the pilus-negative and adhesin-negative strains colonized as well as their type 1-piliated parent. Essentially the same result was observed when the type 1-piliated E. coli K-12 strain ORN152 was fed to streptomycin-treated mice together with a nearly isogenic K-12 FimA- strain, ORN151. Furthermore, when streptomycin-treated mice were fed E. coli F-18 FimA- or E. coli F-18 FimH- together with E. coli F-18 Col-, which also makes type 1 pili but is a poor colonizer relative to E. coli F-18 because it grows poorly in mucus in the presence of E. coli F-18, the F-18 FimA- and F-18 FimH- strains colonized well (10(6) to 10(7) CFU/g of feces), whereas the number of E. coli F-18 Col- in feces decreased rapidly to 10(2) CFU/g of feces. These data show that in streptomycin-treated mice, the inability to produce functional type 1 pili has no effect on the ability of E. coli F-18 and E. coli K-12 to colonize the large intestine.

Roles of motility, chemotaxis, and penetration through and growth in intestinal mucus in the ability of an avirulent strain of Salmonella typhimurium to colonize the large intestine of streptomycin-treated mice.

Previously, it had been shown that an avirulent strain of Salmonella typhimurium, SL5316, with wild-type lipopolysaccharide (LPS) was a far better colonizer of the streptomycin-treated CD-1 mouse large intestine, was far more motile, did not bind to mouse intestinal mucus nearly as well as, but penetrated through a layer of intestinal mucus in vitro far better than an almost isogenic LPS-deficient transductant, SL5325. In the present investigation, a nonflagellated transductant, SL5681, and a nonchemotactic transductant, SL5784, were isolated from SL5316 and tested for relative colonizing ability versus SL5316 (smooth) and SL5325 (rough) in streptomycin-treated mice. In addition, the Salmonella strains were tested for their ability to grow together in cecal intestinal mucus and in cecal luminal contents, for their tumbling and swimming activities after growth in cecal mucus, and for their ability to adhere to and travel through cecal mucus in vitro. The data show that the nonflagellated and nonchemotactic derivatives colonized large intestine nearly as well as their parent and were far better colonizers than the LPS-deficient mutant, that all the strains grew equally well in cecal mucus but did not grow in cecal luminal contents, and that cecal mucus-grown strains lost tumbling and swimming activities. Furthermore, the LPS-deficient strain adhered to cecal mucus far better but penetrated mucus far worse than did the nonflagellated transductant, the nonchemotactic transductant, and the parent. Thus, motility and chemotaxis do not appear to play a major role in the ability of the avirulent S. typhimurium strains to colonize the mouse large intestine, colonization may require growth in cecal mucus but does not depend on growth in cecal luminal contents, growth in cecal mucus inhibits S. typhimurium motility, and increased adhesion of the LPS-deficient mutant to cecal mucus and its poor ability to penetrate cecal mucus may play a role in its poor intestine-colonizing ability.