Methylotrophic growth of a mutant strain of the acetogenic bacterium Eubacterium limosum that uses acetate as co-substrate in the absence of CO2

Abstract 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 .     

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

Abstract 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.     

Isolation and characterization of a Clo DF13::Tn901 plasmid mutant with thermosensitive control of DNA replication.

After nitrosoguanidine mutagenesis, a mutant Escherichia coli strain harboring the Clo DF13::Tn901 plasmid pJN03 was isolated that is thermosensitive (Ts) for growth at 43 degrees C. The mutation responsible for this thermosensitive phenotype resides on the pJN03 plasmid genome. Cells harboring the pJN03 cop-1(Ts) plasmid mutant showed a large increase in plasmid copy number at 43 degrees C accompanied by an increase in the synthesis of plasmid-specified gene products like cloacin DF13 and beta-lactamase. The pJN03 cop-1(Ts) mutant showed uncontrolled plasmid DNA replication at the nonpermissive temperature. Analysis of plasmid deletions showed that the mutation is located in the Clo DF13 map interval from 0 to 12% or 29 to 45%. This implies that native cloacin DF13 and the Clo DF13-specified polypeptides B, C, D, E, and G are not involved in the pleiotropic phenotype of the plasmid mutant pJN03 cop-1(Ts).     

Bifidobacteria and human health: regulatory effect of indigenous bifidobacteria on Escherichia coli intestinal colonization

Bifidobacteria are assumed to exert colonization resistance to enteric pathogens. We associated C3H germfree mice with either Bifidobacterium longum or Escherichia coli or both strains and studied how they settled in the gut and the lymphoid organs as well as their effect on mucus composition. Within 24 hE. coli colonized the gut of germfree or B. longum ex-germfree mice. In contrast,B. longum was established in the intestine of E. coli ex-germfree mice only 1 month after inoculation whereas it colonized the germfree gut within 24 h. Although B. longum did not exert colonization resistance to E. coli, the establishing of bifidobacteria in the gut partly prevented changes in the E. coli cell wall. After colonization of the germfree or B. longum mono-associated mice, E. coli lipopolysaccharide exhibited a higher concentration of Kdo and the O-antigen side chain disappeared. A reduction in Kdo content was observed within 1 month in E. coli-B. longum diassociated mice whereas it remained at a high level in E. coli mono-associated mice. Association in a second step with B. longum led to Kdo reduction. Changes in E. coli LPS might be related to mucus modification. Inoculation of either bacterium led to a slow increase in mucus protein content which was however twice as high after E. coli implantation. Inoculation of B. longum in a second step led to a reduction in protein content before B. longum colonized the intestine at a high level suggesting that the protein concentration in the mucus was controlled by the host itself. A new glycoprotein of 200-230 kDa detected during the period preceeding colonization seemed to be broken down by B. longum. The resulting end product might participate in the restoration of E. coli LPS. Finally,B. longum inoculation led to the disappearance of E. coli from kidneys, liver, spleen and lung. The organs were cleared of E. coli before B. longum highly colonized the intestine suggesting that high intestinal colonization by B. longum was not required. Regulation of E. coli invasion seemed to depend on the ability of B. longum to stimulate the immune system.     

Chemostat modeling of Escherichia coli persistence in conventionalized mono-associated and streptomycin-treated mice

We have previously shown that Escherichia coli BJ4 has similar doubling time in mice that are mono-associated (having only the inoculated E. coli BJ4) or streptomycin-treated (having mainly gram-positive bacteria plus the inoculated E. coli BJ4). We also showed that when the mice were conventionalized (fed cecum homogenate from conventional mice or ones with a complete microbial flora), the introduction of complete flora in both cases increased the in vivo doubling time, while decreasing the colony counts in fecal samples. To determine whether the increase in doubling time could explain the decrease in colony counts, we analyzed our previous results by a chemostat model. The analysis shows that the increasing doubling time alone is sufficient to explain the decrease in colony counts in mono-associated mice, but not in the streptomycin-treated mice. The observed decreasing rate in colony counts in streptomycin-treated mice is slower than predicted. Furthermore, whereas the model predicted a decrease to extinction in both mice, the E. coli persist at a frequency 10-80 times higher in streptomycin-treated mice than in mono-associated mice. Thus, while a chemostat model is able to explain some of the population dynamics of intestinal bacteria in mice, additional factors not included in the model are stabilizing the system. Because we find that E. coli declines more slowly and to a higher stabilization frequency in streptomycin-treated mice, which have a more diverse flora before conventionalization, we take these results to suggest that the persistence of E. coli populations is promoted by species diversity. We propose that a mechanism for the persistence may be the presence of new E. coli niches created by keystone species in the more diverse flora.     

Expression of a Porphyromonas gingivalis lipid A palmitylacyltransferase in Escherichia coli yields a chimeric lipid A with altered ability to stimulate interleukin-8 secretion

In Escherichia coli the gene htrB codes for an acyltransferase that catalyses the incorporation of laurate into lipopolysaccharide (LPS) as a lipid A substituent. We describe the cloning, expression and characterization of a Porphyromonas gingivalis htrB homologue. When the htrB homologue was expressed in wild-type E. coli or a mutant strain deficient in htrB, a chimeric LPS with altered lipid A structure was produced. Compared with wild-type E. coli lipid A, the new lipid A species contained a palmitate (C16) in the position normally occupied by laurate (C12) suggesting that the cloned gene performs the same function as E. coli htrB but preferentially transfers the longer-chain palmitic acid that is known to be present in P. gingivalis LPS. LPS was purified from wild-type E. coli, the E. coli htrB mutant strain and the htrB mutant strain expressing the P. gingivalis acyltransferase. LPS from the palmitate bearing chimeric LPS as well as the htrB mutant exhibited a reduced ability to activate human embryonic kidney 293 (HEK293) cells transfected with TLR4/MD2. LPS from the htrB mutant also had a greatly reduced ability to stimulate interleukin-8 (IL-8) secretion in both endothelial cells and monocytes. In contrast, the activity of LPS from the htrB mutant bacteria expressing the P. gingivalis gene displayed wild-type activity to stimulate IL-8 production from endothelial cells but a reduced ability to stimulate IL-8 secretion from monocytes. The intermediate activation observed in monocytes for the chimeric LPS was similar to the pattern seen in HEK293 cells expressing TLR4/MD2 and CD14. Thus, the presence of a longer-chain fatty acid on E. coli lipid A altered the activity of the LPS in monocytes but not endothelial cell assays and the difference in recognition does not appear to be related to differences in Toll-like receptor utilization.     

The diversity of Escherichia coli serotypes and biotypes in cattle faeces

AIM: To study the diversity of commensal Escherichia coli populations shed in faeces of cattle fed on different diets. METHODS AND RESULTS: Thirty Brahman-cross steers were initially fed a high grain (80%) diet and then randomly allocated into three dietary treatment groups, fed 80% grain, roughage, or roughage + 50% molasses. Up to eight different E. coli isolates were selected from primary isolation plates of faecal samples from each animal. Fifty-two distinct serotypes, including nine different VTEC strains, were identified from a total of 474 E. coli isolates. Cattle fed a roughage + molasses diet had greater serotype diversity (30 serotypes identified) than cattle fed roughage or grain (21 and 17 serotypes identified respectively). Cluster analysis showed that serotypes isolated from cattle fed roughage and roughage + molasses diets were more closely associated than serotypes isolated from cattle fed grain. Resistance to one or more of 11 antimicrobial agents was detected among isolates from 20 different serotypes. Whilst only 2.3% of E. coli isolates produced enterohaemolysin, 25% were found to produce alpha-haemolysin. CONCLUSIONS: Diverse non-VTEC populations of E. coli serotypes are shed in cattle faeces and diet may affect population diversity. SIGNIFICANCE AND IMPACT OF THE STUDY: This study provides new information on the serotype diversity and phenotypic traits of predominant E. coli populations in cattle faeces, which could be sources of environmental contamination.     

Physiological state of Escherichia coli BJ4 growing in the large intestines of streptomycin-treated mice.

Growth rates of Escherichia coli BJ4 colonizing the large intestine of streptomycin-treated mice were estimated by quantitative hybridization with rRNA target probes and by epifluorescence microscopy. The ribosomal contents in bacteria isolated from the cecal mucus, cecal contents, and feces were measured and correlated with the ribosomal contents of bacteria growing in vitro at defined rates. The data suggest that E. coli BJ4 grows at an overall high rate in the intestine. However, when taking into account the total intestinal volume and numbers of bacteria present in cecal mucus, cecal contents, and feces, we suggest that E. coli BJ4 in the intestine consists of two populations, one in the mucus which has an apparent generation time of 40 to 80 min and one in the luminal contents which is static.     

Identification of the Escherichia coli K-12 Nramp orthologue (MntH) as a selective divalent metal ion transporter

The Escherichia coli mntH (formerly yfeP) gene encodes a putative membrane protein (MntH) highly similar to members of the eukaryotic Nramp family of divalent metal ion transporters. To determine the function of E. coli MntH, a null mutant was created and MntH was overexpressed both in wild-type E. coli and in the metal-dependent mutant hflB1(Ts). At the restrictive temperature 42 degrees C, the mntH null mutation reduces the suppression of hflB1(Ts) thermosensitivity by exogenous divalent metals. Conversely, overexpression of MntH restores growth at 42 degrees C, increases suppression of the ts phenotype by Fe(II) and Ni(II) and renders hflB1(Ts) cells hypersensitive to Mn(II). Transport studies in intact cells show that MntH selectively facilitates uptake of 54Mn(II) and 55Fe(II) in a temperature-, time- and proton-dependent manner. Competition studies in uptake assays and growth inhibition experiments in hflB1(Ts) mutants together indicate that MntH is a divalent metal cation transporter of broad substrate specificity. The functional characteristics of MntH suggest that it corresponds to the previously described manganese transporter of E. coli. This study indicates that proton-dependent divalent metal ion uptake has been preserved in the Nramp family from bacteria to humans.     

Phospholipase A-deficient mutants of Escherichia coli B

Phospholipase A-deficient mutants were isolated from Escherichia coli B/SM as follows. Replica plates were incubated to allow formation of colonies and then overlayed with soft agar containing washed sheep erythrocytes, lecithin Ca++, colistin, lysozyme and streptomycin. The mutant colonies were detected as colonies without hemolytic zones. Two or three cycles of treatment with mutagen and selection were necessary for their isolation. The mutants obtained could grow in a synthetic medium with glucose as the sole carbon source, and their phospholipid compositions were similar to that of the parent. They also gave the same agglutination titer as the parent with rabbit antiserum against the parent strain. They supported the growth of all members of the T-series of bacteriophages as effectively as the parent. Some hemolytic substance was produced from either lecithin or bacterial constituents when the mutants were infected with T even phages, but not with T odd phages. When the parent strain was infected with either T1 or T4, free fatty acids (FFA) were produced in the cell debris. Only a trace of FFA was formed in the debris of one of these mutants on infection with T4 and no FFA was formed on infection with T1.     

Identification of important amino acid residues that modulate binding of Escherichia coli GroEL to its various cochaperones

Genetic experiments have shown that the GroEL/GroES chaperone machine of Escherichia coli is absolutely essential, not only for bacterial growth but also for the propagation of many bacteriophages including lambda. The virulent bacteriophages T4 and RB49 are independent of the host GroES function, because they encode their own cochaperone proteins, Gp31 and CocO, respectively. E. coli groEL44 mutant bacteria do not form colonies above 42 degrees nor do they propagate bacteriophages lambda, T4, or RB49. We found that the vast majority (40/46) of spontaneous groEL44 temperature-resistant colonies at 43 degrees were due to the presence of an intragenic suppressor mutation. These suppressors define 21 different amino acid substitutions in GroEL, each affecting one of 13 different amino acid residues. All of these amino acid residues are located at or near the hinge, which regulates the large en bloc movements of the GroEL apical domain. All of these intragenic suppressors support bacteriophages lambda, T4, and RB49 growth to various extents in the presence of the groEL44 allele. Since it is known that the GroEL44 mutant protein does not interact effectively with Gp31, the suppressor mutations should enhance cochaperone binding. Analogous intragenic suppressor studies were conducted with the groEL673 temperature-sensitive allele.     

Escherichia coli K-12 ferrous iron uptake mutants are impaired in their ability to colonize the mouse intestine

Abstract The streptomycin-treated mouse colonization model was used to investigate the role of the Fe²⁺ uptake system (Feo) of Escherichia coli K12 in the colonization of the mouse intestine. Mutants impaired in the uptake of Fe²⁺ ions were shown to be deficient also in their colonization ability. Both enterochelin-producing and enterochelin-nonproducing Escherichia coli feo mutants were unable to colonize the mouse intestine. These results demonstrated that Fe(II) is an essential source of iron for E. coli grown in the intestine.     

Transduction of plasmid antibiotic resistance determinants with pseudo-T-even bacteriophages

Transduction of antibiotic resistance determinants of the plasmid pBR322 with pseudoT-even bacteriophages RB42, RB43, and RB49 was studied. It is established that antibiotic resistance determinants of plasmid pBR322 from Escherichia coli recA(+)- and recA(-)-donor strains do not differ significantly in respect to the efficiency of transduction. Amber mutants RB43-21, RB43-33, and a double amber mutant RB43am21am33 were obtained. These mutants facilitated transduction experiments in some cases. Transduction of antibiotic resistance markers of the vector plasmid pBR325 and recombinant plasmid pVT123, containing a DNA fragment with hoc segE uvsW genes of phage T4, was studied. The frequency of appearance of transductants resistant to pseudoT-even bacteriophages used in transduction was determined, and the sensitivity of resistant transductants to 32 RB bacteriophages and also to phages lambda, T2, T4, T5, T6, T7, and BF23 was estimated. The efficiency of plating pseudoT-even bacteriophages RB42 and RB43 on strain E. coli 802 himA hip carrying mutations in genes that encode subunits of the Integration Host Factor (IHF) was shown to be higher than on isogenic strain E. coli 802. The growth of pseudoT-even bacteriophages limited in vivo by modification-restriction systems of chromosomal (EcoKI, EcoBI), phage (EcoP1I), and plasmid (EcoRI, EcoR124I, and EcoR124II) localization was analyzed. It was shown that these phages were only slightly restricted by the type I modification-restriction systems EcoBI, EcoR124I, and EcoR124II. Phage RB42 was restricted by systems EcoKI, EcoP1I, and EcoRI; phage RB43, by systems EcoKI and EcoRI; and phage RB49, by the EcoRI modification-restriction system.     

Development and application of a spiral plating method for the enumeration of Escherichia coli O157 in bovine faeces

AIM: To develop and validate a direct plating method applicable to epidemiological studies for enumerating Escherichia coli O157 in cattle faeces. METHODS AND RESULTS: The spiral plate count method was used to enumerate E. coli O157 in faecal samples. The accuracy and variation of counts was then assessed using faecal samples inoculated with E. coli O157. There was good agreement between inoculated levels of E. coli O157 and those recovered from faeces, particularly when counts were > 10(2) CFU g(-1) of faeces. The method was applied to a small study assessing short-term survival of E. coli O157 in naturally infected cattle faeces. E. coli O157 was found to survive in faeces for over 10 days at concentrations above 10(3) CFU g(-1) of faeces. Populations of E. coli O157 were also found to increase 100-fold in the first few hours after defecation. CONCLUSIONS: The enumeration method is easy to implement and enables a quick throughput of large numbers of samples. The method is accurate and reliable and enables the inherent variation in count data to be explored but needs to be used in combination with a more sensitive method for samples containing < 10(2) CFU g(-1) of faeces. SIGNIFICANCE AND IMPACT OF THE STUDY: The method described is appropriate for enumeration of E. coli O157 in cattle faeces in large-scale epidemiological studies.     

Isolation and characterization of beta-ketoacyl-acyl carrier protein reductase (fabG) mutants of Escherichia coli and Salmonella enterica serovar Typhimurium

FabG, beta-ketoacyl-acyl carrier protein (ACP) reductase, performs the NADPH-dependent reduction of beta-ketoacyl-ACP substrates to beta-hydroxyacyl-ACP products, the first reductive step in the elongation cycle of fatty acid biosynthesis. We report the first documented fabG mutants and their characterization. By chemical mutagenesis followed by a tritium suicide procedure, we obtained three conditionally lethal temperature-sensitive fabG mutants. The Escherichia coli [fabG (Ts)] mutant contains two point mutations: A154T and E233K. The beta-ketoacyl-ACP reductase activity of this mutant was extremely thermolabile, and the rate of fatty acid synthesis measured in vivo was inhibited upon shift to the nonpermissive temperature. Moreover, synthesis of the acyl-ACP intermediates of the pathway was inhibited upon shift of mutant cultures to the nonpermissive temperature, indicating blockage of the synthetic cycle. Similar results were observed for in vitro fatty acid synthesis. Complementation analysis revealed that only the E233K mutation was required to give the temperature-sensitive growth phenotype. In the two Salmonella enterica serovar Typhimurium fabG(Ts) mutants one strain had a single point mutation, S224F, whereas the second strain contained two mutations (M125I and A223T). All of the altered residues of the FabG mutant proteins are located on or near the twofold axes of symmetry at the dimer interfaces in this homotetrameric protein, suggesting that the quaternary structures of the mutant FabG proteins may be disrupted at the nonpermissive temperature.     

志贺菌福氏2a信号标签诱变突变体文库的构建

以合成的单链序列特异性标签为模板,通过PCR得到双链DNA标签并将其克隆到自杀质粒pUT-Tn5 Km2的转座子中,转化大肠杆菌S17-1λpir;然后用经转化的S17-1λpir与福氏志贺菌2a 2457T交配,挑出对氨苄青霉素敏感,对卡那霉素和萘啶酮酸抗性的菌落,结果表明构建了包含4376个福氏志贺菌突变体信号标签诱变库,为进一步鉴定该病原体的毒力基因打下了基础。     

Genes for TDP-rhamnose synthesis affect the pattern of lipopolysaccharide heterogeneity in Escherichia coli K-12.

The rough lipopolysaccharide (LPS) of commonly used strains of Escherichia coli K-12 has two distinctly different band patterns when analyzed by high-resolution polyacrylamide gel electrophoresis. The LPS of ancestral strains such as W1485F- consists primarily of a single broad gel band. In contrast, the LPS of strains derived from strain Y10 such as AB1133 or C600 gives three sharp gel bands. Complementation studies using DNA fragments from the rfb gene cluster of Shigella dysenteriae 1 indicated that the difference between the two gel patterns is due to a mutation in the gene encoding the TDP-rhamnose synthetase, the final enzyme involved in TDP-rhamnose biosynthesis. This mutation arose during the construction of strain Y10, and not in strain 679-680 as previously thought. The requirement for the rfaS gene for synthesis of the broad major band seen in W1485F- LPS and the shift in gel migration of a component of this band when an rfaQ mutation was introduced indicated that this broad band contained the unique form of rough E. coli LPS which has been termed lipooligosaccharide. This finding indicates that lipooligosaccharide is likely to contain rhamnose and suggests a model in which one of the functions of partial substituents such as rhamnose may be to direct core synthesis into different pathways to produce alternative forms of LPS.     

Acetylation of O-specific lipopolysaccharides from Shigella flexneri 3a and 2a occurs in Escherichia coli K-12 carrying cloned S. flexneri 3a and 2a rfb genes.

Most of the Shigella flexneri O-specific serotypes result from O-acetyl and/or glucosyl groups added to a common O-repeating unit of the lipopolysaccharide (LPS) molecule. The genes involved in acetylation and/or glucosylation of S. flexneri LPS are physically located on lysogenic bacteriophages, whereas the rfb cluster contains the biosynthesis genes for the common O-repeating unit (D.A.R. Simmons and E. Romanowska, J. Med. Microbiol. 23:289-302, 1987). Using a cosmid cloning strategy, we have cloned the rfb regions from S. flexneri 3a and 2a. Escherichia coli K-12 containing plasmids pYS1-5 (derived from S. flexneri 3a) and pEY5 (derived from S. flexneri 2a) expressed O-specific LPS which reacted immunologically with S. flexneri polyvalent O antiserum. However, O-specific LPS expressed in E. coli K-12 also reacted with group 6 antiserum, indicating the presence of O-acetyl groups attached to one of the rhamnose components of the O-repeating unit. This was confirmed by measuring the amounts of acetate released from purified LPS samples and also by the chemical removal of O-acetyl groups, which abolished group 6 reactivity. The O-acetylation phenotype was absent in an E. coli strain with an sbcB-his-rfb chromosomal deletion and could be restored upon conjugation of F' 129, which carries sequences corresponding to a portion of the deleted region. Our data demonstrate that E. coli K-12 strains possess a novel locus which directs the O acetylation of LPS and is located in the sbcB-rfb region of the chromosomal map.     

Intestinal colonization by enteroaggregative Escherichia coli supports long-term bacteriophage replication in mice

Bacteriophages have been known to be present in the gut for many years, but studies of relationships between these viruses and their hosts in the intestine are still in their infancy. We isolated three bacteriophages specific for an enteroaggregative O104:H4 Escherichia coli (EAEC) strain responsible for diarrhoeal diseases in humans. We studied the replication of these bacteriophages in vitro and in vivo in a mouse model of gut colonization. Each bacteriophage was able to replicate in vitro in both aerobic and anaerobic conditions. Each bacteriophage individually reduced biofilms formed on plastic pegs and a cocktail of the three bacteriophages was found to be more efficient. The cocktail was also able to infect bacterial aggregates formed on the surface of epithelial cells. In the mouse intestine, bacteriophages replicated for at least 3 weeks, provided the host was present, with no change in host levels in the faeces. This model of stable and continuous viral replication provides opportunities for studying the long-term coevolution of virulent bacteriophages with their hosts within a mammalian polymicrobial ecosystem.