Lipopolysaccharide with an altered O-antigen produced in Escherichia coli K-12 harbouring mutated, cloned Shigella flexneri rfb genes

Cloning of the rfb genes of Shigella flexneri 2a into Escherichia coli K-12 strain DH1 results in the synthesis of lipopolysaccharides (LPS) with an O-antigen chain having type antigen IV and group antigens 3,4. During genetic studies of these rfb genes in E. coli K-12, we observed that strains harbouring plasmids with certain mutations (inversion and transposon insertions) which should have blocked O-antigen synthesis nevertheless still produced LPS with O-antigen chains. These LPS migrated differently on silver-stained SDS—polyacrylamide gels, compared with the LPS produced by wild-type rfb genes, and the group 3,4 antigens were barely detectable, suggesting that the O-antigen was altered. Investigation of the genetic determinants for production of the altered O-antigen/LPS indicated that: (i) these LPS are produced as a result of mutations which are either polar on rfbF or inactivate rfbF; (ii) the rfbX gene product (or a similar protein in the E. coli K-12 rfb region) is needed for production of the altered O-antigen in the form of LPS; (iii) the rfbG gene product is required for the production of both the parental and altered LPS; (iv) the dTDP-rhamnose biosynthesis genes are required. Additionally, an E. coli K-12 gene product(s) encoded outside the rfb region also contributes to production of the O-antigen of the altered LPS. An antiserum raised to the altered LPS from strain DH1(pPM2217 (rfbX::Tn1725)) was found to cross-react with nearly all S. flexneri serotypes, and with the altered LPS produced by other DH1 strains harbouring plasmids with different rfb mutations, as described above. The reactivity of the altered LPS with a panel of monoclonal antibodies specific for various S. flexneri O-antigen type and group antigens demonstrated that their O-antigen components were closely related to that of S. flexneri serotype 4. The RfbF and RfbG proteins were shown to have similarity to rhamnose transferases, and we identified a motif common to the N-termini of 6-deoxy-hexose nucleotide sugar transferases. We propose that the E. coli K-12 strains harbouring the mutated S. flexneri rfb genes produce LPS with a hybrid O-antigen as a consequence of inactivation of RfbF and complementation by an E. coli K-12 gene product. Analysis of the genetic and immunochemical data suggested a possible structure for the O-antigen component of the altered LPS.     

Function of the rfb gene cluster and the rfe gene in the synthesis of O antigen by Shigella dysenteriae 1

A plasmid that included both an 8.9 kb chromosomal DNA insert containing genes from the rfb cluster of Shigella dysenteriae 1 and a smaller insert containing the rfp gene from a S. dysenteriae 1 multicopy plasmid resulted in efficient expression of O antigen in an rfb-deleted strain of Escherichia coli K-12. Eight genes were identified in the rfb fragment: the rfbB-CAD cluster which encodes dTDP-rhamnose synthesis, rfbX which encodes a hydrophobic protein involved in assembly of the O antigen, rfc which encodes the O antigen polymerase, and two sugar transferase genes. The production of an O antigen also required the E. coli K-12 rfe gene, which is known to encode a transferase which adds N-acetyl-glucosamine phosphate to the carrier lipid unde-caprenol phosphate. Thus Rfe protein appears to function as an analogue of the Salmonella RfbP protein to provide the first sugar of the O unit. Functional analysis of the other genes was facilitated by the fact that partial O units of one, two or three sugars were efficiently transferred to the lipopolysaccharide core. This analysis indicated that the plasmid-encoded Rfp protein is the transferase that adds the second sugar of the O unit while the two rfb transferases add the distal sugars to make an O antigen whose structure is (Rha–Rha–Gal–GlcNAc)n. The use of the rfe gene product as the transferase that adds the first sugar of an O unit is a novel mechanism which may be used for the synthesis of other enteric O antigens.     

Ectopic Gene Conversions in Four <Emphasis Type="BoldItalic">Escherichia coli</Emphasis> Genomes: Increased Recombination in Pathogenic Strains

We characterized the ectopic gene conversions in the genomes of the K-12 MG1655, O157:H7 Sakai, O157:H7 EDL933, and CFT073 strains of E coli. Compared to the three pathogenic strains, the K-12 strain has a much smaller number of gene families, its gene families contain fewer genes, and gene conversions are less frequent. Whereas the three pathogenic strains have gene conversions covering hundreds of nucleotides when their flanking regions have as little as 50% similarity, flanking region similarity of at least 94% on both sides of the converted region is required to observe conversions of more than 87 nucleotides in the K-12 strain. Recombination is therefore more frequent and requires less sequence similarity in the three pathogenic strains than in K-12. This higher recombination level might be due to mutations in some of their mismatch-repair genes. In contrast with the gene conversions present in the yeast genome, the gene conversions found in the E. coli genomes do not occur more frequently between duplicated genes that are close to one another than between duplicated genes that are far apart and are randomly distributed along the length of the genes. In E. coli, gene conversions are not more frequent near the origin of replication. However, they do occur more frequently near the terminus of replication of the Sakai genome, where multigene family members are more abundant. This suggests that, in E. coli, gene conversions occur randomly between genes located in different chromosomal locations or located on different copies of the multiple chromosomes found in E. coli cells.     

Structural variation in the O-specific polysaccharides of Klebsiella pneumoniae serotype O1 and O8 lipopolysaccharide: evidence for clonal diversity in rfb genes

The O-polysaccharide fraction of the lipopolysaccharide from Klebsiella pneumoniae serotype O8 was found to comprise two galactose-containing homopolymers. Structural analysis, using chemical and high-field nuclear magnetic resonance (NMR) techniques, established that the K. pneumoniae O8 polysaccharides are composed of the linear, disaccharide repeating units OAc 1 2/6 →3)-β-d -Galf-(1 →3)-α- d -Galp-(1→d -Galactan I-OAc →3)-α-d -Galp-(1 →3)-β-d -Galp-(1→d -Galactan II. K. pneumoniae O8 mutant RFK-1 was isolated by resistance to phage KO1-2; strain RFK-1 expressed only d -galactan I-OAc. The ¹H- and ¹³C-NMR resonances from this O-polysaccharide indicate that all of the O-acetyl groups within the K. pneumoniae O8 polysaccharide are carried on d -galactan I and O-acetylation occurs only on the β- d -galactofuranose residues; 60% of the available β- d -galactofuranose residues are non-acetylated. The O-acetylation of the remaining residues is equally distributed between the O-2 and O-6 positions. The carbohydrate backbone structures in the O8 polysaccharide are identical to d -galactan I and II expressed by K. pneumoniae O1, accounting for the antigenic cross-reaction between strains belonging to serotypes O1 and O8. However, the O1 polysaccharides are not acetylated and the O-acetyl groups present in the K. pneumoniae serotype O8 polysaccharides provide a structural basis for their recognition as distinct serotypes. The rfb (O-polysaccharide biosynthesis) gene cluster of K. pneumoniae serotype O1 determines the synthesis of d -galactan I. rfb_Kpo1-specific gene probes were used to examine conservation in the rfb gene clusters of other K. pneumoniae serotypes which produce d -galactan I. Six O1 strains were examined and all showed hybridization with rfb_KpO1 probes under conditions of high stringency. Three serotype O2 strains produce d -galactan I and these strains also contained DNA sequences recognized by rfb_KpO1 probes under high stringency. The physical maps of these homologous rfb chromosomal regions showed some polymorphism. Surprisingly, the rfb_KpO8 region from K. pneumoniae serotype O8 was only recognized by rfb_KpO1 probes under low-stringency hybridization conditions, providing evidence for two substantially different clonal groups of rfb genes from K. pneumoniae strains with structurally related O-antigens.     

The lipopolysaccharide of recipient cells is a specific receptor for PilV proteins, selected by shufflon DNA rearrangement, in liquid matings with donors bearing the R64 plasmid

Shufflon DNA rearrangement selects one of seven PilV proteins with different C-terminal segments, which then becomes a minor component of the thin pili of Escherichia coli strains bearing the plasmid R64. The PilV proteins determine the recipient specificity in liquid matings. A recipient Escherichia coli K-12 strain was specifically recognized by the PilVA′, -C, and -C′ proteins, while E. coli B was recognized only by the PilVA′ protein. To identify specific PilV receptors in the recipient bacterial cells, R64 liquid matings were performed using various E. coli K-12 waa (rfa) mutants and E. coli B transformants as recipient cells. E. coli K-12 waa mutants lack receptors for specific PilV proteins. E. coli B cells carrying waaJ or waaJKL genes of E. coli K-12 were recognized by donors expressing the PilVC′ protein or the PilVC and -C′ proteins, respectively, in addition to the PilVA′ protein. Addition of E. coli K-12 or B lipopolysaccharide (LPS) specifically inhibited liquid matings. We conclude that the PilV proteins of the thin pili of R64-bearing donors recognize LPS molecules located on the surface of various recipient bacterial cells in liquid matings. Received: 2 September 1999 / Accepted: 18 November 1999     

Production of Monoclonal Antibody Discriminating Serological Difference in Escherichia coli O9 and O9a Polysaccharides

A monoclonal antibody (mAb) with a unique antigenic specificity against Escherichia coli O9 was produced. The O9a mAb was reactive with a part of the strains in E. coli O9. The O9a mAb did not react with LPS from the E. coli O9 test strain Bi316-42. The distribution of the antigen defined by the O9a mAb in E. coli O9 was consistent with that of E. coli O9a present in E. coli O9 strains. The chemical structure of the repeating unit of the O-specific polysaccharide detected by the mAb was demonstrated to be a mannotetraose by two-dimensional nuclear magnetic resonance spectroscopy. It was confirmed that the mAb recognized E. coli O9a serotype in E. coli O9 serotype strains, suggesting that E. coli O9a serotype might be a dominant strain in E. coli O9.     

Generation of Escherichia coli O9a Serotype, a Subtype of E. coli O9, by Transfer of the wb* Gene Cluster of Klebsiella O3 into E. coli via Recombination

Genetic characterization of the wb* gene in a series of Escherichia coli and Klebsiella strains possessing the mannose homopolymer as the O-specific polysaccharide was carried out. The partial nucleotide sequences and PCR-restriction fragment length polymorphism analysis suggested that E. coli serotype O9a, a subtype of E. coli O9, might have been generated by the insertion of the Klebsiella O3 wb* gene into a certain E. coli strain.     

Development of Primers to O-Antigen Biosynthesis Genes for Specific Detection of Escherichia coli O157 by PCR

The chemical composition of each O-antigen subunit in gram-negative bacteria is a reflection of the unique DNA sequences within each rfb operon. By characterizing DNA sequences contained with each rfb operon, a diagnostic serotype-specific probe to Escherichia coli O serotypes that are commonly associated with bacterial infections can be generated. Recently, from an E. coli O157:H7 cosmid library, O-antigen-positive cosmids were identified with O157-specific antisera. By using the cosmid DNAs as probes, several DNA fragments which were unique to E. coli O157 serotypes were identified by Southern analysis. Several of these DNA fragments were subcloned from O157-antigen-positive cosmids and served as DNA probes in Southern analysis. One DNA fragment within plasmid pDS306 which was specific for E. coli O157 serotypes was identified by Southern analysis. The DNA sequence for this plasmid revealed homology to two rfb genes, the first of which encodes a GDP-mannose dehydratase. These rfb genes were similar to O-antigen biosynthesis genes in Vibrio cholerae and Yersinia enterocolitica serotype O:8. An oligonucleotide primer pair was designed to amplify a 420-bp DNA fragment from E. coli O157 serotypes. The PCR test was specific for E. coli O157 serotypes. PCR detected as few as 10 cells with the O157-specific rfb oligonucleotide primers. Coupled with current enrichment protocols, O157 serotyping by PCR will provide a rapid, specific, and sensitive method for identifying E. coli O157.     

Sequence of the E. coli O104 antigen gene cluster and identification of O104 specific genes

The Escherichia coli O104 polysaccharide is an important antigen, which contains sialic acid and is often associated with EHEC clones. Sialic acid is a component of many animal tissues, and its presence in bacterial polysaccharides may contribute to bacterial pathogenicity. We sequenced the genes responsible for O104 antigen synthesis and have found genes which from their sequences are identified as an O antigen polymerase gene, an O antigen flippase gene, three CMP-sialic acid synthesis genes, and three potential glycosyl transferase genes. The E. coli K9 group IB capsular antigen has the same structure as the O104 O antigen, and we find using gene by gene PCR that the K9 gene cluster is essentially the same as that for O104. It appears that the distinction between presence as group IB capsule or O antigen for this structure does not involve any difference in genes present in the O antigen gene cluster. By PCR testing against representative strains for the 166 E. coli O antigens and some randomly selected Gram-negative bacteria, we identified three O antigen genes which are highly specific to O104/K9. This work provides the basis for a sensitive test for rapid detection of O104 E. coli. This is important both for decisions on patient care as early treatment may reduce the risk of life-threatening complications and for a faster response in control of food borne outbreaks.     

Genetic studies of the ribosomal proteins in Escherichia coli. 7. Mapping of several ribosomal protein components by transduction experiments between different strains of Escherichia coli

Summary Two 50s (50-10 and 50-12) and two 30s (30-4 and 30-7) ribosomal proteins could be distinguished between Shigella dysenteriae Sh/s and Escherichia coli K-12 JC411 with CMC column chromatography. On the other hand, E. coli K-12 AT2472 was shown to have a 30s ribosomal protein, 30-6(AT), which is specific to this strain and distinguishable from 30-6 of other E. coli K-12 strains. Transduction experiments by phage Plkc between Sh. dysenteriae Sh/s and E. coli ATSPCO1, a spectinomycin resistant mutant derived from AT2472 in which the 30-4 protein is altered, indicated that the genes specifying the above five ribosomal protein components are located in the streptomycin region on the E. coli chromosome.The gene order for three 50s (50-8, 50-10 and 50-12) and three 30s [str (30-?), 30-4 and 30-6] ribosomal proteins on the chromosome was determined by transduction technique between Sh. dysenteriae Sh/s and E. coli ATSPC01, between E. coli ATSPC01 and E. coli ER05 (an erythromycin resistant strain in which the 50-8 protein is altered), and between Sh. dysenteriae Sh/s and E. coli ERSPC14 (str ^s spc ^r ery ^r), respectively. It was found that these protein genes are arranged on the chromosome in the order of str (30-?)-30-4-30-6-50-8-50-10-50-12.     

Construction and characterization of isogenic O-antigen variants of Salmonella typhi

A 7.5 kb Kpnl-generated fragment, from within the rfb cluster of Salmonella typhimurium LT2 that encodes abequose synthase (the rfbJ gene) which is necessary for O4 antigen synthesis, and flanking sequences, was inserted into a suicide vector. Using allelic exchange techniques, these rfb sequences of S. typhimurium were integrated into the rfb clusters of wild-type Salmonella typhi Vi-positive strain ISP 1820 (i.e. serotype 09,12; Vi⁺ H-d), S. typhi Vi-negative strain H400 (i.e. serotype 09,12; Vi⁻; H-d), and a double aro mutant of S. typhi ISP 1820, strain CVD 906, resulting in the isolation of strains H325, H404 and CVD 906-O4, respectively. Immunoblot analysis of lipopolysaccharide (LPS) purified from H325, H404 and CVD 906-O4 demonstrated that these 8trains express the 04 antigen (an abequose residue) in place of the O9 antigen (a tyvelose residue) in the LPS molecule. Hence, the serotype of H325 is O4,12; Vi⁺; H-d and the serotype of H404 is O4,12; Vi⁻; H-d. DNA hybridization analysis of chromosomal DNA from H325, H404 and CVD 906-O4 confirmed that a precise recombination event within sequences flanking rfbSE of S. typhi (which encodes the enzymes necessary for cytidine diphosphate-tyvelose synthesis) resulted in replacement of rfbSE with rfbJ (which encodes abequose synthase and is necessary for O4 synthesis) of S. typhimurium in strains H325, H404 and CVD 906-O4. The resistance of each strain to the bactericidal effects of guinea-pig serum (GPC) was assessed. Whereas ISP 1820, H325 and H404 exhibit similar resistance patterns in GPC, strain H400 is sensitive to the bactericidal effects of GPC. The results suggest that the development of the O-antigen serotype diversity of Salmonella is probably the result of both sequence divergence and recombination     

Genetic Transfer of Salmonella typhimurium and Escherichia coli Lipopolysaccharide Antigens to Escherichia coli K-12

Escherichia coli K-12 varkappa971 was crossed with a smooth Salmonella typhimurium donor, HfrK6, which transfers early the ilv-linked rfa region determining lipopolysaccharide (LPS) core structure. Two ilv(+) hybrids differing in their response to the LPS-specific phages FO and C21 were then crossed with S. typhimurium HfrK9, which transfers early the rfb gene cluster determining O repeat unit structure. Most recombinants selected for his(+) (near rfb) were agglutinated by Salmonella factor 4 antiserum. Transfer of an F' factor (FS400) carrying the rfb-his region of S. typhimurium to the same two ilv(+) hybrids gave similar results. LPS extracted from two ilv(+),his(+), factor 4-positive hybrids contained abequose, the immunodominant sugar for factor 4 specificity. By contrast, his(+) hybrids obtained from varkappa971 itself by similar HfrK9 and F'FS400 crosses were not agglutinated by factor 4 antiserum, indicating that the parental E. coli varkappa971 does not have the capacity to attach Salmonella O repeat units to its LPS core. It is concluded that the Salmonella rfb genes are expressed only in E. coli varkappa971 hybrids which have also acquired ilv-linked genes (presumably rfa genes affecting core structure or O-translocase ability, or both) from a S. typhimurium donor. When E. coli varkappa971 was crossed with a smooth E. coli donor, Hfr59, of serotype O8, which transfers his early, most his(+) recombinants were agglutinated by E. coli O8 antiserum and lysed by the O8-specific phage, Omega8. This suggests that, although the parental E. coli K-12 strain varkappa971 cannot attach Salmonella-specific repeat units to its LPS core, it does have the capacity to attach E. coli O8-specific repeat units.     

Overexpression of Arylsulfate Sulfotransferase as Fusion Protein with GlutathioneS-Transferase

A procedure has been developed for the overexpression and purification of milligram quantities of theKlebsiellaK-36 arylsulfate sulfotransferase (ASST). The structural gene was amplified by means of a polymerase chain reaction (PCR) technique and inserted into the plasmid vector pGEX-3X. The plasmid pGEX-100, carrying theKlebsiellaK-36astAstructural gene under the control of theEscherichia coli tacpromoter, was transformed into theE. colistrain BL21 (DE3). The ASST was produced inE. colias a fusion with glutathioneS-transferase. Conditions for protein production, isolation on glutathione Sepharose 4B, and Xa cleavage to generate active ASST were developed. The purification yielded approximately 0.7 mg of pure enzyme per liter of bacterial culture. Kinetic analysis of the overexpressed enzyme indicated that it had kinetic properties almost the same as those of the enzyme purified fromKlebsiellaK-36 cells. The purification procedure was very rapid and is suitable for obtaining considerable amounts of enzyme at a relatively high yield compared with its purifying method from the culture of theKlebsiellaK-36 strain.     

Partial deletion of the cloned rfb gene of Escherichia coli O9 results in synthesis of a new O-antigenic lipopolysaccharide.

The rfb gene, involved in the synthesis of the O-specific polysaccharide (a mannose homopolymer) of Escherichia coli O9 lipopolysaccharide (LPS), was cloned in E. coli K-12 strains. The O9-specific polysaccharide covalently linked to the R core of K-12 was extracted from the K-12 strains harboring the O9 rfb gene. All the other genes required for the synthesis of rfe-dependent LPS are therefore considered to be present in the K-12 strains. It was found that bacteria harboring some clones with deletions of the ca. 20-kilobase-pair (kbp) BglII-StuI fragment no longer synthesized the O9-specific polysaccharide. However, bacteria harboring clones del 21, del 22, and del 25, which carry deletions of the 10-kbp PstI-StuI fragment, synthesized an O-specific polysaccharide antigenically distinct from E. coli O9 LPS. Although this new O-specific polysaccharide consisted solely of mannose and the mannose residues were combined only through alpha-1,2 linkage, it was still composed of a repeating oligosaccharide unit, possibly a trisaccharide unit,----2)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----. It is therefore likely that this new O-specific polysaccharide was derived from a part of the O9-specific polysaccharide----3)alpha Man-(1----3)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----2)alpha Man-(1----and that the deleted part of the clones was responsible for the synthesis of alpha-1,3 linkages of the O9-specific polysaccharide.     

Polysaccharides cellulose, poly-beta-1,6-n-acetyl-D-glucosamine, and colanic acid are required for optimal binding of Escherichia coli O157:H7 strains to alfalfa sprouts and K-12 strains to plastic but not for binding to epithelial cells

When Escherichia coli O157:H7 bacteria are added to alfalfa sprouts growing in water, the bacteria bind tightly to the sprouts. In contrast, laboratory K-12 strains of E. coli do not bind to sprouts under similar conditions. The roles of E. coli O157:H7 lipopolysaccharide (LPS), capsular polysaccharide, and exopolysaccharides in binding to sprouts were examined. An LPS mutant had no effect on the binding of the pathogenic strain. Cellulose synthase mutants showed a significant reduction in binding; colanic acid mutants were more severely reduced, and binding by poly-beta-1,6-N-acetylglucosamine (PGA) mutants was barely detectable. The addition of a plasmid carrying a cellulose synthase gene to K-12 strains allowed them to bind to sprouts. A plasmid carrying the Bps biosynthesis genes had only a marginal effect on the binding of K-12 bacteria. However, the introduction of the same plasmid allowed Sinorhizobium meliloti and a nonbinding mutant of Agrobacterium tumefaciens to bind to tomato root segments. These results suggest that although multiple redundant protein adhesins are involved in the binding of E. coli O157:H7 to sprouts, the polysaccharides required for binding are not redundant and each polysaccharide may play a distinct role. PGA, colanic acid, and cellulose were also required for biofilm formation by a K-12 strain on plastic, but not for the binding of E. coli O157:H7 to mammalian cells.     

Development of an Allele-Specific PCR Assay for Simultaneous Sero-Typing of Avian Pathogenic Escherichia coli Predominant O1, O2, O18 and O78 Strains

Systemic infections by avian pathogenic Escherichia coli (APEC) are economically devastating to poultry industries worldwide. E. coli strains belonging to serotypes O1, O2, O18 and O78 are preferentially associated with avian colibacillosis. The rfb gene cluster controlling O antigen synthesis is usually various among different E. coli serotypes. In present study, the rfb gene clusters of E. coli serotypes O1, O2, O18 and O78 were characterized and compared. Based on the serotype-specific genes in rfb gene cluster, an allele-specific polymerase chain reaction (PCR) assay was developed. This PCR assay was highly specific and reliable for sero-typing of APEC O1, O2, O18 and O78 strains. The sensitivity of the assay was determined as 10 pg DNA or 10 colony forming units (CFUs) bacteria for serotypes O2 and O18 strains, and 500 pg DNA or 1,000 CFUs bacteria for serotypes O1 and O78 strains. Using this PCR system, APEC isolates and the infected tissue samples were categorized successfully. Furthermore, it was able to differentiate the serotypes for the samples with multi-agglutination in the traditional serum agglutination assay. Therefore, the allele-specific PCR is more simple, rapid and accurate assay for APEC diagnosis, epidemiologic study and vaccine development.     

Temperature-sensitive,lipopolysaccharide-deficient mutants of Salmonella typhimurium

Two mutants of Salmonella typhimurium LT2, which were temperature-sensitive for lipopolysaccharide (LPS) synthesis, were isolated from a galE ^- strain based on their resistance to phage C21 and sensitivity to sodium deoxycholate at 42°C. They produced LPS of chemotype Rc at 30°C and deep-rough LPS at 42°C. P22-mediated transductional analysis showed that the mutations responsible for temperature sensitivity are located in the rfa cluster where several genes involved in the synthesis of the LPS core are mapped. A plasmid, carrying rfaC, D and F genes of Escherichia coli K-12, complemented these mutations. These genes are responsible for the synthesis of the inner-core region of the LPS molecule. This indicates that genetic defects in these temperature-sensitive mutants affect the inner-core region of LPS.     

Genome Sequences of Escherichia coli B strains REL606 and BL21(DE3)

Escherichia coli K-12 and B have been the subjects of classical experiments from which much of our understanding of molecular genetics has emerged. We present here complete genome sequences of two E. coli B strains, REL606, used in a long-term evolution experiment, and BL21(DE3), widely used to express recombinant proteins. The two genomes differ in length by 72,304 bp and have 426 single base pair differences, a seemingly large difference for laboratory strains having a common ancestor within the last 67 years. Transpositions by IS1 and IS150 have occurred in both lineages. Integration of the DE3 prophage in BL21(DE3) apparently displaced a defective prophage in the λ attachment site of B. As might have been anticipated from the many genetic and biochemical experiments comparing B and K-12 over the years, the B genomes are similar in size and organization to the genome of E. coli K-12 MG1655 and have > 99% sequence identity over ∼ 92% of their genomes. E. coli B and K-12 differ considerably in distribution of IS elements and in location and composition of larger mobile elements. An unexpected difference is the absence of a large cluster of flagella genes in B, due to a 41 kbp IS1-mediated deletion. Gene clusters that specify the LPS core, O antigen, and restriction enzymes differ substantially, presumably because of horizontal transfer. Comparative analysis of 32 independently isolated E. coli and Shigella genomes, both commensals and pathogenic strains, identifies a minimal set of genes in common plus many strain-specific genes that constitute a large E. coli pan-genome.