Cloning and analysis of the sfrB (sex factor repression) gene of Escherichia coli K-12

Functional specialization of transcription elongation factors

Elongation factors NusG and RfaH evolved from a common ancestor and utilize the same binding site on RNA polymerase (RNAP) to modulate transcription. However, although NusG associates with RNAP transcribing most Escherichia coli genes, RfaH regulates just a few operons containing ops, a DNA sequence that mediates RfaH recruitment. Here, we describe the mechanism by which this specificity is maintained. We observe that RfaH action is indeed restricted to those several operons that are devoid of NusG in vivo. We also show that RfaH and NusG compete for their effects on transcript elongation and termination in vitro. Our data argue that RfaH recognizes its DNA target even in the presence of NusG. Once recruited, RfaH remains stably associated with RNAP, thereby precluding NusG binding. We envision a pathway by which a specialized regulator has evolved in the background of its ubiquitous paralogue. We propose that RfaH and NusG may have opposite regulatory functions: although NusG appears to function in concert with Rho, RfaH inhibits Rho action and activates the expression of poorly translated, frequently foreign genes.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Expression of the O antigen gene cluster is regulated by RfaH through the JUMPstart sequence

O antigen genes are clustered, with a JUMPstart sequence located upstream. JUMPstart is a 39-bp sequence, present upstream of many polysaccharide gene clusters and also upstream of haemolysin and F factor gene clusters. RfaH is known to regulate the expression of E. coli group II capsule, haemolysin, F factor and the outer core of lipopolysaccharide all of which have the JUMPstart sequence, and has been shown to function as a transcriptional antiterminator in some cases. Using lacZ fusions to genes in the O antigen gene cluster of Salmonella enterica serovar Typhimurium, we found that RfaH also regulates the expression of O antigen. We showed that RfaH enhances expression of the 18-kb O antigen gene cluster, with promoter-distal genes affected more dramatically. We also showed that the JUMPstart sequence was required for RfaH function.

Promoter region of the Escherichia coli O7-specific lipopolysaccharide gene cluster: structural and functional characterization of an upstream untranslated mRNA sequence

We report the identification of the promoter region of the Escherichia coli O7-specific lipopolysaccharide (LPS) gene cluster (wbEcO7). Typical -10 and -35 sequences were found to be located in the intervening region between galF and rlmB, the first gene of the wbEcO7 cluster. Data from RNase protection experiments revealed the existence of an untranslated leader mRNA segment of 173 bp, including the JUMPStart and two ops sequences. We characterized the structure of this leader mRNA by using the program Mfold and a combination of nested and internal deletions transcriptionally fused to a promoterless lac operon. Our results indicated that the leader mRNA may fold into a series of complex stem-loop structures, one of which includes the JUMPStart element. We have also found that one of the ops sequences resides on the predicted stem and the other resides on the loop region, and we confirmed that these sequences are essential for the RfaH-mediated regulation of the O polysaccharide cluster. A very similar stem-loop structure could be predicted in the promoter region of the LPS core operon encoding the waaQGPSBIJYZK genes. We observed another predicted stem-loop, located immediately downstream from the wbEcO7 transcription initiation site, which appeared to be involved in premature termination of transcription. This putative stem-loop is common to many other O polysaccharide gene clusters but is not present in core oligosaccharide genes. wbEcO7-lac transcriptional fusions in single copy numbers were also used to determine the effects of various environmental cues in the transcriptional regulation of O polysaccharide synthesis. No effects were detected with temperature, osmolarity, Mg2+ concentration, and drugs inducing changes in DNA supercoiling. We therefore conclude that the wbEcO7 promoter activity may be constitutive and that regulation takes place at the level of elongation of the mRNA in a RfaH-mediated manner.

Enhancing transcription through the Escherichia coli hemolysin operon, hlyCABD: RfaH and upstream JUMPStart DNA sequences function together via a postinitiation mechanism

Escherichia coli hlyCABD operons encode the polypeptide component (HlyA) of an extracellular cytolytic toxin as well as proteins required for its acylation (HlyC) and sec-independent secretion (HlyBD). The E. coli protein RfaH is required for wild-type hemolysin expression at the level of hlyCABD transcript elongation (J. A. Leeds and R. A. Welch, J. Bacteriol. 178:1850-1857, 1996). RfaH is also required for the transcription of wild-type levels of mRNA from promoter-distal genes in the rfaQ-K, traY-Z, and rplK-rpoC gene clusters, supporting the role for RfaH in transcriptional elongation. All or portions of a common 39-bp sequence termed JUMPStart are present in the untranslated regions of RfaH-enhanced operons. In this study, we tested the model that the JUMPStart sequence and RfaH are part of the same functional pathway. We examined the effect of JUMPStart deletion mutations within the untranslated leader of a chromosomally derived hlyCABD operon on hly RNA and HlyA protein levels in either wild-type or rfaH null mutant E. coli. We also provide in vivo physical evidence that is consistent with RNA polymerase pausing at the wild-type JUMPStart sequences.

RfaH enhances elongation of Escherichia coli hlyCABD mRNA

Escherichia coli hlyCABD operons encode the polypeptide component (Hly A) of an extracellular cytolytic toxin, as well as proteins required for its acylation (HlyC) and sec-independent secretion (HlyBD). Previous reports suggested that the E. coli protein RfaH is required for wild-type hemolysin expression, either by positively activating hly transcript initiation (M. J. A. Bailey, V. Koronakis, T. Schmoll, and C. Hughes, Mol. Microbiol. 6:1003-1012, 1992) or by promoting proper insertion of hemolysin export machinery in the E. coli outer membrane (C. Wandersman and S. Letoffe, Mol. Microbiol. 7:141-150, 1993). RfaH is also required for wild-type levels of mRNA transcribed from promoter-distal genes in the rfaQ-K, traY-Z, and rplK-rpoC gene clusters, suggesting that RfaH is a transcriptional antiterminator. We tested these models by analyzing the effects of rfaH mutations on hlyCABD mRNA synthesis and decay, HlyA protein levels, and hemolytic activity. The model system included a uropathogenic strain of E. coli harboring hlyCABD on the chromosome and E. coli K-12 transformed with the hlyCABD operon on a recombinant plasmid. Our results suggest that RfaH enhances hlyCABD transcript elongation, consistent with the model of RfaH involvement in transcriptional antitermination in E. coli. We also demonstrated that RfaH increases toxin efficacy. Modulation of hemolysin activity may be an indirect effect of RfaH-dependent E. coli outer membrane chemotype, which is consistent with the model of lipopolysaccharide involvement in hemolytic activity.

Genetics of lipopolysaccharide biosynthesis in enteric bacteria

From a historical perspective, the study of both the biochemistry and the genetics of lipopolysaccharide (LPS) synthesis began with the enteric bacteria. These organisms have again come to the forefront as the blocks of genes involved in LPS synthesis have been sequenced and analyzed. A number of new and unanticipated genes were found in these clusters, indicating a complexity of the biochemical pathways which was not predicted from the older studies. One of the most dramatic areas of LPS research has been the elucidation of the lipid A biosynthetic pathway. Four of the genes in this pathway have now been identified and sequenced, and three of them are located in a complex operon which also contains genes involved in DNA and phospholipid synthesis. The rfa gene cluster, which contains many of the genes for LPS core synthesis, includes at least 17 genes. One of the remarkable findings in this cluster is a group of several genes which appear to be involved in the synthesis of alternate rough core species which are modified so that they cannot be acceptors for O-specific polysaccharides. The rfb gene clusters which encode O-antigen synthesis have been sequenced from a number of serotypes and exhibit the genetic polymorphism anticipated on the basis of the chemical complexity of the O antigens. These clusters appear to have originated by the exchange of blocks of genes among ancestral organisms. Among the large number of LPS genes which have now been sequenced from these rfa and rfb clusters, there are none which encode proteins that appear to be secreted across the cytoplasmic membrane and surprisingly few which encode integral membrane proteins or proteins with extensive hydrophobic domains. These data, together with sequence comparison and complementation experiments across strain and species lines, suggest that the LPS biosynthetic enzymes may be organized into clusters on the inner surface of the cytoplasmic membrane which are organized around a few key membrane proteins.

Genetics of lipopolysaccharide biosynthesis in enteric bacteria

From a historical perspective, the study of both the biochemistry and the genetics of lipopolysaccharide (LPS) synthesis began with the enteric bacteria. These organisms have again come to the forefront as the blocks of genes involved in LPS synthesis have been sequenced and analyzed. A number of new and unanticipated genes were found in these clusters, indicating a complexity of the biochemical pathways which was not predicted from the older studies. One of the most dramatic areas of LPS research has been the elucidation of the lipid A biosynthetic pathway. Four of the genes in this pathway have now been identified and sequenced, and three of them are located in a complex operon which also contains genes involved in DNA and phospholipid synthesis. The rfa gene cluster, which contains many of the genes for LPS core synthesis, includes at least 17 genes. One of the remarkable findings in this cluster is a group of several genes which appear to be involved in the synthesis of alternate rough core species which are modified so that they cannot be acceptors for O-specific polysaccharides. The rfb gene clusters which encode O-antigen synthesis have been sequenced from a number of serotypes and exhibit the genetic polymorphism anticipated on the basis of the chemical complexity of the O antigens. These clusters appear to have originated by the exchange of blocks of genes among ancestral organisms. Among the large number of LPS genes which have now been sequenced from these rfa and rfb clusters, there are none which encode proteins that appear to be secreted across the cytoplasmic membrane and surprisingly few which encode integral membrane proteins or proteins with extensive hydrophobic domains. These data, together with sequence comparison and complementation experiments across strain and species lines, suggest that the LPS biosynthetic enzymes may be organized into clusters on the inner surface of the cytoplasmic membrane which are organized around a few key membrane proteins.

Analysis of the Escherichia coli genome: DNA sequence of the region from 84.5 to 86.5 minutes

The DNA sequence of 91.4 kilobases of the Escherichia coli K-12 genome, spanning the region between rrnC at 84.5 minutes and rrnA at 86.5 minutes on the genetic map (85 to 87 percent on the physical map), is described. Analysis of this sequence identified 82 potential coding regions (open reading frames) covering 84 percent of the sequenced interval. The arrangement of these open reading frames, together with the consensus promoter sequences and terminator-like sequences found by computer searches, made it possible to assign them to proposed transcriptional units. More than half the open reading frames correlated with known genes or functions suggested by similarity to other sequences. Those remaining encode still unidentified proteins. The sequenced region also contains several RNA genes and two types of repeated sequence elements were found. Intergenic regions include three "gray holes," 0.6 to 0.8 kilobases, with no recognizable functions.

Comparison of lipopolysaccharide biosynthesis genes rfaK, rfaL, rfaY, and rfaZ of Escherichia coli K-12 and Salmonella typhimurium

Analysis of the sequence of a 4.3-kb region downstream of rfaJ revealed four genes. The first two of these, which encode proteins of 27,441 and 32,890 Da, were identified as rfaY and rfaZ by homology of the derived protein sequences of their products to the products of similar genes of Salmonella typhimurium. The amino acid sequences of proteins RfaY and RfaZ showed, respectively, 70 and 72% identity. Genes 3 and 4 were identified as rfaK and rfaL on the basis of size and position, but the derived amino acid sequences of the products of these genes showed very little similarity (about 12% identity) between Escherichia coli K-12 and S. typhimurium. The next gene in the cluster, rfaC, encodes a product which also shows strong protein sequence homology between E. coli K-12 and S. typhimurium, as do the rfaF and rfaD genes which lie beyond it. Thus, the rfa gene cluster appears to consist of two blocks of genes which are conserved flanking a central region of two genes which are not conserved between these species. Although the RfaL protein sequence is not conserved, hydropathy plots of the two RfaL species are nearly identical and indicate that this is a typical integral membrane protein with 10 or more potential transmembrane domains. We noted the similarity of the structure of the rfa gene cluster to that of the rfb gene cluster, which has now been sequenced in several Salmonella serovars. The rfb cluster also contains a gene which lies within a central nonconserved region and encodes an integral membrane protein similar to protein RfaL. We speculate that protein RfaL may interact in a strain- or species-specific way with one or more Rfb proteins in the expression of surface O antigen.

Escherichia coli HlyT protein, a transcriptional activator of haemolysin synthesis and secretion, is encoded by the rfaH (sfrB) locus required for expression of sex factor and lipopolysaccharide genes

Synthesis and secretion of the 110kDa haemolysin toxin of Escherichia coli and other pathogenic Gram-negative bacteria are governed by the four genes of the hly operon. We have identified, by transposon mutagenesis, an E. coli cellular locus, hlyT, required for the synthesis and secretion of haemolysin encoded in trans by intact hly operons carrying the hly upstream regulatory region. Mutation of the hlyT locus specifically reduced the level of hlyA structural gene transcript 20-100-fold and thus markedly lowered both intracellular and extracellular levels of the HlyA protein. Genetic and structural analysis of the hlyT locus mapped it at co-ordinate 3680 kbp (minute 87) on the chromosome adjacent to the fadBA operon, and identified it specifically as the rfaH (sfrB) locus which is required for transcription of the genes encoding synthesis of the sex pilus and also the lipopolysaccharide core for attachment of the O-antigen of E. coli and Salmonella. Expression of the hly operon in the E. coli hlyT mutant was restored in trans by both the hlyT and rfaH genes, suggesting that the rfaH gene is an important activator of regulon structures that are central to the fertility and virulence of these pathogenic bacteria. DNA sequencing of the hlyT locus identifies the HlyT/RfaH transcriptional activator as a protein of 162 amino acids (Mr 18325) which shows no identity to characterized transcription factors.

Effect of rfaH (sfrB) and temperature on expression of rfa genes of Escherichia coli K-12

In order to study the regulation of a large block of contiguous genes at the rfa locus of Escherichia coli K-12 which are involved in synthesis and modification of the lipopolysaccharide core, the transposon TnlacZ was used to generate in-frame lacZ fusions to the coding regions of five genes (rfaQ, -G, -P, -B and -J) within this block. The beta-galactosidase activity of strains in which these fusions had been crossed into the chromosomal rfa locus was significantly decreased when the rfaH11 (sfrB11) allele was introduced and was restored to wild-type levels when these strains were lysogenized with a lambda phage carrying wild-type rfaH. This indicates that the positive regulatory function encoded by rfaH is required throughout this block of genes. In addition, expression of the lacZ fusion to rfaJ was reduced by growth at 42 degrees C, and this correlated with a temperature-induced change in the electrophoretic profile of the core lipopolysaccharide.

Molecular analysis of lipooligosaccharide biosynthesis in Neisseria gonorrhoeae

A HindIII gene bank of Neisseria gonorrhoeae MUG116 was constructed in the cosmid vector pHC79. A cosmid (pSY81) was isolated that was able to convert N. gonorrhoeae FA5100 to reactivity with monoclonal antibody (MAb) 2-1-L8. Several MAb-reactive transformants were isolated and characterized with respect to lipooligosaccharide (LOS) production as analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, their ability to react with two other LOS-specific MAbs (3F11 and O6B4), and Southern blot analysis. Escherichia coli containing the clone had altered lipopolysaccharide expression as determined by electrophoretic analysis; however, no reactivity was seen with gonococcus-specific MAbs. The introduction of pSY81 into FA5100 had a pleiomorphic effect, giving rise to transformants having the full parental phenotype or transformants lacking reactivity to a combination of LOS-specific MAbs. Southern blot analysis indicated that the LOS biosynthetic mutation in FA5100 was not due to chromosomal rearrangement or large deletions.

Cosmid-derived map of E. coli strain BHB2600 in comparison to the map of strain W3110

A physical map for the genome of E. coli K12 strain BHB2600 was constructed by use of 570 cloned DNA elements (CDEs) withdrawn from a cosmid library. Dot blot hybridisation was applied to establish contig interrelations with subsequent fine mapping achieved by analysis of EcoR1 restriction patterns on Southern blots. The derived map covers nearly 95% of the E. coli genome resulting in 12 minor gaps. It may be compared to the almost complete map for strain W3110 of Kohara et al. (1). Except for one tiny gap (lpp,36.5') remaining gaps in BHB2600 do not coincide with those in W3110 so that both maps complement each other establishing an essentially complete clone represented map. Besides numerous minute differences (site and fragment gains and losses) both strains harbour at differing positions extended rearrangements flanked by mutually inverted repetitive elements, in our case insertion elements (IS1 and IS5).