SummarySalmonella typhimurium causes enteric and systemic disease by invading the intestinal epithelium of the distal ileum, a process requiring the invasion genes of Salmonella pathogenicity island 1 (SPI-1). BarA, a sensor kinase postulated to interact with the response regulator SirA, is required for the expression of SPI-1 invasion genes. We found, however, that a barA null mutation had little effect on virulence using the mouse model for septicaemia. This confounding result led us to seek environmental signals present in the distal ileum that might supplant the need for BarA. We found that acetate restored the expression of invasion genes in the barA mutant, but had no effect on a sirA mutant. Acetate had its effect only at a pH that allowed its accumulation within the bacterial cytoplasm and not with the deletion of ackA and pta , the two genes required to produce acetylphosphate. These results suggest that the rising concentration of acetate in the distal ileum provides a signal for invasion gene expression by the production of acetyl-phosphate in the bacterial cytoplasm, a pathway that bypasses barA . We also found that a D D D D ( ackA-pta ) mutation alone had no effect on virulence but, in combination with D D D D ( barA ), it increased the oral LD 50 24-fold. Thus, the combined loss of the BarA-and acetate-dependent pathways is required to reduce virulence. Two other short-chain fatty acids (SCFA), propionate and butyrate, present in high concentrations in the caecum and colon, had effects opposite to those of acetate: neither restored invasion gene expression in the barA mutant, and both, in fact, reduced expression in the wild-type strain. Further, a combination of SCFAs found in the distal ileum restored invasion gene expression in the barA mutant, whereas colonic conditions failed to do so and also reduced expression in the wild-type strain. These results suggest that the concentration and composition of SCFAs in the distal ileum provide a signal for productive infection by Salmonella , whereas those of the large intestine inhibit invasion.
No abstract
Acetate and formate are major fermentation products of Escherichia coli. Below pH 7, the balance shifts to lactate; an oversupply of acetate or formate retards growth. E. coli W3110 was grown with aeration in potassium-modified Luria broth buffered at pH 6.7 in the presence or absence of added acetate or formate, and the protein profiles were compared by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Acetate increased the steady-state expression levels of 37 proteins, including periplasmic transporters for amino acids and peptides (ArtI, FliY, OppA, and ProX), metabolic enzymes (YfiD and GatY), the RpoS growth phase regulon, and the autoinducer synthesis protein LuxS. Acetate repressed 17 proteins, among them phosphotransferase (Pta). An ackA-pta deletion, which nearly eliminates interconversion between acetate and acetyl-coenzyme A (acetyl-CoA), led to elevated basal levels of 16 of the acetate-inducible proteins, including the RpoS regulon. Consistent with RpoS activation, the ackA-pta strain also showed constitutive extreme-acid resistance. Formate, however, repressed 10 of the acetate-inducible proteins, including the RpoS regulon. Ten of the proteins with elevated basal levels in the ackA-pta strain were repressed by growth of the mutant with formate; thus, the formate response took precedence over the loss of the ackA-pta pathway. The similar effects of exogenous acetate and the ackA-pta deletion, and the opposite effect of formate, could have several causes; one possibility is that the excess buildup of acetyl-CoA upregulates stress proteins but excess formate depletes acetyl-CoA and downregulates these proteins.
A Salmonella typhimurium chromosomal deletion removing ≈19 kb of DNA at centisome 65 reduces invasion of cultured epithelial cells as well as the expression of lacZY operon fusions to several genes required for the invasive phenotype. As the deleted region contains no genes previously known to affect Salmonella invasion, we investigated the roles of individual genes in the deleted region using a combination of cloning, complementation and directed mutation. We find that the deletion includes two unrelated regulatory genes. One is the Salmonella homologue of Escherichia coli barA (airS ), which encodes a member of the multistep phosphorelay subgroup of two‐component sensor kinases. The action of BarA is coupled to that of SirA, a member of the phosphorylated response regulator family of proteins, and includes both HilA‐dependent and HilA‐independent components. The other regulatory gene removed by the deletion is the Salmonella homologue of E. coli csrB, which specifies a regulatory RNA implicated in controlling specific message turnover in E. coli. These results identify a protein that is likely to play a key role in the environmental control of Salmonella invasion gene expression, and they also suggest that transcriptional control of invasion genes could be subject to refinement at the level of message turnover.
Genes can be regulated by the interaction of proteins with specific sequences in DNA (1). Proteins called repressors specifically turn off transcription, and positive regulatory proteins enhance specific transcription. In this article we describe the complete sequence of two control regions in the DNA of a bacteriophage. We show how interaction of these sequences with a regulatory protein mediates intricate patterns of gene regulation. In particular, we show that one of these sequences is arranged so that a single protein can function both as a positive and a negative regulator. Moreover, we argue that this same control region may contain information important for posttranscriptional control.
Cystic fibrosis tnsmembrane conductance regulator (CFTR) generates cAMP-regulated channels; mutations in CFFR cause defective Cl-channel function in cystic fibrosis epithelia. We used the patch-chmp technique to determine the single channel properties of Cl-channels in cells expressing recombinant CFIR. In cell-attached patches, an increase in cellular cAMP reversibly activated low conductance Cl-channels. cAMP-dependent regulation is due to phosphorylation, because the catalytic subunit of cAMP-dependent protein kinase plus ATP reversibly activated the channel in excised, cell-free patches of membrane. In symmetrical a-solutions, the channel had a channel conductance of 10.4±0.2 (a = 7) pS and a linear current-voltage relation. The channel was more permeable to Cla than to I-and showed no appreciable time-dependent voltage effects. These biophysical properties are consistent with macroscopic studies of a-channels in single cells expressing CFTR and in the apical membrane of secretory epithelia. Identification of the single channel characteristics of CFIR-generated channels allows further studies oftheir regulation and the mechanism of ion permeation. (J. Cli,. Invest.
DNA polymerase III holoenzyme is a multiprotein complex responsible for the bulk of chromosomal replication in Escherichia coli and Salmonella typhimurium. The catalytic core of the holoenzyme is an arO heterotrimer that incorporates both a polymerase subunit ((; dnaE) and a proofreading subunit (£; dnaQ). The role of 0 is unknown. Here, we describe a null mutation of holE, the gene for 0. A strain carrying this mutation was fully viable and displayed no mutant phenotype. In contrast, a dnaQ null mutant exhibited poor growth, chronic SOS induction, and an elevated spontaneous mutation rate, like dnaQ null mutants of S. typhimurium described previously. The poor growth was suppressible by a mutation affecting a which was identical to a suppressor mutation identified in S. typhimurium. A double mutant null for both holE and dnaQ was indistinguishable from the dnaQ single mutant. These results show that the 0 subunit is dispensable in both dnaQ+ and mutant dnaQ backgrounds, and that the phenotype of e mutants cannot be explained on the basis of interference with 0 function.
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