Effects of global regulatory proteins and environmental conditions on fimbrial gene expression of F165(1) and F165(2) produced by Escherichia coli causing septicaemia in pigs

Structures of Escherichia coli DNA adenine methyltransferase (Dam) in complex with a non-GATC sequence: potential implications for methylation-independent transcriptional repression

DNA adenine methyltransferase (Dam) is widespread and conserved among the γ-proteobacteria. Methylation of the Ade in GATC sequences regulates diverse bacterial cell functions, including gene expression, mismatch repair and chromosome replication. Dam also controls virulence in many pathogenic Gram-negative bacteria. An unexplained and perplexing observation about Escherichia coli Dam (EcoDam) is that there is no obvious relationship between the genes that are transcriptionally responsive to Dam and the promoter-proximal presence of GATC sequences. Here, we demonstrate that EcoDam interacts with a 5-base pair non-cognate sequence distinct from GATC. The crystal structure of a non-cognate complex allowed us to identify a DNA binding element, GTYTA/TARAC (where Y = C/T and R = A/G). This element immediately flanks GATC sites in some Dam-regulated promoters, including the Pap operon which specifies pyelonephritis-associated pili. In addition, Dam interacts with near-cognate GATC sequences (i.e. 3/4-site ATC and GAT). Taken together, these results imply that Dam, in addition to being responsible for GATC methylation, could also function as a methylation-independent transcriptional repressor.

Monitoring F1651 P-like fimbria expression at the single-cell level reveals a highly heterogeneous phenotype

F1651 and the pyelonephritis-associated pili (Pap) are two members of the type P family of adhesive factors. They play a key role in establishing disease caused by extraintestinal pathogenic Escherichia coli (ExPEC) strains in animals and humans. Both F1651 and Pap are under the control of an epigenetic and reversible switch that defines the number of fimbriated (ON) and afimbriated (OFF) cells within a clonal population. Using the Gfp reporter system, we monitored in vitro the level of fluorescence intensity corresponding to the F1651 and Pap fimbrial synthesis. Monitoring individual Escherichia coli cells by flow cytometry and by real-time fluorescence microscopy, we identified cells associated with a low or high level of fluorescence intensity and a large amount of cells with partial levels of fluorescence, mostly present in the F1651 system. This mixed population identified through fluorescence intensity could be attributed to the high switching rate previously observed in F1651-positive bacteria. The fimbrial heterogeneous phenotype for these ExPEC could represent increased fitness in unpredictable environments. Our study illustrates that within the large repertoire of fimbrial variants such as the well-characterized Pap, F1651 is an exquisite example of regulatory expression that arms the bacterium with strategies for surviving in more than one particular environment.

Lrp-DNA complex stability determines the level of ON cells in type P fimbriae phase variation

F165(1) and the pyelonephritis-associated pili (Pap) are two members of the type P family of adhesive factors that play a key role in the establishment of disease caused by extraintestinal Escherichia coli (ExPEC) strains. They are both under the control of an epigenetic and reversible switch that defines the number of fimbriated (ON) and afimbriated (OFF) cells within a clonal population. Our present study demonstrates that the high level of ON cells found during F165(1) phase variation is due to altered stability of the DNA complex formed by the leucine-responsive regulatory protein (Lrp) at its repressor binding sites 1-3; after each cell cycle, complex formation is also modulated by the local regulator FooI (homologue to PapI) which promotes the transit of Lrp towards its activator binding sites 4-6. Furthermore, we identified two nucleotides (T490, G508) surrounding the Lrp binding site 1 that are critical to maintaining a high OFF to ON switch rate during F165(1) phase variation, as well as switching Pap fimbriae towards the OFF state.

Regulation of Fimbrial Expression

Fimbria-mediated interaction with the host elicits both innate and adaptive immune responses, and thus their expression may not always be beneficial in vivo. Furthermore, the metabolic drain of producing fimbriae is significant. It is not surprising, therefore, to find that fimbrial production in Escherichia coli and Salmonella enterica is under extensive environmental regulation. In many instances, fimbrial expression is regulated by phase variation, in which individual cells are capable of switching between fimbriate and afimbriate states to produce a mixed population. Mechanisms of phase variation vary considerably between different fimbriae and involve both genetic and epigenetic processes. Notwithstanding this, fimbrial expression is also sometimes controlled at the posttranscriptional level. In this chapter, we review key features of the regulation of fimbrial gene expression in E. coli and Salmonella. The occurrence and distribution of fimbrial operons vary significantly among E. coli pathovars and even among the many Salmonella serovars. Therefore, general principles are presented on the basis of detailed discussion of paradigms that have been extensively studied, including Pap, type 1 fimbriae, and curli. The roles of operon specific regulators like FimB or CsgD and of global regulatory proteins like Lrp, CpxR, and the histone-like proteins H-NS and IHF are reviewed as are the roles of sRNAs and of signalling nucleotide cyclic-di-GMP. Individual examples are discussed in detail to illustrate how the regulatory factors cooperate to allow tight control of expression of single operons. Molecular networks that allow coordinated expression between multiple fimbrial operons and with flagella in a single isolate are also presented. This chapter illustrates how adhesin expression is controlled, and the model systems also illustrate general regulatory principles germane to our overall understanding of bacterial gene regulation.

GATC flanking sequences regulate Dam activity: evidence for how Dam specificity may influence pap expression

Escherichia coli DNA adenine methyltransferase (Dam) plays essential roles in DNA replication, mismatch repair and gene regulation. The differential methylation by Dam of the two GATC sequences in the pap promoter regulates the expression of pili genes necessary for uropathogenic E.coli cellular adhesion. Dam processively methylates GATC sites in various DNA substrates, yet the two pap GATC sites are not processively methylated. We previously proposed that the flanking sequences surrounding the two pap GATC sites contribute to the enzyme's distributive methylation. We show here that replacement of the poorly methylated pap GATC sites with sites predicted to be processively methylated indeed results in an increase in Dam processivity. The increased processivity is due to a change in the methyltransfer kinetics and not the binding efficiency of Dam. A competition experiment in which the flanking sequences of only one pap GATC site were altered demonstrates that the GATC flanking sequences directly regulate the enzyme's catalytic efficiency. The GATC flanking sequences in Dam-regulated promoters in E.coli and other bacteria are similar to those in the pap promoter. Gene regulation from some of these promoters involves mechanisms and proteins that are quite different from those in the pap operon. Further, GATC sequences previously identified to remain unmethylated within the E.coli genome, but whose function remains largely unassigned, are flanked by sequences predicted to be poorly methylated. We conclude that the GATC flanking sequences may be critical for expression of pap and other Dam-regulated genes by affecting the activity of Dam at such sites and, thus, its processivity. A model is proposed, illustrating how the sequences flanking the GATC sites in Dam-regulated promoters may contribute to this epigenetic mechanism of gene expression, and how flanking sequences contribute to the diverse biological roles of Dam.

Influence of L-leucine and L-alanine on Lrp regulation of foo, coding for F1651, a Pap homologue

The foo operon encodes F165 1 fimbriae that belong to the P-regulatory family and are synthesized by septicemic Escherichia coli. Using an Lrp-deficient host and the lrp gene cloned under the arabinose pBAD promoter, we demonstrated that foo was transcribed proportionally to the amount of Lrp synthesized. L-leucine and L-alanine decreased drastically the steady-state transcription of foo and modified phase variation, independently of the presence of FooI. Specific mutations in the C-terminal region of Lrp reduced or abolished the repressive effect of these amino acids, indicating that they modulate F165 1 by affecting Lrp.

Influence of environmental cues on transcriptional regulation of foo and clp coding for F165(1) and CS31A adhesins in Escherichia coli

F165(1) (foo) and CS31A (clp) are bacterial adhesins synthesized by Escherichia coli strains associated with diarrhea and septicemia in piglets and calves. They belong to the P-regulatory family and as such are subject to a phase variation control mediated by Lrp (leucine responsive regulatory protein) and regulators homologous to PapI. Analysis of expression of transcriptional fusions between the fooB or fooI promoters and lacZ showed that Lrp is an activator of foo and fooI transcription, whereas it represses clp transcription. Furthermore, foo phase variation leads to a large majority of phase-ON cells, whereas clp phase variation leads to a majority of phase-OFF cells. We compared the influence of several environmental cues on foo and clp expression, with special attention to the effects of leucine and alanine known to be mediated by Lrp. Inhibition or significant repression of foo and clp transcription was observed at low temperature, in LB medium, and in the presence of glucose, alanine, or leucine. Glucose repression of foo but not of clp was totally relieved by addition of cAMP. Osmolarity and pH had little effect. Alanine but not leucine, and LB medium inhibited foo and clp phase variation, locking cells in the OFF phase. Low temperature inhibited clp phase variation and altered the switch frequency of foo phase variation, leading to more phase-OFF cells. Glucose altered the phase variation of both operons, increasing the number of phase-OFF cells in the population. The regulation pattern of foo and clp is consistent with F165(1) and CS31A production in low nutrient environments, even at moderately acidic pH or high osmolarity.

Leucine-responsive regulatory protein-mediated repression of clp (encoding CS31A) expression by L-leucine and L-alanine in Escherichia coli

CS31A produced by septicemic and diarrheic Escherichia coli belongs to the Pap-regulatory family of adhesive factors, which are under methylation-dependent transcriptional regulation. Common features of operons encoding members of this family include two conserved GATC sites in the upstream regulatory region, and transcriptional regulators homologue to the PapB and PapI proteins. Methylation protection of GATC sites was previously shown to be dependent on the leucine-responsive regulatory protein (Lrp). Lrp and ClpB, the PapB equivalent, repressed clp basal transcription. A PapI homologue (AfaF) was required together with Lrp to establish the phase variation control, which gave rise to phase-ON cells that expressed CS31A and phase-OFF cells that did not express CS31A. In phase-OFF cells, the GATC(dist) site was methylated and the GATC(prox) site was protected from methylation, whereas in phase-ON cells, the inverse situation was found. Unlike Pap fimbriae, CS31A synthesis was dramatically reduced in media containing L-alanine or L-leucine. L-Alanine prevented the OFF-to-ON switch, locking clp expression in the OFF phase, whereas L-leucine repressed transcription without obvious effect on the switch frequency of phase variation. In phase-variable cells, leucine and alanine promoted methylation of GATC(dist) and methylation protection of GATC(prox), increasing the methylation pattern characteristic of repressed cells. Furthermore, alanine prevented the AfaF-dependent methylation protection of GATC(dist) and thus the appearance of phase-ON cells. In addition, analysis of clp expression in a Lrp-negative background indicated that alanine and leucine also repressed clp transcription by a methylation-independent mechanism.

Phase variation of F165(1) (Prs-like) fimbriae from Escherichia coli causing septicaemia in animals

Escherichia coli O115:F165 strains are associated with septicaemia in young pigs and synthesize fimbriae involved in virulence, designated as F165(1). F165(1) fimbriae belong to the P fimbrial family and are encoded by the foo gene cluster. The foo regulatory region of strain 5131 possesses characteristics similar to that of members of the P regulatory family, including papI and papB homologues, and two GATC sites separated by 102 bp, targets of differential Dam methylation. In wild-type strains, the synthesis of F165(1) is repressed by leucine and the fimbriae undergo phase variation. Immunofluorescence staining showed that phase variation of F165(1) results in a majority of cells (98%) in the ON phase, in contrast with phase variation of other members of this regulatory family, for which the majority of the cells are in the OFF state. Using a translational fusion in strain 5131 between phoA and fooA, encoding for the major structural subunit of F165(1), it was shown that leucine inhibits the OFF to ON switch and modulates the basal transcription of the foo operon.