DNA bending by the TrpI protein of Pseudomonas aeruginosa

Differential protein-DNA contacts for activation and repression by ArgP, a LysR-type (LTTR) transcriptional regulator in Escherichia coli

ArgP is a LysR-type transcriptional regulator (LTTR) that operates with two effector molecules, lysine and arginine, to differentially regulate gene expression. Effector-free ArgP stimulates transcription of all investigated regulon members, except argO, whereas lysine abolishes this effect. Activation of argO, encoding an exporter for arginine and canavanine, is strictly dependent on arginine-bound ArgP. Lysine counteracts this effect and even though lysine-bound ArgP stimulates RNA polymerase recruitment at the argO promoter, the complex is non-productive. It is presently unclear what distinguishes argO from other ArgP targets and how binding of arginine and lysine translates in antagonistic effects on promoter activity. Here we generate high resolution contact maps of effector-free and effector-bound ArgP-DNA interactions and identify the sequence 5'-CTTAT as the consensus recognition motif for ArgP binding. argO is the only operator at which ArgP binding overlaps the -35 promoter element and binding of arginine results in a repositioning of the promoter proximal bound ArgP-arg subunits. This effect was mimicked by the generation of a 10bp insertion mutant (ins-10) in the argO operator that renders its activation by ArgP arginine-independent. ArgP-induced DNA bending of the argO operator by approximately 60° was found to be effector independent. An ArgP:DNA binding stoichiometry of 4:1 indicates binding of four ArgP subunits even to DNA constructs that are truncated for one binding subsite (ΔABS). These results provide insight into the molecular mechanisms of ArgP-mediated regulation and a molecular explanation for the unique arginine-dependence of argO activation that distinguishes this particular ArgP target from all others.

The regulatory mechanism of 2,4,6-trichlorophenol catabolic operon expression by HadR in Ralstonia pickettii DTP0602

Ralstonia pickettii DTP0602 utilizes 2,4,6-trichlorophenol (2,4,6-TCP) as its sole source of carbon. The expression of catabolic pathway genes (hadA, hadB and hadC) for 2,4,6-TCP has been reported to be regulated by the LysR-type transcriptional regulator (LTTR) HadR. Generally, coinducers are recognized as being important for the function of LTTRs, and alteration of the LTTR-protection sequence and the degree of DNA bending are characteristic of LTTRs with or without a recognized coinducer. In this study, we describe the mechanism by which HadR regulates the expression of 2,4,6-TCP catabolic genes. The 2,4,6-TCP catabolic pathway genes in DTP0602 consist of two transcriptional units: hadX-hadA-hadB-hadC and monocistronic hadR. Purified HadR binds to the hadX promoter and HadR-DNA complex formation was induced in the presence of 16 types of substituted phenols, including chloro- and nitro-phenols and tribromo-phenol. In contrast with observations of other well-characterized LTTRs, the tested phenols showed no diversity of the bending angle of the HadR binding fragment. The expression of 2,4,6-TCP catabolic pathway genes, which are regulated by HadR, was not influenced by the DNA bending angle of HadR. Moreover, the transcription of hadX, hadA and hadB was induced in the presence of seven types of substituted phenols, whereas the other substituted phenols, which induced formation of the HadR-DNA complex, did not induce the transcription of hadX, hadA or hadB in vivo.

Transcriptional cross-regulation between Gram-negative and gram-positive bacteria, demonstrated using ArgP-argO of Escherichia coli and LysG-lysE of Corynebacterium glutamicum

The protein-gene pairs ArgP-argO of Escherichia coli and LysG-lysE of Corynebacterium glutamicum are orthologous, with the first member of each pair being a LysR-type transcriptional regulator and the second its target gene encoding a basic amino acid exporter. Whereas LysE is an exporter of arginine (Arg) and lysine (Lys) whose expression is induced by Arg, Lys, or histidine (His), ArgO exports Arg alone, and its expression is activated by Arg but not Lys or His. We have now reconstituted in E. coli the activation of lysE by LysG in the presence of its coeffectors and have shown that neither ArgP nor LysG can regulate expression of the noncognate orthologous target. Of several ArgP-dominant (ArgP(d)) variants that confer elevated Arg-independent argO expression, some (ArgP(d)-P274S, -S94L, and, to a lesser extent, -P108S) activated lysE expression in E. coli. However, the individual activating effects of LysG and ArgP(d) on lysE were mutually extinguished when both proteins were coexpressed in Arg- or His-supplemented cultures. In comparison with native ArgP, the active ArgP(d) variants exhibited higher affinity of binding to the lysE regulatory region and less DNA bending at both argO and lysE. We conclude that the transcription factor LysG from a Gram-positive bacterium, C. glutamicum, is able to engage appropriately with the RNA polymerase from a Gram-negative bacterium, E. coli, for activation of its cognate target lysE in vivo and that single-amino-acid-substitution variants of ArgP can also activate the distantly orthologous target lysE, but by a subtly different mechanism that renders them noninterchangeable with LysG.

Most mutant OccR proteins that are defective in positive control hold operator DNA in a locked high-angle bend

OccR is a LysR-type transcriptional regulator of Agrobacterium tumefaciens that positively regulates the octopine catabolism operon of the Ti plasmid. Positive control of the occ genes occurs in response to octopine, a nutrient released from crown gall tumors. OccR also functions as an autorepressor in the presence or absence of octopine. OccR binds to a site between occQ and occR in the presence or absence of octopine, although octopine triggers a conformational change that shortens the DNA footprint and relaxes a DNA bend. In order to determine the roles of this conformational change in transcriptional activation, we isolated 11 OccR mutants that were defective in activation of the occQ promoter but were still capable of autorepression. The mutations in these mutants spanned most of the length of the protein. Two additional positive-control mutants were isolated using site-directed mutagenesis. Twelve mutant proteins displayed a high-angle DNA bend in the presence or absence of octopine. One mutant, the L26A mutant, showed ligand-responsive DNA binding similar to that of wild-type OccR and therefore must be impaired in a subsequent step in activation.

Regulatory system of the protocatechuate 4,5-cleavage pathway genes essential for lignin downstream catabolism

Sphingobium sp. strain SYK-6 converts various lignin-derived biaryls with guaiacyl (4-hydroxy-3-methoxyphenyl) and syringyl (4-hydroxy-3,5-dimethoxyphenyl) moieties to vanillate and syringate. These compounds are further catabolized through the protocatechuate (PCA) 4,5-cleavage (PCA45) pathway. In this article, the regulatory system of the PCA45 pathway is described. A LysR-type transcriptional regulator (LTTR), LigR, activated the transcription of the ligK-orf1-ligI-lsdA and ligJABC operons in the presence of PCA or gallate (GA), which is an intermediate metabolite of vanillate or syringate, respectively, and repressed transcription of its own gene. LigR bound to the positions -77 to -51 and -80 to -48 of the ligK and ligJ promoters, respectively, and induced DNA bending. In the presence of PCA or GA, DNA bending on both promoters was enhanced. The LigR-binding regions of the ligK and ligJ promoters in the presence of inducer molecules were extended and shortened, respectively. The LTTR consensus sequences (Box-K and Box-J) in the ligK and ligJ promoters were essential for the binding of LigR and transcriptional activation of both operons. In addition, the regions between the LigR binding boxes and the -35 regions were required for the enhancement of DNA bending, although the binding of LigR to the -35 region of the ligJ promoter was not observed in DNase I footprinting experiments. This study shows the binding features of LigR on the ligK and ligJ promoters and explains how the PCA45 pathway genes are expressed during degradation of lignin-derived biaryls by this bacterium.

Evolution of bacterial trp operons and their regulation

Survival and replication of most bacteria require the ability to synthesize the amino acid L-tryptophan whenever it is not available from the environment. In this article we describe the genes, operons, proteins, and reactions involved in tryptophan biosynthesis in bacteria, and the mechanisms they use in regulating tryptophan formation. We show that although the reactions of tryptophan biosynthesis are essentially identical, gene organization varies among species--from whole-pathway operons to completely dispersed genes. We also show that the regulatory mechanisms used for these genes vary greatly. We address the question--what are some potential advantages of the gene organization and regulation variation associated with this conserved, important pathway?

Residues that influence in vivo and in vitro CbbR function in Rhodobacter sphaeroides and identification of a specific region critical for co-inducer recognition

CbbR is a LysR-type transcriptional regulator (LTTR) that is required to activate transcription of the cbb operons, responsible for CO2 fixation, in Rhodobacter sphaeroides. LTTR proteins often require a co-inducer to regulate transcription. Previous studies suggested that ribulose 1,5-bisphosphate (RuBP) is a positive effector for CbbR function in this organism. In the current study, RuBP was found to increase the electrophoretic mobility of the CbbR/cbb(I) promoter complex. To define and analyse the co-inducer recognition region of CbbR, constitutively active mutant CbbR proteins were isolated. Under growth conditions that normally maintain transcriptionally inactive cbb operons, the mutant CbbR proteins activated transcription. Fourteen of the constitutively active mutants resulted from a single amino acid substitution. One mutant was derived from amino acid substitutions at two separate residues that appeared to act synergistically. Different mutant proteins showed both sensitivity and insensitivity to RuBP and residues that conferred constitutive transcriptional activity could be highlighted on a three-dimensional model, with several residues unique to CbbR shown to be at locations critical to LTTR function. Many of the constitutive residues clustered in or near two specific loops in the LTTR tertiary structure, corresponding to a proposed site of co-inducer binding.

Constitutive mutations of the OccR regulatory protein affect DNA bending in response to metabolites released from plant tumors

OccR is a LysR-type transcriptional regulator of Agrobacterium tumefaciens that positively regulates the octopine catabolism operon of the Ti plasmid and is also an autorepressor. Positive control of the occ genes occurs in response to octopine, a nutrient released from crown gall tumors. OccR binds to a site upstream of the occQ promoter in the presence and absence of octopine. Octopine causes prebound OccR to undergo a conformational change at the DNA binding site that causes changes in footprint length and DNA bending. To determine the roles of these conformational changes in transcriptional activation, we isolated 22 OccR mutants that were able to activate the occQ promoter in the absence of octopine. Thirteen of these mutants contained single amino acid substitutions, and nine contained two base pair changes resulting in two amino acid substitutions, which in most cases acted synergistically. These mutations spanned the entire length of the protein. Most of these mutant proteins in the absence of octopine displayed DNA binding and bending properties characteristic of transcriptionally active OccR-octopine complexes.

Recognition of binding sites I and II by the TrpI activator protein of pseudomonas aeruginosa: efficient binding to both sites requires InGP even when site II is replaced by site I

TrpI protein, the activator of transcription of the trpBA operon of three species of fluorescent Pseudomonads, bends the DNA when it forms either of two well-characterized complexes with the trpBA regulatory region. In complex 1, TrpI is bound only to its strong binding site (site I), whereas in complex 2, which is required for activation of the trpBA promoter, TrpI is bound both to site I and to the weaker site II. Indoleglycerol phosphate (InGP) strongly stimulates formation of complex 2 and is required for activation. The present study focuses on the binding of TrpI to DNA containing a duplication of site I and the effect of the duplication on TrpI-induced DNA bending. We find that even on DNA containing a tandem (direct or inverted) duplication of site I, the formation of DNA-TrpI complexes with both sites occupied is strongly stimulated by InGP. Thus, even when TrpI binding to two adjacent sites needs not be cooperative, InGP significantly promotes the formation of complex 2. Gel binding data indicate that InGP can have several effects: (1) TrpI molecules bound to either of two adjacent strong binding sites appear to interfere with binding to the other site; InGP relieves this apparent interference. (2) InGP increases the intrinsic affinity of TrpI for sites I and II and/or enhances cooperative TrpI binding to adjacent DNA sites. Furthermore, a third molecule of TrpI can form a footprint adjacent to the duplication on DNA containing a direct (but not inverted) repeat of site I, indicating that TrpI bound to site I is oriented asymmetrically in spite of the quasi-symmetry of the binding site. The calculated bending angle for DNA in complex 2 is increased by approximately 20 degrees when site I is substituted in either orientation for site II; thus, on DNA containing a site I duplication, the bending angle of complex 2 is nearly twice that of complex 1.

In vivo analysis of the interactions of the LysR-like regulator SpvR with the operator sequences of the spvA and spvR virulence genes of Salmonella typhimurium

The interaction of the Salmonella typhimurium virulence gene regulator, SpvR, with its operator sites upstream of the spvA and spvR genes was analysed in vivo by dimethyl sulphate (DMS) footprinting and site-directed mutagenesis. DMS methylation protection assays showed that, in vivo, SpvR forms direct protein-DNA contacts with nucleotides clustered in two regions (+1 to -27 and -51 to -71) of the spvA regulatory region. These regions were subjected to site-directed mutagenesis and the effects on SpvR binding and gene activation assessed. Mutations that prevented occupancy of the promoter distal site (-51 to -71) in vivo also prevented occupancy of the promoter proximal site (+1 to -27), whereas mutations in the proximal site affected binding only at the proximal site and not the distal site. SpvR binding at the promoter proximal site was an essential prerequisite for transcription activation. These findings demonstrated a hierarchy of SpvR binding in which the promoter distal site is dominant to the proximal. The spvR gene was found to possess an operator site that resembled closely the distal SpvR binding site of the spvA operator. Nonetheless, SpvR interaction with the spvR operator was difficult to detect in vivo. When the nucleotide sequence of the spvR operator was altered at two nucleotides so that it corresponded more precisely to that of the distal site of the spvA operator, strong SpvR-DNA interactions were detected, with nucleotides in the region -31 to -67 being protected from DMS methylation in vivo. However, despite the improved interaction with the transcriptional activator, the altered regulatory region was poorer at promoting spvR gene transcription than the wild type. We describe a two-step model for activation of the spvA promoter and discuss the possibility that a specific cofactor in addition to sigma factor RpoS is required for SpvR action at this promoter in vivo.