Mutational uncoupling of the transcriptional activation function of the TyrR protein of Escherichia coli K-12 from the repression function

Aromatic amino acid-dependent expression of indole-3-pyruvate decarboxylase is regulated by TyrR in Enterobacter cloacae UW5

The plant growth-promoting rhizobacterium Enterobacter cloacae UW5 synthesizes the plant growth hormone indole-3-acetic acid (IAA) via the indole-3-pyruvate pathway utilizing the enzyme indole-3-pyruvate decarboxylase that is encoded by ipdC. In this bacterium, ipdC expression and IAA production occur in stationary phase and are induced by an exogenous source of tryptophan, conditions that are present in the rhizosphere. The aim of this study was to identify the regulatory protein that controls the expression of ipdC. We identified a sequence in the promoter region of ipdC that is highly similar to the recognition sequence for the Escherichia coli regulatory protein TyrR that regulates genes involved in aromatic amino acid transport and metabolism. Using a tyrR insertional mutant, we demonstrate that TyrR is required for IAA production and for induction of ipdC transcription. TyrR directly induces ipdC expression, as was determined by real-time quantitative reverse transcription-PCR, by ipdC promoter-driven reporter gene activity, and by electrophoretic mobility shift assays. Expression increases in response to tryptophan, phenylalanine, and tyrosine. This suggests that, in addition to its function in plant growth promotion, indolepyruvate decarboxylase may be important for aromatic amino acid uptake and/or metabolism.

Biosynthesis of the Aromatic Amino Acids

This chapter describes in detail the genes and proteins of Escherichia coli involved in the biosynthesis and transport of the three aromatic amino acids tyrosine, phenylalanine, and tryptophan. It provides a historical perspective on the elaboration of the various reactions of the common pathway converting erythrose-4-phosphate and phosphoenolpyruvate to chorismate and those of the three terminal pathways converting chorismate to phenylalanine, tyrosine, and tryptophan. The regulation of key reactions by feedback inhibition, attenuation, repression, and activation are also discussed. Two regulatory proteins, TrpR (108 amino acids) and TyrR (513 amino acids), play a major role in transcriptional regulation. The TrpR protein functions only as a dimer which, in the presence of tryptophan, represses the expression of trp operon plus four other genes (the TrpR regulon). The TyrR protein, which can function both as a dimer and as a hexamer, regulates the expression of nine genes constituting the TyrR regulon. TyrR can bind each of the three aromatic amino acids and ATP and under their influence can act as a repressor or activator of gene expression. The various domains of this protein involved in binding the aromatic amino acids and ATP, recognizing DNA binding sites, interacting with the alpha subunit of RNA polymerase, and changing from a monomer to a dimer or a hexamer are all described. There is also an analysis of the various strategies which allow TyrR in conjunction with particular amino acids to differentially affect the expression of individual genes of the TyrR regulon.

The TyrR regulon

The TyrR protein of Escherichia coli can act both as a repressor and as an activator of transcription. It can interact with each of the three aromatic amino acids, with ATP and, under certain circumstances, with the C-terminal region of the alpha-subunit of RNA polymerase. TyrR protein is a dimer in solution but in the presence of tyrosine and ATP it self-associates to form a hexamer. Whereas TyrR dimers can, in the absence of any aromatic amino acids, bind to certain recognition sequences referred to as 'strong TyrR boxes', hexamers can bind to extended sequences including lower-affinity sites called 'weak TyrR boxes', some of which overlap the promoter. There is no single mechanism for repression, which in some cases involves exclusion of RNA polymerase from the promoter and in others, interference with the ability of bound RNA polymerase to form open complexes or to exit the promoter. When bound to a site upstream of certain promoters, TyrR protein in the presence of phenylalanine, tyrosine or tryptophan can interact with the alpha-subunit of RNA polymerase to activate transcription. In one unusual case, activation of a non-productive promoter is used to repress transcription from a promoter on the opposite strand. Regulation of individual transcription units within the regulon reflects their physiological function and is determined by the position and nature of the recognition sites (TyrR boxes) associated with each of the promoters. The intracellular levels of the various forms of the TyrR protein are also postulated to be of critical importance in determining regulatory outcomes. TyrR protein remains a paradigm for a regulator that is able to interact with multiple cofactors and exert a range of regulatory effects by forming different oligomers on DNA and making contact with other proteins. A recent analysis identifying putative TyrR boxes in the E. coli genome raises the possibility that the TyrR regulon may extend beyond the well-characterized transcription units described in this review.

The global gene expression response of Escherichia coli to l-phenylalanine

We investigated the global gene expression changes of Escherichia coli due to the presence of different concentrations of phenylalanine or shikimate in the growth medium. The response to 0.5 g l(-1) phenylalanine primarily reflected a perturbed aromatic amino acid metabolism, in particular due to TyrR-mediated regulation. The addition of 5g l(-1) phenylalanine reduced the growth rate by half and elicited a great number of likely indirect effects on genes regulated in response to changed pH, nitrogen or carbon availability. Consistent with the observed gene expression changes, supplementation with shikimate, tyrosine and tryptophan relieved growth inhibition by phenylalanine. In contrast to the wild-type, a tyrR disruption strain showed increased expression of pckA and of tktB in the presence of phenylalanine, but its growth was not affected by phenylalanine at the concentrations tested. The absence of growth inhibition by phenylalanine suggested that at high phenylalanine concentrations TyrR-defective strains might perform better in phenylalanine production.

Mode of action of the TyrR protein: repression and activation of the tyrP promoter of Escherichia coli

The tyrP gene of Escherichia coli encodes a tyrosine specific transporter. Its synthesis is repressed by tyrosine but is activated by phenylalanine and to a lesser extent by tryptophan. Both of these effects are mediated by the TyrR protein when it binds to one or both of its cognate binding sites (TyrR boxes) which encompass nucleotides -30 to -75. Activation in the presence of phenylalanine or tryptophan involves a dimer binding to the upstream box and interacting with the alpha subunit (alphaCTD) of RNA polymerase (RNAP). Repression in the presence of tyrosine involves a hexamer binding to both TyrR boxes. The molecular basis for this repression has been studied in vitro. Whereas initial gel shift experiments fail to show the exclusion of RNAP from the promoter region when TyrR hexamer is bound, a DNase I analysis of slices from the gel shows that in the presence of TyrR, RNAP now binds to a previously unrecognized upstream promoter. Although this upstream promoter is bound strongly by RNAP and forms an open complex on linear DNA templates, it fails to form an open complex on supercoiled templates in vitro and is unable to initiate transcription in vivo. A subsequent gel shift assay using a tyrP fragment which eliminates the upstream RNAP binding site confirms conclusively that, in the presence of tyrosine and ATP, the TyrR protein prevents RNAP from binding to the tyrP promoter. In vitro studies have also been carried out in the presence of TyrR protein and phenylalanine. Binding of TyrR protein to the upstream TyrR box in the presence of phenylalanine is shown to increase the affinity of RNAP for the promoter and stimulate open complex formation at the -10 region of the tyrP promoter. This observation coupled with the results from mutational analysis supports the proposal that TyrR-phenylalanine activates tyrP transcription by stimulating the onset of open complex formation.

Molecular analysis of tyrosine-and phenylalanine-mediated repression of the tyrB promoter by the TyrR protein of Escherichia coli

The mechanism of repression of the tyrB promoter by TyrR protein has been studied in vivo and in vitro. In tyrR+ strains, transcription of tyrB is repressed by either tyrosine or phenylalanine. Both of the TyrR binding sites (strong and weak TyrR boxes) lie downstream of the tyrB transcription start site and are required for tyrosine- or phenylalanine-mediated repression. Our results establish that the binding of the TyrR protein to the weak box, induced by cofactor tyrosine or phenylalanine, is critical for repression to occur. Neither the binding of the TyrR protein dimer formed in the presence of phenylalanine, nor the binding of the hexamer formed in the presence of tyrosine, blocks the binding of RNA polymerase to the promoter. Instead, open complex formation is inhibited in the presence of tyrosine whereas a step(s) following open complex formation is inhibited in the presence of phenylalanine. Moving the TyrR boxes 3 bp or more further away from the promoter affects tyrosine-mediated repression without affecting phenylalanine-mediated repression which remains unaltered until 6 bp are inserted between the TyrR boxes and the promoter. Analysis of deletion and insertion mutants fails to reveal any face of the helix specificity for either tyrosine- or phenylalanine-mediated repression.

The influence of ATP on the association and unfolding of the tyrosine repressor ligand response domain of Haemophilus influenzae

The secondary structure of the ligand response domain of the Haemophilus influenzae tyrosine repressor, TyrR(lrd), was investigated using CD spectroscopy which revealed 42.5% alpha-helix, 17.6% beta-sheet, and 39.9% loops. Quaternary structure analysis by fluorescence anisotropy showed that TyrR(lrd) is monomeric at a concentration of 100 nM to 2 microM but that the protein readily dimerizes in the presence of its natural ligand ATP. Equilibrium unfolding studies of TyrR(lrd) using guanidinium hydrochloride suggested a two-state model with no detectable stable intermediates. The unfolding transition monitored by CD spectroscopy was responsive to tyrosine and ATP resulting in a shift to higher denaturant concentrations in the presence of these ligands. Differential scanning calorimetry yielded melting temperatures, T(m), of 51.15 and 58.07 degrees C for the unliganded and for the ATP-liganded protein, respectively. ATP is thus proposed to be a major structural cofactor for the molecular architecture of TyrR(lrd).

The influence of ATP on the binding of aromatic amino acids to the ligand response domain of the tyrosine repressor of Haemophilus influenzae

The binding of aromatic amino acids to the ligand response domain of the tyrosine repressor (TyrR) protein (TyrR(lrd)) of Haemophilus influenzae was investigated using circular dichroism and fluorescence spectroscopy. The induced secondary structural changes were unique for each aromatic amino acid and were further influenced by the presence or absence of ATP. Tyrosine was found to have the highest affinity for TyrR(lrd) in the absence of ATP, whereas the affinity for ATP itself increased in the presence of tyrosine. Binding of tyrosine is therefore the conformational trigger for the activation of TyrR whereas ATP is regarded as a conformational co-activator.

Mechanism of repression of the aroP P2 promoter by the TyrR protein of Escherichia coli

Previously, we have shown that expression of the Escherichia coli aroP P2 promoter is partially repressed by the TyrR protein alone and strongly repressed by the TyrR protein in the presence of the coeffector tyrosine or phenylalanine (P. Wang, J. Yang, and A. J. Pittard, J. Bacteriol. 179:4206-4212, 1997). Here we present in vitro results showing that the TyrR protein and RNA polymerase can bind simultaneously to the aroP P2 promoter. In the presence of tyrosine, the TyrR protein inhibits open complex formation at the P2 promoter, whereas in the absence of any coeffector or in the presence of phenylalanine, the TyrR protein inhibits a step(s) following the formation of open complexes. We also present mutational evidence which implicates the N-terminal domain of the TyrR protein in the repression of P2 expression. The TyrR binding site of aroP, which includes one weak and one strong TyrR box, is located 5 bp downstream of the transcription start site of P2. Results from a mutational analysis show that the strong box (which is located more closely to the P2 promoter), but not the weak box, plays a critical role in P2 repression.

Isolated operator binding and ligand response domains of the TyrR protein of Haemophilus influenzae associate to reconstitute functional repressor

Highly purified preparations of the TyrR protein of Haemophilus influenzae Rd undergo specific and limited proteolytic cleavage during storage at 4 degreesC to generate two fragments of 28 and 8 kDa. Under nondenaturing conditions, the two fragments remain tightly associated. Nicked TyrR is identical to full-length TyrR in its operator binding characteristics. The 8-kDa fragment containing amino acid residues 258-318 was separated from the 28-kDa fragment (residues 1-257) by gel filtration chromatography in the presence of 4 M urea. Upon renaturation, this fragment bound to operator with an affinity similar to that of full-length TyrR but was unresponsive to ligands that normally modulate operator binding (gamma-S-ATP and L-tyrosine). It was not possible to renature the urea-treated 28-kDa fragment. Highly purified soluble preparations of truncated TyrR containing residues 1-257 were obtained after the overexpression of a shortened form of the tyrR gene via a specific plasmid construct. By several criteria, this species had native secondary and tertiary structure. The 28-kDa fragment was unable to bind to operator but could reconstitute nicked TyrR when added to the renatured 8-kDa fragment, as shown by physical properties and responsiveness to cofactors in operator binding. When either the 28- or 8-kDa species was expressed in vivo, there was no detectable operator binding, as evaluated using a lacZ reporter system driven by the repressible aroF promoter. When the two fragments were co-expressed in a common cytoplasm, an operator-binding species was formed, as demonstrated through partial restoration of repression capability.

In situ mutagenesis and chemotactic selection of microorganisms in a diffusion gradient chamber

A new method has been developed to rapidly generate and select microbial strains having increased resistance to an inhibitory compound. The method combines in situ mutagenesis with use of a continuous gradient of the inhibitor to sort cells according to their resistance levels. Microbial chemotaxis is induced to accelerate the selection process. The method was used to develop a strain of E. coli having a feedback-resistant DAHP synthase enzyme. An unsteady-state mathematical model of the process has been developed. The model, that can reproduce key trends observed experimentally, was used to explore the effects of chemotaxis on the efficiency of the selection process.

Expression, purification, and functional analysis of the TyrR protein of Haemophilus influenzae

The gene that was inferred to encode the TyrR protein of Haemophilus influenzae Rd was synthesized by polymerase chain reaction and inserted into a T7-based expression vector. Methods were developed to overexpress the TyrR protein of H. influenzae in Escherichia coli and to purify the protein on a large scale. Both in vitro and in vivo functional comparisons of the H. influenzae and E. coli TyrR proteins were carried out. The TyrR protein of H. influenzae was able to bind in vitro to an operator target upstream of the aroF-tyrA gene of E. coli. In the presence of [gamma-S]ATP, the DNA binding ability of the H. influenzae TyrR protein was drastically reduced. Despite the much shorter peptide chain length (318 amino acid residues vs 513), the TyrR protein of H. influenzae was as active in repressing the aroF promoter as the TyrR protein of E. coli. Repression by both proteins was enhanced in the presence of tyrosine; however, the transcriptional activation function associated with the TyrR protein of E. coli could not be detected when the H. influenzae TyrR protein was expressed in E. coli. By computer analysis, at least five operator targets for TyrR were identified within the genomic DNA of H. influenzae. These observations show that the assignment of function to the tyrR gene of H. influenzae was correctly made. Further studies of the H. influenzae TyrR protein in comparison to its E. coli counterpart should provide valuable mechanistic information on transcriptional regulation in this system.

The various strategies within the TyrR regulation of Escherichia coli to modulate gene expression

The TyrR Regulon of Escherichia coli comprises eight transcription units whose expression is modulated by the TyrR protein. This protein, which is normally a homodimer in solution, can self-associate to form a hexamer, bind with high affinity to specific DNA sequences (TyrR boxes) and interact with the alpha subunit of the RNA polymerase. These various reactions are influenced by the abundance of one or more of the aromatic amino acids, tyrosine, phenylalanine or tryptophan and by the specific location and sequence of the TyrR boxes associated with each transcription unit. This review describes how these activities can be combined in different ways to produce a variety of responses to varying levels of the three aromatic amino acids.

Further genetic analysis of the activation function of the TyrR regulatory protein of Escherichia coli

Previous reports (J. Cui and R. L. Somerville, J. Bacteriol. 175:1777-1784, 1993; J. Yang, H. Camakaris, and A. J. Pittard, J. Bacteriol. 175:6372-6375, 1993) have identified a number of amino acids in the N-terminal domain of the TyrR protein which are critical for activation of gene expression but which play no role in TyrR-mediated repression. These amino acids were clustered in a single region involving positions 2, 3, 5, 7, 9, 10, and 16. Using random and site-directed mutagenesis, we have identified an additional eight key amino acids whose substitution results in significant or total loss of activator function. All of these are located in the N-terminal domain of TyrR. Alanine scanning at these eight new positions and at five of the previously identified positions for which alanine substitutions had not been obtained has identified three amino acids whose side chains are critical for activation, namely, D-9, R-10, and D-103. Glycine at position 37 is also of critical importance. Alanine substitutions at four other positions (C-7, E-16, D-19, and V-93) caused partial but significant loss of activation, indicating that the side chains of these amino acids also play a contributing role in the activation process.

Mutations in the tyrR gene of Escherichia coli which affect TyrR-mediated activation but not TyrR-mediated repression

Site-directed mutagenesis has been used to further characterize amino acid residues necessary for the activation of gene expression by the TyrR protein. Amino acid substitutions have been made at positions 2, 4, 5, 6, 7, 8, 9, 10, and 16. TyrR mutants with amino acid substitutions V-5-->P (VP5), VF5, CS7, CR7, DR9, RI10, RS10, and ER16 show no or very little activation of expression of either mtr or tyrP. In each case, however, the ability to repress aroF is unaltered. Amino acid substitutions at positions 4, 6, and 8 have no effect on activation. Small internal deletions of residues 10 to 19, 20 to 29, or 30 to 39 also destroy phenylalanine- or tyrosine-mediated activation of mtr and tyrP. In these mutants repression of aroF is also unaltered. In activation-defective tyrR mutants, expression of mtr is repressed in the presence of tyrosine. This tyrosine-mediated repression is trpR dependent and implies an interaction between TrpR and TyrR proteins in the presence of tyrosine.

A mutational analysis of the structural basis for transcriptional activation and monomer-monomer interaction in the TyrR system of Escherichia coli K-12

In response to the binding of tyrosine or phenylalanine, the TyrR protein (513 amino acids) activates certain promoters and represses others. In a previous study (J. Cui and R. L. Somerville, J. Bacteriol. 175:303-306, 1993), it was shown that promoter activation was selectively abolished in mutant proteins lacking amino acid residues 2 to 9. An additional series of constructs that encoded mutant TyrR proteins having deletions or point mutations near the N terminus were analyzed. Residues Arg-2 and Leu-3 were shown to be critical for the activation of the mtr promoter. In confirmation of previous findings, none of the activation-defective mutant TyrR proteins had lost significant repression function. The TyrR protein was shown by chemical cross-linking to be dimeric. The polypeptide segments critical for dimer formation in vivo were identified by evaluating the negative dominance phenotypes of a series of mutant proteins, all defective in DNA binding, lacking progressively greater numbers of amino acid residues from either the N terminus or the C terminus. Amino acid residues 194 to 438 were found to contain all of the essential dimerization determinants.