Analysis of an Escherichia coli mutant TyrR protein with impaired capacity for tyrosine-mediated repression, but still able to activate at sigma 70 promoters

Research overview of L-DOPA production using a bacterial enzyme, tyrosine phenol-lyase

L-DOPA is an amino acid that is used as a treatment for Parkinson's disease. A simple enzymatic synthesis method of L-DOPA had been developed using bacterial L-tyrosine phenol-lyase (Tpl). This review describes research on screening of bacterial strains, culture conditions, properties of the enzyme, reaction mechanism of the enzyme, and the reaction conditions for the production of L-DOPA. Furthermore, molecular bleeding of constitutively Tpl-overproducing strains is described, which were developed based on mutations in a DNA binding protein, TyrR, which controls the induction of tpl gene expression.

Engineering ligand-specific biosensors for aromatic amino acids and neurochemicals

Microbial biosensors have diverse applications in metabolic engineering and medicine. Specific and accurate quantification of chemical concentrations allows for adaptive regulation of enzymatic pathways and temporally precise expression of diagnostic reporters. Although biosensors should differentiate structurally similar ligands with distinct biological functions, such specific sensors are rarely found in nature and challenging to create. Using E. coli Nissle 1917, a generally regarded as safe microbe, we characterized two biosensor systems that promiscuously recognize aromatic amino acids or neurochemicals. To improve the sensors' selectivity and sensitivity, we applied rational protein engineering by identifying and mutagenizing amino acid residues and successfully demonstrated the ligand-specific biosensors for phenylalanine, tyrosine, phenylethylamine, and tyramine. Additionally, our approach revealed insights into the uncharacterized structure of the FeaR regulator, including critical residues in ligand binding. These results lay the groundwork for developing kinetically adaptive microbes for diverse applications. A record of this paper's transparent peer review process is included in the supplemental information.

Characterization of the TyrR Regulon in the Rhizobacterium Enterobacter ludwigii UW5 Reveals Overlap with the CpxR Envelope Stress Response

The TyrR transcription factor controls the expression of genes for the uptake and biosynthesis of aromatic amino acids in Escherichia coli In the plant-associated and clinically significant proteobacterium Enterobacter ludwigii UW5, the TyrR orthologue was previously shown to regulate genes that encode enzymes for synthesis of the plant hormone indole-3-acetic acid and for gluconeogenesis, indicating a broader function for the transcription factor. This study aimed to delineate the TyrR regulon of E. ludwigii by comparing the transcriptomes of the wild type and a tyrR deletion strain. In E. ludwigii, TyrR positively or negatively regulates the expression of over 150 genes. TyrR downregulated expression of envelope stress response regulators CpxR and CpxP through interaction with a DNA binding site in the intergenic region between divergently transcribed cpxP and cpxR Repression of cpxP was alleviated by tyrosine. Methyltransferase gene dmpM, which is possibly involved in antibiotic synthesis, was strongly activated in the presence of tyrosine and phenylalanine by TyrR binding to its promoter region. TyrR also regulated expression of genes for aromatic catabolism and anaerobic respiration. Our findings suggest that the E. ludwigii TyrR regulon has diverged from that of E. coli to include genes for survival in the diverse environments that this bacterium inhabits and illustrate the expansion and plasticity of transcription factor regulons.IMPORTANCE Genome-wide RNA sequencing revealed a broader regulatory role for the TyrR transcription factor in the ecologically versatile bacterium Enterobacter ludwigii beyond that of aromatic amino acid synthesis and transport that constitute the role of the TyrR regulon of E. coli In E. ludwigii, a plant symbiont and human gut commensal, the TyrR regulon is expanded to include genes that are beneficial for plant interactions and response to stresses. Identification of the genes regulated by TyrR provides insight into the mechanisms by which the bacterium adapts to its environment.

Characterization of melanin-overproducing transposon mutants of Pseudomonas putida F6

Two melanin-overproducing Pseudomonas putida F6 mutants were generated using transposon (Tn5) mutagenesis. Mutants were disrupted in a transcriptional regulator (TR) and a homogentisate 1,2-dioxygenase (HDO) gene. Colonies of mutant F6-TR overproduced a black pigment on solid medium. The same mutant (F6-TR) had a 3.7-fold higher tyrosinase activity compared with the wild-type strain when induced with ferulic acid. However in tyrosine uptake assays whole cells of the mutant strain F6-TR consumed eight times less tyrosine compared with the wild-type strain. Mutant F6-HDO produced a diffusible red pigment into the growth medium. Pigment production by mutant F6-HDO is sixfold higher than the wild-type strain. The biomass yield of mutant F6-HDO grown on tyrosine as the sole source of carbon and energy was 1.2-fold lower than the wild-type strain. While the growth of the wild-type strain was completely inhibited by 5 min of exposure to UV light (254 nm) both mutant strains showed survival rates >30%. Mutant F6-HDO was able to tolerate higher concentrations of hydrogen peroxide (H(2)O(2)) exhibiting 1.5 times smaller zones of inhibition at 10 mM H(2)O(2) compared with mutant F6-TR and the wild-type strain. The pigments produced by all strains were purified and confirmed to be melanins.

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.

Altered oligomerization properties of N316 mutants of Escherichia coli TyrR

The transcriptional regulator TyrR is known to undergo a dimer-to-hexamer conformational change in response to aromatic amino acids, through which it controls gene expression. In this study, we identified N316D as the second-site suppressor of Escherichia coli TyrR(E274Q), a mutant protein deficient in hexamer formation. N316 variants exhibited altered in vivo regulatory properties, and the most drastic changes were observed for TyrR(N316D) and TyrR(N316R) mutants. Gel filtration analyses revealed that the ligand-mediated oligomer formation was enhanced and diminished for TyrR(N316D) and TyrR(N316R), respectively, compared with the wild-type TyrR. ADP was substituted for ATP in the oligomer formation of TyrR(N316D).

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.

folA, a new member of the TyrR regulon in Escherichia coli K-12

The folA gene was identified as a new member of the TyrR regulon by genomic SELEX. Binding of TyrR to two sites in folA activated its transcription. Mutations in the N-terminal or central domain of TyrR, the alpha subunit of RNA polymerase, or integration host factor all abolished activation of the folA promoter.

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.

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 central domain of Escherichia coli TyrR is responsible for hexamerization associated with tyrosine-mediated repression of gene expression

TyrR from Escherichia coli regulates the expression of genes for aromatic amino acid uptake and biosynthesis. Its central ATP-hydrolyzing domain is similar to conserved domains of bacterial regulatory proteins that interact with RNA polymerase holoenzyme associated with the alternative sigma factor, sigma(54). It is also related to the common module of the AAA+ superfamily of proteins that is involved in a wide range of cellular activities. We expressed and purified two TyrR central domain polypeptides. The fragment comprising residues 188-467, called TyrR-(188-467), was soluble and stable, in contrast to that corresponding to the conserved core from residues 193 to 433. TyrR-(188-467) bound ATP and rhodamine-ATP with association constants 2- to 5-fold lower than TyrR and hydrolyzed ATP at five times the rate of TyrR. In contrast to TyrR, which is predominantly dimeric at protein concentrations less than 10 microm in the absence of ligands, or in the presence of ATP or tyrosine alone, TyrR-(188-467) is a monomer, even at high protein concentrations. Tyrosine in the presence of ATP or ATPgammaS promotes the oligomerization of TyrR-(188-467) to a hexamer. Tyrosine-dependent repression of gene transcription by TyrR therefore depends on ligand binding and hexamerization determinants located in the central domain polypeptide TyrR-(188-467).

Sequencing of the Francisella tularensis strain Schu 4 genome reveals the shikimate and purine metabolic pathways, targets for the construction of a rationally attenuated auxotrophic vaccine

Francisella tularensis is the etiological agent of tularemia, a serious disease in several Northern hemisphere countries. The organism has fastidious growth requirements and is very poorly understood at the genetic and molecular levels. Given the lack of data on this organism, we undertook the sample sequencing of its genome. A random library of DNA fragments from a highly virulent strain (Schu 4) of F. tularensis was constructed and the nucleotide sequences of 13,904 cloned fragments were determined and assembled into 353 contigs. A total of 1.83 Mb of nucleotide sequence was obtained that had a G+C content of 33.2%. Genes located on plasmids pOM1 and pNFL10, which had been previously isolated from low virulence strains of F. tularensis, were absent but all of the other known F. tularensis genes were represented in the assembled data. F. tularensis Schu4 was able to grow in the absence of aromatic amino acids and orthologues of genes which could encode enzymes in the shikimate pathway in other bacteria were identified in the assembled data. Genes that could encode all of the enzymes in the purine biosynthetic and most of the en- zymes in the purine salvage pathways were also identified. This data will be used to develop defined rationally attenuated mutants of F. tularensis, which could be used as replacements for the existing genetically undefined live vaccine strain.

Cloning and random mutagenesis of the Erwinia herbicola tyrR gene for high-level expression of tyrosine phenol-lyase

Tyrosine phenol-lyase (Tpl), which can synthesize 3, 4-dihydroxyphenylalanine from pyruvate, ammonia, and catechol, is a tyrosine-inducible enzyme. Previous studies demonstrated that the tpl promoter of Erwinia herbicola is activated by the TyrR protein of Escherichia coli. In an attempt to create a high-Tpl-expressing strain, we cloned the tyrR gene of E. herbicola and then randomly mutagenized it. Mutant TyrR proteins with enhanced ability to activate tpl were screened for by use of the lac reporter system in E. coli. The most increased transcription of tpl was observed for the strain with the mutant tyrR allele involving amino acid substitutions of alanine, cysteine, and glycine for valine-67, tyrosine-72, and glutamate-201, respectively. A tyrR-deficient derivative of E. herbicola was constructed and transformed with a plasmid carrying the mutant tyrR allele (V67A Y72C E201G substitutions). The resultant strain expressed Tpl without the addition of tyrosine to the medium and produced as much of it as was produced by the wild-type strain grown under tyrosine-induced conditions. The regulatory properties of the mutant TyrR(V67A), TyrR(Y72C), TyrR(E201G), and TyrR(V67A Y72C E201G) proteins were examined in vivo. Interestingly, as opposed to the wild-type TyrR protein, the mutant TyrR(V67A) protein had a repressive effect on the tyrP promoter in the presence of phenylalanine as the coeffector.

The sigma(70) transcription factor TyrR has zinc-stimulated phosphatase activity that is inhibited by ATP and tyrosine

The TyrR protein of Escherichia coli (513 amino acid residues) is the chief transcriptional regulator of a group of genes that are essential for aromatic amino acid biosynthesis and transport. The TyrR protein can function either as a repressor or as an activator. The central region of the TyrR protein (residues 207 to 425) is similar to corresponding polypeptide segments of the NtrC protein superfamily. Like the NtrC protein, TyrR has intrinsic ATPase activity. Here, we report that TyrR possesses phosphatase activity. This activity is subject to inhibition by L-tyrosine and its analogues and by ATP and ATP analogues. Zinc ion (2 mM) stimulated the phosphatase activity of the TyrR protein by a factor of 57. The phosphatase-active site of TyrR was localized to a 31-kDa domain (residues 191 to 467) of the protein. However, mutational alteration of distant amino acid residues at both the N terminus and the C terminus of TyrR altered the phosphatase activity. Haemophilus influenzae TyrR (318 amino acid residues), a protein with a high degree of sequence similarity to the C terminus of the E. coli TyrR protein, exhibited a phosphatase activity similar to that of E. coli TyrR.

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.

Specific contacts between residues in the DNA-binding domain of the TyrR protein and bases in the operator of the tyrP gene of Escherichia coli

In the presence of tyrosine, the TyrR protein of Escherichia coli represses the expression of the tyrP gene by binding to the double TyrR boxes which overlap the promoter. Previously, we have carried out methylation, uracil, and ethylation interference experiments and have identified both guanine and thymine bases and phosphates within the TyrR box sequences that are contacted by the TyrR protein (J. S. Hwang, J. Yang, and A. J. Pittard, J. Bacteriol. 179:1051-1058, 1997). In this study, we have used missing contact probing to test the involvement of all of the bases within the tyrP operator in the binding of TyrR. Our results indicate that nearly all the bases within the palindromic arms of the strong and weak boxes are important for the binding of the TyrR protein. Two alanine-substituted mutant TyrR proteins, HA494 and TA495, were purified, and their binding affinities for the tyrP operator were measured by a gel shift assay. HA494 was shown to be completely defective in binding to the tyrP operator in vitro, while, in comparison with wild-Type TyrR, TA495 had only a small reduction in DNA binding. Missing contact probing was performed by using the purified TA495 protein, and the results suggest that T495 makes specific contacts with adenine and thymine bases at the +/-5 positions in the TyrR boxes.

In vivo studies on the positive control function of NifA: a conserved hydrophobic amino acid patch at the central domain involved in transcriptional activation

The eubacterial enhancer-binding proteins activate transcription by binding to distant sites and, simultaneously, contacting the RNA polymerase r54 promoter complex (Esigma54). The positive control function is located at the central domain of these proteins, but it is not know which specific region has the determinants for the interaction with Esigma54. Here, we present genetic evidence that a small region of hydrophobic amino acids, previously denominated C3, at the central domain of Bradyrhizobium japonicum NifA is involved in positive control. We obtained 26 missense mutants along this conserved region. Among these, only strains expressing the NifA(F307-->Y) and NifA(A310-->S) mutant proteins retained some of the transcriptional activity (<20%), whereas those carrying NifA(E298-->D) and NifA(T308-->S) had very low but detectable activity (< 1.0%). The rest of the NifA mutants did not induce any measurable transcriptional activity. When expressed in the presence of wild-type NifA, the great majority of the mutants displayed a dominant phenotype, suggesting that their oligomerization determinants were not altered. In vivo dimethyl-sulphate footprinting experiments for a subset of the NifA mutants showed that they were still able to bind specifically to DNA. Analysis of intragenic supressors highlight the functional role of a hydroxyl group at position 308 to activate transcription.

Activation of the toluene-responsive regulator XylR causes a transcriptional switch between sigma54 and sigma70 promoters at the divergent Pr/Ps region of the TOL plasmid

The mechanism by which XylR, the toluene-responsive activator of the sigma54-dependent Pu and Ps promoters of the Pseudomonas TOL plasmid pWW0, downregulates its own sigma70 promoter Prhas been examined. An in vitro transcription system was developed in order to reproduce the repression of Probserved in cells of P. putida (pWW0) both in the presence and in the absence of the XylR inducer, benzyl alcohol. DNA templates bearing the two sigma70-RNA polymerase (RNAP) binding sites of Pr, which overlap the upstream activating sequences (UAS) for XylR in the divergent sigma54 promoter Ps, were transcribed in the presence of a constitutively active XylR variant deleted of its N-terminal domain (XylRdeltaA). The addition of ATP, known to trigger multimerization of the regulator at the UAS, enhanced the repression of Pr by XylR. Furthermore, we observed activation of the divergent sigma54 promoter Ps during Pr downregulation by XylRdeltaA. These results support the notion that activation of XylR by aromatic inducers in vivo triggers a transcriptional switch between Pr and Ps. Such a switch is apparently caused by the ATP-dependent multimerization and strong DNA binding of the protein required for activation of the sigma54 promoter. This device could reset the level of XylR expression during activation of the sigma54 Pu and Ps promoters of the TOL plasmid.

Repression of the aroP gene of Escherichia coli involves activation of a divergent promoter

The repression of aroP expression which is mediated by the TyrR protein with phenylalanine, tyrosine, or tryptophan has been shown to be primarily a direct result of TyrR-mediated activation of a divergent promoter, P3, which directs the RNA polymerase away from promoter P1. Evidence which has been presented to support this conclusion is as follows. Repression of P1 does not occur either in vitro or in vivo if wild-type TyrR protein is substituted by the activation-negative mutant RQ10 (with an R-to-Q change at position 10). Repression of P1 is greatly diminished if the P3 promoter is inactivated or if a 5-bp insertion is made between the P3 promoter and the binding sites for TyrR. Repression is also abolished if the promoter strength of P1 is increased or a putative UP element associated with P3 is altered. Repression of the second promoter, P2, still occurs if the wild-type TyrR protein is substituted with RQ10 or EQ274. The tryptophan-mediated repression of aroP does not involve the TrpR protein.

A proposed architecture for the central domain of the bacterial enhancer-binding proteins based on secondary structure prediction and fold recognition

The expression of genes transcribed by the RNA polymerase with the alternative sigma factor sigma 54 (E sigma 54) is absolutely dependent on activator proteins that bind to enhancer-like sites, located far upstream from the promoter. These unique prokaryotic proteins, known as enhancer-binding proteins (EBP), mediate open promoter complex formation in a reaction dependent on NTP hydrolysis. The best characterized proteins of this family of regulators are NtrC and NifA, which activate genes required for ammonia assimilation and nitrogen fixation, respectively. In a recent IRBM course (@ontiers of protein structure prediction," IRBM, Pomezia, Italy, 1995; see web site http://www.mrc-cpe.cam.uk/irbm-course95/), one of us (J.O.) participated in the elaboration of the proposal that the Central domain of the EBPs might adopt the classical mononucleotide-binding fold. This suggestion was based on the results of a new protein fold recognition algorithm (Map) and in the mapping of correlated mutations calculated for the sequence family on the same mononucleotide-binding fold topology. In this work, we present new data that support the previous conclusion. The results from a number of different secondary structure prediction programs suggest that the Central domain could adopt an alpha/beta topology. The fold recognition programs ProFIT 0.9, 3D PROFILE combined with secondary structure prediction, and 123D suggest a mononucleotide-binding fold topology for the Central domain amino acid sequence. Finally, and most importantly, three of five reported residue alterations that impair the Central domain. ATPase activity of the E sigma 54 activators are mapped to polypeptide regions that might be playing equivalent roles as those involved in nucleotide-binding in the mononucleotide-binding proteins. Furthermore, the known residue substitution that alter the function of the E sigma 54 activators, leaving intact the Central domain ATPase activity, are mapped on region proposed to play an equivalent role as the effector region of the GTPase superfamily.

In vitro transcriptional analysis of TyrR-mediated activation of the mtr and tyrP+3 promoters of Escherichia coli

In order to understand the mechanism by which the TyrR protein activates transcription from the mtr and tyrP+3 promoters, we have carried out in vitro transcription experiments with supercoiled DNA templates. We have shown that addition of the histone-like protein HU or integration host factor (IHF) greatly inhibited the transcription from the mtr and tyrP+3 promoters. In the presence of phenylalanine, the wild-type TyrR protein, but not a mutant TyrR protein (activation negative), was able to relieve the HU- or IHF-mediated inhibition of transcription. In contrast, the alleviation of the HU- or IHF-mediated transcription inhibition by the wild-type TyrR protein did not occur when a mutant RNA polymerase with a C-terminally truncated alpha subunit was used to carry out the transcription reaction.

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.