Solution structure of the DNA-binding domain of the TyrR protein of Haemophilus influenzae.

The TyrR protein of Haemophilus influenzae is a 36-kD transcription factor whose major function is to control the expression of genes important in the biosynthesis and transport of aromatic amino acids. Using (1)H and (15)N NMR spectroscopy, we have determined the 3D solution structure of the TyrR C-terminal DNA-binding domain (DBD) containing residues from 258 to 318 (TyrR[258-318]). The NMR results show that this segment of TyrR consists of a potential hinge helix at its N terminus (residues 263-270) as well as three well-defined alpha-helices extending from residues 277-289 (HR-2), 293-300 (HR-1), and 304-314 (HR). Helix HR-1 and HR fold in a typical helix-turn-helix (HTH) motif. The three helices and the hinge helix are tightly bound together by hydrophobic interaction and hydrogen bonds. Several hydrophilic residues whose side chains may directly interact with DNA are identified. A hydrophobic patch that may be part of the interaction surface between the domains of TyrR protein is also observed. Comparisons with the structures of other HTH DNA-binding proteins reveal that in terms of the spatial orientation of the three helices, this protein most closely resembles the cap family.

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.

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.

Antigen mimicry by anti-idiotypic antibodies: study of interactions between complementary surfaces in macromolecules.

Anti-idiotypic antibodies were obtained from New Zealand White rabbits injected with affinity-purified rabbit anti-TrpR antibodies. In gel mobility shift studies, such immunoglobulin preparations were shown to contain one or more species able to form specific complexes with DNA molecules bearing a trp operator. In competitive ELISA assays, the binding of anti-idiotypic antibodies to operator-bearing DNA was reversed by TrpR. The demonstration that the immune repertoire contains information for operator-specific DNA-binding proteins may be relevant to the etiology of certain autoimmune diseases.

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.

Integration host factor and cyclic AMP receptor protein are required for TyrR-mediated activation of tpl in Citrobacter freundii.

The tpl gene of Citrobacter freundii encodes an enzyme that catalyzes the conversion of L-tyrosine to phenol, pyruvate, and ammonia. This gene is known to be positively regulated by TyrR. The amplitude of regulation attributable to this transcription factor is at least 20-fold. Three TyrR binding sites, designated boxes A, B, and C, centered at coordinates -272.5, -158.5, and -49.5, respectively, were identified in the upstream region of the tpl promoter. The results of mutational experiments suggest that TyrR binds in cooperative fashion to these sites. The nonavailability of any TyrR site impairs transcription. Full TyrR-mediated activation of tpl required integration host factor (IHF) and the cAMP receptor protein (CRP). By DNase I footprinting, it was shown that the IHF binding site is centered at coordinate -85 and that there are CRP binding sites centered at coordinates -220 and -250. Mutational alteration of the IHF binding site reduced the efficiency of the tpl promoter by at least eightfold. The proposed roles of CRP and IHF are to introduce bends into tpl promoter DNA between boxes A and B or B and C. Multimeric TyrR dimers were demonstrated by a chemical cross-linking method. The formation of hexameric TyrR increased when tpl DNA was present. The participation of both IHF and CRP in the activation of the tpl promoter suggests that molecular mechanisms quite different from those that affect other TyrR-activated promoters apply to this system. A model wherein TyrR, IHF, and CRP collaborate to regulate the expression of the tpl promoter is presented.

The tpl promoter of Citrobacter freundii is activated by the TyrR protein.

The ability of microorganisms to degrade L-tyrosine to phenol, pyruvate, and ammonia is catalyzed by the inducible enzyme L-tyrosine phenol lyase (EC 4.1.99.2). To investigate possible mechanisms for how the synthesis of this enzyme is regulated, a variety of biochemical and genetic procedures was used to analyze transcription from the tpl promoter of Citrobacter freundii ATCC 29063 (C. braakii). By computer analysis of the region upstream of the tpl structural gene, two segments of DNA bearing strong homology to the known operator targets of the TyrR protein of Escherichia coli were detected. A DNA fragment of 509 bp carrying these operator targets plus the presumptive tpl promoter was synthesized by PCR and used to construct a single-copy tpl-lacZ reporter system. The formation of beta-galactosidase in strains carrying this reporter system, which was measured in E. coli strains of various genotypes, was strongly dependent on the presence of a functional TyrR protein. In strains bearing deletions of the tyrR gene, the formation of beta-galactosidase was reduced by a factor of 10. Several mutationally altered forms of TyrR were deficient in their abilities to activate the tpl promoter. The pattern of loss of activation function was exactly parallel to the effects of the same tyrR mutations on the mtr promoter, which is known to be activated by the TyrR protein. When cells carrying the tpl-lacZ reporter system were grown on glycerol, the levels of beta-galactosidase were 10- to 20-fold higher than those observed in glucose-grown cells. The effect was the same whether or not TyrR-mediated stimulation of the tpl promoter was in effect. By deleting the cya gene, it was shown that the glycerol effect was attributable to stimulation of the tpl promoter by the cyclic AMP (cAMP)-cAMP reporter protein system. A presumptive binding site for this transcription factor was detected just upstream of the -35 recognition hexamer of the tpl promoter. The transcriptional start point of the tpl promoter was determined by chemical procedures. The precise locations of the TyrR binding sites, which were established by DNase I footprinting, agreed with the computer-predicted positions of these regulatory sites. The two TyrR operators, which were centered at coordinates -272.5 and -158.5 with respect to the transcriptional start point, were independently disabled by site-directed mutagenesis. When the upstream operator was altered, activation was completely abolished. When the downstream operator was altered, there was a fourfold reduction in reporter enzyme levels. The tpl system presents a number of intriguing features not previously encountered in TyrR-activated promoters. First among these is the question of how the TyrR protein, bound to widely separated operators, activates the tpl promoter which is also widely separated from the operators.

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.

Functional analysis of E. coli threonine dehydrogenase by means of mutant isolation and characterization.

The oxidation of L-threonine to 2-amino-ketobutyrate, as catalyzed by L-threonine dehydrogenase, is the first step in the major pathway for threonine catabolism in both eukaryotes and prokaryotes. Threonine dehydrogenase of E. coli has considerable amino-acid sequence homology with a number of Zn(2+)-containing, medium-chain alcohol dehydrogenases. In order to further explore structure/function interrelationships of E. coli threonine dehydrogenase, 35 alleles of tdh that imparted a no-growth or slow-growth phenotype on appropriate indicator media were isolated after mutagenesis with hydroxylamine. Within this collection, 14 mutants had single amino-acid changes that were divided into 4 groups: (a) amino-acid changes associated with proposed ligands to Zn2+; (b) a substitution of one of several conserved glycine residues; (c) mutations at the substrate or coenzyme binding site; (d) alterations that resulted in a change of charge near the active site. These findings uncover previously unidentified amino-acid residues that are important for threonine dehydrogenase catalysis and also indicate that the three-dimensional structure of tetrameric E. coli threonine dehydrogenase has considerable similarity with the dimeric horse liver alcohol dehydrogenase.

Synechocystis PCC 6803 contains a single gene for the beta subunit of tryptophan synthase with strong homology to the trpB genes of Arabidopsis and maize (Zea mays L.).

We report the sequence of the trpB gene of the cyanobacterium Synechocystis sp. PCC 6803. This gene was cloned from a plasmid library by functional complementation of a trpB mutant of Escherichia coli K-12. Among the known trpB sequences, the Synechocystis gene bears the greatest homology to the duplicated trpB genes of Arabidopsis thaliana and Zea mays. Southern and northern blotting analyses suggest that Synechocystis contains only a single trpB gene. In contrast to all other prokaryotes, Synechocystis has a trpB gene that is monocistronic. Attempts to construct a trpB null mutant of Synechocystis by standard techniques were unsuccessful, suggesting that this organism is unable to concentrate tryptophan from the external medium.

Nucleotide sequence of the Salmonella typhimurium trpR gene.

The sequence of the Salmonella typhimurium trpR gene and flanking DNA was determined on both strands. The DNA sequence predicts a polypeptide product of 108 amino acids with a molecular weight of 12,274 daltons. The TrpR protein of S. typhimurium differs by three amino acid residues from that of E. coli. The promoter/operator region of trpR is completely conserved between E. coli and S. typhimurium. The nucleotide sequence of the trpR sector of the S. typhimurium genome was 87.4% identical to the corresponding region of the E. coli genome. Within the protein coding segments of the two organisms, 94.4% of the amino acid residues were identical. In S. typhimurium, as in E. coli, there is a Palindromic Unit element (PU) between the translation termination triplet of trpR and that of a divergently oriented unidentified reading frame (URF-143). However, the PU segment of S. typhimurium is 85 nucleotides shorter than its E. coli counterpart.

An amino acid switch (Gly281-->Arg) within the "hinge" region of the tryptophan synthase beta subunit creates a novel cleavage site for the OmpT protease and selectively diminishes affinity toward a specific monoclonal antibody.

The in vitro susceptibility to endogenous proteases of the beta subunit of Escherichia coli tryptophan synthase was studied immunochemically. Whereas the wild-type beta subunit was apparently very stable, the missense mutant beta(B8), carrying an amino acid switch from Gly to Arg at residue 281, underwent specific proteolytic cleavage. Polyclonal chicken antibodies and monoclonal antibodies specific for the N terminus (monoclonal antibody (mAb) 15-1), the C terminus (mAb 93-6), and the "hinge" region (mAb 164-2) were used to study the hydrolysis of the beta(B8) polypeptide. Cleavage products of 30 kDa, from the N terminus, and 13 kDa, from the C terminus, were observed. These two polypeptides correspond to the well characterized F1 (N-terminal) and F2 (C-terminal) fragments that are generated during the limited tryptic proteolysis of the wild-type beta subunit. The outer membrane-associated protease OmpT was shown to be responsible for the cleavage of the beta(B8) mutant protein. Proteolytic cleavage, observed only under neutral non-denaturing conditions, was specific for the peptide bond between Arg281 and Met282. The Arg-Met peptide bond has not previously been reported to be susceptible to cleavage by the OmpT protease. The beta(B8) polypeptide had dramatically reduced affinity for mAb 164-2. This antibody interacted more strongly with the OmpT-generated F1-like fragment than with the intact beta(B8) protein. These results strongly suggest that the G281R mutation alters the conformation of the hinge region of the mutant beta subunit, particularly the beta-turn around Gly281. The implications with respect to the epitope recognized by mAb 164-2 are discussed.

A single amino acid switch within the "hinge" region of the tryptophan synthase beta subunit of Escherichia coli that leads to diminished association with alpha subunit and arrested conversion of ESII to product.

The trpB8 mutation of Escherichia coli causes a major conformational change within the beta subunit of tryptophan synthase. The basis of this effect is a replacement of glycine 281 by arginine within a structurally important "hinge" region. The mutant subunit, beta(B8), is catalytically active only under certain conditions, both in vivo and in vitro. Physiologically, the availability of wild type alpha subunit is the most important determinant of catalytic proficiency (Zhao, G.-P., and Somerville, R. L. (1992) J. Biol. Chem. 267, 526-541; Zhao, G.-P., and Somerville, R. L. (1993) J. Biol. Chem. 268, 14912-14920). Through enzyme activity titration experiments it was shown that the alpha subunit of tryptophan synthase dramatically stimulates catalysis by the beta 2(B8) mutant enzyme. However, by size exclusion high performance liquid chromatography, the stability of the alpha.beta 2(B8) complex was markedly reduced in comparison with wild type. The alpha-mediated stimulation of catalysis by the beta 2(B8) mutant enzyme was enhanced by polyethylene glycol, a volume excluder. By absorption spectroscopy, it was shown that catalysis by the beta(B8) mutant protein is blocked in at least one step after the formation of a particular Schiff base intermediate (ESII). Either the alpha subunit or ammonium ion was able to overcome this block. The microenvironment of the ESII catalytic intermediate was examined by fluorescence spectroscopy. The data are consistent with a less hydrophobic environment for ESII in the beta 2(B8) mutant protein than in the wild type protein. These lines of evidence not only support a conformational switch model of open versus closed states within the beta subunit during the catalytic cycle but also suggest a functional role for the hinge region in the process of conformational switching.

A stationary-phase protein of Escherichia coli that affects the mode of association between the trp repressor protein and operator-bearing DNA.

Highly purified preparations of trp repressor (TrpR) protein derived from Escherichia coli strains that were engineered to overexpress this material were found to contain another protein, of 21 kDa. The second protein, designated WrbA [for tryptophan (W) repressor-binding protein] remained associated with its namesake through several sequential protein fractionation steps. The N-terminal amino acid sequence of the WrbA protein guided the design of two degenerate oligonucleotides that were used as probes in the cloning of the wrbA gene (198 codons). The WrbA protein, in purified form, was found by several criteria to enhance the formation and/or stability of noncovalent complexes between TrpR holorepressor and its primary operator targets. The formation of an operator-holorepressor-WrbA ternary complex was demonstrated by gel mobility-shift analysis. The WrbA protein alone does not interact with the trp operator. During the stationary phase, cells deficient in the WrbA protein were less efficient than wild type in their ability to repress the trp promoter. It is proposed that the WrbA protein functions as an accessory element in blocking TrpR-specific transcriptional processes that might be physiologically disadvantageous in the stationary phase of the bacterial life cycle.

ATPase activity of TyrR, a transcriptional regulatory protein for sigma 70 RNA polymerase.

The TyrR protein of Escherichia coli is the chief transcriptional regulator of several genes essential for aromatic amino acid biosynthesis and transport. It was established in previous studies that this protein binds ATP, that the TyrR.ATP complex has enhanced affinity for tyrosine, and that the susceptibility of the TyrR protein to hydrolysis by trypsin is altered by ATP. Here we show that the TyrR protein has ATPase activity, which is stimulated by tyrosine. In this respect the TyrR protein resembles the transcriptional activator NtrC. The NtrC protein contains an internal polypeptide segment, 220 amino acid residues in length, with a high degree of identity to the TyrR protein, that contains the presumptive ATPase catalytic center.

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.

The TyrR protein of Escherichia coli, analysis by limited proteolysis of domain structure and ligand-mediated conformational changes.

The TyrR protein of Escherichia coli K12 is a homodimer containing 513 amino acids/subunit. This protein is important in the transcriptional regulation of several genes whose protein products catalyze steps in aromatic amino acid biosynthesis or transport. Methods were developed for efficiently purifying the TyrR protein to apparent homogeneity. We analyzed the pattern of cleavage of the TyrR protein by trypsin, either in the absence of ligands or in the presence of saturating levels of L-tyrosine, ATP, or poly(dI-dC). At low (1:200 ratio by weight) trypsin levels, in the absence of ligands, two major digestion products accumulated. These were polypeptides of 22 and 31 kDa, shown to contain amino acid residues 1-190 and 191-467, respectively. The pattern of trypsin cleavage was unaffected by tyrosine. In the presence of ATP, an intermediate species of 53 kDa, probably containing amino acid residues 1-467, was observed. The kinetics of appearance of the 53-kDa species were consistent with a role for ATP in accelerating the hydrolysis of the R467-F468 peptide bond. The 53-kDa polypeptide underwent further tryptic hydrolysis to yield fragments of 22 and 31 kDa. When both tyrosine and ATP were present, the rate of formation of the 22- and 31-kDa fragments was more rapid than in the absence of these ligands. It appears that when both ligands are bound, the rates of hydrolysis of peptide bonds R190-Q191 and R467-F468 are both enhanced. Additional limited proteolysis experiments suggested that polypeptide segment 191-467 contains ATP binding site(s), and that the rate of cleavage of peptide bonds R190-Q191 and R467-F468 is altered when the TyrR protein interacts with poly(dI-dC), an analog of target DNA. Our results reveal the presence of two major structural domains within the TyrR protein. The first domain (amino acid residues 1-190) is extremely resistant to hydrolysis by trypsin. The second domain (residues 191-467), which is likely to contain ATP-binding site(s), is homologous to several other transcriptional activators specific for promoters responsive to the sigma 54 form of RNA polymerase. The remainder of the TyrR protein (residues 468-513) contains the operator recognition elements, probably arranged in the form of a helix-turn-helix motif. This polypeptide segment was not detected as a discrete tryptic hydrolysis product.

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

The tyrosine repressor (TyrR) protein of Escherichia coli can function either as a transcriptional enhancer or as a repressor. The structural basis for these opposite effects was analyzed in specific tyrR deletion mutants constructed in vitro. The functional behavior of the mutant TyrR proteins was evaluated in vivo by using single-copy lacZ reporter systems based on the mtr promoter (10-fold activation by wild-type TyrR protein, mediated by phenylalanine or tyrosine) or the aroF promoter (over 20-fold repression by wild-type TyrR protein, mediated by tyrosine). A mutant TyrR protein lacking amino acids 2 to 9 was completely devoid of transcriptional activation function. Five additional mutant TyrR proteins lacking progressively greater numbers of N-terminal amino acids were likewise activation defective. The mutant TyrR proteins lacking amino acid residues 2 to 9 or 2 to 19 were essentially identical to the wild-type TyrR protein in their ability to repress the aroF promoter. Three other TyrR mutant proteins, lacking up to 143 amino acid residues from the N-terminal end of the protein, retained the ability to repress the aroF promoter, to different extents, in a tyrosine-dependent manner.