Characterization of tryptophan synthase alpha subunit mutants of Arabidopsis thaliana

Three mutations in the Arabidopsis thaliana gene encoding the alpha subunit of tryptophan synthase were isolated by selection for resistance to 5-methylanthranilate or 5-fluoroindole, toxic analogs of tryptophan pathway intermediates. Plants homozygous for trp3-1 and trp3-2 are light-conditional tryptophan auxotrophs, while trp3-100 is a more leaky mutant. Genetic complementation crosses demonstrated that the three mutations are allelic to each other, and define a new complementation group. All three mutants have decreased steady-state levels of tryptophan synthase alpha protein, and the trp3-100 polypeptide exhibits altered electrophoretic mobility. All three mutations were shown to be in the TSA1 (tryptophan synthase alpha subunit) structural gene by several criteria. Firstly, the trp3-1 mutation is linked to TSA1 on the bottom of chromosome 3. Secondly, the trp3-1 mutation was complemented when transformed with the wild-type TSA1 gene. Finally, DNA sequence analysis of the TSA1 gene revealed a single transition mutation in each trp3 mutant.     

Site-directed mutagenesis of the alpha subunit of tryptophan synthase from Salmonella typhimurium

Site-specific mutagenesis has been used to prepare two mutant forms of the alpha subunit of tryptophan synthase from Salmonella typhimurium in which either cysteine-81 or cysteine-118 is replaced by a serine residue. These mutant proteins are potentially useful for x-ray crystallographic studies since a heavy metal binding site is specifically eliminated in each mutant. The purified mutant proteins are fully active in four reactions catalyzed by the wild type alpha 2 beta 2 complex of tryptophan synthase. However, the mutant alpha 2 beta 2 complexes dissociate more readily and are less heat-stable than the wild type alpha 2 beta 2 complex. Thus, cysteine-81 and cysteine-118 of the alpha subunit serve structural but not functional roles.     

Synergism in folding of a double mutant of the alpha subunit of tryptophan synthase

The urea-induced unfolding of the inactive single mutants Tyr-175----Cys and Gly-211----Glu and the active double mutant Cys-175/Glu-211 of the alpha subunit of tryptophan synthase from Escherichia coli was examined by using ultraviolet difference spectroscopy. Equilibrium techniques were used to determine the equilibrium free energies of unfolding for the mutant proteins to permit comparison with the wild-type protein. The sum of the changes in stability for the single mutants is not equal to the change seen in the double mutant. This inequality is evidence for a structural interaction between these two residues. Kinetic studies show that this synergism, which destabilizes the native form by 1.5-2.0 kcal/mol at pH 7.8, 25 degrees C, occurs only after the final rate-limiting step of domain association.     

Characterization of a slow folding reaction for the alpha subunit of tryptophan synthase

The equilibria and kinetics of urea-induced unfolding and refolding of the alpha subunit of tryptophan synthase of E. coli have been examined for their dependences on viscosity, pH, and temperature in order to investigate the properties of one of the rate-limiting steps, domain association. A viscosity enhancer, 0.58 M sucrose, was found to slow unfolding and accelerate refolding. This apparently anomalous result was shown to be due to the stabilizing effect of sucrose on the folding reaction. After accounting for this stabilization effect by using linear free-energy plots, the unfolding and refolding kinetics were found to have a viscosity dependence. A decrease in pH was found to stabilize the domain association reaction by increasing the refolding rate and decreasing the unfolding rate. This effect was accounted for by protonation of a single residue with a pK value of 8.8 in the native state and 7.1 in the intermediate, in which the two domains are not yet associated. The activation energy of unfolding is 4.8 kcal/mol, close to the diffusion limit. The negative activation entropy of unfolding, -47 cal/deg-mol, which controls this reaction, may result from ordering of solvent about the newly exposed domain interface of the transition state. These results may provide information on the types of noncovalent interactions involved in domain association and improve the ability to interpret the folding of mutants with single amino-acid substitutions at the interface.     

Characterization of tryptophan synthase alpha subunit mutants of Arabidopsis thaliana

 Three mutations in the Arabidopsis thaliana gene encoding the alpha subunit of tryptophan synthase were isolated by selection for resistance to 5-methylanthranilate or 5-fluoroindole, toxic analogs of tryptophan pathway intermediates. Plants homozygous for trp3-1 and trp3-2 are light-conditional tryptophan auxotrophs, while trp3-100 is a more leaky mutant. Genetic complementation crosses demonstrated that the three mutations are allelic to each other, and define a new complementation group. All three mutants have decreased steady-state levels of tryptophan synthase alpha protein, and the trp3-100 polypeptide exhibits altered electrophoretic mobility. All three mutations were shown to be in the TSA1 (tryptophan synthase alpha subunit) structural gene by several criteria. Firstly, the trp3-1 mutation is linked to TSA1 on the bottom of chromosome 3. Secondly, the trp3-1 mutation was complemented when transformed with the wild-type TSA1 gene. Finally, DNA sequence analysis of the TSA1 gene revealed a single transition mutation in each trp3 mutant. Received: 28 May 1996 / Accepted: 19 June 1996     

Selection and analysis of non-interactive mutants in the Escherichia coli tryptophan synthase alpha subunit.

Summary The inherent infidelity of Taq DNA polymerase in the polymerase chain reaction was exploited to produce random mutations in thetrp A gene. Screening of the resulting clones allowed selection of non-interactive mutant subunits retaining their intrinsic catalytic activity. Two single changes responsible for this phenotype were identified by DNA sequencing as: 126 valine (GTG)glutamic acid (GAG) and 128 valine (GTT)aspartic acid (GAT). Three single changes giving a non-interactive phenotype with an impaired intrinsic catalytic activity were identified by DNA sequencing as a66 asparagine (AAC)aspartic acid (GAC); 109lysine (AAA) arginine (AGA); 118 cysteine (TGC)arginine (CGC). Where possible, we individually assessed the importance of these residues in interaction in light of structural information from X-ray crystallography and by intergeneric protein sequence comparison.     

Improved method for measuring the catalytic activity of tryptophan synthase alpha subunit in cell extracts

An improved method has been developed for measuring the catalytic activity of tryptophan synthase alpha-subunit in cell extracts using the indole-3-glycerol phosphate (InGP)----tryptophan reaction. The method involves the chemical and enzymatic synthesis of the substrate InGP immediately before use and avoids the preparation of salt-free hydroxylamine. The method is more convenient, safer and more reliable than the traditional method employing the InGP----indole reaction.     

Role of diffusion in the folding of the alpha subunit of tryptophan synthase from Escherichia coli

The rate-limiting step in the folding of the alpha subunit of tryptophan synthase has been proposed to be the association of two folding units. To probe the role of diffusion in this rate-limiting step, the urea-induced unfolding and refolding of the protein was examined in the presence of a number of viscosity-enhancing agents. The analysis was simplified by studying the effect of these agents on folding unit dissociation, the rate-limiting unfolding reaction, and the reverse of the rate-limiting step in refolding. In the presence of ethylene glycol, the relaxation times for unfolding to the same final conditions increased with increasing concentration of the cosolvent. When the effects of the cosolvent on protein stability were taken into account, the rates were found to show a unitary linear dependence on the viscosity of the solution. Similar results were obtained with glycerol and low concentrations of glucose, demonstrating that the effect is general and not specific to any viscogenic agent. These results clearly demonstrate that the rate-limiting folding unit association/dissociation reaction in the alpha subunit of tryptophan synthase involves a diffusional process.     

Effect of single amino acid substitutions on the protease susceptibility of tryptophan synthase alpha subunit

In order to explore the correlation between protease susceptibility and conformational stability of a protein, the proteolytic degradation by trypsin, subtilisin and pronase P of the wild-type alpha subunit of tryptophan synthase from Escherichia coli and of its two mutant proteins was studied by measuring circular dichroism at 222 nm at various pH values at 37 degrees C. The mutant proteins are substituted by Gln or Met in place of Glu at position 49. The single amino acid substitutions at position 49 significantly affected susceptibility of this protein to the three proteases. Dependence of protease susceptibility of the wild-type and the two mutant proteins on pH was characteristic of each protein and similar for the three proteases. Comparison of the present results with the conformational stabilities of the three proteins previously measured shows that the order of resistance to the proteases among the three proteins coincides with the order of the values of unfolding Gibbs energy change, suggesting that protein degradation depends upon the conformational stability of a protein.     

Allosteric communication between alpha and beta subunits of tryptophan synthase: modelling the open-closed transition of the alpha subunit

Ligand binding to the alpha-subunit of the alpha2beta2 complex of tryptophan synthase induces the alphaloop6 closure over the alpha-active site. This conformational change is associated with the formation of a hydrogen bond between alphaGly181 NH group and betaSer178 carbonyl oxygen, a key event for the triggering of intersubunit allosteric signals. Mutation of betaSer178 to Pro and alphaGly181 to Pro, Ala, Phe and Val abolishes the ligand-induced intersubunit communication. Molecular dynamics methods were applied to simulate the conformation of the highly flexible and crystallographically undetectable open state of alphaloop6 in the wild type and in the alpha181 mutants. The open conformation of alphaloop6 is favoured in the wild type enzyme in the absence of alpha-ligands, and in the alpha181 mutants both in the presence and absence of bound ligands. A very good correlation was found between the extent of limited tryptic proteolysis and both the hydrogen bond distance between alphaX181 and betaSer178, obtained from the molecular dynamics simulation, and the hydrogen bond strength, evaluated by HINT, an empirical force field that takes into account both enthalpic and entropic contributions. Comparison of the open and closed conformations of alphaloop6 suggests a pathway for substrate entrance into the alpha-active site and provides an explanation for the limited catalytic efficiency of the open state.     

Prediction of secondary structure by evolutionary comparison: application to the alpha subunit of tryptophan synthase

The amino acid sequences of the a subunits of tryptophan synthase from ten different microorganisms were aligned by standard procedures. The alpha helices, beta strands and turns of each sequence were predicted separately by two standard prediction algorithms and averaged at homologous sequence positions. Additional evidence for conserved secondary structure was derived from profiles of average hydropathy and chain flexibility values, leading to a joint prediction. There is good agreement between (1) predicted beta strands, maximal hydropathy and minimal flexibility, and (2) predicted loops, great chain flexibility, and protein segments that accept insertions of various lengths in individual sequences. The a subunit is predicted to have eight repeated beta-loop-alpha-loop motifs with an extra N-terminal alpha helix and an intercalated segment of highly conserved residues. This pattern suggests that the territory structure of the a subunit is an eightfold alpha/beta barrel. The distribution of conserved amino acid residues and published data on limited proteolysis, chemical modification, and mutagenesis are consistent with the alpha/beta barrel structure. Both the active site of the a subunit and the combining site for the beta 2 subunit are at the end of the barrel formed by the carboxyl-termini of the beta strands.     

Cooperative fluctuations and subunit communication in tryptophan synthase

Tryptophan synthase (TRPS), with linearly arrayed subunits alphabetabetaalpha, catalyzes the last two reactions in the biosynthesis of L-tryptophan. The two reactions take place in the respective alpha- and beta-subunits of the enzyme, and the intermediate product, indole, is transferred from the alpha- to the beta-site through a 25 A long hydrophobic tunnel. The occurrence of a unique ligand-mediated long-range cooperativity for substrate channeling, and a quest to understand the mechanism of allosteric control and coordination in metabolic cycles, have motivated many experimental studies on the structure and catalytic activity of the TRPS alpha2beta2 complex and its mutants. The dynamics of these complexes are analyzed here using a simple but rigorous theoretical approach, the Gaussian network model. Both wild-type and mutant structures, in the unliganded and various liganded forms, are considered. The substrate binding site in the beta-subunit is found to be closely coupled to a group of hinge residues (beta77-beta89 and beta376-beta379) near the beta-beta interface. These residues simultaneously control the anticorrelated motion of the two beta-subunits, and the opening or closing of the hydrophobic tunnel. The latter process is achieved by the large amplitude fluctuations of the so-called COMM domain in the same subunit. Intersubunit communications are strengthened in the presence of external aldimines bound to the beta-site. The motions of the COMM core residues are coordinated with those of the alpha-beta hinge residues beta174-beta179 on the interfacial helix betaH6 at the entrance of the hydrophobic tunnel. And the motions of betaH6 are coupled, via helix betaH1 and alphaL6, to those of the loop alphaL2 that includes the alpha-subunit catalytically active residue Asp60. Overall, our analysis sheds light on the molecular machinery underlying subunit communication, and identifies the residues playing a key role in the cooperative transmission of conformational motions across the two reaction sites.     

Effect of a single amino acid substitution on the folding of the alpha subunit of tryptophan synthase

The urea-induced unfolding of a missense mutant of the alpha subunit of tryptophan synthase from Escherichia coli involving the replacement of Gly by Glu at position 211 has been monitored by absorbance changes at 286 nm. Like the wild-type protein, the equilibrium unfolding curve demonstrates the presence of one or more stable intermediates. Comparison of these results with those from the wild-type alpha subunit [Matthews, C. R., & Crisanti, M. M. (1981) Biochemistry 20, 784] shows that the transition from the native conformation to the stable intermediates is displaced to higher urea concentration in the mutant alpha subunit; however, the transition from the intermediates to the unfolded form is unaffected. Kinetic studies show that the amino acid replacement slows the rate of unfolding by an order of magnitude. The effect on refolding rates is complex. One phase, previously assigned to proline isomerization [Crisanti, M. M., & Matthews, C. R. (1981) Biochemistry 20, 2700], is unaffected by the substitution. The rate of the second phase, which is urea dependent down to about 1 M urea, is slower than the corresponding phase in the wild-type protein by approximately a factor of 2. Below about 1 M urea, the rate of this phase becomes urea independent and identical with that of the wild-type alpha subunit. This change in urea dependence has been ascribed to a change in the nature of the rate-limiting step for this process from one involving folding to one involving proline isomerization. The results support the folding model for the alpha subunit proposed previously [Matthews, C. R., & Crisanti, M. M. (1981) Biochemistry 20, 784] and clarify the role of proline isomerization in limiting the rate of folding.     

Proline isomerization and the slow folding reactions of the alpha subunit of tryptophan synthase from Escherichia coli

Previous studies on the refolding of the alpha subunit of tryptophan synthase from Escherichia coli assigned two slow refolding phases to rate-limiting isomerizations of two 'essential' proline residues, one in each of the two domains of the protein (Matthews, C.R., Crisanti, M.M., Manz, J.T. and Gepner, G.L. (1983) Biochemistry 22, 1445-1452). The double-jump experiment (Brandts, J.F., Halvorson, H.R. and Brennan, M. (1975) Biochemistry 14, 4953-4963) was used to further investigate this phenomenon. The reaction assigned to the carboxyl domain is consistent with the proline isomerization hypothesis. The amino domain process is more rapid than expected for proline isomerization and may reflect another type of slow folding reaction. The results permit a further refinement of the folding model for the alpha subunit and demonstrate the existence of a third unfolded species whose folding is not limited by either of these two reactions.     

The tryptophan synthase alpha 2 beta 2 complex. Cleavage of a flexible loop in the alpha subunit alters allosteric properties

This study explores the catalytic and allosteric roles of a flexible loop in tryptophan synthase. Trypsin is known to cleave the tryptophan synthase alpha 2 beta 2 complex in an alpha subunit loop at Arg-188. Cleavage yields an active "nicked" alpha 2 beta 2 derivative. The new results provide evidence that the alpha subunit loop serves two important roles: substrate binding and communicating the effects of substrate binding to the beta subunit. A role for the loop in substrate binding is supported by our finding that addition of a substrate analogue of the alpha subunit, alpha-glycerol 3-phosphate, decreases the rate of cleavage by trypsin. An allosteric role for the loop is supported by the finding although the native alpha 2 beta 2 complex is strongly inhibited by alpha-glycerol 3-phosphate, the nicked alpha 2 beta 2 complex is desensitized to this inhibition. The time course of proteolysis in the presence and absence of alpha-glycerol 3-phosphate is followed by sodium dodecyl sulfate-gel electrophoresis and by assays of activity in the presence and absence of alpha-glycerol 3-phosphate. We use spectroscopic measurements of the pyridoxal phosphate-L-tryptophan intermediates at the active site of the beta subunit to determine the affinity of the native and nicked enzymes for L-tryptophan and alpha-glycerol 3-phosphate. Although cleavage alters the equilibrium distribution of intermediates and reduces the affinity for alpha-glycerol 3-phosphate, it has little effect on the affinity for amino acids bound to the beta subunit. We conclude that the loop in the alpha subunit is important for ligand binding and for communicating the effects of ligand binding from the alpha subunit to the beta subunit in the alpha 2 beta 2 complex.     

Characterization of an early intermediate in the folding of the alpha subunit of tryptophan synthase by hydrogen exchange measurement

The development of the hydrogen bonding network in the early stages of the folding of the alpha subunit of tryptophan synthase was monitored with a hydrogen exchange technique. The orders of magnitude difference between the rapid conversions of the unfolded forms to two stable intermediates (milliseconds) and the subsequent slow conversions of the intermediates to the native form (greater than 100 s) was used to selectively label with tritium the hydrogen bonds that form in the first 30 s of folding at 0 degree C. Rapid removal of the tritiated solvent by gel filtration ensured that hydrogen bonds formed in subsequent folding reactions would be unlabeled. Limited proteolysis and separation of peptides by high-pressure liquid chromatography permitted the determination of the amount of label retained in individual peptides by scintillation counting. Peptides 1-70 and 71-188, which when covalently linked comprise the stable amino domain in the native conformation, retain 91% and 93%, respectively, of the label retained when the protein is allowed to completely refold in tritiated solvent. Peptide 189-268, the marginally stable carboxyl domain, only retains 43% of the label. The striking difference in retention of label confirms the independent folding of these two domains and shows that the kinetic intermediates that appear in the folding of alpha subunit correspond to structural domains in the native conformation. The near-equality of the labeling of the two peptides comprising the amino domain shows that this domain folds as a single entity and that subdomain folding is unlikely.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identifying the structural boundaries of independent folding domains in the alpha subunit of tryptophan synthase, a beta/alpha barrel protein.

Two equilibrium intermediates have previously been observed in the urea denaturation of the alpha subunit of tryptophan synthase (alphaTS) from Escherichia coli, an eight-stranded beta/alpha barrel protein. In the current study, a series of amino-terminal fragments were characterized to probe the elementary folding units that may be in part responsible for this complex behavior. Stop-codon mutagenesis was used to produce eight fragments ranging in size from 105-214 residues and containing incremental elements of secondary structure. Equilibrium studies by circular dichroism indicate that all of these fragments are capable of adopting secondary structure. All except for the shortest fragment fold cooperatively. The addition of the fourth, sixth, and eighth beta-strands leads to distinct increases in structure, cooperativity, and/or stability, suggesting that folding involves the modular assembly of betaalphabeta supersecondary structural elements. One-dimensional NMR titrations at high concentrations of urea, probing the environment around His92, were also performed to test for the presence of residual structure in the fragments. All fragments that contained the first four betaalpha units of structure exhibited a cooperative unfolding transition at high concentrations of urea with significant but reduced stability relative to the full-length protein. These results suggest that the residual structure in alphaTS requires the participation of hydrophobic residues in multiple beta-strands that span the entire sequence.