Allosteric regulation of tryptophan synthase channeling: the internal aldimine probed by trans-3-indole-3'-acrylate binding

Substrate channeling in the tryptophan synthase bienzyme complex from Salmonella typhimurium is regulated by allosteric interactions triggered by binding of ligand to the alpha-site and covalent reaction at the beta-site. These interactions switch the enzyme between low-activity forms with open conformations and high-activity forms with closed conformations. Previously, allosteric interactions have been demonstrated between the alpha-site and the external aldimine, alpha-aminoacrylate, and quinonoid forms of the beta-site. Here we employ the chromophoric l-Trp analogue, trans-3-indole-3'-acrylate (IA), and noncleavable alpha-site ligands (ASLs) to probe the allosteric properties of the internal aldimine, E(Ain). The ASLs studied are alpha-d,l-glycerol phosphate (GP) and d-glyceraldehyde 3-phosphate (G3P), and examples of two new classes of high-affinity alpha-site ligands, N-(4'-trifluoromethoxybenzoyl)-2-aminoethyl phosphate (F6) and N-(4'-trifluoromethoxybenzenesulfonyl)-2-aminoethyl phosphate (F9), that were previously shown to bind to the alpha-site by optical spectroscopy and X-ray crystal structures [Ngo, H., Harris, R., Kimmich, N., Casino, P., Niks, D., Blumenstein, L., Barends, T. R., Kulik, V., Weyand, M., Schlichting, I., and Dunn, M. F. (2007) Synthesis and characterization of allosteric probes of substrate channeling in the tryptophan synthase bienzyme complex, Biochemistry 46, 7713-7727]. The binding of IA to the beta-site is stimulated by the binding of GP, G3P, F6, or F9 to the alpha-site. The binding of ASLs was found to increase the affinity of the beta-site of E(Ain) for IA by 4-5-fold, demonstrating for the first time that the beta-subunit of the E(Ain) species undergoes a switching between low- and high-affinity states in response to the binding of ASLs.     

Allosteric regulation of substrate channeling in tryptophan synthase: modulation of the L-serine reaction in stage I of the beta-reaction by alpha-site ligands

In the tryptophan synthase bienzyme complex, indole produced by substrate cleavage at the alpha-site is channeled to the beta-site via a 25 A long tunnel. Within the beta-site, indole and l-Ser react with pyridoxal 5'-phosphate in a two-stage reaction to give l-Trp. In stage I, l-Ser forms an external aldimine, E(Aex1), which converts to the alpha-aminoacrylate aldimine, E(A-A). Formation of E(A-A) at the beta-site activates the alpha-site >30-fold. In stage II, indole reacts with E(A-A) to give l-Trp. The binding of alpha-site ligands (ASLs) exerts strong allosteric effects on the reaction of substrates at the beta-site: the distribution of intermediates formed in stage I is shifted in favor of E(A-A), and the binding of ASLs triggers a conformational change in the beta-site to a state with an increased affinity for l-Ser. Here, we compare the behavior of new ASLs as allosteric effectors of stage I with the behavior of the natural product, d-glyceraldehyde 3-phosphate. Rapid kinetics and kinetic isotope effects show these ASLs bind with affinities ranging from micro- to millimolar, and the rate-determining step for conversion of E(Aex1) to E(A-A) is increased by 8-10-fold. To derive a structure-based mechanism for stage I, X-ray structures of both the E(Aex1) and E(A-A) states complexed with the different ASLs were determined and compared with structures of the ASL complexes with the internal aldimine [Ngo, H., Harris, R., Kimmich, N., Casino, P., Niks, D., Blumenstein, L., Barends, T. R., Kulik, V., Weyand, M., Schlichting, I., and Dunn, M. F. (2007) Biochemistry 46, 7713-7727].     

Synergistic effects on escape of a ligand from the closed tryptophan synthase bienzyme complex

Substrate channeling in the tryptophan synthase bienzyme complex is regulated by allosteric signals between the alpha- and beta-active sites acting over a distance of 25 A. At the alpha-site, indole is cleaved from 3-indole-D-glycerol 3'-phosphate (IGP) and is channeled to the beta-site via a tunnel. Harris and Dunn [Harris, R. M., and Dunn, M. F. (2002) Biochemistry 41, 9982-9990] showed that when the novel amino acid, dihydroiso-L-tryptophan (DIT), reacts with the beta-site, the alpha-aminoacrylate Schiff base, E(A-A), is formed and the enzyme releases indoline. The indoline produced exits the enzyme via the tunnel out the open alpha-site. When the alpha-site ligand (ASL) alpha-D,L-glycerol 3-phosphate (GP) binds and closes the alpha-site, indoline generated in the DIT reaction is trapped for a short period of time as the quinonoid intermediate in rapid equilibrium with bound indoline and the E(A-A) intermediate before leaking out of the closed enzyme. In this work, we use the DIT reaction and a new, high-affinity, ASL, N-(4-trifluoromethoxybenzenesulfonyl)-2-amino-1-ethyl phosphate (F9), to explore the mechanism of ligand leakage from the closed enzyme. It was found that F9 binding to the alpha-site is significantly more effective than GP in trapping indoline in the DIT reaction; however, leakage of indoline from the enzyme into solution still occurs. It was also found that a combination of benzimidazole (BZI) and GP provided even more effective trapping than F9. The new experiments with F9 and the combination of BZI and GP provide evidence that the coincident binding of GP and BZI at the alpha-site exhibits a strong synergistic effect that greatly slows the leakage of indoline in the DIT reaction and enhances the trapping effect. This synergism functions to tightly close the alpha-site and sends an allosteric signal that stabilizes the closed structure of the beta-site. These studies also support a mechanism for the escape of indoline through the alpha-site that is limited by ASL dissociation.     

The tryptophan synthase bienzyme complex transfers indole between the alpha- and beta-sites via a 25-30 A long tunnel

The bacterial tryptophan synthase bienzyme complexes (with subunit composition alpha 2 beta 2) catalyze the last two steps in the biosynthesis of L-tryptophan. For L-tryptophan synthesis, indole, the common metabolite, must be transferred by some mechanism from the alpha-catalytic site to the beta-catalytic site. The X-ray structure of the Salmonella typhimurium tryptophan synthase shows the catalytic sites of each alpha-beta subunit pair are connected by a 25-30 A long tunnel [Hyde, C. C., Ahmed, S. A., Padlan, E. A., Miles, E. W., & Davies, D. R. (1988) J. Biol. Chem. 263, 17857-17871]. Since the S. typhimurium and Escherichia coli enzymes have nearly identical sequences, the E. coli enzyme must have a similar tunnel. Herein, rapid kinetic studies in combination with chemical probes that signal the bond formation step between indole (or nucleophilic indole analogues) and the alpha-aminoacrylate Schiff base intermediate, E(A-A), bound to the beta-site are used to investigate tunnel function in the E. coli enzyme. If the tunnel is the physical conduit for the transfer of indole from the alpha-site to the beta-site, then ligands that block the tunnel should also inhibit the rate at which indole and indole analogues from external solution react with E(A-A). We have found that when D,L-alpha-glycerol 3-phosphate (GP) is bound to the alpha-site, the rate of reaction of indole and nucleophilic indole analogues with E(A-A) is strongly inhibited. These compounds appear to gain access to the beta-site via the alpha-site and the tunnel, and this access is blocked by the binding of GP to the alpha-site. However, when small nucleophiles such as hydroxylamine, hydrazine, or N-methylhydroxylamine are substituted for indole, the rate of quinonoid formation is only slightly affected by the binding of GP. Furthermore, the reactions of L-serine and L-tryptophan with alpha 2 beta 2 show only small rate effects due to the binding of GP. From these experiments, we draw the following conclusions: (1) L-Serine and L-tryptophan gain access to the beta-site of alpha 2 beta 2 directly from solution. (2) The small effects of GP on the rates of the L-serine and L-tryptophan reactions are due to GP-mediated allosteric interactions between the alpha- and beta-sites.(ABSTRACT TRUNCATED AT 400 WORDS)     

Allosteric communication in the tryptophan synthase bienzyme complex: roles of the beta-subunit aspartate 305-arginine 141 salt bridge

The allosteric interactions that regulate substrate channeling and catalysis in the tryptophan synthase bienzyme complex from Salmonella typhimurium are triggered by covalent reactions at the beta-site and binding of substrate/product to the alpha-site. The transmission of these allosteric signals between the alpha- and beta-catalytic sites is modulated by an ensemble of weak bonding interactions consisting of salt bridges, hydrogen bonds, and van der Waals contacts that switch the subunits between open and closed conformations. Previous work has identified a scaffolding of salt-bridges extending between the alpha- and beta-sites consisting of alphaAsp 56, betaLys 167, and betaAsp 305. This work investigates the involvement of yet another salt bridging interaction involving the betaAsp 305-betaArg 141 pair via comparison of the spectroscopic, catalytic, and allosteric properties of the betaD305A and betaR141A mutants with the behavior of the wild-type enzyme. These mutations were found to give bienzyme complexes with impaired allosteric communication. The betaD305A mutant also exhibits altered beta-site substrate reaction specificity, while the catalytic activity of the betaR141A mutant exhibits impaired beta-site catalytic activity. The >25-fold activation of the alpha-site by alpha-aminoacrylate Schiff base formation at the beta-site found in the Na(+) form of the wild-type enzyme is abolished in the Na(+) forms of both mutants. Replacing Na(+) by NH(4)(+) or Cs(+) restores the betaD305A to a wild-type-like behavior, whereas only partial restoration is achieved with the betaR141A mutant. These studies establish that the betaD305-betaR141 salt bridge plays a crucial role both in the formation of the closed conformation of the beta-site and in the transmission of allosteric signals between the alpha- and beta-sites that switch the alpha-site on and off.     

Investigation of allosteric linkages in the regulation of tryptophan synthase: the roles of salt bridges and monovalent cations probed by site-directed mutation, optical spectroscopy, and kinetics

The tryptophan synthase bienzyme complex is the most extensively documented example of substrate channeling in which the oligomeric unit has been described at near atomic resolution. Transfer of the common metabolite, indole, between the alpha- and the beta-sites occurs by diffusion along a 25-A-long interconnecting tunnel within each alphabeta-dimeric unit of the alpha(2)beta(2) oligomer. The control of metabolite transfer involves allosteric interactions that trigger the switching of alphabeta-dimeric units between open and closed conformations and between catalytic states of low and high activity. This allosteric signaling is triggered by covalent transformations at the beta-site and ligand binding to the alpha-site. The signals are transmitted between sites via a scaffolding of structural elements that includes a monovalent cation (MVC) binding site and salt bridging interactions of betaLys 167 with betaAsp 305 or alphaAsp 56. Through the combined strategies of site-directed mutations of these amino acid residues and cation substitutions at the MVC site, this work examines the interrelationship of the MVC site and the alternative salt bridges formed between Lys beta167 with Asp beta305 or Asp alpha56 to the regulation of channeling. These experiments show that both the binding of a MVC and the formation of the Lys beta167-Asp alpha56 salt bridge are important to the transmission of allosteric signals between the sites, whereas, the salt bridge between betaK167 and betaD305 appears to be only of minor significance to catalysis and allosteric regulation. The mechanistic implications of these findings both for substrate channeling and for catalysis are discussed.     

Allosteric interactions coordinate catalytic activity between successive metabolic enzymes in the tryptophan synthase bienzyme complex.

Tryptophan synthase from enteric bacteria is an alpha 2 beta 2 bienzyme complex that catalyzes the final two reactions in the biosynthesis of L-tryptophan (L-Trp) from 3-indole-D-glycerol 3'-phosphate (IGP) and L-serine (L-Ser). The bienzyme complex exhibits reciprocal ligand-mediated allosteric interactions between the heterologous subunits [Houben, K., & Dunn, M. F. (1990) Biochemistry 29, 2421-2429], but the relationship between allostery and catalysis had not been completely defined. We have utilized rapid-scanning stopped-flow (RSSF) UV-visible spectroscopy to study the relationship between allostery and catalysis in the alpha beta-reaction catalyzed by the bienzyme complex from Salmonella typhimurium. The pre-steady-state spectral changes that occur when L-Ser and IGP are mixed simultaneously with the alpha 2 beta 2 complex show that IGP binding to the alpha-site accelerates the formation of alpha-aminoacrylate [E(A-A)] from L-Ser at the beta-site. Through the use of L-Ser analogues, we show herein that the formation of the E(A-A) intermediate is the chemical signal which triggers the conformational transition that activates the alpha-subunit. beta-subunit ligands, such as L-Trp, that react to form covalent intermediates at the beta-site, but are incapable of E(A-A) formation, do not stimulate the activity of the alpha-subunit. Titration experiments show that the affinity of G3P and GP at the alpha-site is dependent upon the nature of the chemical intermediate present at the beta-active site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Beta D305A mutant of tryptophan synthase shows strongly perturbed allosteric regulation and substrate specificity.

Substrate channeling in the tryptophan synthase bienzyme is regulated by allosteric interactions. Allosteric signals are transmitted via a scaffolding of structural elements that includes a monovalent cation-binding site and salt-bridging interactions between the side chains of betaAsp 305, betaArg 141, betaLys 167, and alphaAsp 56 that appear to modulate the interconversion between open and closed conformations. betaAsp 305 also interacts with the hydroxyl group of the substrate L-Ser in some structures. One possible functional role for betaAsp 305 is to ensure the allosteric transmission that triggers the switching of alphabeta-dimeric units between open and closed conformations of low and high activity. This work shows that substitution of betaAsp 305 with Ala (betaD305A) decreases the affinity of the beta-site for the substrate L-Ser, destabilizes the enzyme-bound alpha-aminoacrylate, E(A-A), and quinonoid species, E(Q), and changes the nucleophile specificity of the beta-reaction. The altered specificity provides a biosynthetic route for new L-amino acids derived from substrate analogues. betaD305A also shows an increased rate of formation of pyruvate upon reaction with L-Ser relative to the wild-type enzyme. The formation of pyruvate is strongly inhibited by the binding of benzimidazole to E(A-A). Upon reaction with L-Ser and in the presence of the alpha-site substrate analogue, alpha-glycerol phosphate, the Na(+) form of betaD305A undergoes inactivation via reaction of nascent alpha-aminoacrylate with bound PLP. This work establishes important roles for betaAsp 305 both in the conformational change between open and closed states that takes place at the beta-site during the formation of the E(A-A) and in substrate binding and recognition.     

BetaQ114N and betaT110V mutations reveal a critically important role of the substrate alpha-carboxylate site in the reaction specificity of tryptophan synthase

In the PLP-requiring alpha2beta2 tryptophan synthase complex, recognition of the substrate l-Ser at the beta-site includes a loop structure (residues beta110-115) extensively H-bonded to the substrate alpha-carboxylate. To investigate the relationship of this subsite to catalytic function and to the regulation of substrate channeling, two loop mutants were constructed: betaThr110 --> Val, and betaGln114 --> Asn. The betaT110V mutation greatly impairs both catalytic activity in the beta-reaction, and allosteric communication between the alpha- and beta-sites. The crystal structure of the betaT110V mutant shows that the modified l-Ser carboxylate subsite has altered protein interactions that impair beta-site catalysis and the communication of allosteric signals between the alpha- and beta-sites. Purified betaQ114N consists of two species of mutant protein, one with a reddish color (lambdamax = 506 nm). The reddish species is unable to react with l-Ser. The second betaQ114N species displays significant catalytic activities; however, intermediates obtained on reaction with substrate l-Ser and substrate analogues exhibit perturbed UV/vis absorption spectra. Incubation with l-Ser results in the formation of an inactive species during the first 15 min with lambdamax approximately 320 nm, followed by a slower conversion over 24 h to the species with lambdamax = 506 nm. The 320 and 506 nm species originate from conversion of the alpha-aminoacrylate external aldimine to the internal aldimine and alpha-aminoacrylate, followed by the nucleophilic attack of alpha-aminoacrylate on C-4' of the internal aldimine to give a covalent adduct with PLP. Subsequent treatment with sodium hydroxide releases a modified coenzyme consisting of a vinylglyoxylic acid moiety linked through C-4' to the 4-position of the pyridine ring. We conclude that the shortening of the side chain accompanying the replacement of beta114-Gln by Asn relaxes the steric constraints that prevent this reaction in the wild-type enzyme. This study reveals a new layer of structure-function interactions essential for reaction specificity in tryptophan synthase.     

Distinct conformational dynamics and allosteric networks in alpha tryptophan synthase during active catalysis

Experimental observations of enzymes under active turnover conditions have brought new insight into the role of protein motions and allosteric networks in catalysis. Many of these studies characterize enzymes under dynamic chemical equilibrium conditions, in which the enzyme is actively catalyzing both the forward and reverse reactions during data acquisition. We have previously analyzed conformational dynamics and allosteric networks of the alpha subunit of tryptophan synthase under such conditions using NMR. We have proposed that this working state represents a four to one ratio of the enzyme bound with the indole‐3‐glycerol phosphate substrate (E:IGP) to the enzyme bound with the products indole and glyceraldehyde‐3‐phosphate (E:indole:G3P). Here, we analyze the inactive D60N variant to deconvolute the contributions of the substrate‐ and products‐bound states to the working state. While the D60N substitution itself induces small structural and dynamic changes, the D60N E:IGP and E:indole:G3P states cannot entirely account for the conformational dynamics and allosteric networks present in the working state. The act of chemical bond breakage and/or formation, or possibly the generation of an intermediate, may alter the structure and dynamics present in the working state. As the enzyme transitions from the substrate‐bound to the products‐bound state, millisecond conformational exchange processes are quenched and new allosteric connections are made between the alpha active site and the surface which interfaces with the beta subunit. The structural ordering of the enzyme and these new allosteric connections may be important in coordinating the channeling of the indole product into the beta subunit.     

Tryptophan synthase, an allosteric molecular factory

Tryptophan synthase (TrpS) is a pyridoxal phosphate-containing bifunctional enzyme that catalyzes the last two steps in the biosynthesis of L-tryptophan. Indole, an intermediate generated at the active site of the alpha-subunit is channeled via a 25 A long tunnel to the beta-active site where it reacts with an aminoacrylate intermediate derived from L-serine. The two reactions are kept in phase by allosteric interactions between the two subunits. The recent development of novel alpha-site ligands and alpha-reaction transition state analogs combined with kinetic and crystal structure analysis of Salmonella typhimurium tryptophan synthase has provided new insights into the allosteric regulation of substrate channeling, the reaction mechanisms of the alpha and beta active sites, and the influence of structural dynamics.     

Allosteric regulation of substrate channeling and catalysis in the tryptophan synthase bienzyme complex

The tryptophan synthase α₂β₂ bi-enzyme complex catalyzes the last two steps in the synthesis of l-tryptophan (l-Trp). The α-subunit catalyzes cleavage of 3-indole-d-glycerol 3′-phosphate (IGP) to give indole and d-glyceraldehyde 3′-phosphate (G3P). Indole is then transferred (channeled) via an interconnecting 25 Å-long tunnel, from the α-subunit to the β-subunit where it reacts with l-Ser in a pyridoxal 5′-phosphate-dependent reaction to give l-Trp and a water molecule. The efficient utilization of IGP and l-Ser by tryptophan synthase to synthesize l-Trp utilizes a system of allosteric interactions that (1) function to switch the α-site on and off at different stages of the β-subunit catalytic cycle, and (2) prevent the escape of the channeled intermediate, indole, from the confines of the α- and β-catalytic sites and the interconnecting tunnel. This review discusses in detail the chemical origins of the allosteric interactions responsible both for switching the α-site on and off, and for triggering the conformational changes between open and closed states which prevent the escape of indole from the bienzyme complex.     

Evidence that mutations in a loop region of the alpha-subunit inhibit the transition from an open to a closed conformation in the tryptophan synthase bienzyme complex.

Rapid-scanning stopped-flow (RSSF) UV-visible spectroscopy has been used to investigate the effects of single amino acid mutations in the alpha-subunit of the Salmonella typhimurium tryptophan synthase bienzyme complex on the reactivity at the beta-subunit active site located 25 to 30 A distant. The pyridoxal 5'-phosphate (PLP) cofactor provides a convenient spectroscopic probe to directly monitor catalytic events at the beta-active site. Single substitutions of Phe for Glu at position 49, Leu for Gly at position 51, or Tyr for Asp at position 60 in the alpha-subunit strongly alter the observed steady state and pre-steady state inhibitory effects of the alpha-subunit-specific ligand alpha-glycerophosphate (GP) on the PLP-dependent beta-reaction. However, similar GP-induced allosteric effects on the distribution of covalent intermediates bound at the beta-site that are observed with the wild-type enzyme (Houben, K.F., and Dunn, M.F. (1990) Biochemistry 29, 2421-2429) also are observed for each of the mutant bienzyme complexes. These results support the hypothesis that the preferred pathway of indole from solution into the beta-site is via the alpha-site and the interconnecting tunnel (Dunn, M.F., Aguilar, V., Brzovi?, P., Drewe, W.F., Houben, K.F., Leja, C.A., and Roy, M. (1990) Biochemistry 29, 8598-8607). Residues alpha E49, alpha G51, and alpha D60 are part of a highly conserved inserted sequence in the alpha/beta-barrel topology of the alpha-subunit. We propose that the GP-induced inhibition of the beta-reaction results, in part, from a ligand-dependent conformational change from an "open" to a "closed" structure of the alpha-subunit which involves this region of the alpha-subunit and serves to obstruct the direct access of indole into the tunnel. Our findings suggest that the altered kinetic behavior observed for the alpha-mutants in the presence of GP reflects an impaired ability of the modified bienzyme complex to undergo the conformational transition from the open to the closed form.     

Intermediate trapping via a conformational switch in the Na(+)-activated tryptophan synthase bienzyme complex

The tryptophan synthase bienzyme complex channels substrate indole between the alpha- and beta-sites via a 25 A long interconnecting tunnel. Channeling efficiency is dependent upon a conformational switch in alphabeta-dimeric units between open conformations of low activity to which substrates bind and closed conformations of high activity wherein substrates react. In experiments designed to gain a better understanding of the linkage between chemical steps and conformational transitions in the catalytic cycle, the novel amino acid dihydroiso-L-tryptophan (DIT) was used as an analogue of L-Trp. In the forward reaction (indoline + L-Ser) to synthesize DIT, the quinonoid species, E(Q)(indoline), is formed quickly, while in the reverse reaction (DIT cleavage), the accumulation of E(Q)(indoline) occurs very slowly. Nevertheless, when the alpha-site substrate analogue alpha-D,L-glycerol phosphate (GP) is bound, DIT cleavage was found to give a rapid formation and dissipation of E(Q)(indoline) followed by a very slow reappearance of E(Q)(indoline). This result led to the conclusion that the reaction of DIT proceeds quickly through the quinonoid state to give indoline and the alpha-aminoacrylate Schiff base, E(A-A), both in the absence and in the presence of GP. In the absence of GP the slow conversion of E(A-A) to pyruvate and ammonium ion limits the rate of accumulation of free indoline and therefore the rate of buildup of E(Q)(indoline). However, when GP is bound to the alpha-site, the indoline generated by DIT cleavage in the first turnover is trapped within the enzyme complex, shifting the equilibrium distribution strongly in favor of E(Q)(indoline) as a consequence of the high local concentration of sequestered indoline. This sequestering is the result of a switching of alphabeta-subunit pairs to a closed conformation when GP binds to the alpha-site and E(A-A) and/or E(Q)(indoline) is formed at the beta-site, thereby trapping indoline inside. The decay of the transiently formed E(Q)(indoline) occurs due to leakage of indoline from the closed system.     

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.     

Crystal structure of wild-type tryptophan synthase complexed with the natural substrate indole-3-glycerol phosphate

We used freeze trapping to stabilize the Michaelis complex of wild-type tryptophan synthase and the alpha-subunit substrate indole-3-glycerol phosphate (IGP) and determined its structure to 1. 8 A resolution. In addition, we determined the 1.4 A resolution structure of the complex with indole-3-propanole phosphate (IPP), a noncleavable IGP analogue. The interaction of the 3'-hydroxyl of IGP with the catalytic alphaGlu49 leads to a twisting of the propane chain and to a repositioning of the indole ring compared to IPP. Concomitantly, the catalytic alphaAsp60 rotates resulting in a translocation of the COMM domain [betaGly102-betaGly189, for definition see Schneider et al. (1998) Biochemistry 37, 5394-5406] in a direction opposite to the one in the IPP complex. This results in loss of the allosteric sodium ion bound at the beta-subunit and an opening of the beta-active site, thereby making the cofactor pyridoxal 5'-phosphate (PLP) accessible to solvent and thus serine binding. These findings form the structural basis for the information transfer from the alpha- to the beta-subunit and may explain the affinity increase of the beta-active site for serine upon IGP binding.     

Allosteric effects acting over a distance of 20-25 A in the Escherichia coli tryptophan synthase bienzyme complex increase ligand affinity and cause redistribution of covalent intermediates

The reactions of L-histidine (L-His) and L-tryptophan (L-Trp) with the alpha 2 beta 2 complex of Escherichia coli tryptophan synthase are introduced as probes both of beta-subunit catalysis and of ligand-mediated alpha-beta allosteric interactions. Binding of DL-alpha-glycerol 3-phosphate (GP), an analogue of 3-indole-D-glycerol 3'-phosphate (IGP), to the alpha-catalytic site increases the affinity of alpha 2 beta 2 for L-His 4.5-fold and the affinity for L-Trp 17-fold and brings about a redistribution of beta-bound intermediates that favors the quinonoids derived from each amino acid. Inorganic phosphate (Pi) (presumably via binding to the alpha-catalytic site) influences the distribution of L-His intermediates as does GP. Previous binding studies [Heyn, M. P., & Weischet, W. O. (1975) Biochemistry 14, 2962-2968] indicate that when the phosphoryl group subsite of the alpha-catalytic site is occupied by GP or Pi, a high-affinity indole subsite is induced at the alpha-catalytic site. Interaction of benzimidazole (BZ), an analogue of indole, with this site also shifts the distribution of beta-bound L-His intermediates in favor of the L-His quinonoid. In the absence of Pi or GP, BZ interacts primarily at the beta-catalytic site and competes with L-His for the beta-subunit indole subsite. Since L-His and GP (or Pi) are substrate analogues and L-Trp is the physiological product, these allosteric effects likely take place with the natural substrates.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tryptophan synthase: the workings of a channeling nanomachine

Substrate channeling between enzymes has an important role in cellular metabolism by compartmentalizing cytoplasmic synthetic processes. The bacterial tryptophan synthases are multienzyme nanomachines that catalyze the last two steps in L-tryptophan biosynthesis. The common metabolite indole is transferred from one enzyme to the other in each alphabeta-dimeric unit of the alpha2beta2 complex via an interconnecting 25-A-long tunnel. Recent solution studies of the Salmonella typhimurium alpha2beta2 complex coupled with X-ray crystal-structure determinations of complexes with substrates, intermediates and substrate analogs have driven important breakthroughs concerning the identification of the linkages between the bi-enzyme complex structure, catalysis at the alpha- and beta-active sites, and the allosteric regulation of substrate channeling.     

The uridine in "U-turn": contributions to tRNA-ribosomal binding

"U-turns" represent an important class of structural motifs in the RNA world, wherein a uridine is involved in an abrupt change in the direction of the polynucleotide backbone. In the crystal structure of yeast tRNAPhe, the invariant uridine at position 33 (U33), adjacent to the anticodon, stabilizes the exemplar U-turn with three non-Watson-Crick interactions: hydrogen bonding of the 2'-OH to N7 of A35 and the N3-H to A36-phosphate, and stacking between C32 and A35-phosphate. The functional importance of each noncanonical interaction was determined by assaying the ribosomal binding affinities of tRNAPhe anticodon stem and loop domains (ASLs) with substitutions at U33. An unsubstituted ASL bound 30S ribosomal subunits with an affinity (Kd = 140+/-50 nM) comparable to that of native yeast tRNAPhe (Kd = 100+/-20 nM). However, the binding affinities of ASLs with dU-33 (no 2'-OH) and C-33 (no N3-H) were significantly reduced (2,930+/-140 nM and 2,190+/-300 nM, respectively). Surprisingly, the ASL with N3-methyluridine-33 (no N3-H) bound ribosomes with a high affinity (Kd = 220+/-20 nM). In contrast, ASLs constructed with position 33 uridine analogs in nonstacking, nonnative, and constrained conformations, dihydrouridine (C2'-endo), 6-methyluridine (syn) and 2'O-methyluridine (C3'-endo) had almost undetectable binding. The inability of ASLs with 6-methyluridine-33 and 2'O-methyluridine-33 to bind ribosomes was not attributable to any thermal instability of the RNAs. These results demonstrate that proton donations by the N3-H and 2'OH groups of U33 are not absolutely required for ribosomal binding. Rather, the results suggest that the overall uridine conformation, including a dynamic (C3'-endo > C2'-endo) sugar pucker, anti conformation, and ability of uracil to stack between C32 and A35-phosphate, are the contributing factors to a functional U-turn.