Reactions of O-acyl-L-serines with tryptophanase, tyrosine phenol-lyase, and tryptophan synthase

Characterization of aminoacrylate intermediates of pyridoxal-5'-phosphate dependent enzymes

Pyridoxal-5'-phosphate (PLP) Schiff's bases of 2-aminoacrylate are intermediates in β-elimination and β-substitution reaction of PLP-dependent enzymes. These enzymes are found in two major families, the α-, or aminotransferase, superfamily, and the β-family. While the α-family enzymes primarily catalyze β-eliminations, the β-family enzymes catalyze both β-elimination and β-substitution reactions. Tyrosine phenol-lyase (TPL), which catalyzes the reversible elimination of phenol from l-tyrosine, is an example of an α-family enzyme. Tryptophan synthase catalyzes the irreversible formation of l-tryptophan from l-serine and indole, and is an example of a β-family enzyme. The identification and characterization of aminoacrylate intermediates in the reactions of both of these enzymes is discussed. The use of UV-visible absorption and fluorescence spectroscopy, X-ray and neutron crystallography, and NMR spectroscopy to identify aminoacrylate intermediates in these and other PLP enzymes is presented.

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.

M379A Mutant Tyrosine Phenol-lyase from Citrobacter freundii Has Altered Conformational Dynamics

The M379A mutant of Citrobacter freundii tyrosine phenol‐lyase (TPL) has been prepared. M379A TPL is a robust catalyst to prepare a number of tyrosines substituted at the 3‐position with bulky groups that cannot be made with wild type TPL. The three dimensional structures of M379A TPL complexed with L‐methionine and 3‐bromo‐dl‐phenylalanine have been determined by X‐ray crystallography. Methionine is bound as a quinonoid complex in a closed active site in 3 of 4 chains of homotetrameric M379A TPL. M379A TPL reacts with l‐methionine about 8‐fold slower than wild type TPL. The temperature dependence shows that the slower reaction is due to less positive activation entropy. The structure of the M379A TPL complex of 3‐bromo‐DL‐phenylalanine has a quinonoid complex in two subunits, with an open active site conformation. The effects of the M379A mutation on TPL suggest that the mutant enzyme has altered the conformational dynamics of the active site.

SGLT-1-specific inhibition ameliorates renal failure and alters the gut microbial community in mice with adenine-induced renal failure

Sodium-dependent glucose cotransporters (SGLTs) have attracted considerable attention as new targets for type 2 diabetes mellitus. In the kidney, SGLT2 is the major glucose uptake transporter in the proximal tubules, and inhibition of SGLT2 in the proximal tubules shows renoprotective effects. On the other hand, SGLT1 plays a role in glucose absorption from the gastrointestinal tract, and the relationship between SGLT1 inhibition in the gut and renal function remains unclear. Here, we examined the effect of SGL5213, a novel and potent intestinal SGLT1 inhibitor, in a renal failure (RF) model. SGL5213 improved renal function and reduced gut-derived uremic toxins (phenyl sulfate and trimethylamine-N-oxide) in an adenine-induced RF model. Histological analysis revealed that SGL5213 ameliorated renal fibrosis and inflammation. SGL5213 also reduced gut inflammation and fibrosis in the ileum, which is a primary target of SGL5213. Examination of the gut microbiota community revealed that the Firmicutes/Bacteroidetes ratio, which suggests gut dysbiosis, was increased in RF and SGL5213 rebalanced the ratio by increasing Bacteroidetes and reducing Firmicutes. At the genus level, Allobaculum (a major component of Erysipelotrichaceae) was significantly increased in the RF group, and this increase was canceled by SGL5213. We also measured the effect of SGL5213 on bacterial phenol-producing enzymes that catalyze tyrosine into phenol, following the reduction of phenyl sulfate, which is a novel marker and a therapeutic target for diabetic kidney disease DKD. We found that the enzyme inhibition was less potent, suggesting that the change in the microbial community and the reduction of uremic toxins may be related to the renoprotective effect of SGL5213. Because SGL5213 is a low-absorbable SGLT1 inhibitor, these data suggest that the gastrointestinal inhibition of SGLT1 is also a target for chronic kidney diseases.

The roles of Ser-36, Asp-132 and Asp-201 in the reaction of Pseudomonas fluorescens Kynureninase

Kynureninase from Pseudomonas fluorescens (Pfkynase) catalyzes the pyridoxal-5'-phosphate (PLP) dependent hydrolytic cleavage of L-kynurenine to give anthranilate and L-alanine. Asp-132 and Asp-201 are located in the structure near the pyridine NH of the PLP, with Asp-201 forming a hydrogen bond. Mutation of Asp-132 to alanine and glutamate and Asp-201 to glutamate results in reduced catalytic activity with L-kynurenine and β-benzoyl-L-alanine, but not O-benzoyl-l-serine. D132A, D132E D201E and S36A mutant Pfkynases all can form quinonoid and vinylogous amide intermediates with β-benzoyl-L-alanine, similar to wild-type enzyme. D132A, D132E, and D201E Pfkynase react more slowly with β-benzoyl-L-alanine and benzaldehyde to form an aldol product absorbing at 490 nm than wild-type, with D132E reacting the slowest. The ¹H NMR spectra of wild-type and D201E Pfkynase are very similar in the low field region from 10 to 18 ppm, but that of D132A Pfkynase is missing a resonance at 13.1 ppm. These results show that these residues modulate the reactivity of the PLP at different stages during the reaction cycle. Ser-36 is located near the expected location of the carbonyl oxygen of the substrate. Mutation of Ser-36 to alanine results in a 230-fold reduction of k_cat and 30-fold reduction in k_cat/K_m with L-kynurenine, but very little effect on the reaction of O-benzoyl-l-serine. Thus, the rate-determining step in the reaction of S36A Pfkynase is the C_β-C_γ bond cleavage. These results support the hypothesis that Ser-36 together with Tyr-226 is part of an oxyanion hole that polarizes the carbonyl of the substrate in the catalytic mechanism of Pfkynase.

The Catalytic Mechanisms of the Reactions between Tryptophan Indole-Lyase and Nonstandard Substrates: The Role of the Ionic State of the Catalytic Group Accepting the Cα Proton of the Substrate

In the reaction between tryptophan indole-lyase (TIL) and a substrate containing a bad leaving group (L-serine), general acid catalysis is required for the group's elimination. During this stage, the proton originally bound to the Cα atom of the substrate is transferred to the leaving group, which is eliminated as a water molecule. As a result, the basic group that had accepted the Cα proton at the previous stage has to be involved in the catalytic stage following the elimination in its basic form. On the other hand, when the substrate contains a good leaving group (β-chloro-L-alanine), general acid catalysis is not needed at the elimination stage and cannot be implemented, because there are no functional groups in enzymes whose acidity is strong enough to protonate the elimination of a base as weak as Cl- anion. Consequently, the group that had accepted the Cα proton does not lose its additional proton during the elimination stage and should take part in the subsequent stage in its acidic (not basic) form. To shed light on the mechanistic consequences of the changes in the ionic state of this group, we have considered the pH dependencies of the main kinetic parameters for the reactions of TIL with L-serine and β-chloro-L-alanine and the kinetic isotope effects brought about by replacement of the ordinary water used as a solvent with 2H2O. We have found that in the reaction between TIL and β-chloro-L-alanine, the aminoacrylate hydrolysis stage is sensitive to the solvent isotope effect, while in the reaction with L-serine it is not. We have concluded that in the first reaction, the functional group containing an additional proton fulfills a definite catalytic function, whereas in the reaction with L-serine, when the additional proton is absent, the mechanism of hydrolysis of the aminoacrylate intermediate should be fundamentally different. Possible mechanisms were considered.

The role of substrate strain in the mechanism of the carbon-carbon lyases

The carbon-carbon lyases, tryptophan indole lyase (TIL) and tyrosine phenol-lyase (TPL) are bacterial enzymes which catalyze the reversible elimination of indole and phenol from l-tryptophan and l-tyrosine, respectively. These PLP-dependent enzymes show high sequence homology (∼40% identity) and both form homotetrameric structures. Steady state kinetic studies with both enzymes show that an active site base is essential for activity, and α-deuterated substrates exhibit modest primary isotope effects on kcat and kcat/Km, suggesting that substrate deprotonation is partially rate-limiting. Pre-steady state kinetics with TPL and TIL show rapid formation of external aldimine intermediates, followed by deprotonation to give quinonoid intermediates absorbing at about 500nm. In the presence of phenol and indole analogues, 4-hydroxypyridine and benzimidazole, the quinonoid intermediates of TPL and TIL decay to aminoacrylate intermediates, with λmax at about 340nm. Surprisingly, there are significant kinetic isotope effects on both formation and subsequent decay of the quinonoid intermediates when α-deuterated substrates are used. The crystal structure of TPL with a bound competitive inhibitor, 4-hydroxyphenylpropionate, identified several essential catalytic residues: Tyr-71, Thr-124, Arg-381, and Phe-448. The active sites of TIL and TPL are highly conserved with the exceptions of these residues: Arg-381(TPL)/Ile-396 (TIL); Thr-124 (TPL)/Asp-137 (TIL), and Phe-448 (TPL)/His-463 (TIL). Mutagenesis of these residues results in dramatic decreases in catalytic activity without changing substrate specificity. The conserved tyrosine, Tyr-71 (TPL)/Tyr-74 (TIL) is essential for elimination activity with both enzymes, and likely plays a role as a proton donor to the leaving group. Mutation of Arg-381 and Thr-124 of TPL to alanine results in very low but measurable catalytic activity. Crystallography of Y71F and F448H TPL with 3-fluoro-l-tyrosine bound demonstrated that there are two quinonoid structures, relaxed and tense. In the relaxed structure, the substrate aromatic ring is in plane with the Cβ-Cγ bond, but in the tense structure, the substrate aromatic ring is about 20° out of plane with the Cβ-Cγ bond. In the tense structure, hydrogen bonds are formed between the substrate OH and the guanidinium of Arg-381 and the OH of Thr-124, and the phenyl rings of Phe-448 and 449 provide steric strain. Based on the effects of mutagenesis, the substrate strain is estimated to contribute about 10(8) to TPL catalysis. Thus, the mechanisms of TPL and TIL require both substrate strain and acid/base catalysis, and substrate strain is probably responsible for the very high substrate specificity of TPL and TIL.

The phosphate of pyridoxal-5'-phosphate is an acid/base catalyst in the mechanism of Pseudomonas fluorescens kynureninase

Kynureninase (L-kynurenine hydrolase, EC 3.7.1.3) catalyzes the hydrolytic cleavage of L-kynurenine to L-alanine and anthranilic acid. The proposed mechanism of the retro-Claisen reaction requires extensive acid/base catalysis. Previous crystal structures showed that Tyr226 in the Pseudomonas fluorescens enzyme (Tyr275 in the human enzyme) hydrogen bonds to the phosphate of the pyridoxal-5'-phosphate (PLP) cofactor. This Tyr residue is strictly conserved in all sequences of kynureninase. The human enzyme complexed with a competitive inhibitor, 3-hydroxyhippuric acid, showed that the ligand carbonyl O is located 3.7 Å from the phenol of Tyr275 (Lima, S., Kumar, S., Gawandi, V., Momany, C. & Phillips, R. S. (2009) J. Med. Chem. 52, 389-396). We prepared a Y226F mutant of P. fluorescens kynureninase to probe the role of this residue in catalysis. The Y226F mutant has approximately 3000-fold lower activity than wild-type, and does not show the pKa values of 6.8 on kcat and 6.5 and 8.8 on k(cat)/K(m) seen for the wild-type enzyme (Koushik, S. V., Moore, J. A. III, Sundararaju, B. & Phillips, R. S. (1998) Biochemistry 37, 1376-1382). Wild-type kynureninase shows a resonance at 4.5 ppm in (31)P-NMR, which is shifted to 5.0, 3.3 and 2.0 ppm when the potent inhibitor 5-bromodihydrokynurenine is added. However, Y226F kynureninase shows resonances at 3.6 and 2.5 ppm, and no change in the peak position is seen when 5-bromodihydrokynurenine is added. Taken together, these results suggest that Tyr226 mediates proton transfer between the substrate and the phosphate, which accelerates formation of external aldimine and gem-diol intermediates. Thus, the phosphate of PLP acts as an acid/base catalyst in the mechanism of kynureninase.

Crystallographic snapshots of tyrosine phenol-lyase show that substrate strain plays a role in C-C bond cleavage

The key step in the enzymatic reaction catalyzed by tyrosine phenol-lyase (TPL) is reversible cleavage of the Cβ-Cγ bond of L-tyrosine. Here, we present X-ray structures for two enzymatic states that form just before and after the cleavage of the carbon-carbon bond. As for most other pyridoxal 5'-phosphate-dependent enzymes, the first state, a quinonoid intermediate, is central for the catalysis. We captured this relatively unstable intermediate in the crystalline state by introducing substitutions Y71F or F448H in Citrobacter freundii TPL and briefly soaking crystals of the mutant enzymes with a substrate 3-fluoro-L-tyrosine followed by flash-cooling. The X-ray structures, determined at ~2.0 Å resolution, reveal two quinonoid geometries: "relaxed" in the open and "tense" in the closed state of the active site. The "tense" state is characterized by changes in enzyme contacts made with the substrate's phenolic moiety, which result in significantly strained conformation at Cβ and Cγ positions. We also captured, at 2.25 Å resolution, the X-ray structure for the state just after the substrate's Cβ-Cγ bond cleavage by preparing the ternary complex between TPL, alanine quinonoid and pyridine N-oxide, which mimics the α-aminoacrylate intermediate with bound phenol. In this state, the enzyme-ligand contacts remain almost exactly the same as in the "tense" quinonoid, indicating that the strain induced by the closure of the active site facilitates elimination of phenol. Taken together, structural observations demonstrate that the enzyme serves not only to stabilize the transition state but also to destabilize the ground state.

Identification and molecular characterization of tryptophanase encoded by tnaA in Porphyromonas gingivalis

Indole produced via the beta-elimination reaction of l-tryptophan by pyridoxal 5'-phosphate-dependent tryptophanase (EC 4.1.99.1) has recently been shown to be an extracellular and intercellular signalling molecule in bacteria, and controls bacterial biofilm formation and virulence factors. In the present study, we determined the molecular basis of indole production in the periodontopathogenic bacterium Porphyromonas gingivalis. A database search showed that the amino acid sequence deduced from pg1401 of P. gingivalis W83 is 45 % identical with that from tnaA of Escherichia coli K-12, which encodes tryptophanase. Replacement of the pg1401 gene in the chromosomal DNA with the chloramphenicol-resistance gene abolished indole production. The production of indole was restored by the introduction of pg1401, demonstrating that the gene is functionally equivalent to tnaA. However, RT-PCR and RNA ligase-mediated rapid amplification of cDNA ends analyses showed that, unlike E. coli tnaA, pg1401 is expressed alone in P. gingivalis and that the nucleotide sequence of the transcription start site is different, suggesting that the expression of P. gingivalis tnaA is controlled by a unique mechanism. Purified recombinant P. gingivalis tryptophanase exhibited the Michaelis-Menten kinetics values K(m)=0.20+/-0.01 mM and k(cat)=1.37+/-0.06 s(-1) in potassium phosphate buffer, but in sodium phosphate buffer, the enzyme showed lower activity. However, the cation in the buffer, K(+) or Na(+), did not appear to affect the quaternary structure of the enzyme or the binding of pyridoxal 5'-phosphate to the enzyme. The enzyme also degraded S-ethyl-l-cysteine and S-methyl-l-cysteine, but not l-alanine, l-serine or l-cysteine.

Insights into the catalytic mechanism of tyrosine phenol-lyase from X-ray structures of quinonoid intermediates

Amino acid transformations catalyzed by a number of pyridoxal 5'-phosphate (PLP)-dependent enzymes involve abstraction of the Calpha proton from an external aldimine formed between a substrate and the cofactor leading to the formation of a quinonoid intermediate. Despite the key role played by the quinonoid intermediates in the catalysis by PLP-dependent enzymes, limited accurate information is available about their structures. We trapped the quinonoid intermediates of Citrobacter freundii tyrosine phenol-lyase with L-alanine and L-methionine in the crystalline state and determined their structures at 1.9- and 1.95-A resolution, respectively, by cryo-crystallography. The data reveal a network of protein-PLP-substrate interactions that stabilize the planar geometry of the quinonoid intermediate. In both structures the protein subunits are found in two conformations, open and closed, uncovering the mechanism by which binding of the substrate and restructuring of the active site during its closure protect the quinonoid intermediate from the solvent and bring catalytically important residues into positions suitable for the abstraction of phenol during the beta-elimination of L-tyrosine. In addition, the structural data indicate a mechanism for alanine racemization involving two bases, Lys-257 and a water molecule. These two bases are connected by a hydrogen bonding system allowing internal transfer of the Calpha proton.

A twisted base? The role of arginine in enzyme-catalyzed proton abstractions

Arginine residues are generally considered poor candidates for the role of general bases because they are predominantly protonated at physiological pH. Nonetheless, Arg residues have recently emerged as general bases in several enzymes: IMP dehydrogenase, pectate/pectin lyases, fumarate reductase, and l-aspartate oxidase. The experimental evidence suggesting this mechanistic function is reviewed. Although these enzymes have several different folds and distinct evolutionary origins, a common structural motif is found where the critical Arg residue is solvent accessible and adjacent to carboxylate groups. The chemistry of the guanidine group suggests unique strategies to lower the pK(a) of Arg. Lastly, the presumption that general bases must be predominantly deprotonated is revisited.

The mechanism of alpha-proton isotope exchange in amino acids catalysed by tyrosine phenol-lyase. What is the role of quinonoid intermediates?

To shed light on the mechanism of isotopic exchange of alpha-protons in amino acids catalyzed by pyridoxal phosphate (PLP)-dependent enzymes, we studied the kinetics of quinonoid intermediate formation for the reactions of tyrosine phenol-lyase with L-phenylalanine, L-methionine, and their alpha-deuterated analogues in D2O, and we compared the results with the rates of the isotopic exchange under the same conditions. We have found that, in the L-phenylalanine reaction, the internal return of the alpha-proton is operative, and allowing for its effect, the exchange rate is accounted for satisfactorily. Surprisingly, for the reaction with L-methionine, the enzymatic isotope exchange went much faster than might be predicted from the kinetic data for quinonoid intermediate formation. This result allows us to suggest the existence of an alternative, possibly concerted, mechanism of alpha-proton exchange.

Tyrosine phenol-lyase and tryptophan indole-lyase encapsulated in wet nanoporous silica gels: Selective stabilization of tertiary conformations

The pyridoxal 5'-phosphate-dependent enzymes tyrosine phenol-lyase and tryptophan indole-lyase were encapsulated in wet nanoporous silica gels, a powerful method to selectively stabilize tertiary and quaternary protein conformations and to develop bioreactors and biosensors. A comparison of the enzyme reactivity in silica gels and in solution was carried out by determining equilibrium and kinetic parameters, exploiting the distinct spectral properties of catalytic intermediates and reaction products. The encapsulated enzymes exhibit altered distributions of ketoenamine and enolimine tautomers, increased values of inhibitors dissociation constants, slow attaining of steady-state in the presence of substrate and substrate analogs, modified steady-state distribution of catalytic intermediates, and a sixfold-eightfold decrease of specific activities. This behavior can be rationalized by a reduced conformational flexibility for the encapsulated enzymes and a selective stabilization of either the open (inactive) or the closed (active) form of the enzymes. Despite very similar structures and catalytic mechanisms, the influence of encapsulation is more pronounced for tyrosine phenol-lyase than tryptophan indole-lyase. This finding indicates that subtle structural and dynamic differences can lead to distinct interactions of the protein with the gel matrix.

Role of Aspartate-133 and Histidine-458 in the Mechanism of Tryptophan Indole-Lyase from Proteus vulgaris

Tryptophan indole-lyase (Trpase) from Proteus vulgaris is a pyridoxal 5'-phosphate dependent enzyme that catalyzes the reversible hydrolytic cleavage of L-Trp to yield indole and ammonium pyruvate. Asp-133 and His-458 are strictly conserved in all sequences of Trpase, and they are located in the proposed substrate-binding region of Trpase. These residues were mutated to alanine to probe their role in substrate binding and catalysis. D133A mutant Trpase has no measurable activity with L-Trp as substrate, but still retains activity with S-(o-nitrophenyl)-L-cysteine, S-alkyl-L-cysteines, and beta-chloro-L-alanine. H458A mutant Trpase has 1.6% of wild-type Trpase activity with L-Trp, and high activity with S-(o-nitrophenyl)-L-cysteine, S-alkyl-L-cysteines, and beta-chloro-L-alanine. H458A mutant Trpase does not exhibit the pK(a) of 5.3 seen in the pH dependence of k(cat)/K(m) of L-Trp for wild-type Trpase. Both mutant enzymes are inhibited by L-Ala, L-Met, and L-Phe, with K(i) values similar to those of wild-type Trpase, but oxindolyl-L-alanine and beta-phenyl-DL-serine show much weaker binding to the mutant enzymes, suggesting that Asp-133 and His-458 are involved in the binding of these ligands. D133A and H458A mutant Trpase exhibit absorption and CD spectra in the presence of substrates and inhibitors that are similar to wild-type Trpase, with peaks at about 420 and 500 nm. The rate constants for formation of the 500 nm bands for the mutant enzymes are equal to or greater than those of wild-type Trpase, indicating that Asp-133 and His-458 do not play a role in the formation of quinonoid intermediates. In constrast to wild-type and H458A mutant Trpase, D133A mutant Trpase forms an intermediate from S-ethyl-L-Cys that absorbs at 345 nm, and is likely to be an alpha-aminoacrylate. Crystals of D133A and H458A mutant Trpase bind amino acids with similar affinity as the proteins in solution, except for L-Ala, which binds to D133A mutant Trpase crystals about 20-fold stronger than in solution. These results suggest that Asp-133 and His-458 play an important role in the elimination reaction of L-Trp. Asp-133 likely forms a hydrogen bond directly to the indole NH of the substrate, while His-458 probably is hydrogen bonded to Asp-133.

Structure and mechanism of tryptophan indole-lyase and tyrosine phenol-lyase

Tyrosine phenol-lyase (TPL) and tryptophan indole-lyase (Trpase) catalyse the reversible hydrolytic cleavage of L-tyrosine or L-tryptophan to phenol or indole, respectively, and ammonium pyruvate. These enzymes are very similar in sequence and structure, but show strict specificity for their respective physiological substrates. We have mutated the active site residues of TPL (Thr(124), Arg(381), and Phe(448)) to those of Trpase and evaluated the effects of the mutations. Tyr(71) in Citrobacter freundii TPL, and Tyr(74) in E. coli Trpase, are essential for activity with both substrates. Mutation of Arg(381) of TPL to Ala, Ile, or Val (the corresponding residues in the active site of Trpase) results in a dramatic decrease in L-Tyr beta-elimination activity, with little effect on the activity of other substrates. Arg(381) may be the catalytic base with pK(a) of 8 seen in pH-dependent kinetic studies. T124D TPL has no measureable activity with L-Tyr or 3-F-L-Tyr as substrate, despite having high activity with SOPC. T124A TPL has very low but detectable activity, which is about 500-fold less than wild-type TPL, with L-Tyr and 3-F-L-Tyr. F448H TPL also has very low activity with L-Tyr. None of the mutant TPLs has any detectable activity with L-Trp as substrate. H463F Trpase also exhibits low activity with L-Trp, but retains high activity with other substrates. Thus, additional residues remote from the active site may be needed for substrate specificity. Both Trpase and TPL may react by a rare S(E)2-type mechanism.

Crystals of tryptophan indole-lyase and tyrosine phenol-lyase form stable quinonoid complexes

The binding of substrates and inhibitors to wild-type Proteus vulgaris tryptophan indole-lyase and to wild type and Y71F Citrobacter freundii tyrosine phenol-lyase was investigated in the crystalline state by polarized absorption microspectrophotometry. Oxindolyl-lalanine binds to tryptophan indole-lyase crystals to accumulate predominantly a stable quinonoid intermediate absorbing at 502 nm with a dissociation constant of 35 microm, approximately 10-fold higher than that in solution. l-Trp or l-Ser react with tryptophan indole-lyase crystals to give, as in solution, a mixture of external aldimine and quinonoid intermediates and gem-diamine and external aldimine intermediates, respectively. Different from previous solution studies (Phillips, R. S., Sundararju, B., & Faleev, N. G. (2000) J. Am. Chem. Soc. 122, 1008-1114), the reaction of benzimidazole and l-Trp or l-Ser with tryptophan indole-lyase crystals does not result in the formation of an alpha-aminoacrylate intermediate, suggesting that the crystal lattice might prevent a ligand-induced conformational change associated with this catalytic step. Wild-type tyrosine phenol-lyase crystals bind l-Met and l-Phe to form mixtures of external aldimine and quinonoid intermediates as in solution. A stable quinonoid intermediate with lambda(max) at 502 nm is accumulated in the reaction of crystals of Y71F tyrosine phenol-lyase, an inactive mutant, with 3-F-l-Tyr with a dissociation constant of 1 mm, approximately 10-fold higher than that in solution. The stability exhibited by the quinonoid intermediates formed both by wild-type tryptophan indole-lyase and by wild type and Y71F tyrosine phenol-lyase crystals demonstrates that they are suitable for structural determination by x-ray crystallography, thus allowing the elucidation of a key species of pyridoxal 5'-phosphate-dependent enzyme catalysis.

Threonine-124 and phenylalanine-448 in Citrobacter freundii tyrosine phenol-lyase are necessary for activity with L-tyrosine

Thr-124 and Phe-448 are located in the active site of Citrobacter freundii tyrosine phenol-lyase (TPL) near the phenol ring of a bound substrate analogue, 3-(4'-hydroxyphenyl)propionic acid [Sundararaju, Antson, Phillips, Demidkina, Barbolina, Gollnick, Dodson and Wilson (1997) Biochemistry 36, 6502-6510]. Thr-124 is replaced by Asp and Phe-448 is replaced by His in the crystal structure of a structurally similar enzyme, Proteus vulgaris tryptophan indole-lyase, which has 50% identical residues. Hence, Thr-124 and Phe-448 in TPL were mutated to Ala or Asp, and His, respectively, in order to probe the role of these residues in the reaction specificity for L-Tyr. These mutant enzymes have little or no beta-elimination activity with L-Tyr or 3-fluoro-L-Tyr as a substrate, but retain significant elimination activity with S-(o-nitrophenyl)-L-cysteine, S-alkyl-L-cysteines and beta-chloroalanine. Furthermore, the binding of L-Tyr and other non-substrate amino acids is not significantly affected by the mutations. The mutant TPLs form intermediates in rapid-scanning stopped-flow experiments with L-Phe, L-Tyr and L-Trp, similar to those seen with wild-type TPL. These results demonstrate that Thr-124 and Phe-448 are necessary for the reaction specificity of TPL for L-Tyr, and probably play a role in the elimination stage of the reaction mechanism. Thr-124 is within hydrogen-bonding distance of the phenolic group of the bound substrate, and may help to orientate the ring for beta-elimination to occur. Phe-448 may be important to allow the formation of the closed conformation during the reaction.

Formation in vitro of hybrid dimers of H463F and Y74F mutant Escherichia coli tryptophan indole-lyase rescues activity with L-tryptophan

Y74F and H463F mutant forms of Escherichia coli tryptophan indole-lyase (Trpase) have been prepared. These mutant proteins have very low activity with L-Trp as substrate (kcat and kcat/Km values less than 0.1% of wild-type Trpase). In contrast, these mutant enzymes exhibit much higher activity with S-(o-nitrophenyl)-L-cysteine and S-ethyl-L-cysteine (kcat/Km values about 1-50% of wild-type Trpase). Thus, Tyr-74 and His-463 are important for the substrate specificity of Trpase for L-Trp. H463F Trpase is not inhibited by a potent inhibitor of wild-type Trpase, oxindolyl-L-alanine, and does not exhibit the pK(a) of 6.0 seen in previous pH dependence studies [Kiick, D. M., and Phillips, R. S. (1988) Biochemistry 27, 7333]. These results suggest that His-463 may be the catalytic base with a pK(a) of 6.0 and Tyr-74 may be a general acid catalyst for the elimination step, as we found previously with tyrosine phenol-lyase [Chen, H., Demidkina, T. V., and Phillips, R. S. (1995) Biochemistry 34, 12776]. H463F Trpase reacts with L-Trp and S-ethyl-L-cysteine in rapid-scanning stopped-flow experiments to form equilibrating mixtures of external aldimine and quinonoid intermediates, similar to those observed with wild-type Trpase. In contrast to the results with wild-type Trpase, the addition of benzimidazole to reactions of H463F Trpase with L-Trp does not result in the formation of an aminoacrylate intermediate. However, addition of benzimidazole with S-ethyl-L-cysteine results in the formation of an aminoacrylate intermediate, with lambda(max) at 345 nm, as was seen previously with wild-type Trpase [Phillips, R. S. (1991) Biochemistry 30, 5927]. This suggests that His-463 plays a specific role in the elimination step of the reaction of L-Trp. Refolding of equimolar mixtures of H463F and Y74F Trpase after unfolding in 4 M guanidine hydrochloride results in a dramatic increase in activity with L-Trp, indicating the formation of a hybrid H463F/Y74F dimer with one normal active site.

Inhibition of tyrosine phenol-lyase from Citrobacter freundii by 2-azatyrosine and 3-azatyrosine

The interactions of 2-azatyrosine and 3-azatyrosine with tyrosine phenol-lyase (TPL) from Citrobacter freundii have been examined. 2-Aza-DL-tyrosine and 3-aza-DL-tyrosine were synthesized by standard methods of amino acid synthesis, while the L-isomers were prepared from 3-hydroxypyridine and 2-hydroxypyridine, respectively, with TPL (Watkins, E. B., and Phillips, R. S. (2001) Bioorg. Med. Chem. Lett. 11, 2099-2100). 3-Azatyrosine was examined as a potential transition state analogue inhibitor of TPL. Both compounds were found to be competitive inhibitors of TPL, with K(i) values of 3.4 mM and 135 microM for 3- and 2-aza-L-tyrosine, respectively. Thus, 3-azatyrosine does not act as a transition state analogue, possibly due to the lack of tetrahedral geometry at C-1. However, 2-aza-L-tyrosine is the most potent competitive inhibitor of TPL found to date. The K(i) value of 2-aza-L-tyrosine is half that of 2-aza-DL-tyrosine, indicating that the D-enantiomer is inactive as an inhibitor. Neither azatyrosine isomer was shown to be a substrate for beta-elimination, based on coupled assays with lactate dehydrogenase and on HPLC measurements. Both isomers of azatyrosine form equilibrium mixtures of external aldimine and quinonoid intermediates when they bind to TPL. However, 2-azatyrosine reacts about 10-fold faster to form a quinonoid intermediate than does 3-azatyrosine. Since 2-azatyrosine is in the zwitterion or phenolate ion form at all the pH values examined, the strong binding of this compound suggests that L-tyrosine may be bound to the active site of TPL as the phenolate anion.

Interaction of tyrosine phenol-lyase with phosphoroorganic analogues of substrate amino acids

The phosphinic analogues of tyrosine and pyruvate were first demonstrated to be substrates in the reactions of elimination and synthesis catalyzed by tyrosine phenol-lyase. Kinetic parameters of the enzymatic process were determined, and the first enzymic synthesis of an aminophosphinic acid was carried out. Replacement of the planar HOOC-group by the tetrahedral (HO)(O)PH-group in the substrate slightly affected its affinity for the enzyme but substantially diminished the conversion rate. For phosphonic analogues, containing (HO)2(O)P group, the affinity to the enzyme was decreased considerably while the conversion was completely prevented. Thus, the structural parameters of the acid group are important not only for the affinity for the enzyme, but also for the formation of the catalytically competent conformation of the active site.

The role of glutamic acid-69 in the activation of Citrobacter freundii tyrosine phenol-lyase by monovalent cations

Tyrosine phenol-lyase (TPL) from Citrobacter freundii is activated about 30-fold by monovalent cations, the most effective being K(+), NH(4)(+), and Rb(+). Previous X-ray crystal structure analysis has demonstrated that the monovalent cation binding site is located at the interface between subunits, with ligands contributed by the carbonyl oxygens of Gly52 and Asn262 from one chain and monodentate ligation by one of the epsilon-oxygens of Glu69 from another chain [Antson, A. A., Demidkina, T. V., Gollnick, P., Dauter, Z., Von Tersch, R. L., Long, J., Berezhnoy, S. N., Phillips, R. S., Harutyunyan, E. H., and Wilson, K. S. (1993) Biochemistry 32, 4195]. We have studied the effect of mutation of Glu69 to glutamine (E69Q) and aspartate (E69D) to determine the role of Glu69 in the activation of TPL. E69Q TPL is activated by K(+), NH(4)(+), and Rb(+), with K(D) values similar to wild-type TPL, indicating that the negative charge on Glu69 is not necessary for cation binding and activation. In contrast, E69D TPL exhibits very low basal activity and only weak activation by monovalent cations, even though monovalent cations are capable of binding, indicating that the geometry of the monovalent cation binding site is critical for activation. Rapid-scanning stopped-flow kinetic studies of wild-type TPL show that the activating effect of the cation is seen in an acceleration of rates of quinonoid intermediate formation (30-50-fold) and of phenol elimination. Similar rapid-scanning stopped-flow results were obtained with E69Q TPL; however, E69D TPL shows only a 4-fold increase in the rate of quinonoid intermediate formation with K(+). Preincubation of TPL with monovalent cations is necessary to observe the rate acceleration in stopped flow kinetic experiments, suggesting that the activation of TPL by monovalent cations is a slow process. In agreement with this conclusion, a slow increase (k < 0.5 s(-)(1)) in fluorescence intensity (lambda(ex) = 420 nm, lambda(em) = 505 nm) is observed when wild-type and E69Q TPL are mixed with K(+), Rb(+), and NH(4)(+) but not Li(+) or Na(+). E69D TPL shows no change in fluorescence under these conditions. High concentrations (>100 mM) of all monovalent cations result in inhibition of wild-type TPL. This inhibition is probably due to cation binding to the ES complex to form a complex that releases pyruvate slowly.

Citrobacter freundii tyrosine phenol-lyase: the role of asparagine 185 in modulating enzyme function through stabilization of a quinonoid intermediate

Asn185 is an invariant residue in all known sequences of TPL and of closely related tryptophanase and it may be aligned with the Asn194 in aspartate aminotransferase. According to X-ray data, in the holoenzyme and in the Michaelis complex Asn185 does not interact with the cofactor pyridoxal 5'-phosphate, but in the external aldimine a conformational change occurs which is accompanied by formation of a hydrogen bond between Asn185 and the oxygen atom in position 3 of the cofactor. The substitution of Asn185 in TPL by alanine results in a mutant N185A TPL of moderate residual activity (2%) with respect to adequate substrates, L-tyrosine and 3-fluoro-L-tyrosine. The affinities of the mutant enzyme for various amino acid substrates and inhibitors, studied by both steady-state and rapid kinetic techniques, were lower than for the wild-type TPL. This effect mainly results from destabilization of the quinonoid intermediate, and it is therefore concluded that the hydrogen bond between Asn185 and the oxygen at the C-3 position of the cofactor is maintained in the quinonoid intermediate. The relative destabilization of the quinonoid intermediate and external aldimine leads to the formation of large amounts of gem-diamine in reactions of N185A TPL with 3-fluoro-L-tyrosine and L-phenylalanine. For the reaction with 3-fluoro-L-tyrosine it was first possible to determine kinetic parameters of gem-diamine formation by the stopped-flow method. For the reactions of N185A TPL with substrates bearing good leaving groups the observed values of k(cat) could be accounted for by taking into consideration two effects: the decrease in the quinonoid content under steady-state conditions and the increase in the quinonoid reactivity in a beta-elimination reaction. Both effects are due to destabilization of the quinonoid and they counterbalance each other. Multiple kinetic isotope effect studies on the reactions of N185A TPL with suitable substrates, L-tyrosine and 3-fluoro-L-tyrosine, show that the principal mechanism of catalysis, suggested previously for the wild-type enzyme, does not change. In the framework of this mechanism the observed considerable decrease in k(cat) values for reactions of N185A TPL with L-tyrosine and 3-fluoro-L-tyrosine may be ascribed to participation of Asn185 in additional stabilization of the keto quinonoid intermediate.

First fatty acylated dipeptides to affect muscarinic receptor ligand binding

Fatty acylated dipeptides homologous to Gi alpha N-termini affect ligand binding to muscarinic acetylcholine receptors. Myristylglycine-serine containing dipeptides decrease antagonist binding at both M1 and M2 muscarinic receptors. Palmitate on the serine analogous to native palmitoylated cysteine affords dipeptide which selectively decreases the number of high affinity agonist binding sites at M2 but not M1 receptor.

Conversion of tyrosine phenol-lyase to dicarboxylic amino acid beta-lyase, an enzyme not found in nature

Tyrosine phenol-lyase (TPL), which catalyzes the beta-elimination reaction of L-tyrosine, and aspartate aminotransferase (AspAT), which catalyzes the reversible transfer of an amino group from dicarboxylic amino acids to oxo acids, both belong to the alpha-family of vitamin B6-dependent enzymes. To switch the substrate specificity of TPL from L-tyrosine to dicarboxylic amino acids, two amino acid residues of AspAT, thought to be important for the recognition of dicarboxylic substrates, were grafted into the active site of TPL. Homology modeling and molecular dynamics identified Val-283 in TPL to match Arg-292 in AspAT, which binds the distal carboxylate group of substrates and is conserved among all known AspATs. Arg-100 in TPL was found to correspond to Thr-109 in AspAT, which interacts with the phosphate group of the coenzyme. The double mutation R100T/V283R of TPL increased the beta-elimination activity toward dicarboxylic amino acids at least 10(4)-fold. Dicarboxylic amino acids (L-aspartate, L-glutamate, and L-2-aminoadipate) were degraded to pyruvate, ammonia, and the respective monocarboxylic acids, e.g. formate in the case of L-aspartate. The activity toward L-aspartate (kcat = 0.21 s-1) was two times higher than that toward L-tyrosine. beta-Elimination and transamination as a minor side reaction (kcat = 0.001 s-1) were the only reactions observed. Thus, TPL R100T/V283R accepts dicarboxylic amino acids as substrates without significant change in its reaction specificity. Dicarboxylic amino acid beta-lyase is an enzyme not found in nature.

The crystal structure of Citrobacter freundii tyrosine phenol-lyase complexed with 3-(4'-hydroxyphenyl)propionic acid, together with site-directed mutagenesis and kinetic analysis, demonstrates that arginine 381 is required for substrate specificity

The X-ray structure of tyrosine phenol-lyase (TPL) complexed with a substrate analog, 3-(4'-hydroxyphenyl)propionic acid, shows that Arg 381 is located in the substrate binding site, with the side-chain NH1 4.1 A from the 4'-OH of the analog. The structure has been deduced at 2.5 A resolution using crystals that belong to the P2(1)2(1)2 space group with a = 135.07 A, b = 143.91 A, and c = 59.80 A. To evaluate the role of Arg 381 in TPL catalysis, we prepared mutant proteins replacing arginine with alanine (R381A), with isoleucine (R381I), and with valine (R381V). The beta-elimination activity of R381A TPL has been reduced by 10(-4)-fold compared to wild type, whereas R381I and R381V TPL exhibit no detectable beta-elimination activity with L-tyrosine as substrate. However, R381A, R381I, and R381V TPL react with S-(o-nitrophenyl)-L-cysteine, beta-chloro-L-alanine, O-benzoyl-L-serine, and S-methyl-L-cysteine and exhibit k(cat) and k(cat)/Km values comparable to those of wild-type TPL. Furthermore, the Ki values for competitive inhibition by L-tryptophan and L-phenylalanine are similar for wild-type, R381A, and R381I TPL. Rapid-scanning-stopped flow spectroscopic analyses also show that wild-type and mutant proteins can bind L-tyrosine and form quinonoid complexes with similar rate constants. The binding of 3-(4'-hydroxyphenyl)propionic acid to wild-type TPL decreases at high pH values with a pKa of 8.4 and is thus dependent on an acidic group, possibly Arg404, which forms an ion pair with the analog carboxylate, or the pyridoxal 5'-phosphate Schiff base. R381A TPL shows only a small decrease in k(cat)/Km for tyrosine at lower pH, in contrast to wild-type TPL, which shows two basic pKas with an average value of about 7.8. Thus, it is possible that Arg 381 is one of the catalytic bases previously observed in the pH dependence of k(cat)/Km of TPL with L-tyrosine [Kiick, D. M., & Phillips. R. S. (1988) Biochemistry 27, 7333-7338], and hence Arg 381 is at least partially responsible for the substrate specificity of TPL.

Site-directed mutagenesis of tyrosine-71 to phenylalanine in Citrobacter freundii tyrosine phenol-lyase: evidence for dual roles of tyrosine-71 as a general acid catalyst in the reaction mechanism and in cofactor binding

Tyr71 is an invariant residue in all known sequences of tyrosine phenol-lyase (TPL). The substitution of Tyr71 in TPL by phenylalanine results in a mutant Y71F TPL with no detectable activity (greater than 3 x 10(5)-fold reduction) for beta-elimination of L-tyrosine. Y71F TPL can react with S-alkylcysteines, but these substrates exhibit kcat values reduced by 10(3)-10(4)-fold, while the kcat/Km values are reduced by 10(2)-10(3)-fold, compared to wild-type TPL. However, for substrates with good leaving groups (S-(o-nitrophenyl)-L-cysteine,beta-chloro-L-alanine, and O-benzoyl-L-serine), Y71F TPL exhibits kcat values 1.85-7% those of wild-type TPL. Y71F TPL forms very stable quinonoid complexes with strong absorbance at 502 nm from L-phenylalanine, tyrosines (L-tyrosine, 3-fluoro-L-tyrosine, and [alpha-2H]-3-fluoro-L-tyrosine), and S-alkylcysteines (S-methyl-L-cysteine, S-ethyl-L-cysteine, and S-benzyl-L-cysteine). The time courses of the formation of quinonoid intermediates in these reactions are biphasic. The slow phase shows a dependence on concentration of PLP and is due to the cofactor binding steps, while the fast phase is due to the amino acid alpha-deprotonation and reprotonation steps. The rate constants for the fast phase of the reactions of Y71F TPL with L-phenylalanine and S-methylcysteine are similar to those for alpha-deprotonation or reprotonation steps in the reactions of wild-type TPL. The PLP binding constant of Y71F TPL is estimated to be 1 mM by spectrophotometric titration, compared to 0.6 microM for wild-type TPL.(ABSTRACT TRUNCATED AT 250 WORDS)

The mechanism of Escherichia coli tryptophan indole-lyase: substituent effects on steady-state and pre-steady-state kinetic parameters for aryl-substituted tryptophan derivatives

We have examined the reaction of Escherichia coli tryptophan indole-lyase with fluoro, chloro, methyl and hydroxytryptophans using steady-state kinetics, rapid-scanning and single wavelength stopped-flow spectrophotometry, and rapid chemical quench methods. All of the 16 tryptophan derivatives examined are substrates for alpha, beta-elimination catalyzed by tryptophan indole-lyase. The steady-state kinetic parameter, kcat/Km, did not show a consistent trend with the steric bulk of the substituent, but Km increased for larger substituents. Rapid-scanning stopped-flow spectra show that all tryptophan analogues undergo covalent reaction with the pyridoxal-5'-phosphate cofactor to give equilibrating mixtures of external aldimine and quinonoid intermediates, but the relative amounts of each intermediate are strongly dependent on the nature and position of the substituent. The dissociation constants for external aldimine formation, Kd, obtained from single-wavelength stopped-flow experiments decreased for most substituted tryptophans, which suggests that part of the binding energy is derived from hydrophobic interactions between the enzyme and the indole ring of tryptophan. In contrast, the rate constants of quinonoid intermediate formation and reprotonation and of indole elimination were quite variable, depending on the position and the nature of the substituent. Overall, 6-substituted tryptophans have the most consistent reactivity, which indicates that there may be space in the enzyme active site near the 6-position. There is a good linear correlation between log (kcat/Km) and log (kf/Kd) (apparent second order rate constant for quinonoid intermediate formation), with a slope of 0.66. This suggests that quinonoid intermediate formation contributes only about 66% of the activation energy for the reaction, and thus a later step in the reaction must be partially rate-limiting. Rapid chemical quench experiments demonstrate a 'burst' of indole in the reaction of L-tryptophan under single turnover conditions, confirming that a step subsequent to the elimination is partially rate-determining. In contrast, 5-methyl-L-tryptophan does not exhibit a significant 'burst', suggesting that 5-methylindole elimination is nearly completely rate-determining. These results support the proposed mechanism and demonstrate that there are significant effects of aryl substituents on the distribution of covalent intermediates and on the rate-determining step in the alpha, beta-elimination reaction catalyzed by E. coli tryptophan indole-lyase.

Binding of phenol and analogues to alanine complexes of tyrosine phenol-lyase from Citrobacter freundii: implications for the mechanisms of alpha,beta-elimination and alanine racemization

We have examined the interaction of Citrobacter freundii tyrosine phenol-lyase with both L- and D-alanine. This enzyme catalyzes the racemization of alanine as a side reaction, in addition to the physiological beta-elimination of L-tyrosine to give phenol and ammonium pyruvate. The steady-state kinetic parameters for alanine racemization, kcat and Km, for D-alanine are 0.008 S-1 and 32 mM, respectively, while those for L-alanine are 0.03 S-1 and 11 mM. Incubation of tyrosine phenol-lyase with either L- or D-alanine forms a quinonoid complex that exhibits a strong peak at 500 nm. The presence of K+ increases the intensity of the 500-nm absorption with L-alanine, but decreases the intensity of the peak with D-alanine. Rate constants for the formation of these quinonoid intermediates and the effects of phenol and analogues on the reaction with either L- or D-alanine have been studied by rapid-scanning and single-wavelength stopped-flow spectrophotometry. Phenol binds to all the intermediates of tyrosine phenol-lyase with L- and D-alanine, but most strongly to the external aldimine complex, resulting in a decrease in the absorbance at 500 nm at equilibrium. Pyridine N-oxide binds selectively to the quinonoid complex of alanine, and thus causes an increase in the absorbance at 500 nm at equilibrium. 4-Hydroxypyridine causes a decrease in absorbance at 500 nm during the fast phase, but an increase in absorbance at 502 nm in a subsequent slow relaxation.(ABSTRACT TRUNCATED AT 250 WORDS)

6-(Difluoromethyl)tryptophan as a probe for substrate activation during the catalysis of tryptophanase

A substrate analogue, 6-(difluoromethyl)tryptophan, was developed and characterized for mechanistic investigation of tryptophanase. The utility of this derivative was based on its ability to partition between fluoride elimination and carbon-carbon bond scission during tryptophan metabolism. The non-enzymatic hydrolysis to 6-formyltryptophan occurred slowly under neutral conditions with a first-order rate constant of 0.0039 min-1. This process, however, was accelerated by 10(4)-fold upon deprotonation of the indolyl nitrogen (N-1) at high pH. Tryptophanase did not detectably facilitate this hydrolysis reaction, since no protein-dependent conversion of the difluoromethyl group was detected. Instead, the enzyme accepted the fluorinated species as an analogue of tryptophan and catalyzed the corresponding formation of 6-(difluoromethyl)indole, pyruvate, and ammonium ion. Anionic intermediates are therefore not expected to form during the catalytic activation of the indolyl moiety. Instead, aromatic protonation likely promotes the release of indole during enzymatic degradation of tryptophan.