Three-dimensional structures of noncovalent complexes of Citrobacter freundii methionine γ-lyase with substrates.

Crystal structures of Citrobacter freundii methionine γ-lyase complexes with the substrates of γ- (L-1-amino-3-methylthiopropylphosphinic acid) and ß- (S-ethyl-L-cysteine) elimination reactions and the competitive inhibitor L-norleucine have been determined at 1.45, 1.8, and 1.63 Å resolution, respectively. All three amino acids occupy the active site of the enzyme but do not form a covalent bond with pyridoxal 5'-phosphate. Hydrophobic interactions between the active site residues and the side groups of the substrates and the inhibitor are supposed to cause noncovalent binding. Arg374 and Ser339 are involved in the binding of carboxyl groups of the substrates and the inhibitor. The hydroxyl of Tyr113 is a potential acceptor of a proton from the amino groups of the amino acids.

Role of arginine 226 in the mechanism of tryptophan indole-lyase from Proteus vulgaris.

In the spatial structure of tryptophanase from Proteus vulgaris the guanidinium group of arginine 226 forms a salt bridge with the 3;-oxygen atom of the coenzyme. The replacement of arginine 226 with alanine using site-directed mutagenesis reduced the affinity of the coenzyme for the protein by one order of magnitude compared to the wild-type enzyme. The catalytic activity of the mutant enzyme in the reaction with L-tryptophan was reduced 10(5)-fold compared to the wild-type enzyme. The rates of the reactions with some other substrates decreased 10(3)-10(4)-fold. The mutant enzyme catalyzed exchange of the C-alpha-proton in complexes with some inhibitors with rates reduced 10(2)-fold compared to the wild-type enzyme. Absorption and circular dichroism spectra of the mutant enzyme and the enzyme-inhibitor complexes demonstrate that the replacement of arginine 226 with alanine does not significantly affect the tautomeric equilibrium of the internal aldimine, but it leads to an alteration of the optimal conformation of the coenzyme-substrate intermediates.

Tryptophan indole-lyase from Proteus vulgaris: kinetic and spectral properties.

An efficient method for purification of recombinant tryptophanase from Proteus vulgaris was developed. Catalytic properties of the enzyme in reactions with L-tryptophan and some other substrates as well as competitive inhibition by various amino acids in the reaction with S-o-nitrophenyl-L-cysteine were studied. Absorption and circular dichroism spectra of holotryptophanase and its complexes with characteristic inhibitors modeling the structure of the principal reaction intermediates were examined. Kinetic and spectral properties of two tryptophanases which markedly differ in their primary structures are compared. It was found that although the spectral properties of the holoenzymes and their complexes with amino acid inhibitors are different, the principal kinetic properties of the enzymes from Proteus vulgaris and Escherichia coli are analogous. This indicates structural similarity of their active sites.

Crystal structure of tryptophanase.

The X-ray structure of tryptophanase (Tnase) reveals the interactions responsible for binding of the pyridoxal 5'-phosphate (PLP) and atomic details of the K+ binding site essential for catalysis. The structure of holo Tnase from Proteus vulgaris (space group P2(1)2(1)2(1) with a = 115.0 A, b = 118.2 A, c = 153.7 A) has been determined at 2.1 A resolution by molecular replacement using tyrosine phenol-lyase (TPL) coordinates. The final model of Tnase, refined to an R-factor of 18.7%, (Rfree = 22.8%) suggests that the PLP-enzyme from observed in the structure is a ketoenamine. PLP is bound in a cleft formed by both the small and large domains of one subunit and the large domain of the adjacent subunit in the so-called "catalytic" dimer. The K+ cations are located on the interface of the subunits in the dimer. The structure of the catalytic dimer and mode of PLP binding in Tnase resemble those found in aspartate amino-transferase, TPL, omega-amino acid pyruvate aminotransferase, dialkylglycine decarboxylase (DGD), cystathionine beta-lyase and ornithine decarboxylase. No structural similarity has been detected between Tnase and the beta 2 dimer of tryptophan synthase which catalyses the same beta-replacement reaction. The single monovalent cation binding site of Tnase is similar to that of TPL, but differs from either of those in DGD.

2-Methyl-L-tryptophan is a substrate of tryptophanase.

Tryptophanase was generally considered to be inactive towards tryptophan derivatives substituted at 2-position of the indole ring. We have shown that cells containing tryptophanase catalyze the formation of 2-methyl-L-tryptophan from 2-methylindole and L-serine, and from 2-methylindole, pyruvate and ammonium ion. The kinetics of pyruvate formation from 2-methyl-L-tryptophan and its alpha-deuterated analogue catalyzed by homogeneous tryptophanase were examined. The primary deuterium isotope effect (kH/kD = 4.0) as well as the absorption spectrum of tryptophanase complex with 2-methyl-L-tryptophan indicate that the rate of enzymatic reaction of 2-methyl-L-tryptophan is in a considerable degree determined by the stage of removal of alpha-proton.

Tryptophanase from Escherichia coli: catalytic and spectral properties in water-organic solvents.

In water-methanol and water-dimethylformamide (DMF) (1:1 v/v) solutions tryptophanase from E.coli retains its abilities to form a quinonoid complex with quasisubstrates and to catalyze the decomposition of S-o-nitrophenyl-L-cysteine (SOPC). Both the KM and Vmax values decrease in water-organic media. The affinities of tryptophanase for L-alanine, L-tryptophan, oxindolyl-L-alanine and indole in aqueous methanol are decreased, the effect being stronger for the more hydrophobic substances. In a water solution tryptophanase catalizes the reaction of SOPC with indole to form L-tryptophan while in water-organic solvents only decomposition of SOPC is observed.

Crystallization and preliminary X-ray investigation of holotryptophanases from Escherichia coli and Proteus vulgaris.

Crystals of Proteus vulgaris holotryptophanase have been grown by the hanging-drop technique using polyethylene glycol 4000 as precipitant in the presence of monovalent cations K+ or Cs+. Orthorhombic crystals (P2(1)2(1)2(1)) grown with Cs+ have unit cell parameters a = 115.0 A, b = 118.2 A and c = 153.7 A and diffract to 1.8 A. There are four subunits of the tetrameric molecule in the asymmetric unit. Native data have been collected to 2.5 A resolution. The 3.4 A data were collected from tetragonal crystals of Escherichia coli holotryptophanase grown under conditions described by Kawata et al. (1991). The molecular replacement solution for this crystal form has been found using tyrosine phenol-lyase coordinates. The correct enantiomorph is P4(3)2(1)2. There are two subunits in the asymmetric unit.

Linear dichroism studies of tryptophanase and its quasisubstrate complexes oriented in polyacrylamide gel.

Tryptophanase from Escherichia coli was oriented in a compressed slab of polyacrylamide gel and its linear dichroism (LD) and absorption spectra have been measured. The free enzyme displays four LD bands at 305, 340, 425 and 490 nm. Two bands at 340 and 425 nm belong to the internal coenzyme-lysine aldimine. The 305-nm band apparently belongs to an aromatic amino acid residue. The 490-nm band disappears after treatment with NaBH4 or after incubation with L-alanine and subsequent dialysis. It is suggested that the 490-nm band belongs to a quinonoid enzyme subform. The reaction of tryptophanase with threo-3-phenyl-DL-serine, L-threonine and D-alanine leads to formation of an external aldimine with an intense absorption band at 420-425 nm. The values of reduced LD (delta A/A) in this band strongly differ from that in the 420-nm band of the free enzyme. The LD value of the complex with D-alanine is intermediate between those of the free enzyme and the complex with 3-phenylserine. In the presence of indole the complex with D-alanine displays the same LD as that observed with 3-phenylserine. The reaction of tryptophanase with L-alanine or oxindolyl-L-alanine leads to formation of a quinonoid intermediate with an absorption band near 500 nm. The LD value in this band is close to that of an external aldimine with L-threonine. It is concluded that reorientations of the coenzyme occur in the course of the tryptophanase reaction.

Conformational changes in the active site of tryptophanase revealed by the circular dichroism method.

Tryptophanase from E. coli displays positive CD in the coenzyme absorption bands at 337 and 420 nm. Breaking of the internal coenzyme-lysine imine bond upon reaction with hydroxylamine or amino-oxyacetate is accompanied by a strong diminution of the positive CD. Interaction of tryptophanase with L-threonine and beta-phenyl-DL-serine(threo form) leads to a decrease in absorbance at 337 nm and to an increase at 425 nm. This is associated with inversion of the CD sign, i.e. with disappearance of the positive CD in the 420-nm band and its replacement by a negative CD. L-Phenylalanine, alpha-methyl-DL-serine and D-alanine cause an increase in absorbance at 425-430 nm and a diminution of the positive CD in this band. In the presence of D-alanine and indole a negative CD appears in the 400-450 nm region. It is inferred that an external coenzyme-quasisubstrate aldimine is formed on interaction of the above amino acids with the enzyme. L-Alanine and oxindolyl-L-alanine evoke an intense narrow absorption band at 500 nm ascribed to a quinonoid intermediate; a positive CD is observed in this band. The dissymmetry factor delta A/A in the 500-nm band is much smaller than that in the absorption bands of the unliganded enzyme. Inversion of the CD sign on formation of the external aldimine and diminution of the dissymmetry factor in the quinonoid band indicate that reorientations of the coenzyme occur in the course of the catalytic action of tryptophanase.