Aldimine Formation Research Articles

Polyclonal antibody-catalysed aldimine formation

An antiserum catalysed imine formation from pyridoxal and phenylalanine is described, under conditions in which the uncatalysed reaction is not observed. This polyclonal antibody preparation shows Michaelian kinetic characteristics and presents a very good specificity for the pyridoxal structure.

Lysine 87 in the beta subunit of tryptophan synthase that forms an internal aldimine with pyridoxal phosphate serves critical roles in transimination, catalysis, and product release.

This study provides valuable insights into the functions of the lysine residue that forms an internal aldimine with pyridoxal phosphate in the beta subunit of tryptophan synthase from Salmonella typhimurium. Our spectroscopic and kinetic studies demonstrate that a mutant alpha 2 beta 2 complex having beta subunit lysine 87 replaced by threonine forms external aldimines with several amino acids including L-serine, beta-chloro-1-alanine, L-tryptophan, and D-tryptophan. Because the rates of aldimine formation are very slow, we conclude that one role of lysine 87 in the wild type enzyme is to facilitate formation of external aldimines by transimination. Lysine 87 is an essential catalytic residue because the mutant alpha 2 beta 2 complex has no measurable activity in reactions catalyzed by the beta subunit and does not convert external aldimines to products. The mutant enzyme carries out two slow partial beta-elimination reactions: the conversion of beta-chloro-L-alanine and L-serine to enzyme-bound aminoacrylate. The reaction with L-serine is catalyzed by ammonia, which partially replaces the deleted epsilon-amino group. Lysine 87 is important for substrate and product release because L-serine, L-tryptophan, and aminoacrylate dissociate very slowly from the mutant alpha 2 beta 2 complex. Our ability to prepare very stable derivatives of the mutant alpha 2 beta 2 complex containing tightly bound aldimines with a substrate, a product, or a reaction intermediate provides valuable materials for ongoing x-ray crystallographic investigations and future kinetic analyses of the allosteric activation of the alpha subunit by beta subunit ligands.

The role of Lys272 in the pyridoxal 5-phosphate active site of Synechococcus glutamate-1-semialdehyde aminotransferase.

Glutamate-1-semialdehyde (GSA) aminotransferase catalyzes transfer of the C2 amino group of glutamate 1-semialdehyde to the C1 position to yield the tetrapyrrole precursor 5-aminolevulinate. Based on spectrophotometric and steady-state data, GSA aminotransferase is a B6-containing enzyme which uses a ping-pong bi-bi mechanism described for other aminotransferases. A putative active-site lysine at position 272 of Synechococcus GSA aminotransferase was replaced by Arg, Ile or Glu, and genes encoding the corresponding three site directed mutants were expressed in Escherichia coli. The catalytic competence of the resulting enzymes was determined. The similarity of the absorbance spectra of pyridoxal-P-treated forms of Lys272----Arg, Lys272----Ile, Lys272----Glu with free pyridoxal-P indicates that enzyme-bound pyridoxal-P does not form an internal aldimine in in these three site-directed mutants. Whereas Lys----Ile and Lys----Glu form only stable ketimines and aldimines with GSA and its analogues, addition of these compounds to the pyridoxamine-P and pyridoxal-P forms of Lys----Arg induces slow spectral changes, indicating the catalysis of a half-reaction with GSA, 4,5-dioxovalerate and 4,5-diaminovalerate. 5-Aminolevulinate apparently binds with both coenzyme forms of Lys272----Arg, however significant tautomeric rearrangement is only observed with the pyridoxal-P form. It is suggested that Lys272 is the covalent pyridoxal-P-binding site and that this catalytically active lysine residue channels the overall transamination reaction towards 5-aminolevulinate. The second-half reaction (4,5-diaminovalerate in equilibrium with 5-aminolevulinate) is possibly supported by the formation of an internal aldimine which correctly positions the C4 amino group of 4,5-diaminovalerate relative to the enzyme-bound pyridoxal-P.

The K258R mutant of aspartate aminotransferase stabilizes the quinonoid intermediate.

Lys-258 of aspartate aminotransferase forms a Schiff base with pyridoxal phosphate and is responsible for catalysis of the 1,3-prototropic shift central to the transamination reaction sequence. Substitution of arginine for Lys-258 stabilizes the otherwise elusive quinonoid intermediate, as assessed by the long wavelength absorption bands observed in the reactions of this mutant with several amino acid substrates. The external aldimine intermediate is not detectable during reactions of this mutant with amino acids, although the inhibitor alpha-methylaspartate does slowly and stably form this species. These results suggest that external aldimine formation is one of the rate-determining steps of the reaction. The pyridoxamine-5'-phosphate-like enzyme form (330-nm absorption maximum) is unreactive toward keto acid substrates, and the coenzyme bound to this species is not dissociable from the protein.

Spectroscopic characterization of true enzyme-substrate intermediates of aspartate aminotransferase trapped at subzero temperatures

Absorption and circular dichroism spectra of stable enzyme-substrate intermediates of aspartate aminotransferase were recorded at subzero temperatures (down to -65 degrees C) in the cryosolvent water/methanol. The intermediates were formed either between the pyridoxal form of the enzyme and its amino acid substrates, or between the pyridoxamine form and its oxo acid substrates. Kd values determined by spectroscopic titration were very close to the Km values reported for the different substrates. The adsorption complex of the pyridoxal form was probably obtained on addition of cysteine sulfinate. This complex is characterized by an increased absorption at 430 nm together with a positive Cotton effect, as also observed in the case of the complex with the competitive inhibitor maleate indicating protonation of the internal aldimine. Addition of the substrates aspartate or glutamate to the pyridoxal form seemed to result in the direct accumulation of the external aldimine which showed a slight decrease in both the absorbance and the Cotton effect at 360 nm. Additionally, a bathochromic shift of 5 nm was observed in the case of glutamate. At 430 nm, only a minor increase in absorbance, but not in circular dichroism, was observed with aspartate, and no changes were found with glutamate and the substrate analog 2-methylaspartate, indicating a deprotonated external aldimine. Presumably, the ketimine intermediate was obtained on addition of the oxo acids 2-oxoglutarate or oxalacetate to the pyridoxamine form. The intermediate showed a slight bathochromic shift (2 nm) of the absorption band and decreased circular dichroism. On formation of the ketimine, a tyrosine residue, probably active-site Tyr225, becomes partly ionized. The finding that the external aldimine can probably be accumulated in the conversion of the pyridoxal to the pyridoxamine form with the natural substrates would confirm the proton abstraction at C alpha to be the rate-limiting step in the tautomerization, although with cysteine sulfinate, the formation of the external aldimine might contribute to the rate limitation. Accumulation of the ketimine in the reverse direction would indicate that the proton abstraction at C4' is rate-limiting in this half-reaction. The results demonstrate the feasibility of further structural investigations of true enzyme-substrate intermediates.

NMR observation of exchangeable protons of pyridoxal phosphate and histidine residues in cytosolic aspartate aminotransferase.

Observation of the 93-kDa cytosolic aspartate aminotransferase by 500-MHz 1H NMR spectroscopy in H2O has revealed a series of resonances in the 10-18 ppm range arising from exchangeable protons. One of these (peak A) has been assigned to the proton bound to the ring nitrogen of the coenzyme pyridoxal 5'-phosphate. A second (peak B) is assigned to H143 which participates in a chain of hydrogen bonds that includes also the coenzyme-bound proton. There is a mutual nuclear Overhauser effect between these two resonances. Peaks A and B respond to changes in pH and to interaction of the enzyme with coenzyme derivatives and inhibitors. Peak A moves from 15.4 to 17.4 ppm as the pH is lowered, while peak B moves in the opposite direction from 14.7 to 13.7 ppm, both with an apparent pKa of 6.15. This pKa is associated with deprotonation of the imine nitrogen at the Schiff base linkage of the coenzyme with K258 of the enzyme. In spectra of enzyme containing pyridoxamine 5'-phosphate, peak A is observed at 16.5 ppm and peak B is at 13.9 ppm over a broad pH range. Peaks A and B are found at 17.8 and 14.0 ppm, respectively, for the enzyme complex with glutarate. When alpha-methylaspartate is added to the enzyme several new resonances appear in the spectrum, which are attributed to formation of the external aldimine. The position of peak A in spectra of various forms of the enzyme is interpreted to reflect the electronic distribution in the coenzyme ring. Several other peaks in this region of the spectrum also are sensitive to changes in pH or the addition of inhibitors. Some possible assignments of these resonances are discussed.

Aldimine to ketoamine isomerization (Amadori rearrangement) potential at the individual nonenzymic glycation sites of hemoglobin a: Preferential inhibition of glycation by nucleophiles at sites of low isomerization potential

The relative roles of the two structural aspects of nonenzymic glycation sites of hemoglobin A, namely the ease with which the amino groups could form the aldimine adducts and the propensity of the microenvironments of the respective aldimines to facilitate the Amadori rearrangement, in dictating the site selectivity of nonenzymic glycation with aldotriose has been investigated. The chemical reactivity of the amino groups of hemoglobin A for in vitro reductive glycation with aldotriose is distinct from that in the nonreductive mode. The reactivity of amino groups of hemoglobin A toward reductive glycation (i.e., propensity for aldimine formation) decreases in the order Val-1(beta), Val-1(alpha), Lys-66(beta), Lys-61(alpha), and Lys-16(alpha). The overall reactivity of hemoglobin A toward nonreductive glycation decreased in the order Lys-16(alpha), Val-1(beta), Lys-66(beta), Lys-82(beta), Lys-61(alpha), and Val-1(alpha). Since the aldimine is the common intermediate for both the reductive and nonreductive modification, the differential selectivity of protein for the two modes of glycation is clearly a reflection of the propensity of the microenvironments of nonenzymic glycation sites to facilitate the isomerization reaction (i.e., Amadori rearrangement). A semiquantitative estimate of this propensity of the microenvironment of the nonenzymic glycation sites has been obtained by comparing the nonreductive (nonenzymic) and reductive modification at individual glycation sites. The microenvironment of Lys-16(alpha) is very efficient in facilitating the rearrangement and the relative efficiency decreases in the order Lys-16(alpha), Lys-82(beta), Lys-66(beta), Lys-61(alpha), Val-1(beta), and Val-1(alpha). The propensity of the microenvironment of Lys-16(alpha) to facilitate the Amadori rearrangement of the aldimine is about three orders of magnitude higher than that of Val-1(alpha) and is about 50 times higher than that of Val-1(beta). The extent of nonenzymic glycation at the individual sites is modulated by various factors, such as the pH, concentration of aldotriose, and the concentration of the protein. The nucleophiles--such as tris, glycine ethyl ester, and amino guanidine--inhibit the glycation by trapping the aldotriose. The nonenzymic glycation inhibitory power of nucleophile is directly related to its propensity to form aldimine. Thus, the extent of inhibition of nonenzymic glycation at a given site by a nucleophile directly reflects the relative role of pKa of the site in dictating the glycation at that site.(ABSTRACT TRUNCATED AT 400 WORDS)

Substitution of glutamine for lysine at the pyridoxal phosphate binding site of bacterial D-amino acid transaminase. Effects of exogenous amines on the slow formation of intermediates.

In bacterial D-amino acid transaminase, Lys-145, which binds the coenzyme pyridoxal 5'-phosphate in Schiff base linkage, was changed to Gln-145 by site-directed mutagenesis (K145Q). The mutant enzyme had 0.015% the activity of the wild-type enzyme and was capable of forming a Schiff base with D-alanine; this external aldimine was formed over a period of minutes depending upon the D-alanine concentration. The transformation of the pyridoxal-5'-phosphate form of the enzyme to the pyridoxamine-5'-phosphate form (i.e. the half-reaction of transamination) occurred over a period of hours with this mutant enzyme. Thus, information on these two steps in the reaction and on the factors that influence them can readily be obtained with this mutant enzyme. In contrast, these reactions with the wild-type enzyme occur at much faster rates and are not easily studied separately. The mutant enzyme shows distinct preference for D- over L-alanine as substrates but it does so about 50-fold less effectively than the wild-type enzyme. Thus, Lys-145 probably acts in concert with the coenzyme and other functional side chain(s) to lead to efficient and stereochemically precise transamination in the wild-type enzyme. The addition of exogenous amines, ethanolamine or methyl amine, increased the rate of external aldimine formation with D-alanine and the mutant enzyme but the subsequent transformation to the pyridoxamine-5'-phosphate form of the enzyme was unaffected by exogenous amines. The wild-type enzyme displayed a large negative trough in the circular dichroic spectrum at 420 nm, which was practically absent in the mutant enzyme. However, addition of D-alanine to the mutant enzyme generated this negative Cotton effect (due to formation of the external aldimine with D-alanine). This circular dichroism band gradually collapsed in parallel with the transformation to the pyridoxamine-5'-phosphate enzyme. Further studies on this mutant enzyme, which displays the characteristics of the wild-type enzyme but at attenuated rates, may yield information on the factors controlling the stereochemistry of the reaction as well as on the catalytic steps of the transaminase pathway.

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 amine 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 β-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, α-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 adsorption band at 500 nm ascribed to a quinonoid intermediate; a positive CD is observed in this band. The dissymmetry factor Δ 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.

ChemInform Abstract: Photoassisted C‐H Bond Activation with RhCl(CO)(PR3)2 in the Presence of Isocyanides Leading to Catalytic Formation of Aldimines.

AbstractCyclohexyl isocyanide (I) is irradiated in benzene (II) or pentane (VI) in the presence of Rh catalysts, yielding the imines (III) or (VII) ‐(IX), the amine (IV), and diphenyl (V).

Synthesis of oxaziridinylquinones and oxaziridinylazines as potential antitumor agents

Abstract1,4‐Benzoquinones, 1,4‐naphthoquinones, as well as pyridines and quinolines having 2‐alkyloxaziridinyl substituents were synthesized. The method involves formation of aldimines and their oxidation to oxaziridines. 1,4‐Dimethoxyarenes bearing oxaziridinyl substituents were converted into the corresponding quinones with silver(II) dipicolinate. Some of the oxaziridinylquinones and ‐azines exhibit activity against KB cells, and the structure‐activity relationship is discussed in terms of the current theory of biologically activated alkylating agents.

Photoassisted C–H Bond Activation with RhCl(CO)(PR3)2 in the Presence of Isocyanides Leading to Catalytic Formation of Aldimines

Abstract C–H bond activation of benzene and pentane in the presence of isocyanides was promoted by RhCl(CO) (PR3)2 to result in the isocyanides insertion into C–H bonds.

ChemInform Abstract: The Catalytic Activation and Functionalization of C‐H Bonds. Aldimine Formation by the Insertion of Isonitriles into Aromatic C‐H Bonds.

AbstractIrradiation of a benzene (IV) solution of the complex (IIIb) results in the formation of the aldimine (V).

The catalytic activation and functionalization of carbon-hydrogen bonds. Aldimine formation by the insertion of isonitriles into aromatic carbon-hydrogen bonds

Many examples of the activation of aromatic and aliphatic carbon-hydrogen bonds by homogeneous transition-metal complexes have appeared over the past few years, offering attractive new routes to organometallic species. While several of these reports involve oxidative addition of low valent metal complexes to alkanes or arenes, these new adducts have not proven to be useful for the generation of functionalized hydrocarbon products. Reports of successful metal-based alkane functionalization include free radical oxidations, intramolecular cyclizations of alkyl carbenoid species to given cyclopentanones, aromatic isonitrile insertion to give indoles, and alkane dehydrogenation to produce olefins. Arene functionalization reactions commonly depend upon the presence of tethering groups, although the production of benzaldehyde, benzoic acid, styrene, and phenylsiloxane insertion products have been recently reported. They report here a new type of iron catalyzed insertion of isonitrile into the C-H bond of arenes to produce aldimines (eq 1). RNC + C/sub 6/H/sub 6/ (Fe) ..-->.. ..delta..G/sup 0/ approx. = -11 Kcal/mol C/sub 6/H/sub 5/ - CH = NR (1).

The characterization of N-methyl, N-ethyl, N-propyl, N-butyl and N-hexyl chitosans, novel film-forming polymers

The N-alkyl chitosans in the title were prepared from chitosan ( Euphausia superba) by aldimine formation and hydrogenation at room temperature in aqueous media. They are white powders with a certain degree of crystallinity; their substitution degrees are: acetamido 36%, secondary amine 23-33%, primary amine 31-41%. The chelating ability of N-alkyl chitosans is specific for certain cations such as Cu 2+, Hg 2+ and Pb 2+ for which the capacities are in the range 2-6% by weight, depending on conditions and choice of N-alkyl chitosan. In the N-alkyl chitosans, the hydrogen bonds are weakened by the presence of substituents and therefore they swell in water. Membranes are easily cast from acetic acid solutions. Circular dichroism and ultraviolet spectrometry measurements indicate that the chelation of metal ions depresses the acetamido group bands and introduces new spectral bands due to the chelates. Circular dichroism spectra also reveal the hydration state of the membranes. Applications are foreseen in the pharmaceutical, cosmetic and textile industries

Rates and equilibria of aldimine formation between pyridoxal 5′-phosphate and N-hexylamine

The rate and equilibrium constants of the reaction between n-hexylamine and pyridoxal 5′-phosphate have been studied in aqueous solution as a function of pH at 25 ± 0.1 °C and at an ionic strength of 0.1. The pH profiles of the observed constants have been explained by protonation of the pyridoxal 5′-phosphate and its Schiff's base. This study shows that there is an intramolecular general acid catalysis of the Schiff's base formation, which can explain why the aldimine is formed at a reasonably high rate at neutral pH, in spite of the low amount of unprotonated reacting amine at this pH.

Equilibrium and kinetic measurements of the binding of pyridoxal 5'-phosphate to hybrid tryptophan synthase from Escherichia coli.

Hybrid tryptophan synthase was prepared that contains a β, subunit with one functional active site while the internal aldimine between cofactor and enzyme of the other protomer was reduced with sodium borohydride (α,ββ*). The modified enzyme shows a specific activity for the l‐serine+indole to l‐tryptophan reaction of about 50% compared to the native enzyme [Hathaway, G. M., Kida, S. and Crawford, I. P., Biochemistry 8, 989—997 (1969)]. The binding of pyridoxal 5′‐phosphate (pyridoxal‐P) to the α2apo ββ* complex and to the apo ββ* subunit was studied by equilibrium methods and rapid mixing experiments.The equilibrium binding curves for the hybrid species are hyperbolic (i. e. non‐cooperative), yielding apparent microscopic dissociation constants of 1.6±O.2 × 10−6 M for the α2 holoββ* subunit.The rate of formation of the internal aldimine in the unmodified active site was followed by fast reduction with sodium borohydride, L‐tryptophan synthesis was used to monitor the rate of formation of active enzyme.Cofactor binding to the α2apo ββ* complex is characterized by three sequential steps of decreasing rate: formation of a non‐covalent initial complex, which reacts to an enzymatically inactive internal aldimine, followed by a conformational change leading to the active α2holo ββ* bienzyme complex. A similar series of consecutive steps with decreasing reaction rates is observed for the binding of pyridoxal‐P to the apoββ* subunit. The formation of active enzyme, however, is biphasic. The faster process, which parallels the formation of the internal aldimine and which accounts for 85% of the total amplitude, obviously involves an already active high‐affinity state of the hybrid molecule whereas the second phase parallels the activation process as observed for cofactor binding to the native dimer.These findings are discussed with respect to the recently proposed mechanism for pyridoxal‐P binding to the unmodified apoβ2 subunit [Bartholmes, P. Balk, H. and Kirschner, K, Biochemistry 19, 4527–4533 (1980]

Circular dichroism studies on the interaction of tryptophan synthase with pyridoxal 5'-phosphate.

The interaction between the beta 2 subunit of tryptophan synthase and the coenzyme pyridoxal 5'-phosphate (PLP) is characterized by induced circular dichroism (CD) in the near-UV (260-285 nm) and in the visible region (320-480 nm, extrinsic Cotton effect). Because of its high mean residue ellipticity ([theta] = 56 deg cm2 dmol-1 for the isolated holo-beta 2 subunit and 102 deg cm2 dmol-1 for the alpha 2-holo-beta 2 complex, respectively) the latter has been used to define different conformational states of the beta 2 dimer via CD titrations. Fitting the obtained binding parameters to the known data from equilibrium dialysis leads to the result that the low-affinity state of the isolated beta 2 subunit shows a 3 times greater rotational strength than the holoenzyme in the high-affinity state. The generation of the final CD amplitude is characterized by a rate constant intermediate between the values for the formation of the internal aldimine and for the regain of enzymatic activity. Interaction of the alpha 2-apo-beta 2 bienzyme complex with the cofactor leads to a hyperbolic binding curve which is apparently free of contributions caused by unspecific PLP binding outside the active center. The determined dissociation constant of 9 x 10(-7) M is in good agreement with the value of 1 x 10(-6) M as obtained by equilibrium dialysis. Binding kinetics reveal a very slow process with a rate constant of 2.6 x 10(-4) s-1, significantly smaller than that for the regain of catalytic activity during reconstitution of the enzyme.

Mechanism of reconstitution of the apo beta 2 subunit and the alpha 2 apo beta 2 complex of tryptophan synthase with pyridoxal 5'-Phosphate: kinetic studies.

The mechanism of pryidoxal 5'-phosphate (PLP) binding to both the alpha apo beta 2 complex and the apo beta 2 subunit of tryptophan synthase was investigated by rapid mixing experiments. Absorption and fluorescence changes were used to monitor the binding reaction directly. Reduction with sodium borohydride provided the rate of formation of the internal aldimine with the lysine amino group of the enzyme, and substrate turnover monitored the rate of formation of active enzyme. The alpha 2 apo beta 2 complex binds PLP in a sequence of three steps of decreasing rate: formation of a noncovalent complex, which isomerizes to an enzymically inactive internal aldimine, followed by formation of an active alpha 2 holo beta 2 complex. The two binding sites appear to bind PLP independently. The apo beta 2 subunit binds PLP cooperatively in a sequence of three steps of decreasing rate: formation of a noncovalent complex, which isomerizes to an enzymically inactive internal aldimine, followed by the formation of the enzymically active holo beta 2 subunit. Taken together with kinetic studies of pyridoxine phosphate binding [Tschopp, J., & Kirschner, K. (1980) Biochemistry (second paper of three in this issue)], the rate data of the apo beta 2 subunit are shown to be consistent with the concerted mechanism. The difference between the values of the isomerization rate constants of bound PLP and bound PNP appear to result from the covalent internal aldimine, which is formed with PLP but not with PNP.