Catalysis of dehydrogenation of 4-trans-(N,N-dimethylamino)cinnamaldehyde by aldehyde dehydrogenase.

4-trans-(N,N-dimethylamino)cinnamaldehyde (DACA) is a chromophoric and fluorogenic substrate of aldehyde dehydrogenase. Fluorescence of DACA is enhanced by binding to aldehyde dehydrogenase in the absence of catalysis both in the presence and absence of the coenzyme analogue 5'AMP. DACA binds to aldehyde dehydrogenase with a dissociation constant of 1-3 microM and stoichiometry of 2 mol mol(-1) enzyme. Incorporation of DACA during catalysis was also investigated and found to be 2 mol DACA mol(-1) enzyme. Effect of pH on the stoichiometry of DACA incorporation during catalysis has shown that DACA incorporation remained constant at 2 mol DACA mol(-1) enzyme, despite a 74-fold velocity enhancement between pH 5.0 and 9.0. Increase of pH increased decomposition of enzyme-acyl intermediate without affecting the rate-limiting step of the reaction. At pH 7.0 the pH stimulated velocity enhancement was 10-fold over that at pH 5.0; further velocity enhancement (11.5-fold that of pH 7.0) was achieved by 150 microM Mg(2+) ions. The velocity at pH 7.0 with Mg(2+) exceeded that of pH 9.0, and that at maximal pH stimulation at pH 9.5. It was observed that level of intermediate decreased to about 1 mol mol(-1) enzyme, indicating that Mg(2+) ions increased the rate of decomposition of the enzyme-acyl intermediate and shifted the rate-limiting step of the reaction to another step in the reaction sequence.

Binding and incorporation of 4-trans-(N,N-dimethylamino) cinnamaldehyde by aldehyde dehydrogenase.

4-trans-(N,N-Dimethylamino)cinnamaldehyde (DACA) is a chromophoric substrate of aldehyde dehydrogenase (EC 1.2.1.3) whose fate can be followed during catalysis. During this investigation we found that DACA also fluoresces and that this fluorescence is enhanced and blue-shifted upon binding to aldehyde dehydrogenase. Binding of DACA to aldehyde dehydrogenase also occurs in the absence of coenzyme. Benzaldehyde (a substrate), acetophenone (a substrate-competitive inhibitor), and the substrate-competitive affinity reagent bromoacetophenone interfere with DACA binding. Thus, DACA binds to the active site and can be employed for titration of active aldehyde dehydrogenase. Both E1 and E2 isozymes, which are homotetramers, bind DACA with dissociation constants of 1-4 microM with a stoichiometry of 2 mol DACA/ mol enzyme. The stoichiometry of enzyme-acyl intermediate was also found to be 2 mol DACA/ mol enzyme for both E1 and E2 isozymes. Thus, both enzymes appear to have only two substrate-binding sites which participate in catalysis. The level of enzyme-acyl intermediate remained constant at different pH values, showing that enhancement of velocity with pH was not due to altered DACA-enzyme levels. When the reaction velocity was increased even further by using 150 microM Mg2+ the intermediate level was decreased, suggesting that both increased pH and Mg2+ promote decomposition of the DACA-enzyme intermediate. Titration with DACA permits study of aldehyde substrate catalysis before central complex interconversion.

Mechanism of inhibition of aldehyde dehydrogenase by citral, a retinoid antagonist.

Low concentrations of citral (3,7-dimethyl-2,6-octadienal), an inhibitor of retinoic acid biosynthesis, inhibited E1, E2 and E3 isozymes of human aldehyde dehydrogenase (EC1.2.1.3). The inhibition was reversible on dilution and upon long incubation in the presence of NAD+; it occurred with simultaneous formation of NADH and of geranic acid. Thus, citral is an inhibitor and also a substrate. Km values for citral were 4 microM for E1, 1 microM for E2 and 0.1 microM for E3; Vmax values were highest for E1 (73 nmol x min-1 x mg-1), intermediate for E2 (17 nmol x min-1 x mg-1) and lowest (0.07 nmol x min-1 x mg-1) for the E3 isozyme. Citral is a 1 : 2 mixture of isomers: cis isomer neral and trans isomer, geranial; the latter structurally resembles physiologically important retinoids. Both were utilized by all three isozymes; a preference for the trans isomer, geranial, was observed by HPLC and by enzyme kinetics. With the E1 isozyme, both geranial and neral, and with the E2 isozyme, only neral obeyed Michaelis-Menten kinetics. With the E2 isozyme and geranial sigmoidal saturation curves were observed with S0.5 of approximately 50 nM; the n-values of 2-2.5 indicated positive cooperativity. Geranial was a better substrate and a better inhibitor than neral. The low Vmax, which appeared to be controlled by either the slow formation, or decomposition via the hydride transfer, of the thiohemiacetal reaction intermediate, makes citral an excellent inhibitor whose selectivity is enhanced by low Km values. The Vmax for citral with the E1 isozyme was higher than those of the E2 and E3 isozymes which explains its fast recovery following inhibition by citral and suggests that E1 may be the enzyme involved in vivo citral metabolism.

N-tosyl-L-phenylalanine chloromethyl ketone, a serine protease inhibitor, identifies glutamate 398 at the coenzyme-binding site of human aldehyde dehydrogenase. Evidence for a second "naked anion" at the active site.

Human aldehyde dehydrogenase isozymes were inactivated by N-tosyl-L-phenylalanine chloromethyl ketone (TPCK), an inhibitor of chymotrypsin. The inactivation was a first-order process that followed saturation kinetics. NAD and chloral when used together protected against inactivation. In steady-state kinetics, TPCK produced only slope effects versus varied NAD, both slope and intercept effects versus varied glycolaldehyde were produced, indicating that TPCK reacted with the same enzyme form with which NAD reacted. Ki values from steady-state kinetics and saturation kinetics were comparable. Use of [3H]-labeled TPCK showed that inactivation was associated with the incorporation of two molecules of TPCK per molecule of enzyme. The label incorporation occurred into a single tryptic peptide and also into a single chymotryptic peptide of the E1 isozyme. Purification of labeled peptides, followed by sequencing, demonstrated that E398 of aldehyde dehydrogenase was labeled. Reaction of a haloketone, TPCK, with a carboxyl group of E398 indicates that E398 occurs as a "naked anion" within the molecule. This paper constitutes identification of the second (after E268) "naked anion" at the active site of aldehyde dehydrogenase.

Haloenol lactones as inactivators and substrates of aldehyde dehydrogenase.

Human aldehyde dehydrogenase (EC 1.2.1.3) isozymes E1 and E2 were irreversibly inactivated by stoichiometric concentrations of the haloenol lactones 3-isopropyl-6(E)-bromomethylene tetrahydro-pyran-2-one and 3-phenyl-6(E)-bromomethylene tetrahydropyran-2-one. No inactivation occurred with the corresponding nonhalogenated enol lactones. Both the dehydrogenase and esterase activities were abolished. Activity was not regained on dialysis or treatment with 2-mercaptoethanol. The inactivation was subject to substrate protection: NAD afforded protection which increased in the presence of the aldehyde-substrate competitive inhibitor chloral. Saturation kinetics gave positive gamma-axis intercepts, allowing the determination of binding constants. Inactivation stiochiometry determined with 14C-labeled 3-(1-naphthyl)-6(E)-iodomethylene tetrahydropyran-2-one was found to correspond to the active-site number. The nonhalogenated lactone, 3-(1-naphthyl)-6(E)-methylene tetrahydropyran-1-one was shown to be a substrate for aldehyde dehydrogenase via its esterase function. Inactivation and enzymatic hydrolysis occurred within a similar time frame. Opening of the lactone ring to form enzyme-acyl intermediate with active site cysteine appears to be a necessary prerequisite to inactivation, since halogen in the lactone ring is nonreactive. Thus, the inactivation of aldehyde dehydrogenase by haloenol lactones is mechanism-based. Inactivation by haloenol lactones occurs in a manner analogous to that of chymotrypsin with which aldehyde dehydrogenase shares esterase activity and binding of haloenol lactones at the active site.

Aspartic proteinase from Penicillium camemberti: purification, properties, and substrate specificity.

An acid proteinase from the culture filtrate of Penicillium camemberti was isolated in a two-step purification procedure by cation exchange chromatography and gel filtration. The enzyme is an aspartic proteinase inhibited by pepstatin, DAN, and EPNP, with a molecular mass determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of 33.5 kDa. The optimum activity for hydrolysis of denatured hemoglobin is around pH 3.4. The enzyme is highly specific for the aromatic and hydrophobic amino acid residue in insulin B-chain and, like pepsin, selectively splits only one Leu7-Met8 peptide bond in the squash trypsin inhibitor CMTI 1. The hydrolyzed bond can be resynthesized by P. camemberti proteinase at neutral pH.

Steady-state kinetics of the binding of beta-lactams and penicilloates to the second binding site of the Enterobacter cloacae P99 beta-lactamase.

Previous research has shown that the class C beta-lactamase of Enterobacter cloacae P99 is able to catalyze the hydrolysis and aminolysis of acyclic depsipeptides. The steady kinetics of these reactions are complicated by the presence of an additional (depsi)peptide binding site in addition to the active site [Pazhanisamy, S., & Pratt, R. F. (1989) Biochemistry 28, 6875-6882]. The present paper presents a steady-state kinetic analysis of the inhibition of depsipeptide hydrolysis by sodium benzylpenicilloate, methyl benzylpenicilloate, 6-aminopenicillanic acid, and 7-aminocephalosporanic acid. The two beta-lactams are considerably poorer substrates than the depsipeptide employed, m-[[(phenylacetyl)glycyl]oxy]benzoic acid. The aim was to determine the relative affinity of these ligands for the active site and the second site. Three types of experiments were employed: (i) measurements of direct inhibition of depsipeptide hydrolysis, (ii) measurements of the effect of an active-site-directed inhibitor, m-(dansylamidophenyl)-boronic acid, on the effectiveness of the ligands as inhibitors, and (iii) measurements of the effect of a preferential second site ligand, N-(phenylacetyl)glycyl-D-phenylalanine, on the effectiveness of the ligands as inhibitors. The results suggest that all four ligands preferentially bind to the active site, with weaker binding at the second site. The necessarily weaker binding of a ligand to the second site when the active site is occupied by a transition-state analog inhibitor was analyzed. Perhaps surprisingly, the intact beta-lactams appeared to bind more firmly to the alternative site than do the flexible penicilloates.(ABSTRACT TRUNCATED AT 250 WORDS)

Inactivation of the Enterobacter cloacae P99 beta-lactamase by a fluorescent phosphonate: direct detection of ligand binding at the second site.

The synthesis of a fluorescent beta-lactamase inhibitor, p-nitrophenyl [(dansylamido)methyl]-phosphonate is described. The compound inactivated the class C beta-lactamase of Enterobacter cloacae P99 with stoichiometric release of p-nitrophenol, presumably, as with other phosphonate inhibitors, by phosphonylation of the active site serine. The inhibited enzyme exhibited typical dansyl fluorescence emission at 533 nm with excitation maxima at 345 and 283 nm; the latter excitation peak probably arises from radiationless energy transfer to the dansyl group from aromatic chromophores on the protein-inspection of the crystal structure shows that the closest are tyrosines. The fluorescence of the p-nitrophenyl phosphonate and the inhibited enzyme varied with pH in a very similar fashion, reflecting dissociation of the dimethylammonium ion in the ground state at low pH and of the sulfonamide in the excited state above pH 6. No perturbation of the fluorescence of the inhibited enzyme due to active site functional groups was observed. This may reflect the distance between the dansyl fluorophore and the phosphonyl group and/or the high pKa's of the protonated active site functional groups in the presence of the phosphonate. The addition of certain small molecular weight N-acyl amino acids, of preferred structure D-RCONHCHR'CO2-, to the inhibited enzyme led to an enhancement of dansyl fluorescence intensity and a blue shift in the emission maximum. This suggested that these molecules bind to the beta-lactamase at a site other than the active site and supports previous kinetic data to this effect [Dryjanski, M., & Pratt, R. F., (1995) Biochemistry 34, preceding paper in this issue].(ABSTRACT TRUNCATED AT 250 WORDS)

Single peptide bond hydrolysis/resynthesis in squash inhibitors of serine proteinases. 2. Limited proteolysis of Curcurbita maxima trypsin inhibitor I by pepsin.

Porcine pepsin hydrolyzes the Leu7-Met8 (P2'-P3') peptide bond in Cucurbita maxima trypsin inhibitor I (CMTI I) in the pH range 2.0-4.8. The reaction proceeds to equilibrium between intact CMTI I and its cleaved form. The pH-independent value of the equilibrium constant (Khyd0 = 0.78) indicates that both forms of the inhibitor have similar Gibbs energies. The pH dependence of this constant shows that the peptide bond hydrolysis does not perturb ionization constants of any preexistent groups. The same equilibrium values can also be reached from the cleaved inhibitor side through pepsin-catalyzed resynthesis of the Leu7-Met8 peptide bond. Catalytic rate constants for the forward (hydrolysis) and reverse (resynthesis) reactions are similar. Both catalytic rate constants are strongly pH dependent, approaching the highest values at pH 2.0. Michaelis constant values for hydrolysis and resynthesis reactions depend much less on pH and are within values typical for oligopeptide substrates of pepsin. The influence of the binding loop rigidity on slow proteolysis by pepsin and other proteinases is discussed.

Metallo-proteinase from the seedlings of kale (Brassica oleracea L. var. sabellica): : Preparation, partial characterization and substrate specificity.

Metallo-proteinase from 8-d-old seedlings of kale was isolated. The enzyme was extracted with 1% NaCl, concentrated by ammonium sulfate and finally purified by high-performance liquid chromatography. The isolated enzyme had a molecular weight of 22.4 kDa and showed a maximum activity at pH 9.0 using casein as a substrate. Proteolytic activity of proteinase was inhibited by chelators. The inhibition by ethylenediaminetetraacetate (EDTA) was abolished by some divalent metals ions, especially by Zn(2+). The enzyme showed activity against the synthetic peptides Suc-Ala-Ala-Pro-Leu-pNA and Suc-Ala-Ala-Pro-Phe-pNA, and hydrolized the following peptide bonds in the oxidized insulin B-chain: Leu6-Cya7, Leu15-Tyr16, Leu17-Val18 and Phe25-Tyr26.

Serine proteinase from Cucurbita ficifolia seed; purification, properties, substrate specificity and action on native squash trypsin inhibitor (CMTI I).

A proteinase was purified from resting seeds of Cucurbita ficifolia by ammonium sulfate fractionation and successive chromatography on CM-cellulose, Sephacryl S-300 and TSK DEAE-2SW (HPLC) columns. Inhibition by DFP and PMSF suggests that the enzyme is a serine proteinase. The apparent molecular mass of this enzyme is ca. 77 kDa. The optimum activity for hydrolysis of casein and Suc-Ala-Ala-Pro-Phe-pNA is around pH 10.5. The following peptide bonds in the oxidized insulin B-chain were hydrolysed by the proteinase: Phe1-Val2, Asn3-Gln4, Gln4-His5, Cya7-Gly8, Glu13-Ala14, Ala14-Leu15, Cya19-Gly20, Pro28-Lys29 and Lys29-Ala30. The proteinase is more selective towards the native squash seed trypsin inhibitor (CMTI I) and primarily cuts off only its N-terminal arginine. The inhibitor devoided of the N-terminal arginine residue is still active against trypsin.

Serine proteinase from Cucurbita ficifolia seeds.

A new serine proteinase was isolated from Cucurbita ficifolia seeds by the purification procedure, which includes: extraction, salting out with ammonium sulphate, chromatography on CM-cellulose. Sephacryl S-300 gel filtration and h.p.l.c. on DEAE-2SW TSK column. The enzyme was homogeneous both in native and SDS PAGE. Three independent methods showed its molecular mass to be approximately 77 kDa. The enzyme was inhibited by specific serine proteinase organic inhibitors, and was active in the presence of inhibitors specific for other proteinase classes. Surprisingly, squash proteinase exhibited a very high and broad pH optimum with a maximum at 10.7. It hydrolysed many different peptide bonds in B-chain of insulin and was able to cleave four bonds in endogenous serine proteinase inhibitor (CMTI).