Studies on lysophospholipases, V. The action of lysolecithin-hydrolyzing enzymes on lecithins and 1-acyl lysolecithins with varying fatty acid chain-length.

The activity of two purified lysolecithin-hydrolyzing enzymes on homologous series of synthetic lecithins containing two identical fatty acyl chains and of 1-acyl-lysolecithins has been measured as a function of substrate concentration. In general, enzymatic activity toward lecithins decreased with increasing chain length. Maximal hydrolysis rates for the lysolecithin series were measured with 1-dodecanoyllysolecithin. In this series increased affinities for substrates with increasing acyl-chain length was noticed. In the substrate concentration versus enzymatic velocity curves no breaks were observed at the critical micelle concentration of the various substrates. The initial site of attack during hydrolysis of short-chain lecithins was determined using 1-octanoyl-2pentanoyl-lecithin, 1-hexanoyl-2-hexyllecithin and 1 -hexyl-2-hexanoyllecithin. Both enzymes exhibited a pronounced preference for hydrolysis of the acyl ester bond at the 1-position. Especially the enzyme from beef pancreas seems to be suitable for the enzymatic preparation of 2-acyl lysolecithins from the corresponding short-chain lecithins.     

Kinetic studies on the reactivation of d-β-hydroxybutyrate dehydrogenase with mixtures of short-chain lecithins

d-β-hydroxybutyrate dehydrogenase, purified as soluble, lipid-free apoenzyme (inactive) from rat liver mitochondria can be reactivated by the short-chain dihexanoyl, diheptanoyl, and dioctanoyl lecithins at the monomeric state, upon formation of a reversible enzyme-lecithin complex. Previous studies with these lecithins suggested that reactivation of the apoenzyme requires the simultaneous occupation of two identical, noninteracting lecithin binding sites via a rapid equilibrium random mechanism. The short-chain lecithins exhibited similar reactivating capacities, differing only in their affinities towards the enzyme. In order to further test that model, the reactivation of the apoenzyme was studied when two or three short-chain lecithins were simultaneously present in the reaction medium. The initial velocities were measured either as a function of the concentration of one lecithin while the other(s) were kept constant, or as a function of the total phospholipid concentration with mixtures of different lecithins at a constant molar ratio. The pertinent equations were derived on the principles of multiple equilibria with identical, noninteracting sites able to be occupied by any of the different lecithins present in the reaction medium, with the doubly occupied enzyme as the only active species. In agreement with the above-proposed model, the results obtained indicates that the molar fraction of the doubly occupied (active) enzyme species can be calculated from equilibrium considerations and that the maximal attainable with the different short-chain lecithins are similar.     

Spectral and kinetic studies on Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating)

Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating) contains two FAD molecules in one molecule of the enzyme (Koyama, H. (1983) J. Biochem. 93, 1313-1319). When the enzyme was mixed anaerobically with L-phenylalanine, beta-2-thienylalanine, L-tyrosine, or L-methionine, a spectral species (purple intermediate) with a broad absorption band around 540 nm was observed with each substrate, and decayed slowly. From the data on the overall reaction kinetics, the rate of the L-phenylalanine oxidase reaction was expressed as follows. e/v = e/Vm + A/[S] + B/[O2] where e represents the concentration of enzyme unit, v the rate of the overall reaction, Vm the maximum velocity, and A and B are constants. Furthermore, the reactions of the enzyme with beta-2-thienylalanine (mostly an oxygenase substrate) and L-methionine (an oxidase substrate) were analyzed by the "stopped flow" method. The following scheme for the mechanism of L-phenylalanine oxidase reaction with both substrates is proposed, based on the data obtained. (formula; see text) Where Eox represents the oxidized form of the enzyme unit, EoxS the enzyme unit (oxidized form)-substrate compound, X the purple intermediate with a characteristic broad absorption band around 540 nm, S the substrate and P the product.     

A neutral phospholipase D activity from rat brain synaptic plasma membranes. Identification and partial characterization

Rapid activation of phospholipase D (PLD) in response to cell stimulation was recently demonstrated in many systems, raising the hypothesis that PLD participates in transduction of extracellular signals across the plasma membrane. In the present study, we describe the identification of a neutral PLD activity in purified rat brain synaptic plasma membranes, and the in vitro conditions required to assay its catalytic activity with exogenous [3H]phosphatidylcholine as substrate. Production of [3H]phosphatidic acid, the natural lipid product of PLD and of [3H]phosphatidylethanol, catalyzed by PLD in the presence of ethanol via transphosphatidylation, were measured. The synaptic membrane PLD exhibited its highest activity at pH 7.2 and was thus defined as a neutral PLD. Enzyme activity was absolutely dependent on the presence of sodium oleate and was strongly activated by Mg2+ ions (at 1 mM). Ca2+ at concentrations up to 0.25 mM was as stimulatory as Mg2+, but at 2 mM it completely inhibited enzyme activity. Mg2+ extended the linear phase of PLD activity from 2 to 15 min, suggesting that it may stabilize the enzyme under our assay conditions. The production of [3H]phosphatidylethanol was a saturable function of ethanol concentration. Production of [3H] phosphatidic acid was inversely related to the concentration of ethanol and to the accumulation of phosphatidylethanol, indicating that the two phospholipids are indeed produced by the competing hydrolase and transferase activities of the same enzyme. beta,beta-Dimethylglutaric acid, utilized previously as a buffer in studies of rat brain PLD, inhibited enzyme activity at neutral pH but not at acidic pH. The properties of the neutral synaptic membrane PLD and its relationships with other in vitro, acid, and neutral PLD activities, as well as with the signal-dependent PLD detected in intact cells, are discussed.     

Purification and characterization of a mutant human platelet phospholipase A2 expressed in Escherichia coli. Cleavage of a fusion protein with cyanogen bromide.

Both methionine residues in phospholipase A2 (PLA2) from porcine pancreas have been replaced by leucines with retention of full enzymatic activity. The methionine-less mutant has been expressed as a Cro-LacZ fusion protein in Escherichia coli, from which a pro-PLA2 was liberated by chemical cleavage with CNBr. The general applicability of CNBr cleavage of proteins lacking methionine residue(s) was demonstrated by replacing the single Met8 in human platelet phospholipase A2 (HP-PLA2) by a leucine residue, and the introduction of a methionine at a position just preceding the HP-PLA2 sequence. This protein was expressed in E. coli as a 68-kDa Cro-LacZ fusion protein. CNBr cleavage liberated the HP-PLA2 fragment which was reoxidized in vitro. The [Met8----Leu]HP-PLA2 is monomeric in aqueous solutions, requires calcium ions in the millimolar range for enzymatic activity and has optimal activity around pH 8. p-Bromophenacyl bromide rapidly inactivates the enzyme with calcium ions having a protective effect. The highest specific activities, 2400 U/mg and 9300 U/mg, were found with pure micelles of 1,2-dioctanoyl-sn-glycero-3-phosphoglycol and with mixed micelles of taurodeoxycholate and 1,2-dioctanoyl-sn-glycero-3-phosphoglycol, respectively. In mixed micelles the activity on dioleoyl phospholipids decreases in the order phosphatidylglycerol greater than phosphatidylethanolamine much greater than phosphatidylcholine. The enzyme has low activity on monomeric 1,2-diheptanoyl-sn-glycero-3-phosphocholine as a substrate, but high activity on micelles with a distinct jump in activity at the critical micellar concentration. The binding of the HP-PLA2, porcine pancreatic PLA2 and PLA2 from Naja melanoleuca venom to lipid/water interfaces was determined with micellar solutions of the substrate analog n-hexadecylphosphocholine. The HP-PLA2 has a high apparent Kd (2 mM) compared to pancreatic (0.2 mM) and venom (0.03 mM) PLA2. In mixed micelles of taurodeoxycholate and 1,2-didodecanoyl-sn-glycero-3-phosphocholine, the competitive inhibition of HP-PLA2 by the R and S enantiomers of 2-tetradecanoylaminohexanol-1-phosphocholine, its phosphoglycol, and its phosphoethanolamine derivatives were tested. The S enantiomers are only weak inhibitors, whereas the R enantiomers are potent inhibitors. The inhibitory power depends on the nature of the polar head group and increases in the order phosphocholine much less than phosphoethanolamine less than phosphoglycol. The best inhibitor, (R)-2-tetradecanoylaminohexanol-1-phosphoglycol, binds 2200 times stronger than the substrate to the HP-PLA2 active site.     

Phospholipase D from savoy cabbage: purification and preliminary kinetic characterization

Phospholipase D has been purified 680-fold from an acetone powder of savoy cabbage in an overall yield of 30%. The purification involves solubilization of the acetone powder in a Ca2+-containing buffer and subsequent ammonium sulfate fractionation. Gel filtration on Sephadex G-200 and hydrophobic affinity chromatography using a gamma-aminopropane-agarose gel complete the purification. The two chromatographic steps were conducted in buffers containing 50% ethylene glycol, which was necessary in order to maintain stability of the enzyme. Purity was established on the basis of gel electrophoresis and ultracentrifugation. A preliminary kinetic characterization of the enzyme was carried out by using lecithins with short-chain fatty acids below the critical micelle concentration. A complex series of results were obtained which demonstrated the following. (1) The enzyme is quite sensitive to ionic strength, being inhibited at high ionic strength. (2) The pH optimum depends on the concentration of Ca2+ used in the assay. At 0.5 mM Ca2+ the pH optimum is 7.25, but it is 6.0 at 50 mM Ca2+. (3) The effect of substrate concentration at a given pH and ionic strength did not show simple hyperbolic kinetics but rather regions of parabolic and hyperbolic kinetics.     

Kinetic analysis of urea-inactivation of beta-galactosidase in the presence of galactose

The effect of galactose on the inactivation of purified beta-galactosidase from the black bean, Kestingiella geocarpa, in 5 M urea at 50 degrees C and at pH 4.5, was determined. Lineweaver-Burk plots of initial velocity data in the presence and absence of urea and galactose were used to determine the relevant K(m) and V(max) values, with p-nitrophenyl beta-D-galactopyranoside (PNPG) as substrate, S. The inactivation data were analysed using the Tsou equation and plots. Plots of ln([P](infinity) - [P](t) ) against time in the presence of urea yielded the inactivation rate constant, A. Plots of A vs [S] at different galactose concentrations were zero order showing that A was independent of [S]. Plots of [P](infinity) vs [S] were used to determine the mode of inhibition of the enzyme by galactose, and slopes and intercepts of the 1/[P](infinity) vs. 1/[S] yielded k(+0) and k '(+0), the microscopic rate constants for the free enzyme and the enzyme-substrate complex, respectively. Plots of k(+0) and k '(+0) vs. galactose concentrations showed that galactose protected the free enzyme and not the enzyme-substrate complex against urea inactivation via a noncompetitive mechanism at low galactose concentrations and a competitive pattern of inhibition at high galactose concentrations. The implication of the different modes of inhibition in protecting the free enzyme was discussed.     

A new plot for the kinetic analysis of dead-end enzyme inhibitors

A new procedure to characterize reversible dead-end inhibitors is presented. Preliminary identification of the inhibitor type is made by plotting vo/vi against the inhibitor concentration at different substrate concentrations. The inhibition constants for competitive, uncompetitive and mixed dead-end inhibitors are determined by secondary plots of l/(slope) vs [S], l/(slope) vs l/[S] and (slope)(Ks + [S] vs [S] respectively. These secondary plots render straight lines only for their corresponding type of inhibitor. For noncompetitive inhibitors all the secondary plots used yield straight lines. Therefore, the application of this plotting procedure leads to unambiguous diagnosis of the inhibitor type. An important feature of the procedure presented here is that the variable used (vo/vi) is independent on Vmax values. Therefore, experimental values obtained from enzyme preparations showing significant differences in their specific activities -i.e. enzyme coming from different purification steps- can be used.     

Molecular mechanism for the inhibition of acetylcholinesterase enzyme by organophosphorothionates

The different mechanisms, whereby EPN and malathion inhibit the action of cholinesterase on acetylcholine, are described. Partially purified brain enzyme was used for the kinetic studies. The approach of the theory of Krupka and Laidler was followed. The ratio of [S]I opt/[S]opt = 1 + Ki [I] to the first power was found with malathion but to the square root of (1 + Ki [I]) 1/2 with EPN. The intercept on the slope axis of plots of slopes of (1/V not equal to [I]) against the reciprocal of substrate concentrations showed a non-zero value in the case of EPN and a zero value in the case of malathion. Accordingly, and based on the above theory, it seems that malathion acts as a competitive inhibitor of cholinesterase while EPN seems to be a mixed type inhibitor.     

Functional expression in insect cells, one-step purification and characterization of a recombinant phospholipase D from cowpea (Vigna unguiculata L. Walp)

Phospholipase D (PLD) is an important enzyme involved in signal transduction, vesicle trafficking and membrane metabolism. In this study, large amounts of a recombinant plant PLD alpha were secreted into the culture medium of baculovirus-infected insect cells and purified to homogeneity in the form of a fully active enzyme. The transient production of recombinant PLD alpha yielded a protein (rPLD alpha a, 88 kDa) together with a shorter form (rPLD alpha b, 87 kDa), which accumulated in the medium. N-Terminal amino acid sequencing of the rPLD alpha a and rPLD alpha b showed that rPLD alpha b resulted from proteolytic cleavage at Gly8-Ile9. Immunoblotting showed that both rPLD alpha a and rPLD alpha b are recognized by a polyclonal antibody previously raised against native soybean PLD alpha. One-step calcium-dependent octyl-Sepharose chromatography was used to obtain the two highly purified forms of rPLD alpha, as attested by gel electrophoresis, N-terminal amino acid sequence and mass spectrometry. The N-terminal region of PLD alpha is homologous with the C2 domains which are present in a number of enzymes known to be involved in signal transduction and/or phospholipid metabolism. The truncated rPLD alpha b lacks the first acidic amino acid in its N-terminus, which is probably involved in the calcium binding site. The rPLD alpha b was thus easily eluted from the octyl-Sepharose column by decreasing the calcium concentration of the buffer from 50 to 30 mM, whereas, the rPLD alpha a was eluted after chelating calcium ions with EDTA. The purified rPLD alpha yield reached a level of 10 mg per liter of serum-free culture medium. The availability of baculovirus-derived rPLD alpha constitutes a valuable source of enzyme for future crystallographic studies to determine its three-dimensional structure.     

A protein kinase C inhibitor, staurosporine, activates phospholipase D via a pertussis toxin-sensitive GTP-binding protein in rabbit peritoneal neutrophils.

In rabbit peritoneal neutrophils prelabeled with [3H] lyso platelet-activating factor, a protein kinase C inhibitor, staurosporine (> 1 microM), increased [3H]phosphatidylethanol ([3H]PEt) level in the presence of ethanol in a concentration- and time-dependent manner, providing evidence for staurosporine activation of phospholipase D (PLD). The staurosporine activation of the enzyme absolutely required both extracellular calcium and cytochalasin B, and was almost completely inhibited by pretreatment of the cells with pertussis toxin (IAP). In a reconstituted system where the purified Gi1 had been incorporated into phospholipid vesicles, staurosporine activated GTPase activity of Gi1 in a concentration-dependent fashion, with a maximal 4-5-fold effect. ADP-ribosylation by IAP of Gi1 in vesicles significantly suppressed the staurosporine activation. As with the GTPase activity of Gi1, GTPase activities of other purified IAP-sensitive G proteins, such as Gi2 and G(o), were significantly stimulated by staurosporine, but the cholera toxin substrate Gs was appreciably less sensitive to the staurosporine stimulation. The staurosporine activation of GTPase was also observed in rabbit neutrophil membranes from control cells, but not in membranes from IAP-treated neutrophils. From these results, we conclude that the staurosporine activation of PLD in rabbit neutrophils is attributed to the direct activation of an IAP-sensitive G protein in a similar manner to receptors occupied by agonists. By contrast, staurosporine failed to activate phosphoinositide-specific phospholipase C (PI-PLC) under the conditions in which it activated PLD, indicating that there exists a PLD activation pathway independent of PI-PLC. Furthermore, it was found that N-acetyl-beta-glucosaminidase release from the granules of intact neutrophils was evoked by staurosporine to almost the same extent as by fMLP (100 nM), but O2- generation was not affected. These results suggest a possibility that PLD pathway plays an important role in enzyme release, but is not sufficient for O2- generation, in rabbit peritoneal neutrophils.     

Steady-state kinetic analysis for the reaction of ammonium and alkylammonium ions with methylamine dehydrogenase from bacterium W3A1

The steady-state kinetic mechanism for the reaction of n-alkylamines and phenazine ethosulfate (PES) or phenazine methosulfate (PMS) with methylamine dehydrogenase from bacterium W3A1 is found to be of the ping-pong type. This conclusion is based on the observations that 1/v versus 1/[methylamine] or 1/[butylamine] plots, at various constant concentrations of an oxidizing substrate, and 1/v versus 1/[PES] or 1/[PMS] plots, at various constant concentrations of a reducing substrate, are parallel. Additionally, the values of kcat/Km for four n-alkylamines are identical when PES is the oxidizing substrate, as were the kcat/Km values for four reoxidizing substrates when methylamine was the reducing substrate. Last, analysis of steady-state kinetic data obtained when methylamine and propylamine are presented to the enzyme simultaneously and PES and PMS are used simultaneously also supports the involvement of a ping-pong mechanism. The enzymic reaction with either methylamine or PES is dependent on the ionic strength, and the data indicate that each interacts with an anionic site on methylamine dehydrogenase. The presence of ammonium ion at low concentration activates the enzyme, but at high concentration this ion is a competitive inhibitor in the reaction involving methylamine and the enzyme. A complete steady-state mechanism describing these ammonia effects is presented and is discussed in light of the nature of the pyrroloquinoline quinone cofactor covalently bound to the enzyme.     

Purification and substrate specificity of Staphylococcus hyicus lipase

The Staphylococcus hyicus lipase gene has been cloned and expressed in Staphylococcus carnosus. From the latter organism the enzyme was secreted into the medium as a protein with an apparent molecular mass of 86 kDa. This protein was purified, and the amino-terminal sequence showed that the primary gene product was indeed cleaved at the proposed signal peptide cleavage site. The protein was purified from large-scale preparations after tryptic digestion. This limited proteolysis reduced the molecular mass to 46 kDa and increased the specific activity about 3-fold. Although the enzyme had a low specific activity in the absence of divalent cations, the activity increased about 40-fold in the presence of Sr2+ or Ca2+ ions. The purified lipase has a broad substrate specificity. The acyl chains were removed from the primary and secondary positions of natural neutral glycerides and from a variety of synthetic glyceride analogues. Thus triglycerides were fully hydrolyzed to free fatty acid and glycerol. The enzyme hydrolyzed naturally occurring phosphatidylcholines, their synthetic short-chain analogues, and lysophospholipids to free fatty acids and water-soluble products. The enzyme had a 2-fold higher activity on micelles of short-chain D-lecithins than on micelles composed of the L-isomers. Thus the enzyme from S. hyicus has lipase activity and also high phospholipase A and lysophospholipase activity.     

Kinetic Analysis in Mixed Micelles of Partially Purified Rat Brain Phospholipase D Activity and its Activation by Phosphatidylinositol 4,5-Bisphosphate

A partially purified rat brain membrane phospholipase D (PLD) activity was characterized in a mixed micellar system consisting of l-palmitoyl-2-[6-N-(7-nitrobenzo-2-oxa-1,3-diazol-4-yl)-amino]caproyl-phosphatidylcholine (NBD-PC) and Triton X-100, under conditions where Triton X-100 has a surface dilution effect on PLD activity and the catalytic rate is dependent on the surface concentration (expressed in terms of molar ratio) of NBD-PC. PLD activity was specifically activated by phosphatidylinositol 4,5-bisphosphate (PIP₂), and the curve of activation versus PIP₂ molar ratio fitted a Michaelis-Menten equation with a K_act value between molar ratios of 0.001–0.002. Maximal activation was observed at a PIP₂ molar ratio of 0.01. Similar values were obtained when activities of partially purified PLD as well as membrane-bound PLD were determined towards pure NBD-PC micelles. In the mixed micellar system PIP₂ was shown to elevate by 6–22 fold the specificity constant of PLD towards NBD-PC (K_A, which is proportional to V_max/K_m). Kinetic analysis of PLD trans-phosphatidylation activity towards ethanol, 1-propanol and 1-butanol revealed a Michaelis-Menten type dependence on alcohol concentration up to 1000, 200 and 80 mM, respectively. While V_max values were similar towards all three alcohols, enzyme affinity increased as the alcohol was longer, and K_m values for ethanol, 1-propanol and 1-butanol were 291, 75 and 16 mM (respectively). PLD specificity constants (K_A) towards ethanol, 1-propanol and 1-butanol were shown to be respectively 260, 940 and 5,920 times higher than to water, the competing substrate. 1-Propanol and 1-butanol inhibited PLD activity above 400 and 100 mM, respectively. The present results indicate that partially purified PLD obeys surface dilution kinetics with regard to its phospholipid substrate PC and its cofactor PIP₂, and that in the presence of alcohols, its transphosphatidylation activity may be analyzed as a competitive reaction to the hydrolysis reaction.     

Renal angiotensin I-converting enzyme as a mixture of sialo- and asialo-enzyme, and a rapid purification method.

Angiotensin I-converting enzyme [EC 3.4.15.1] was rapidly and highly purified from a particulate fraction of hog kidney cortex with 13% yield. The procedure, which was rapid, included fractionation on DEAE-cellulose and calcium phosphate gel, chromatographies on DEAE-Sephadex A-50 and hydroxylapatite columns, and gel filtration on a Sephadex G-200 column. The purified enzyme preparation gave two protein bands on standard disc gel electrophoresis, but showed a single protein component on the gel after treatment with neuraminidase [EC 3.2.1.18]. The data strongly suggest that the purified enzyme preparation was a mixture of sialo- and asialo-enzyme. Sialic acid residues apparently do not contribute to the catalytic activity of the enzyme. The enzyme was activated more by chloride ions than by other halide ions tested, using Bz-Gly-Gly-Gly as a substrate. The dissociation constant for chloride ions was determined to be 2.2 mM. Chloride did not protect the enzyme against heat or low pH. The enzyme was resistant to inactivation by trypsin [EC 3.4.21.4] and chymotrypsin [EC 3.4.21.1].     

Asymmetric short-chain phosphatidylcholines: defining chain binding constraints in phospholipases

Several short-chain asymmetric lecithins with a total of 14 carbons in the acyl chains (ranging from 1-lauroyl-2-acetylphosphatidylcholine to 1-hexanoyl-2-octanoylphosphatidylcholine) have been synthesized and characterized. The specific activities of phospholipase A2 from cobra venom, phospholipase A2 from porcine pancreas, and phospholipase C from Bacillus cereus toward these lecithins as micelles have been determined. The results of these kinetic studies allow the definition of hydrophobic binding requirements in the active sites of these water-soluble phospholipases. For phospholipase C, with the exception of monomyristoylphosphatidylcholine, each of the asymmetric short-chain lecithins exhibits high activity, comparable to the 14-carbon symmetric short-chain species, diheptanoylphosphatidylcholine. Therefore, for phospholipase C, in addition to the acyl linkages, only a certain degree of hydrophobicity in the fatty acyl chains is requisite for substrate binding and appreciable hydrolysis; there is no chain specificity. The activity of phospholipase A2 from cobra venom toward the same asymmetric lecithins is quite different. As the sn-2 chain lengthens, activity is increased to a maximum for diheptanoyl-PC. Further increase in the number of carbons in the sn-2 chain has no effect on hydrolysis rates. For this enzyme, seven carbons in the sn-2 chain are necessary for optimal activity. In contrast, porcine pancreatic phospholipase A2 activity shows very little dependence on sn-2 chain length.     

Regio- and stereospecificity of homogeneous 3 alpha-hydroxysteroid-dihydrodiol dehydrogenase for trans-dihydrodiol metabolites of polycyclic aromatic hydrocarbons

The homogeneous 3 alpha-hydroxysteroid dehydrogenase (EC 1.1.1.50) of rat liver cytosol is indistinguishable from dihydrodiol dehydrogenase (trans-1,2-dihydrobenzene-1,2-diol dehydrogenase EC 1.3.1.20), Penning, T. M., Mukharji, I., Barrows, S., and Talalay, P. (1984) Biochem. J. 222, 601-611). Examination of the substrate specificity of the purified dehydrogenase for trans-dihydrodiol metabolites of polycyclic aromatic hydrocarbons indicates that the enzyme will catalyze the NAD(P)-dependent oxidation of trans-dihydrodiols of benzene, naphthalene, phenanthrene, chrysene, 5-methylchrysene, and benzo[a]pyrene under physiological conditions. Comparison of the utilization ratios Vmax/Km indicates that benzenedihydrodiol and the trans-1,2- and trans-7,8-dihydrodiols of 5-methylchrysene were most efficiently oxidized by the purified dehydrogenase, followed by the trans-7,8-dihydrodiol of benzo[a]pyrene and the trans-1,2-dihydrodiols of phenanthrene, chrysene, and naphthalene. The purified enzyme appears to display rigid regio-selectivity, since it will readily oxidize non-K-region trans-dihydrodiols but will not oxidize the K-region trans-dihydrodiols of phenanthrene and benzo[a]pyrene. The stereochemical course of enzymatic dehydrogenation was investigated by circular dichroism spectrometry. For the trans-1,2-dihydrodiols of benzene, naphthalene, phenanthrene, chrysene, and 5-methylchrysene, the dehydrogenase preferentially oxidized the (+)-[S,S]-isomer. Apparent inversion of this stereochemical preference occurred with the trans-7,8-dihydrodiol of 5-methylchrysene, as the (-)-enantiomer was preferentially oxidized. No change in the sign of the Cotton Effect was observed following oxidation of the racemic trans-7,8-dihydrodiol of benzo[a]pyrene, suggesting that both stereoisomers of this compound were substrates. Large-scale incubation of the [3H]-(+/-)-trans-7,8-dihydrodiol of benzo[a]pyrene with the purified dehydrogenase resulted in greater than 90% utilization of this potent proximate carcinogen, suggesting that the enzyme utilizes both the (-)-[R,R] and the (+)-[S,S]-stereoisomers, which confirms the circular dichroism result. These data show that dihydrodiol dehydrogenase displays the appropriate regio- and stereospecificity to catalyze the oxidation of both the major and minor non-K-region trans-dihydrodiols that arise from the microsomal metabolism of benzo[a]pyrene in vivo.     

A fluorescence assay for alpha-1,2-mannosidases involved in glycoprotein processing reactions

A highly specific, sensitive, and convenient fluorescence assay for alpha-1,2-mannosidases involved in glycoprotein processing reactions is described. The assay utilizes a coupled enzyme system to determine the amount of free mannose liberated from the disaccharide O-methyl-2-O-alpha-D-mannopyranosyl-alpha-D-mannopyranoside by the alpha-1,2-mannosidase. The assay was used to determine the substrate specificity of a calcium ion-activated alpha-1,2-mannosidase purified from rabbit liver microsomes. The microsomal mannosidase was specific for hydrolysis of the alpha-1,2 linkage. The mannosyl linkages in alpha-1,3- and alpha-1,6-linked methyl-disaccharides, in methyl-alpha-D-mannopyranoside, and in yeast mannan were hydrolyzed at rates of 2% or less than that noted with the alpha-1,2-linked disaccharide. Mannosidase activity was linear with time and was proportional to enzyme concentration. The Km for the alpha-1,2-linked methyl-disaccharide is 0.5 mM.     

Noncooperative vs. cooperative reactivation of D-beta-hydroxybutyrate dehydrogenase: multiple equilibria for lecithin binding are determined by the physical state (soluble vs. bilayer) and composition of the phospholipids

D-beta-Hydroxybutyrate dehydrogenase (BDH) is a lecithin-requiring mitochondrial enzyme that catalyzes the interconversion of beta-hydroxybutyrate and acetoacetate. The purified soluble enzyme devoid of lipid (i.e., the apodehydrogenase) can be reactivated with soluble lecithin or by insertion into phospholipid vesicles containing lecithin. Lipid activation curves have a sigmoidal shape, and two models have been proposed to explain them. We have previously reported that the kinetics of reactivation with short-chain lecithins in the soluble state is consistent with a model in which the enzyme enzyme contains two identical, noninteracting lecithin binding sites, both of which must be occupied to activate the enzyme [noncooperative mechanism; Cortese, J.D., Vidal, J.C., Churchill, P., McIntyre, J.O., & Fleischer, S. (1982) Biochemistry 21, 3899-3908]. More recently a kinetic model involving cooperative interactions between lecithin binding sites was proposed for the reactivation of the membrane-bound enzyme [Sandermann, H., Jr., McIntyre, J.O., & Fleischer, S. (1986) J. Biol. Chem. 261, 6201-6208]. This study reinvestigates the basis for the different conclusions in these two studies. The previous study with soluble lecithins was limited to about 34% of maximal activation compared with mitochondrial phospholipid, due to inactivation of the enzyme at the critical micellar concentration. We could now extend this study to 91% activation by increasing the ethanol concentration. This experimental evidence confirms that the soluble system follows a noncooperative equation. We provide a new kinetic approach to test the cooperative model. A velocity equation is derived for a Hill-type cooperative ligand binding system interacting with a mixture of ligands. This equation predicts a proportionality between an overall weighted cooperative dissociation constant [Kcoop(w)] and a dissociation constant for a single lecithin (PC) species from interacting sites (KPC), regulated by the PC molar fraction (XPC): 1/Kcoop(w) = XPC/KPC. The equation was applied to the data of Sandermann et al. [Sandermann, H., Jr., McIntyre, J.O., & Fleischer, S. (1986) J. Biol. Chem. 261, 6201-6208] as well as to newly obtained data. The results obtained over a wide range of PC molar fractions and different mixtures of bilayer phospholipids fit this equation, confirming the cooperative behavior. We conclude that BDH has a different mode of reactivation depending on the nature of the lipid environment. With soluble lecithin, the activation is noncooperative, whereas in the bilayer, mixtures of phospholipids give cooperative behavior that fits a Hill equation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Kinetic analysis of Arabidopsis phospholipase Ddelta. Substrate preference and mechanism of activation by Ca2+ and phosphatidylinositol 4,5-biphosphate

Phospholipase D (PLD) is a major plant phospholipase family involved in many cellular processes such as signal transduction, membrane remodeling, and lipid degradation. Five classes of PLDs have been identified in Arabidopsis thaliana, and Ca(2+) and polyphosphoinositides have been suggested as key regulators for these enzymes. To investigate the catalysis and regulation mechanism of individual PLDs, surface-dilution kinetics studies were carried out on the newly identified PLDdelta from Arabidopsis. PLDdelta activity was dependent on both bulk concentration and surface concentration of substrate phospholipids in the Triton X-100/phospholipid mixed micelles. V(max), K(s)(A), and K(m)(B) values for PLDdelta toward phosphatidylcholine or phosphatidylethanolamine were determined; phosphatidylethanolamine was the preferred substrate. PLDdelta activity was stimulated greatly by phosphatidylinositol 4,5-bisphosphate (PIP(2)). Maximal activation was observed at a PIP(2) molar ratio around 0.01. Kinetic analysis indicates that PIP(2) activates PLD by promoting substrate binding to the enzyme, without altering the bulk binding of the enzyme to the micelle surface. Ca(2+) is required for PLDdelta activity, and it significantly decreased the interfacial Michaelis constant K(m)(B). This indicates that Ca(2+) activates PLD by promoting the binding of phospholipid substrate to the catalytic site of the enzyme.