High-performance liquid chromatographic assay for farnesyl-protein transferase activity with dabsylated peptide

An HPLC assay for farnesyl-protein transferase activity using a dabsylated peptide is described. The substrates used were a synthetic dabsylated nonapeptide, N-dabsyl-l-serinyl-l-methioninyl-l-glycinyl-l-leucinyl-l-prolinyl-l-cysteinyl-l-valinyl-l-valinyl-l-methionine, corresponding to the C-terminal peptide seqeunce of human N-Ras p21 without the N-terminal serine, and farnesyl disphosphate. The product was separated from the substrates on a reversed-phase C₁₈ column, using gradient elution with acetonitrile (0.05% trifluoroacetic acid)-water (0.1% trifluoroacetic acid) and was detected at 436 nm. The addition of the farnesyl group to the peptide was confirmed by MS and NMR. Enzymatic reaction was ascertained from the dependences on time, on the protein of the enzyme source and on the substrates. The reaction was specifically inhibited by l-cysteinyl-l-valinyl-l-valinyl-l-methionine, the tetrapeptide corresponding to the “CAAX” motif. The limit of detection was 2 pmol per 100-μl reaction mixture. The farnesyl-protein transferase activity can quantitatively be measured up to 200 μg cytosolic protein in human liver. This method provides a convenient and quantitative assay for crude materials, such as tissue homogenate from clinical samples, without the use of radioactive probes and large amounts of Ras protein.     

Characterization of the activity of purified recombinant human 5-lipoxygenase in the absence and presence of leukocyte factors.

Purified recombinant human 5-lipoxygenase was used to investigate the catalytic properties of the protein in the presence and absence of leukocyte stimulatory factors. Recombinant human 5-lipoxygenase was purified to apparent homogeneity (95-99%) from a high expression baculovirus system by chromatography on ATP-agarose with a yield of 0.6 mg of protein per 100 ml of culture (2 x 10(8) cells) and a specific activity of 3-6 mumol of 5-hydroperoxyeicosatetraenoic acid (5-HPETE) per mg of protein in the presence of ATP, Ca2+, and phosphatidylcholine as the only factors. In the absence of leukocyte factors, the reaction catalyzed by the purified recombinant enzyme showed a half-time of maximal 5-HPETE formation of 0.5-0.7 min and was sensitive to the selective 5-lipoxygenase inhibitors BW755C (IC50 = 13 microM) and L-656,224 (IC50 = 0.8 microM). The reaction products of arachidonic acid oxidation were 5-HPETE and 6-trans- and 12-epi-6-trans-leukotriene B4, the nonenzymatic hydrolysis products of leukotriene A4 (LTA4), indicating that the purified protein expressed both the 5-oxygenase and leukotriene A4 synthase activities (ratio 6:1). The microsomal fraction and the 60-90% ammonium sulfate precipitate fraction from sonicated human leukocytes did not increase product formation by the isolated enzyme when assayed in the presence of ATP, Ca2+, and phosphatidylcholine. These factors were found to stabilize 5-lipoxygenase during preincubation of the enzyme at 37 degrees C with the assay mixture but they failed to stimulate enzymatic activity when added at the end of the preincubation period. The results demonstrate that human 5-lipoxygenase can be isolated in a catalytically active form and that protein factors from leukocytes protect against enzyme inactivation but are not essential for enzyme activity.     

NAD(P)H-dependent reduction of 12-ketoeicosatetraenoic acid to 12(R)- and 12(S)-hydroxyeicosatetraenoic acid by rat liver microsomes

The possibility that 12-keto-5,8,10,14 eicosatetraenoic acid (12-KETE) could be used as substrate by reductase(s) to generate 12-hydroxyeicosatetraenoic acid (12-HETE) was investigated using rat liver microsomes as a source of enzyme activity. Microsomes catalyzed the time-dependent reduction of 12-KETE to 12-HETE in a reaction that required NAD(P)H. The maximal specific activity of 12-HETE formation was 1.7 nmol/min/mg of protein in the presence of NADH. The reaction could not be detected in the absence of cofactor or by using heat inactivated microsomes. The identity of the 12-HETE product was established by U.V. spectroscopy and co-elution with 12-HETE in two different systems of RP-HPLC. Resolution of the methyl esters of reaction products by chromatography on chiral columns also indicated that the reduction of 12-KETE with either NADPH or NADH generated a mixture of 12(S)- and 12(R)-HETE in a ratio of about 2:1. The results demonstrate the presence of a 12-KETE reductase activity in rat liver microsomes which can form both the R and S isomers of 12-HETE.     

In situ assay for 5-aminolevulinate dehydratase and application to the study of a catabolite repression-resistant Saccharomyces cerevisiae mutant.

To facilitate the study of the effects of carbon catabolite repression and mutations on 5-aminolevulinate dehydratase (EC 4.2.1.24) from Saccharomyces cerevisiae, a sensitive in situ assay was developed, using cells permeabilized by five cycles of freezing and thawing. Enzymatic activity was measured by colorimetric determination of porphobilinogen with a modified Ehrlich reagent. For normal strains, porphobilinogen production was linear for 15 min, and the reaction rate was directly proportional to the permeabilized cell concentration up to 20 mg (dry weight) per ml. The reaction exhibited Michaelis-Menten-type kinetics, and an apparent Km of 2.6 mM was obtained for 5-aminolevulinic acid. This value is only slightly higher than the value of 1.8 mM obtained for the enzyme assayed in cell extracts. The in situ assay was used to assess catabolite repression-dependent changes in 5-aminolevulinate dehydratase during batch culture on glucose medium. In normal S. cerevisiae cells, the enzyme is strongly repressed as long as glucose is present in the medium. In contrast, a strain bearing the hex2-3 mutation exhibits derepressed levels of enzyme activity during growth on glucose. Synthesis of cytochromes by this strain is also resistant to catabolite repression. Similar studies employing a strain containing the glc1 mutation, which enhances porphyrin accumulation, did not reveal any significant phenotypic change in catabolite regulation of 5-aminolevulinate dehydratase.     

Identification of enzyme activity that conjugates indole-3-acetic acid to aspartate in immature seeds of pea (Pisum sativum)

This study describes the first identification of plant enzyme activity catalyzing the conjugation of indole-3-acetic acid to amino acids. Enzymatic synthesis of indole-3-acetylaspartate (IAA-Asp) by a crude enzyme preparation from immature seeds of pea (Pisum sativum) was observed. The reaction yielded a product with the same Rf as IAA-Asp standard after thin layer chromatography. The identity of IAA-Asp was verified by HPLC analysis. IAA-Asp formation was dependent on ATP and Mg2+, and was linear during a 60 min period. The enzyme preparation obtained after poly(ethylene glycol) 6000 fractionation showed optimum activity at pH 8.0, and the temperature optimum for IAA-Asp synthesis was 30 degrees C.     

Characteristic properties of retinal oxidase (retinoic acid synthase) from rabbit hepatocytes

Retinal oxidase (retinoic acid synthase) (EC 1.2.3.11) was purified electrophoretically, as a single protein band, from rabbit liver cytosol. The characteristic properties, enzymatic reaction mechanism, substrate specificity and kinetic parameters for retinals and molecular oxygen of the retinal oxidase were investigated. The K_m values for all-trans-retinal of the retinal of the retinal oxidase was the lowest than those for the other retinal derivatives. The retinal oxidase is a metalloflavoenzyme containing 2 FADs as the coenzyme, and 8 irons, 2 molybdenums,2 disulfide bonds and 8 inorganic sulfurs. Its relative molecular mass was determined to be 270 kDa by gel filtration HPLC on a TSKgel G3000sw_XL column. Its minimum molecular mass was estimated to be 135 kDa by SDS-PAGE. The optical spectrum of the retinal oxidase showed absorption peaks at 275, 340 and 450 nm, and shoulders at 420 and 473 nm, in the oxidized form. The molecular extinction coefficients of the oxidase at selected wavelengths were determined. Circular dichroism spectra of the retinal oxidase were measured in the ultraviolet and visible regions. These spectra showed positive absorption in the visible region. The amino-acid composition was determined. The activity of the oxidase was not affected by any cofactors, such as NADP⁺, NAD⁺, NADPH and NADH, and it did not occur under anaerobic conditions. The oxidase was not inhibited by BOF-4272, a potent inhibitor of xanthine dehydrogenase, or rat anti-xanthine dehydrogenase IgG. Experiments on retinoic acid formation under ¹⁸O₂ or H₂¹⁸O demonstrated that the oxygen of waer was incorporated into retinoic acid by the retinal oxidase, but not molecular oxygen.     

Biosynthesis of retinoic acid by intestinal enzymes of the rat

The incubation of beta-carotene-(14)C with the soluble fraction of the intestinal mucosa resulted in the formation of small amounts of acidic material. The addition of NAD or NADH to the soluble fraction caused a tenfold increase in this material. Incubation of retinal-15-(14)C with the soluble fraction of the intestinal mucosa plus NAD or NADH resulted in the conversion of 80-90% of the retinal to acidic material, which has been shown to contain retinoic acid. In vivo studies on the formation of retinoic acid in the intestinal mucosa after the administration of beta-carotene-(14)C revealed that an appreciable amount of beta-carotene was converted to acidic compounds. When retinal-15-(14)C was administered, portal blood contained 30-40% of the absorbed radioactivity. 24% of this radioactivity was found in acidic material, which has been shown to contain retinoic acid. It is suggested that enzymes in rat intestine cleave beta-carotene to retinal and oxidize the latter to retinoic acid, which is then transported via the portal circulation to the liver.     

A sensitive, nonradiometric assay for dihydroorotic acid dehydrogenase using anion-exchange high-performance liquid chromatography

A new method to assay the mitochondrial pyrimidine de novo enzyme, dihydroorotate (DHO) dehydrogenase, which catalyzes the dehydrogenation of DHO, with orotic acid as the product was developed. The assay was optimized using a rat liver mitochondrial preparation. Orotic acid was quantified with high-performance liquid chromatography using an anion-exchange column (Partisil-SAX) with uv detection at 280 nm. Isocratic elution with low phosphate buffer at pH 4.0 was used. The detection limit was 20 pmol per injection, which is comparable to previously described radiometric assays. The HPLC assay was compared with a spectrophotometric assay measuring orotic acid formation in a deproteinized reaction mixture. Absorbance was measured at the optimal wavelength for orotic acid, 278.5 nm. This assay is less sensitive and less specific than the HPLC assay, which can also detect UMP which might be formed from orotic acid in whole homogenates. With both assays kinetic parameters of the enzyme were determined. In the high concentration range (80-1000 microM) both Km and Vmax values were comparable. With the HPLC assay the concentration range was extended down to 12 microM and initial rates could be determined. The apparent Km was about 12 microM. The HPLC assay is also suitable for use in the study of inhibition of DHO dehydrogenase.     

Enzymatic oxidation of all-trans retinal to retinoic acid in rat tissues

The 100,000 x g supernatant (cytosolic) fraction of rat tissue homogenates catalyzes the oxidation of all-trans retinal to retinoic acid. Kidney, testis, and lung were the most active of the tissues examined. The presence of enzyme activity in liver and intestine could be detected only when a substrate concentration beyond the saturation point for retinal reductase was used. Spleen, brain, and plasma had no activity. Boiled supernatants did not catalyze the reaction. The enzymatic product was chemically and physically identified as retinoic acid. The cytosol of kidney tissue also catalyzed the conversion of retinol to retinoic acid. These data indicate that kidney tissue has the highest retinal oxidase activity and suggest that it may play a major role in the oxidative metabolism of retinol in the body.     

Assay for the enzymatic conversion of indoleacetic acid to 3-methylindole in a ruminal Lactobacillus species.

An assay to measure the rate of enzymatic formation of 3-methylindole (3MI) from indoleacetic acid (IAA) in Lactobacillus sp. strain 11201 was developed. The reaction mixture contained 50 micrograms of microbial protein per ml (range, 25 to 100 mg/ml), essential low-molecular-weight reaction ingredients, and radiolabeled IAA as substrate (range, 0 to 2 mM IAA). The reaction was anaerobic for 25 min at 39 degrees C. The apparent Michaelis-Menten constants were: Km, 0.14 mM IAA; and Vmax, 64 nmol 3MI.mg-1.min-1. The inhibitors avidin, aminopterin, and EDTA had no effect on the 3MI-forming enzyme. Dithionite stimulated the 3MI-forming enzyme. The product of the reaction, 3MI, acted as a noncompetitive inhibitor of the enzyme. Enzyme activity was associated with the cell wall fraction after sonication; treatment with the French press; or treatment with detergents, proteolytic enzymes, and EDTA.     

Assay for the enzymatic conversion of indoleacetic acid to 3-methylindole in a ruminal Lactobacillus species

An assay to measure the rate of enzymatic formation of 3-methylindole (3MI) from indoleacetic acid (IAA) in Lactobacillus sp. strain 11201 was developed. The reaction mixture contained 50 micrograms of microbial protein per ml (range, 25 to 100 mg/ml), essential low-molecular-weight reaction ingredients, and radiolabeled IAA as substrate (range, 0 to 2 mM IAA). The reaction was anaerobic for 25 min at 39 degrees C. The apparent Michaelis-Menten constants were: Km, 0.14 mM IAA; and Vmax, 64 nmol 3MI.mg-1.min-1. The inhibitors avidin, aminopterin, and EDTA had no effect on the 3MI-forming enzyme. Dithionite stimulated the 3MI-forming enzyme. The product of the reaction, 3MI, acted as a noncompetitive inhibitor of the enzyme. Enzyme activity was associated with the cell wall fraction after sonication; treatment with the French press; or treatment with detergents, proteolytic enzymes, and EDTA.     

Biosynthesis of all-trans-retinoic acid from retinal. Recognition of retinal bound to cellular retinol binding protein (type I) as substrate by a purified cytosolic dehydrogenase.

An NAD-dependent rat liver cytosolic dehydrogenase accepted as substrate retinal generated in situ by microsomes from retinol bound to excess CRBP (cellular retinol binding protein, type I). This activity, which was not retained by anion-exchange chromatography at pH 9.15, was designated P1. P1 activity increased 2.5-fold, with no statistically significant change in its K or Hill coefficient, in liver cytosol from rats fed a retinoid-deficient diet. Orally dosed retinoic acid partially suppressed the increase. Activities chromatographically similar to hepatic P1 were observed in cytosols from rat kidney and testes. P1, purified from rat liver cytosol, had a pI of approximately 8.3, migrated as a tetramer (214 kDa) on a Sephadex G-200 column, and had a subunit molecular mass of 55 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. With free retinal it catalyzed a maximum rate of retinoic acid synthesis of 265 nmol/min/mg of protein and exhibited allosteric kinetics with a K of 0.76 +/- 0.35 microM and a Hill coefficient of 1.5 +/- 0.13 (mean +/- S.D., n = 4). Substrate inhibition was noted with retinal concentrations greater than 6 microM. The purified enzyme not only recognized retinal generated by microsomes as substrate, but also recognized retinal bound to CRBP. The rates of retinoic acid synthesis from CRBP-retinal, with a series of increasing apoCRBP concentrations, exceeded the rates that would be supported by the free retinal present. The CRBP-retinal complex exhibited allosteric kinetics (K, 0.13 microM; Hill coefficient, 1.75; averages of duplicates) in the presence of excess apoCRBP (the ratio total CRBP/total retinal at each concentration of retinal was 2). This enzyme is likely to play a significant role in retinoic acid synthesis in vivo, because it participates in the synthesis of retinoic acid from a physiologically occurring form of retinol (holoCRBP), reflects retinoid status, and is distributed in extrahepatic tissues in addition to liver. These results also suggest a novel role for CRBP in retinoid metabolism, facilitating the conversion of retinal into retinoic acid.     

Retinol metabolism in LLC-PK1 Cells. Characterization of retinoic acid synthesis by an established mammalian cell line

Specific assays, based on gas chromatography-mass spectrometry and high-performance liquid chromatography, were used to quantify the conversion of retinol and retinal into retinoic acid by the pig kidney cell line LLC-PK1. Retinoic acid synthesis was linear for 2-4 h as well as with graded amounts of either substrate to at least 50 microM. Retinoic acid concentrations increased through 6-8 h, but decreased thereafter because of substrate depletion (t1/2 of retinol = 13 h) and product metabolism (1/2 = 2.3 h). Retinoic acid metabolism was accelerated by treating cells with 100 nM retinoic acid for 10 h (t1/2 = 1.7 h) and was inhibited by the antimycotic imidazole ketoconazole. Feedback inhibition was not indicated since retinoic acid up to 100 nM did not inhibit its own synthesis. Retinol dehydrogenation was rate-limiting. The reduction and dehydrogenation of retinal were 4-8-fold and 30-60-fold faster, respectively. Greater than 95% of retinol was converted into metabolites other than retinoic acid, whereas the major metabolite of retinal was retinoic acid. The synthetic retinoid 13-cis-N-ethylretinamide inhibited retinoic acid synthesis, but 4-hydroxylphenylretinamide did not. 4'-(9-Acridinylamino)methanesulfon-m-anisidide, an inhibitor of aldehyde oxidase, and ethanol did not inhibit retinoic acid synthesis. 4-Methylpyrazole was a weak inhibitor: disulfiram was a potent inhibitor. These data indicate that retinol dehydrogenase is a sulfhydryl group-dependent enzyme, distinct from ethanol dehydrogenase. Homogenates of LLC-PK1 cells converted retinol into retinoic acid and retinyl palmitate and hydrolyzed retinyl palmitate. This report suggests that substrate availability, relative to enzyme activity/amount, is a primary determinant of the rate of retinoic acid synthesis, identifies inhibitors of retinoic acid synthesis, and places retinoic acid synthesis into perspective with several other known pathways of retinoid metabolism.     

A radiometric assay for kynurenine 3-hydroxylase based on the release of 3H2O during hydroxylation of L-[3,5-3H]kynurenine.

A rapid and sensitive assay for kynurenine 3-hydroxylase (KH) has been developed. This radiometric assay is based on the enzymatic synthesis of tritiated water from L-[3,5-3H]kynurenine during the hydroxylation reaction. Radiolabeled water is quantified following selective adsorption of the isotopic substrate and its metabolite with activated charcoal. The assay is suitable for detecting 0.1 pmol enzyme activity per minute per milligram protein in tissues displaying low levels of the enzyme. The amount of water produced in the reaction, as calculated from the tritium released, was stoichiometric with the 3-hydroxykynurenine product detected by HPLC. Rat liver KH was characterized by cofactor specificity and kinetic parameters. NADPH was preferred over NADH as coreductant in the reaction. Tetrahydrobiopterin was not a cofactor. The tissue distribution of KH activity in the rat suggested that the majority of active enzyme is located in liver and kidney. Detectable amounts were found in several other tissues, including brain which had low but significant levels of activity in every region assayed.     

Adaptation of the tetrazolium reduction test for the measurement of the electron transport system (ETS) activity during embryonic development of medaka

The quantitative electron transport system (ETS)-assay based on tetrazolium reduction has been adapted for determining the terminal ETS activity during embryonic development of the subtropical teleost fish Oryzias latipes , medaka. Homogenization with a glass potter for 1–2 min was required for the complete extraction of the ETS. Additional sonication and centrifugation had a degradatory effect on the ETS activity. The main substrate of the ETS of fish embryos was NADH. NADPH also donated electrons for the ETS but with much less intensity. The impacts of the NADH and the NADPH on the enzyme activity was not additive. Succinate was ineffective as a substrate for the ETS. NADH (1.7 mM) and NADPH (0.25 mM) in combination with 0.8 mM of the artificial electron acceptor, 2-( p -iodophenyl)-3-( p -nitrophenyl)-5-phenyl tetrazolium chloride (INT), ensured a V _max for the ETS if the reaction mixture contained 400 μg wet weight egg ml⁻¹ of cell-free homogenate. The pH-optimum of the ETS was between pH 8.0 and 8.6. The enzyme reaction at 24°C was linear during 40 min incubation. The ETS activity increased exponentially during embryonic development. The assay could be a useful tool for detecting the effect of pollutants on the development of the respiratory enzyme system in fish during embryogenesis.     

Enzymatic esterification of exogenous retinol and 3,4-didehydroretinol in the retinal pigment epithelium

The kinetics of esterification of exogenous retinol by cell membranes prepared from the crude homogenate of the frog retinal pigment epithelium was studied. The formation of retinyl palmitate from added retinol was directly assayed by high performance liquid chromatography (HPLC). A linear relationship was observed between the amount of protein (up to 2 mg) in the incubation medium and the amount of retinyl palmitate formed. At room temperature, this reaction took less than 2 hours to complete. By varying the substrate concentration in the incubation medium, the reciprocal of initial velocity of the reaction (nmol retinyl palmitate formed per hour) was plotted against the reciprocal of substrate concentration (nmol of retinol). This double-reciprocal plot shows that the apparent Km of the reaction was 10 microM with an apparent Vmax of 9.1 nmol of retinyl palmitate per hour per mg protein. When this assay was repeated in the presence of 3,4-didehydroretinol (20 microM), the kinetics of the reaction showed the pattern of that of a competitive inhibitor, suggesting that 3,4-didehydroretinol competes with retinol for the same active site for esterification. The esterification of 3,4-didehydroretinol resulted in the formation of 3,4-didehydroretinyl palmitate, which was also measured by HPLC. The amount of 3,4-didehydroretinyl palmitate formed by this reaction decreased in proportion to increased retinol concentration in the incubation mixture. This further confirms that a competition exists between the esterification of retinol and 3,4-didehydroretinol by retinal pigment epithelium of the frog.     

A growth factor- and hormone-stimulated NADH oxidase from rat liver plasma membrane.

NADH oxidase activity (electron transfer from NADH to molecular oxygen) of plasma membranes purified from rat liver was characterized by a cyanide-insensitive rate of 1 to 5 nmol/min per mg protein. The activity was stimulated by growth factors (diferric transferrin and epidermal growth factor) and hormones (insulin and pituitary extract) 2- to 3-fold. In contrast, NADH oxidase was inhibited up to 80% by several agents known to inhibit growth or induce differentiation (retinoic acid, calcitriol, and the monosialoganglioside, GM3). The growth factor-responsive NADH oxidase of isolated plasma membranes was not inhibited by common inhibitors of oxidoreductases of endoplasmic reticulum or mitochondria. As well, NADH oxidase of the plasma membrane was stimulated by concentrations of detergents which strongly inhibited mitochondrial NADH oxidases and by lysolipids or fatty acids. Growth factor-responsive NADH oxidase, however, was inhibited greater than 90% by chloroquine and quinone analogues. Addition of coenzyme Q10 stimulated the activity and partially reversed the analogue inhibition. The pH optimum for NADH oxidase was 7.0 both in the absence and presence of growth factors. The Km for NADH was 5 microM and was increased in the presence of growth factors. The stoichiometry of the electron transfer reaction from NADH to oxygen was 2 to 1, indicating a 2 electron transfer. NADH oxidase was separated from NADH-ferricyanide reductase, also present at the plasma membrane, by ion exchange chromatography. Taken together, the evidence suggests that NADH oxidase of the plasma membrane is a unique oxidoreductase and may be important to the regulation of cell growth.     

Molecular cloning of retinal oxidase/aldehyde oxidase cDNAs from rabbit and mouse livers and functional expression of recombinant mouse retinal oxidase cDNA in Escherichia coli

Retinal oxidase (EC 1.2.3.11) is a molybdenum-containing flavoenzyme with high enzymatic activity as to retinoic acid synthesis. In this study, we provide direct evidence that retinal oxidase is identical to aldehyde oxidase (EC 1.2.3.1) by cDNA cloning. Retinal oxidase and aldehyde oxidase, purified from rabbit liver cytosol using the original methods, showed completely identical HPLC patterns and amino acid sequences for three corresponding polypeptides (103 amino residues). The primary structural information obtained from the cleaved polypeptides permitted molecular cloning of the full-length cDNA of rabbit liver retinal oxidase (aldehyde oxidase). We also cloned and sequenced the full-length cDNA of mouse retinal oxidase. The cDNAs of rabbit and mouse retinal oxidase have a common sequence approximately 4.6 kb long, comprising 4-kb coding regions. The open reading frames of the cDNAs predict single polypeptides of 1334 and 1333 amino acids; the calculated minimum molecular mass of each is approximately 147,000. Northern blot analysis showed that the rabbit retinal oxidase mRNA was widely expressed in tissues. Finally, we successfully constructed a prokaryotic expression system for mouse retinal oxidase. The purified recombinant retinal oxidase from Escherichia coli showed a typical spectrum of aldehyde oxidases and a lower Km (3.8 microM) for retinal and a higher Vmax (807 nmol/min/mg protein) for retinoic acid synthesis than those of rabbit retinal oxidase (8 microM and 496 nmol/min/mg protein). This represents the first eukaryotic molybdenum-containing flavoprotein to be expressed in an active form in a prokaryotic system.     

Peptide synthesis with immobilized carboxypeptidase Y

Enzymatic peptide synthesis was investigated using carboxypeptidase Y immobilized with glutaraldehyde on 10 mum microparticulate amino-silica. Carboxypeptidase Y was immobilized with 98.5% recovery of active enzyme to yield the immobilized enzyme having 0.55 units esterase activity/mg amino-silica support. The stability of the immobilized enzyme was examined as a function of pH, temperature, and reactant concentrations. Immobilized Carboxypeptidase Y was used in stirred batch and recirculating packed-bed reactors for peptide synthesis. Packed-bed reactors (40 x 4.6 mm, 60 x 4.6 mm) were used to catalyze the synthesis of 170 mg N-benzoyl-L-arginyl-L-methioninamide, 380 mg N-benzoyl-L-arginyl-L-methionyl-L-leucinamide, and 200 mg N-benzoyl-L-arginyl-L-methionyl-L-leucyl-L-phenylalaninamide in 8, 3, and 1 hour, respectively, as intermediates in the synthesis of L-methionyl-L-leucyl-L-phenylalanine. No inactivation of the immobilized enzyme was observed during the course of the reactions. The N-benzoyl-L-arginyl group served to increase the water solubility of the peptides and was removed by immobilized trypsin at the end of synthesis to obtain the final product. While the first two syntheses were conducted with aqueous reaction mixtures, the synthesis of N-benzoyl-L-arginyl-L-methionyl-L-leucyl-L-phenylalaninamide was carried out in a reaction mixture containing dimethylformamide to avoid precipitation of the product. HPLC and amino acid analysis confirmed the high purity and amino acid composition of the final product.     

Purification and properties of sheep-liver aldehyde dehydrogenases.

Sheep liver cytoplasmic aldehyde dehydrogenase was purified to homogeneity to give a sample with a specific activity of 380 nmol NADH min(-1) mg(-1). An amino acid analysis of the enzyme gave results similar to those reported for aldehyde dehydrogenases from other sources. The isoelectric point was at pH 5.25 and the enzyme contained no significant amounts of metal ions. On the binding of NADH to the enzyme there is a shift in absorption maximum of NADH to 344 nm, and a 5.6-fold enhancement of nucleotide fluorescence. The protein fluorescence (lambdaexcit = 290 nm, lambdaemisson = 340 nm) is quenched on the binding of NAD+ and NADH. The enhancement of nucleotide fluorescence on the binding of NADH has been utilised to determine the dissociation constant for the enzyme . NADH complex (Kd = 1.2 +/- 0.2 muM). A Hill plot of the data gave a straight line with a slope of 1.0 +/- 0.3 indicating the absence of co-operative effects. Ellman's reagent reacted only slowly with the enzyme but in the presence of sodium dodecylsulphate complete reaction occurred within a few minutes to an extent corresponding to 36 thiol groups/enzyme. Molecular weights were determined for both cytoplasmic and mitochondrial aldehyde dehydrogenases and were 212 000 +/- 8 000 and 205 000 respectively. Each enzyme consisted of four subunits with molecular weight of 53 000 +/- 2 000. Properties of the cytoplasmic and mitochondrial aldehyde dehydrogenases from sheep liver were compared with other mammalian liver aldehyde dehydrogenases.