Inhibition of rat hepatic mitochondrial aldehyde dehydrogenase isozymes by repeated cyanamide administration: pharmacokinetic-pharmacodynamic relationships.

The inhibition of rat hepatic mitochondrial aldehyde dehydrogenase (ALDH) isozymes was studied in apparent steady-state conditions after repeated intra-peritoneal cyanamide administration. The low-Km mitochondrial ALDH isozyme was more susceptible to cyanamide-induced inhibition (DI50 = 0.104 mg kg-1) than the high-Km isozyme (DI50 = 8.52 mg kg-1), with almost complete inhibition occurring at 0.35 mg kg-1 total cyanamide administered for the low-Km isozyme. The relationships between plasma and liver cyanamide concentrations and the inhibition of high-Km ALDH were established by means of the sigmoid Imax model. The effect of dosing rate on the plasma concentration of cyanamide at apparent steady-state showed non-linearity, indicating that clearance or first-pass metabolism of cyanamide during its absorption after intraperitoneal administration did not remain constant throughout the range of doses studied.

Inactivation mechanism of low-KM rat liver mitochondrial aldehyde dehydrogenase by cyanamide in vitro.

The inactivation of low-KM rat liver mitochondrial aldehyde dehydrogenase (ALDH) by the alcohol-sensitizing agent cyanamide (H2NCN) has been studied in vitro. The effect of the concentrations of NAD+ at different concentrations of catalase on the inactivation of ALDH by cyanamide (20 and 200 microM) in vitro point to an ALDH-NAD(+)-catalase complex prior to the binding to cyanamide to form the holoenzyme-inhibitor complex. Cyanamide itself could be responsible for the inactivation of ALDH. The possibility that both irreversibly inactivated ALDH and cyanamide remain free at the end of the inactivation process is discussed. The effects of pH and ionic strength on the inactivation process are also described. The pseudo-first order rate constants for inactivation of low-KM ALDH depends on both effects, suggesting that electrostatic forces are involved in the process and that a group with pK approximately 6.8, presumably a histidine residue, at the active site of ALDH could be involved. A representative equation for the inactivation process of low-KM ALDH by cyanamide in vitro has been fitted to experimental kinetic data, involving both catalase and inhibitor concentrations.

Comparative binding of lactate dehydrogenase to mitochondrial fractions.

Beef liver mitochondrial fraction showed LDH activity (1.76 +/- 0.25 U/g pellet). Sixty seven% of the initial mitochondrial pellet LDH activity (almost M4 isoenzyme) was released when suspended in NaCl 0.15 M. When the washed particles were sonicated in a 0.15 M NaCl medium, the solubilized LDH activity (all five isoenzymes as cytosoluble fraction) was 5-fold higher than the initial pellet activity. The different isoenzymatic composition of intramitochondrial and externally bound forms of the enzyme should be taken into account when investigating the physiological role of intramitochondrial LDH. Beef liver cytosoluble LDH (very little content of M4 isoenzyme) showed no affinity for the beef liver mitochondrial fraction but purified M4-LDH isoenzyme was able to bind to the particulate fraction from the same source. This suggests an isoenzyme specificity for the interaction. The maximum amount of cytosoluble LDH bound to the mitochondrial fraction depends on the enzyme and the particulate fraction source. Therefore, binding capacity to the mitochondrial fraction depends not only on the net charge of LDH isoenzymes, which play a predominant role in the binding, but also on individual characteristics of the LDH isoenzymes and mitochondrial fractions from different sources. This suggests that electrostatic forces are not the only ones involved in the binding process.

Inactivation of low-Km rat liver mitochondrial aldehyde dehydrogenase by cyanamide in vitro. A catalase-mediated reaction.

The inactivation of the affinity chromatography purified low-Km rat liver mitochondrial aldehyde dehydrogenase (ALDH)--free of catalase activity--by the alcohol sensitizing agent cyanamide was studied in vitro. This ALDH-purified preparation was not susceptible to cyanamide inactivation at concentrations up to 2.5 mM. On the other hand, ALDH activity appears to be irreversibly inhibited when the incubation mixture contained ALDH, catalase, NAD+ and cyanamide. Influence of catalase, NAD+ and cyanamide concentrations in the incubation mixtures on the ALDH activity were also established. The time course of the concentration of cyanamide in an incubation mixture when ALDH activity was inhibited by cyanamide in the presence of catalase and NAD+, was evaluated by HPLC. No disappearance of cyanamide was observed for a period of time up to 24 hr. This result suggests that no metabolic conversion of cyanamide to an active inhibitory form takes place, as has been suggested recently.

Purification and characterization of chicken brain cytosolic aspartate aminotransferase.

Aspartate aminotransferase from the cytosolic fraction of chicken brain was isolated with acceptable yield and high degree of purity. The enzyme appeared in multiple molecular forms: alpha, beta, gamma, and delta (alpha predominates), as detected by polyacrylamide gel electrophoresis with specific staining. These different forms of the enzyme were separated by DEAE-Sephacel chromatography, and showed different isoelectric points and maximal velocities values, whereas their molecular weight, optimum pH and Michaelis constants were very similar. Generation process studies suggest that minors subforms of the enzyme could be raised from alpha form by a mechanism in which the oxidation of particular amino acid groups are involved.

Cytosolic aspartate aminotransferases from different chicken tissues: purification and characterization of their multiple forms.

Cytosolic aspartate aminotransferases from chicken heart, liver, spleen, skeletal muscle and breast muscle differed in number of their molecular forms, detected by polyacrylamide gel electrophoresis and specific staining. The number of molecular forms varied from tissue to tissue but the electrophoretic mobilities of a given form in all tissues were analogous. Within a single tissue most of the enzyme activity was present as the lowest-running band (alpha form) and the rest was distributed in minor bands termed (B,tau, alpha and epsilon forms). We report a method for the purification of cytosolic aspartate aminotransferases from various chicken tissues. The procedure can be carried out in one week and allows the obtention of isolated molecular forms of the enzyme, independently of the tissue under study. Separation of multiple forms was also achieved by chromatofocusing. The isoelectric points determined by this method for a given form in all five tissues were analogous and differed from those of the molecular forms of the enzyme from other origins. An Mr of 100,000 was obtained for all molecular forms of the five chicken tissues studied.

Generation process of cytosolic aspartate aminotransferase molecular forms by several treatments.

Alpha-, beta-, and gamma-forms of chicken liver cytosolic aspartate aminotransferase generate variants on storage (4 degrees C, 25 days). The variants developed from each isolated form appeared as evenly spaced bands with increasing anodic mobilities after polyacrylamide gel electrophoresis (PAGE), pH 8.8, and specific staining. Their mobilities coincided with those of the more negatively charged forms present in fresh tissue. Development of faster-running variants on storage was avoided by addition of thiol reagents to the freshly isolated forms. In their presence, beta- and gamma-forms were partially transformed into one and two variants with lower anodic mobilities analogous to those of native alpha- and beta-forms. Short pH and heat treatments did not modify the electrophoretic patterns of the alpha-, beta-, and gamma-forms, but the incubation with 5 mM L-ascorbic acid (37 degrees C, 7 h) produced more anodic active bands. The formation of these variants was inhibited by the presence, in the incubation mixture, of superoxide dismutase and catalase. The kinetic parameters of the forms submitted to the different treatments were similar to those of the freshly isolated subforms. The results obtained suggest that minor subforms of the enzyme could be generated in vivo by a mechanism in which the oxidation of particular amino acid groups is involved.

Isolation and characterization of bovine brain myelin distribution of 5'-nucleotidase.

Myelin was isolated from bovine brain by several published procedures and modifications of these procedures. High activity of the myelin marker (2',3'-cyclic nucleotide 3'-phosphohydrolase) and low activity of contaminants markers in white matter homogenates in respect to cerebral cortex showed the white matter to be better than the cerebral cortex or the whole brain for myelin isolation. A procedure is described for the preparation of purified myelin from bovine white matter which yielded a content of protein (40%), myelin marker (51%), and 5'-nucleotidase (25%) in purified myelin higher than by any used method. Acetylcholinesterase or succinate dehydrogenase was lower than 7% of its activity in the white matter homogenate, and monoamine oxidase and NADPH:cytochrome c reductase were not recovered in myelin fraction. Morphologically, myelin fraction was shown to mainly consist of multilamellar membranes of different sizes. Sodium dodecyl sulphate polyacrylamide gel electrophoresis of myelin fraction showed a characteristic protein pattern of myelin. When our procedure was applied to frozen white matter, lower protein (32%) and myelin marker (34%) and similar 5'-nucleotidase activity (24%) were recovered in myelin, increasing its recovery in denser fractions of white matter.

Localization of 5'-nucleotidase in bovine brain myelin fraction and myelin subfractions.

Purified myelin from fresh calf brain white matter was subfractionated in a discontinuous sucrose gradient; significant recovery of protein and 2',3'-cyclic nucleotide 3'-phosphohydrolase (CNP) and 5'-nucleotidase (5'N) activities occurred in all three obtained subfractions, the highest recovery being in the light subfraction; highest 5'N and CNP specific activities were in medium myelin. Purified myelin was also subfractionated in a continuous sucrose gradient, with a similar localization of protein; CNP activity and 5'N activity maxima suggest that myelin may be a predominant locus of 5'N in bovine brain white matter. Freezing of brain white matter caused an increase in protein and in CNP and 5'N total activity recoveries in denser myelin subfractions. Cytochemistry showed the reaction product of 5'N in the whole myelin fraction to be associated with the innermost, outermost and medial compact myelin layers. Effects of non-ionic detergent (LUbrol WX) on 5'N activity were studied, and the results also suggest the intrinsic nature of 5'N as an ectoenzyme in myelin membranes. Lubrol WX was viewed as an advisable detergent for the stimulation of myelin 5'N activity, but not for the solubilization of this enzyme.

Purification and partial characterization of brain adenosine deaminase: inhibition by purine compounds and by drugs.

Rat brain adenosine deaminase (E.C. 3.5.4.4.) was purified 667-fold from the supernatant fraction by the following techniques: heat treatment (60 degrees C), fractionation with ammonium sulfate, column chromatography on DEAE-Sepharose, and preparative gel electrophoresis. The purified enzyme was homogeneous by the criterion of polyacrylamide disc gel electrophoresis and isoelectric focusing. Amino acid composition is given. The isoelectric point of the enzyme (5.2) was determined by isoelectric focusing on agarose. The apparent molecular weight was estimated to be 39,000 (Stokes Radius [Rs] = 27.3 A) using a calibrated Sephacryl S-300 column. The study of the influence of the temperature on the initial reaction rates allowed calculation of Ea (8.9 Kcal/mole) and delta H (5.0 Kcal/mole) values. The variation of V and Km with pH suggests the existence of a sulfhydryl group and an imidazole group in the enzyme-substrate complex. The enzyme had a Km (adenosine) of 4.5 X 10(-5) M and was inhibited by inosine, guanosine, adenine, and hypoxanthine but not by other intermediates of purine metabolism. None of the inhibitors were active as substrates. The enzyme was also inhibited by dimethyl sulfoxide and ethanol. Inhibition by ethanol can account partially for the CNS depressant effects of levels 3 and 4 of alcohol intoxication. A number of drugs having therapeutic uses such as sedative, anxiolytic, analgesic, and relaxant are modulators of the enzyme. Among these, lidoflazine, phenylbutazone, and chlordiazepoxide are the most potent as inhibitors (Ki 30, 54, and 83 microM, respectively), whereas medazepam is the most potent as activator (Ka 0.32 mM). Thus, it is concluded that some drugs that inhibit adenosine uptake also modulate adenosine deaminase activity. Besides, since the enzyme is located extracellularly [Franco et al, 1986], these drugs can modulate the physiological effects exerted by extracellular adenosine.

Simultaneous purification and characterization of aspartate aminotransferase isoenzymes from chicken liver.

Cytosolic and mitochondrial isoenzymes of aspartate aminotransferase (EC 2.6.1.1) were purified to homogeneity from chicken liver, without previous fractionation of the subcellular components. The procedure includes initial heat treatment and ammonium sulfate fractionation. The two isoenzymes can then be separated by a DEAE-Sepharose chromatography using a linear gradient of L-aspartate (reaction substrate). The separated fractions can be further purified by a parallel step with HA-Ultrogel prior to octyl-Sepharose (c-AAT) and CM-Sepharose (m-AAT) chromatographies. Michaelis constants, pI values, inhibition by adipate and subforms generation with time were studied for both isoenzymes.

Purification of malate dehydrogenase from chicken liver mitochondria. Existence of a small quantity of cytosolic isoenzyme.

1. A new purification method for chicken liver mitochondrial malate dehydrogenase is described. The application of affinity chromatography through 5'AMP-Sepharose and Blue-Sepharose permits to obtain homogeneous preparations, with good yields (47%), in a short time (48 hr). 2. The 5'AMP-Sepharose chromatography reveals the presence of two malate dehydrogenase species in the mitochondrial extracts. 3. A comparative study of these forms point out the cytosolic nature of the minority form and suggests that its presence could be due to a slight interaction of the cytosolic malate dehydrogenase with mitochondrial membranes.

An improved purification method for cytosolic malate dehydrogenase from several sources.

A new purification method for cytosolic malate dehydrogenases from several sources has been developed. The procedure, employing chromatographies on 5'AMP-Sepharose, DEAE-Sephacel and Blue-Sepharose, allows for a rapid isolation of the enzyme (approximately 40 hours), in large quantities, with good yields (45-54%). The specific activity of final preparations were around 1300 I.U./mg and were judged homogeneous by polyacrylamide gradient gel and sodium dodecyl sulfate polyacrylamide gel electrophoresis, high performance size exclusion chromatography and isoelectric focusing.

5?-Nucleotidase from bovine brain cortex: effect of solubilization on enzyme kinetics and modulation.

The kinetic characteristics and the EDTA inhibition of microsomal 5?-nucleotidase from bovine brain cortex were studied and compared with the properties of the enzyme solubilized with Lubrol WX. The K(m) value after enzyme solubilization was not significantly different from that of the membrane-bound enzyme. Likewise, di- and trinucleotides performed a similar competitive inhibition of the two forms of the enzyme. In contrast, divalent cations inhibited the intact microsomal enzyme activity at the same concentrations in which they increased the soluble-enzyme activity. The solubilization of microsomal 5?-nucleotidase did not change the progressive and irreversible character of the EDTA inhibition, but the mechanism of the irreversible inhibition was different. The addition of divalent metal cations did not affect the irreversibility of either inhibition, even though the effect on the residual activities was different. The Arrhenius plot of the 5?-nucleotidase activity in intact microsomal fraction exhibited a well-defined break at 31 +/- 0.1 degrees C, whereas that of the solubilized enzyme was a straight line. It is concluded then that microsomal 5?-nucleotidase from bovine brain cortex does not require the membrane environment to express its activity, although the influence of this lipidic environment was evident in the differences observed in the enzyme activity modulation by EDTA, cations and temperature.

Lactate and malate dehydrogenase binding to the microsomal fraction from chicken liver.

Chicken liver microsomal fractions show lactate and malate dehydrogenase activities which behave differently with respect to successive extractions by sonication in 0.15 M NaCl, 0.2% Triton X-100 and 0.15 M NaCl, respectively. The Triton X-100-treated pellet did not show malate dehydrogenase activity but exhibited a 10-fold increase in lactate dehydrogenase activity with respect to the sonicated pellet. Total extracted lactate and malate dehydrogenase activities were, respectively, 7.5 and 1.7 times higher than that in the initial pellet. Different isoenzyme compositions were observed for cytosoluble and microsomal extracted lactate and malate dehydrogenases. When the ionic strength (0-500 mM) or the pH values (6.1-8.7) of the media were increased, an efficient release of lactate dehydrogenase was found at NaCl 30-70 mM and pH 6.6-7.3. Malate dehydrogenase solubilization under the same conditions was very small, even at NaCl 500 mM, but it attained a maximum in the 7.3-8.7 pH range. Cytosoluble lactate dehydrogenase bound in vitro to 0.15 M NaCl-treated (M2) and sonicated (M3) microsomal fractions but not to the crude microsomal fraction (M1). Particle saturation by lactate dehydrogenase occurred with M2 and M3, which contained binding sites with different affinities. Cytosoluble malate dehydrogenase did not bind to M1, M2 and M3 fractions, however, a little binding was found when purified basic malate dehydrogenase was incubated with M2 or M3 fractions.

Purification and comparative studies of several mitochondrial aspartate aminotransferases from avian liver.

A new purification method has been developed which only exploits the chromatographic behaviour of avian liver mitochondrial aspartate aminotransferase enzymes (m-AAT), and permits a rapid isolation of the protein (4 days) in large quantities with high yield and low cost. m-AAT from turkey, chicken and quail livers have been isolated by chromatography on CM-Sepharose, Sephadex G-100 and 5' AMP-Sepharose using TEA-acetate buffer (pH 7.4), and specific activities (A.E.) of 311.6, 318.9, 320.1 I.U./mg respectively were obtained. Preparations were homogeneous as judged by various electrophoretic techniques and by size exclusion HPLC. The amino acid composition, Stokes Radius, subunit molecular weight and pI values have been determined and compared, finding no appreciable differences among them. In contrast, the absorption spectrum of the turkey enzyme differed from those of chicken and quail at both pH 7.4 and pH 5.0.

A kinetic method for quantification of aspartate aminotransferase isoenzymes.

A spectrophotometric assay is proposed to determine the levels of aspartate aminotransferase (AAT) isoenzymes from chicken liver by a steady-state kinetic method which depends on the differential inhibition of these isoenzyme forms by high concentrations of substrate 2-oxoglutarate at pH 6.2. The use of a standard curve permits the determination of the percentage of chicken liver c-AAT and m-AAT isoenzymes. This method yields results in good correlation with those achieved by different extent adipate inhibition and by differential centrifugation.

Microheterogeneity of the malate dehydrogenase from several sources.

Different homogeneously purified cytosolic malate dehydrogenases gave, on isoelectric focusing, several active bands. The phenomenon could not be assigned to differences in their molecular weights or to alterations in the enzyme preparations during the purification procedure. Resolution of the multiple malate dehydrogenase active bands was achieved by chromatofocusing. The aged isolated subforms always yielded the original electrofocusing pattern. This fact suggests that conformational isomerism is a likely explanation for the charge heterogeneity of the enzymes studied.

Lactate dehydrogenase activity in the mitochondrial fraction of chicken liver: enzyme binding and kinetic behavior of soluble and bound enzyme.

Chicken liver crude mitochondrial fraction showed lactate dehydrogenase activity (6.5% of cytoplasmic enzyme). Most of the mitochondrial lactate dehydrogenase was solubilized by sonication of the mitochondrial fraction in 0.15 M NaCl, pH 6. Total extracted lactate deshydrogenase activity was 3-fold higher than the initial pellet activity. Different isoenzymatic compositions were observed for cytosoluble and mitochondrial extracted lactate dehydrogenase. The pI, values of the 5 lactate dehydrogenase isoenzymes were found to be independent of their origin. The cytosoluble lactate dehydrogenase and the separated H4,H3M and H2M2 isoenzymes were able to bind to the chicken liver mitochondrial fraction in 5 mM sodium phosphate buffered medium, and could be solubilized afterwards with 0.15 M NaCl, pH 6. The enzyme bound to the mitochondrial fraction was less active than the soluble one. Particle saturation by the bound enzyme occurred with all mitochondrial fractions assayed. According to the Langmuir isotherm, the non-sonicated mitochondrial fractions contain a single type of binding sites for lactate dehydrogenase; in contrast, the sonicated mitochondrial fraction should contain different binding sites. Chicken liver crude or sonicated active mitochondrial fractions showed a hyperbolic behavior with respect to NADH and a non-hyperbolic one with respect to pyruvate. This mechanism is different from the bi-bi compulsory order mechanism of the soluble enzyme. With hydroxypyruvate as the substrate, the active mitochondrial fraction fit a sequential mechanism but lost the rapid-equilibrium characteristics of the soluble enzyme.