Subcellular distribution and properties of aldehyde dehydrogenase from 2-acetylaminofluorine-induced rat hepatomas

The subcellular distribution and properties of four aldehyde dehydrogenase isoenzymes (I-IV) identified in 2-acetylaminofluorene-induced rat hepatomas and three aldehyde dehydrogenases (I-III) identified in normal rat liver are compared. In normal liver, mitochondria (50%) and microsomal fraction (27%) possess the majority of the aldehyde dehydrogenase, with cytosol possessing little, if any, activity. Isoenzymes I-III can be identified in both fractions and differ from each other on the basis of substrate and coenzyme specificity, substrate K(m), inhibition by disulfiram and anti-(hepatoma aldehyde dehydrogenase) sera, and/or isoelectric point. Hepatomas possess considerable cytosolic aldehyde dehydrogenase (20%), in addition to mitochondrial (23%) and microsomal (35%) activity. Although isoenzymes I-III are present in tumour mitochondrial and microsomal fractions, little isoenzyme I or II is found in cytosol. Of hepatoma cytosolic aldehyde dehydrogenase activity, 50% is a hepatoma-specific isoenzyme (IV), differing in several properties from isoenzymes I-III; the remainder of the tumour cytosolic activity is due to isoenzyme III (48%). The data indicate that the tumour-specific aldehyde dehydrogenase phenotype is explainable by qualitative and quantitative changes involving primarily cytosolic and microsomal aldehyde dehydrogenase. The qualitative change requires the derepression of a gene for an aldehyde dehydrogenase expressed in normal liver only after exposure to potentially harmful xenobiotics. The quantitative change involves both an increase in activity and a change in subcellular location of a basal normal-liver aldehyde dehydrogenase isoenzyme.     

Subcellular distribution and properties of aldehyde dehydrogenase in the rat liver

The subcellular distribution and certain properties of rat liver aldehyde dehydrogenase are investigated. The enzyme is shown to be localized in fractions of mitochondria and microsomes. Optimal conditions are chosen for detecting the aldehyde dehydrogenase activity in the mentioned fractions. The enzyme of mitochondrial fraction shows the activity at low (0,03-0.05 mM; isoenzyme I) and high (5 mM; isoenzyme II) concentrations of the substrate. The seeming Km and V of aldehyde dehydrogenase from fractions of mitochondria and microsomes of rat liver are calculated, the acetaldehyde and NAD+ reaction being used as a substrate.     

Different forms of rat liver aldehyde dehydrogenase and their subcellular distribution.

1. The properties and distribution of the NAD-linked unspecific aldehyde dehydrogenase activity (aldehyde: NAD+ oxidoreductase EC 1.2.1.3) has been studied in isolated cytoplasmic, mitochondrial and microsomal fractions of rat liver. The various types of aldehyde dehydrogenase were separated by ion exchange chromatography and isoelectric focusing. 2. The cytoplasmic fraction contained 10-15, the mitochondrial fraction 45-50 and the microsomal fraction 35-40% of the total aldehyde dehydrogenase activity, when assayed with 6.0 mM propionaldehyde as substrate. 3. The cytoplasmic fraction contained two separable unspecific aldehyde dehydrogenases, one with high Km for aldehydes (in the millimolar range) and the other with low Km for aldehydes (in the micromolar range). The latter can, however, be due to leakage from mitochondria. The high-Km enzyme fraction contained also all D-glucuronolactone dehydrogenase activity of the cytoplasmic fraction. The specific formaldehyde and betaine aldehyde dehydrogenases present in the cytoplasmic fraction could be separated from the unspecific activities. 4. In the mitochondrial fraction there was one enzyme with a low Km for aldehydes and another with high Km for aldehydes, which was different from the cytoplasmic enzyme. 5. The microsomal aldehyde dehydrogenase had a high Km for aldehydes and had similar properties as the mitochondrial high-Km enzyme. Both enzymes have very little activity with formaldehyde and glycolaldehyde in contrast to the other aldehyde dehydrogenases. They are apparently membranebound.     

Topography and chemical reactivity of the active-inactive transition-sensitive SH-group in the mitochondrial NADH:ubiquinone oxidoreductase (Complex I)

The spatial arrangement and chemical reactivity of the activation-dependent thiol in the mitochondrial Complex I was studied using the membrane penetrating N-ethylmaleimide (NEM) and non-penetrating anionic 5,5'-dithiobis-(2-nitrobenzoate) (DTNB) as the specific inhibitors of the enzyme in mitochondria and inside-out submitochondrial particles (SMP). Both NEM and DTNB rapidly inhibited the de-activated Complex I in SMP. In mitochondria NEM caused rapid inhibition of Complex I, whereas the enzyme activity was insensitive to DTNB. In the presence of the channel-forming antibiotic alamethicin, mitochondrial Complex I became sensitive to DTNB. Neither active nor de-activated Complex I in SMP was inhibited by oxidized glutathione (10 mM, pH 8.0, 75 min). The data suggest that the active/de-active transition sulfhydryl group of Complex I which is sensitive to inhibition by NEM is located at the inner membrane-matrix interface. These data include the sidedness dependency of inhibition, effect of pH, ionic strength, and membrane bilayer modification on enzyme reactivity towards DTNB and its neutral analogue.     

Topography and chemical reactivity of the active–inactive transition-sensitive SH-group in the mitochondrial NADH:ubiquinone oxidoreductase (Complex I)

The spatial arrangement and chemical reactivity of the activation-dependent thiol in the mitochondrial Complex I was studied using the membrane penetrating N-ethylmaleimide (NEM) and non-penetrating anionic 5,5′-dithiobis-(2-nitrobenzoate) (DTNB) as the specific inhibitors of the enzyme in mitochondria and inside-out submitochondrial particles (SMP). Both NEM and DTNB rapidly inhibited the de-activated Complex I in SMP. In mitochondria NEM caused rapid inhibition of Complex I, whereas the enzyme activity was insensitive to DTNB. In the presence of the channel-forming antibiotic alamethicin, mitochondrial Complex I became sensitive to DTNB. Neither active nor de-activated Complex I in SMP was inhibited by oxidized glutathione (10 mM, pH 8.0, 75 min). The data suggest that the active/de-active transition sulfhydryl group of Complex I which is sensitive to inhibition by NEM is located at the inner membrane–matrix interface. These data include the sidedness dependency of inhibition, effect of pH, ionic strength, and membrane bilayer modification on enzyme reactivity towards DTNB and its neutral analogue.     

Rat liver aldehyde dehydrogenase. I. Isolation and characterization of four high Km normal liver isozymes

From normal rat liver mitochondrial and microsomal fractions, 4 distinct aldehyde dehydrogenase isozymes with millimolar substrate Km values have been purified and characterized. Two isozymes were isolated from mitochondria and 2 from microsomes. A mitochondrial aldehyde dehydrogenase with a substrate Km in the micromolar range was also identified. Subunit molecular weights for all millimolar Km isozymes is 54,000. The mitochondrial and microsomal millimolar Km isozymes are clearly distinguishable from each other by substrate and coenzyme specificity, pH velocity profiles, and thermal stability. By these same properties, the 2 isozymes from each organelle are virtually identical. The 2 mitochondrial isozymes can be distinguished by apparent molecular weight (I, 170,000; II, approximately 250,000), Km for NADP+, effect of inhibitors, and pI. The 2 microsomal isozymes are of the same apparent molecular weight (approximately 250,000), but are distinguishable by their Km values for benzaldehyde and NADP+, response to inhibitors, and pI.     

Subcellular Distribution of Human Brain Aldehyde Dehydrogenase

Abstract: Two human brain surgery biopsies and one autopsy sample were subjected to subcellular fractionation. With either 0.12 or 6 mM-acetaldehyde as substrate, about half of the total aldehyde dehydrogenase activity was found in the mitochondrial (+ synaptosomal) fraction and less activity in the cytosolic, nuclear, and microsomal fractions. High-affinity activity was found only in the mitochondrial fraction. The enzyme in all fractions had a higher affinity for indole-3-acetaldehyde than for acetaldehyde. The kinetic data indicate the presence of several distinct aldehyde dehydrogenase isozymes that have ample capacity to oxidize both aliphatic and aromatic aldehydes in human brain.     

The effect of ethanol ingestion on the aldehyde dehydrogenases of rat liver

The effect of ethanol ingestion on aldehyde dehydrogenase activity in the subcellular fractions of livers from 14 pair-fed male Sprague-Dawley rats was tested. Enzymatic assays were performed at two different concentrations of propionaldehyde (0.068 and 13.6 mM) sufficient to saturate enzymes with high and low affinities for propionaldehyde, respectively. The effect of alcohol ingestion varied depending on the subcellular fraction tested and the propionaldehyde concentration used in the assay. There was a 60% increase in the activity of aldehyde dehydrogenase with high affinity for propionaldehyde in the mitochondrial membranes. Conversely there was a 50% decrease in the activity of aldehyde dehydrogenases with high affinity for propionaldehyde in the microsomal fraction. There was also a 58% decrease in the activity of enzymes from the mitochondrial matrix with low affinity for propionaldehyde. The results suggest that differences in the assay systems employed may account for the conflicting results obtained by previous investigators of the effect of ethanol feeding.     

The effect of ethanol ingestion on the aldehyde dehydrogenases of rat liver.

The effect of ethanol ingestion on aldehyde dehydrogenase activity in the subcellular fractions of livers from 14 pair-fed male Sprague-Dawley rats was tested. Enzymatic assays were performed at two different concentrations of propionaldehyde (0.068 and 13.6 mM) sufficient to saturate enzymes with high and low affinities for propionaldehyde, respectively. The effect of alcohol ingestion varied depending on the subcellular fraction tested and the propionaldehyde concentration used in the assay. There was a 60% increase in the activity of aldehyde dehydrogenase with high affinity for propionaldehyde in the mitochondrial membranes. Conversely there was a 50% decrease in the activity of aldehyde dehydrogenases with high affinity for propionaldehyde in the microsomal fraction. There was also a 58% decrease in the activity of enzymes from the mitochondrial matrix with low affinity for propionaldehyde. The results suggest that differences in the assay systems employed may account for the conflicting results obtained by previous investigators of the effect of ethanol feeding.     

Subcellular distribution and kinetic parameters of HS mouse liver aldehyde dehydrogenase

1. Aldehyde dehydrogenase subcellular distribution studies were performed in a heterogeneous stock (HS) of male and female mice (Mus musculus) with propionaldehyde (5 mM and 50 microM) and formaldehyde (1 mM) and NAD+ or NADP+. 2. The relative percents of distribution were: cytosolic 55-68%, mitochondrial 12-20%, microsomal 9-18% and lysosomal 3-15% for both propionaldehyde concentrations and NAD+. 3. Kinetic experiments using propionaldehyde and acetaldehyde with NAD+ revealed two separate enzymes, Enzyme I (low Km) and Enzyme II (high Km) in the cytosolic and mitochondrial fractions. 4. The kinetic data also indicated a spectrum of cytosolic low Km values that exhibited a bimodal distribution with one congruent to 40 microM and one congruent to 5 microM. 5. It was concluded that there was no significant difference in aldehyde-metabolizing capability between male and female HS mice, compared on a per gram of liver basis. The cytosolic low Km enzyme plays a major role in aldehyde oxidation at moderate to low aldehyde concentrations.     

Subcellular localization of acetaldehyde dehydrogenase in human liver

The subcellular distribution of aldehyde dehydrogenase activity was determined in human liver biopsies by analytical sucrose density-gradient centrifugation. There was bimodal distribution of activity corresponding to mitochondrial and cytosolic localizations. At pH 9.6 cytosolic aldehyde dehydrogenase had a lower apparent Kappm for NAD (0.03 mmol l-1), than the mitochondrial enzyme (Kappm NAD = 1.1 mmol l-1). Also, the pH optimum for cytosolic aldehyde dehydrogenase activity (pH 7.5) was lower than that for the mitochondrial enzyme activity (pH 9.0), and the cytosolic enzyme activity was more sensitive to inhibition by disulfiram in vitro. Disulfiram (40 mumol l-1) caused a 70% reduction in cytosolic aldehyde dehydrogenase activity, but only a 30% reduction in mitochondrial enzyme activity after 10 min incubation. The liver cytosol may therefore be the major site of acetaldehyde oxidation in vivo in man.     

Enzymatic Improvement of Food Flavor I. Purification and Characterization of Bovine Liver Mitochondrial Aldehyde Dehydrogenase

Bovine liver mitochondrial aldehyde dehydrogenase (aldehyde: NAD⁺ oxidoreductase, EC 1.2.1.3) has been purified to homogeneity by conventional purification procedures. The enzyme was found to have a molecular weight of 215,000 based on gel filtration. The protein is composed of polypeptides having the same molecular weight, 54,000 and thus it appears to consist of four subunits of equal size. The enzyme exhibited a broad aldehyde specificity, oxidizing irreversibly a wide variety of aliphatic and aromatic aldehydes to corresponding carboxylic acids. Km values for straight-chain saturated aldehydes were below 0.1 µm, and relatively constant independent of the carbon chain lengths of the aldehydes. The maximum velocities for saturated aldehydes also did not vary appreciably with their carbon chain lengths. Maximum activity was observed at pH 9.3 and 50°C. The enzyme activity was affected by some divalent cations. Ca²⁺ enhanced the activity, while Mg²⁺ inhibited it. The enzyme was quite stable at neutral pH, but was unstable above pH 9 or below pH 6. Bovine liver has three isozymes of aldehyde dehydrogenase which are located in the mitochondrial, cytosolic, and microsomal fractions. Comparison of enzymic properties among these isozymes and yeast enzyme indicates that the mitochondrial enzyme is very suitable for improving the objectionable flavor due to aldehydes in foods.     

Aldehyde dehydrogenase heterogeneity in rat hepatic cells

In normal rat liver, aldehyde dehydrogenase (Aldehyde:NAD+ oxidoreductase, EC 1.2.1.3; ALDH) is found primarily in mitochondrial and microsomal fractions. During hepatocarcinogenesis, an additional tumor-associated aldehyde dehydrogenase (T-ALDH) is detectable in the cytosol of preneoplastic and neoplastic cells. We report here differences in the ALDH distribution pattern in different rat hepatoma cell lines compared to normal rat hepatocytes. Of the four basal ALDH enzymes, one mitochondrial ALDH and one microsomal ALDH account for 96% of total ALDH molecules detectable with our probes in normal hepatocytes. The other two mitochondrial and microsomal ALDH enzymes are only detectable in the appropriate subcellular fraction from large populations of cells. The tumor-associated ALDH is not detectable in normal hepatocytes. In addition to varying amounts of T-ALDH in the six different rat hepatoma cell lines examined, differences in the amounts of mitochondrial and microsomal ALDHs also occur in both high and low T-ALDH activity hepatoma cell lines. Each of five ALDH enzymes examined has a characteristic half-life varying from 45 min to 95 h.     

The subcellular distribution and properties of aldehyde dehydrogenases in rat liver

1. Kinetic experiments suggested the possible existence of at least two different NAD(+)-dependent aldehyde dehydrogenases in rat liver. Distribution studies showed that one enzyme, designated enzyme I, was exclusively localized in the mitochondria and that another enzyme, designated enzyme II, was localized in both the mitochondria and the microsomal fraction. 2. A NADP(+)-dependent enzyme was also found in the mitochondria and the microsomal fraction and it is suggested that this enzyme is identical with enzyme II. 3. The K(m) for acetaldehyde was apparently less than 10mum for enzyme I and 0.9-1.7mm for enzyme II. The K(m) for NAD(+) was similar for both enzymes (20-30mum). The K(m) for NADP(+) was 2-3mm and for acetaldehyde 0.5-0.7mm for the NADP(+)-dependent activity. 4. The NAD(+)-dependent enzymes show pH optima between 9 and 10. The highest activity was found in pyrophosphate buffer for both enzymes. In phosphate buffer there was a striking difference in activity between the two enzymes. Compared with the activity in pyrophosphate buffer, the activity of enzyme II was uninfluenced, whereas the activity of enzyme I was very low. 5. The results are compared with those of earlier investigations on the distribution of aldehyde dehydrogenase and with the results from purified enzymes from different sources.     

Subcellular distribution and characterization of human liver aldehyde dehydrogenase fractions.

The subcellular distribution of human liver aldehyde dehydrogenases (E.C. 1.2.1.3) have been studied and the different types have been separated by ion exchange chromatography. The cytoplasmic fraction contained at least two chromatographically separable aldehyde dehydrogenases, which accounted for about 30% of the total activity. One of the cytoplasmic aldehyde dehydrogenases had a high K_m for aldehydes (in the millimolar range). A considerable part of the activity found in this fraction was due to an enzyme with a low K_m for aldehydes (in the micromolar range). It had properties similar to those of the mitochondrial main enzyme fraction, from where it may have originated as a contamination during subcellular fractionation. Specific betaine aldehyde and formaldehyde dehydrogenases were separated from these unspecific activities in the cytoplasmic fraction. In mitochondria, where more than 50% of the total aldehyde dehydrogenase activity was found, there was also evidence for slight high-K_m activity. The microsomal fraction contained only a high-K_m aldehyde dehydrogenase, which accounted for about 10% of the total activity.     

Human placental aldehyde dehydrogenase. Subcellular distribution and properties

Freshly obtained human term placentae were subjected to subcellular fractionation to study the localization of NAD-dependent aldehyde dehydrogenases. Optimal conditions for the cross-contamination-free subcellular fractionation were standardized as judged by the presence or the absence of appropriate marker enzymes. Two distinct isozymes, aldehyde dehydrogenase I and II, were detected in placental extracts after isoelectric focusing on polyacrylamide gels. Based on a placental wet weight, about 80% of the total aldehyde dehydrogenase activity was found in the cytosolic acid and about 10% in the mitochondrial fraction. The soluble fraction (cytosol) contained predominantly aldehyde dehydrogenase II which has a relatively high Km (9 mmol/l) for acetaldehyde and is strongly inhibited by disulfiram. The results indicate that cytosol is the main site for acetaldehyde oxidation, but the enzyme activity is too slow to prevent the placental passage of normal concentrations of blood acetaldehyde (less than 1 mumol/l) produced by maternal ethanol metabolism.     

Role of mitochondrial thiols of different localization in the generation of reactive oxygen species

The role of thiols of the outer and the inner membranes of mitochondria in the regulation of generation of reactive oxygen species (ROS) has been studied. It was found that N-ethylmaleimide (NEM), which penetrates through the mitochondrial membrane and binds thiols to form thioesters, at concentrations from 20 to 250 μM activates the production of superoxide anion and hydrogen peroxide during the oxidation of the substrates of complexes I and II of the respiratory chain. 5′,5′-Dithiobis-(2-nitrobenzoate) (DTNB), which does not penetrate into mitochondria and binds thiols to form disulfides, weakly activates hydrogen peroxide production during the oxidation of NAD-dependent substrates and inhibits the ROS production upon succinate oxidation. DTNB is particularly effective in inhibiting the menadione-induced formation of ROS. The differences in the ROS formation by these reagents are explained by the fact that they influence different thiol-containing proteins and enzymes. As distinct from NEM, which inhibits complex I of the respiratory chain, DTNB has no effect on the respiratory chain of mitochondria but can bind the SH-groups of NADH-quinone oxidoreductase, which is localized in the outer mitochondrial membrane and participates in the redox cycle of menadione. It was also shown that the ability to inhibit the ADP-stimulated respiration, a feature inherent in both reagents, does not significantly contribute to ROS production.     

Subcellular distribution of steroid delta 4-5 alpha-reductase and 3 alpha-hydroxysteroid dehydrogenase in the rat epididymis during sexual maturation

The curve of the specific activity of rat epididymal nuclear delta 4-5 alpha-reductase is bell shaped as a function of age, whereas that of cytoplasmic 3 alpha-hydroxysteroid dehydrogenase does not change significantly with age. The present study examines the subcellular distribution of delta 4-5 alpha-reductase and 3 alpha-hydroxysteroid dehydrogenase in the caput-corpus and cauda epididymidis during development. A 5-step discontinuous sucrose gradient was developed for fractionation of epididymal homogenates. By using enzyme markers specific for different subcellular organelles, the five different subcellular fractions obtained were shown to be of cytoplasmic, microsomal, mitochondrial, nuclear and spermatozoal origin. 3 alpha-Hydroxysteroid dehydrogenase activity was associated only with the cytoplasmic fraction. The activity of the enzyme did not change significantly with age in either the caput-corpus or cauda epididymidis. delta 4-5 alpha-Reductase activity was found in fractions containing microsomal and nuclear markers. delta 4-5 alpha-Reductase activity in the nuclear fraction of the caput-corpus epididymidis was evident in the youngest age group (Day 25), increased 4-fold and peaked in the next age group (Day 35), and declined with each successive age group: Day 45 (60% of maximum), Day 60 (20% of maximum), Day 75 (15% of maximum) and Day 105 (10% of maximum). In contrast, microsomal delta 4-5 alpha-reductase activity increased successively from Day 25 to Day 105; enzyme activity doubled between these two ages. The ratio of nuclear to microsomal delta 4-5 alpha-reductase activity from the caput-corpus epididymidis thus changed markedly with age: Day 25:1.32; Day 35:3.76; Day 45:2.44; Day 60:1.03; Day 75:0.41; and Day 105:0.21. In the cauda epididymidis nuclear delta 4-5 alpha-reductase activity was only evident at Day 35 and Day 45; in microsomal fractions, activity was first found at Day 35 and did not subsequently change with age. These results demonstrate that: 1) epididymal 3 alpha-hydroxysteroid dehydrogenase activity is found only in the cytoplasmic fraction; 2) delta 4-5 alpha-reductase activity is found in nuclear and microsomal fractions; and 3) the subcellular distribution of delta 4-5 alpha-reductase activity changes markedly with age and epididymal section, suggesting differential regulation of nuclear and microsomal delta 4-5 alpha-reductase activities.     

Differences in the roles of conserved glutamic acid residues in the active site of human class 3 and class 2 aldehyde dehydrogenases.

Although the three-dimensional structure of the dimeric class 3 rat aldehyde dehydrogenase has recently been published (Liu ZJ et al., 1997, Nature Struct Biol 4:317-326), few mechanistic studies have been conducted on this isoenzyme. We have characterized the enzymatic properties of recombinant class 3 human stomach aldehyde dehydrogenase, which is very similar in amino acid sequence to the class 3 rat aldehyde dehydrogenase. We have determined that the rate-limiting step for the human class 3 isozyme is hydride transfer rather than deacylation as observed for the human liver class 2 mitochondrial enzyme. No enhancement of NADH fluorescence was observed upon binding to the class 3 enzyme, while fluorescence enhancement of NADH has been previously observed upon binding to the class 2 isoenzyme. It was also observed that binding of the NAD cofactor inhibited the esterase activity of the class 3 enzyme while activating the esterase activity of the class 2 enzyme. Site-directed mutagenesis of two conserved glutamic acid residues (209 and 333) to glutamine residues indicated that, unlike in the class 2 enzyme, Glu333 served as the general base in the catalytic reaction and E209Q had only marginal effects on enzyme activity, thus confirming the proposed mechanism (Hempel J et al., 1999, Adv Exp Med Biol 436:53-59). Together, these data suggest that even though the subunit structures and active site residues of the isozymes are similar, the enzymes have very distinct properties besides their oligomeric state (dimer vs. tetramer) and substrate specificity.     

Mitochondrial and Peroxisomal β-Oxidation of Stearic and Lignoceric Acids by Rat Brain

Crude subcellular fractions were prepared from adult rat brains by differential centrifugation of brain homogenates. Greater than 98% of the cellular mitochondrial marker enzyme activity sedimented in the heavy and light mitochondrial pellets, and less than 1% of the activity sedimented in microsomal pellets. Lysosomal marker enzyme activities mainly (71-78% of cellular activity) sedimented in the heavy and light mitochondrial pellets. Significant amounts of the lysosomal marker enzyme activity also sedimented in the crude microsomal pellets (9-13% of total) and high-speed supernatants (14-16% of total). The specific activities of microsomal and peroxisomal marker enzyme activities were highest in the crude microsomal pellets. Fractionation of the crude microsomal pellets on Nycodenz gradients resulted in the separation of the bulk of the remaining mitochondrial, lysosomal, and microsomal enzyme activities from peroxisomes. Fatty acyl-CoA synthetase activities separated on Nycodenz gradients as two distinct peaks, and the minor peak of the activities was in the peroxisomal enriched fraction. Fatty acid beta-oxidation activities also separated as two distinct peaks, and the activities were highest in the peroxisomal enriched fractions. Mitochondria were purified from the heavy mitochondrial pellets by Percoll density gradients. Fatty acyl-CoA synthetase and fatty acid beta-oxidation activities were present in both the purified mitochondrial and peroxisomal enriched fractions. Stearoyl-CoA synthetase activities were severalfold greater compared to lignoceroyl-CoA synthetase, and stearic acid beta-oxidation was severalfold greater compared to lignoceric acid beta-oxidation in purified mitochondrial and peroxisomal enriched fractions.(ABSTRACT TRUNCATED AT 250 WORDS)