Nitric oxide inhibits the mitochondrial carnitine/acylcarnitine carrier through reversible S-nitrosylation of cysteine 136.

S-nitrosylation of the mitochondrial carnitine/acylcarnitine transporter (CACT) has been investigated on the native and the recombinant proteins reconstituted in proteoliposomes, and on intact mitochondria. The widely-used NO-releasing compound, GSNO, strongly inhibited the antiport measured in proteoliposomes reconstituted with the native CACT from rat liver mitochondria or the recombinant rat CACT over-expressed in E. coli. Inhibition was reversed by the reducing agent dithioerythritol, indicating a reaction mechanism based on nitrosylation of Cys residues of the CACT. The half inhibition constant (IC50) was very similar for the native and recombinant proteins, i.e., 74 and 71µM, respectively. The inhibition resulted to be competitive with respect the substrate, carnitine. NO competed also with NEM, correlating well with previous data showing interference of NEM with the substrate transport path. Using a site-directed mutagenesis approach on Cys residues of the recombinant CACT, the target of NO was identified. C136 plays a major role in the reaction mechanism. The occurrence of S-nitrosylation was demonstrated in intact mitochondria after treatment with GSNO, immunoprecipitation and immunostaining of CACT with a specific anti NO-Cys antibody. In parallel samples, transport activity of CACT measured in intact mitochondria, was strongly inhibited after GSNO treatment. The possible physiological and pathological implications of the post-translational modification of CACT are discussed.

The mitochondrial carnitine/acylcarnitine carrier is regulated by hydrogen sulfide via interaction with C136 and C155.

BACKGROUND: The carnitine/acylcarnitine carrier (CAC or CACT) mediates transport of acylcarnitines into mitochondria for the ß-oxidation. CAC possesses Cys residues which respond to redox changes undergoing to SH/disulfide interconversion. METHODS: The effect of H2S has been investigated on the [(3)H]carnitine/carnitine antiport catalyzed by recombinant or native CAC reconstituted in proteoliposomes. Site-directed mutagenesis was employed for identifying Cys reacting with H2S. RESULTS: H2S led to transport inhibition, which was dependent on concentration, pH and time of incubation. Best inhibition with IC50 of 0.70 µM was observed at physiological pH after 30-60 min incubation. At longer times of incubation, inhibition was reversed. After oxidation of the carrier by O2, transport activity was rescued by H2S indicating that the inhibition/activation depends on the initial redox state of the protein. The observed effects were more efficient on the native rat liver transporter than on the recombinant protein. Only the protein containing both C136 and C155 responded to the reagent as the WT. While reduced responses were observed in the mutants containing C136 or C155. Multi-alignment of known mitochondrial carriers, highlighted that only the CAC possesses both Cys residues. This correlates well with the absence of effects of H2S on carriers which does not contain the Cys couple. CONCLUSIONS: Altogether, these data demonstrate that H2S regulates the CAC by inhibiting or activating transport on the basis of the redox state of the protein. GENERAL SIGNIFICANCE: CAC represents a specific target of H2S among mitochondrial carriers in agreement with the presence of a reactive Cys couple.

Carnitine-acyltransferase system inhibition, cancer cell death, and prevention of myc-induced lymphomagenesis.

BACKGROUND: The metabolic alterations of cancer cells represent an opportunity for developing selective antineoplastic treatments. We investigated the therapeutic potential of ST1326, an inhibitor of carnitine-palmitoyl transferase 1A (CPT1A), the rate-limiting enzyme for fatty acid (FA) import into mitochondria. METHODS: ST1326 was tested on in vitro and in vivo models of Burkitt's lymphoma, in which c-myc, which drives cellular demand for FA metabolism, is highly overexpressed. We performed assays to evaluate the effect of ST1326 on proliferation, FA oxidation, and FA mitochondrial channeling in Raji cells. The therapeutic efficacy of ST1326 was tested by treating Eµ-myc mice (control: n = 29; treatment: n = 24 per group), an established model of c-myc-mediated lymphomagenesis. Experiments were performed on spleen-derived c-myc-overexpressing B cells to clarify the role of c-myc in conferring sensitivity to ST1326. Survival was evaluated with Kaplan-Meier analyses. All statistical tests were two-sided. RESULTS: ST1326 blocked both long- and short-chain FA oxidation and showed a strong cytotoxic effect on Burkitt's lymphoma cells (on Raji cells at 72 hours: half maximal inhibitory concentration = 8.6 µM). ST1326 treatment induced massive cytoplasmic lipid accumulation, impairment of proper mitochondrial FA channeling, and reduced availability of cytosolic acetyl coenzyme A, a fundamental substrate for de novo lipogenesis. Moreover, treatment with ST1326 in Eµ-myc transgenic mice prevented tumor formation (P = .01), by selectively impairing the growth of spleen-derived primary B cells overexpressing c-myc (wild-type cells + ST1326 vs. Eµ-myc cells + ST1326: 99.75% vs. 57.5%, difference = 42.25, 95% confidence interval of difference = 14% to 70%; P = .01). CONCLUSIONS: Our data indicate that it is possible to tackle c-myc-driven tumorigenesis by altering lipid metabolism and exploiting the neoplastic cell addiction to FA oxidation.

Inhibition of mitochondrial carnitine/acylcarnitine transporter by H(2)O(2): molecular mechanism and possible implication in pathophysiology.

H(2)O(2) inhibits the [(3)H]carnitine/carnitine antiport catalysed by the mitochondrial carnitine/acylcarnitine transporter reconstituted in proteoliposomes. The inhibition was reversed by dithioerythritol, N-acetylcysteine and L-cysteine. Inhibition time-dependence revealed a faster and a slower reaction stages with orders of reaction of 1.0 and 1.9, respectively. Inhibition was tested on mutants in which one or more of the six Cys residues had been substituted with Ser or with Val. The four replacement mutant C23S/C58S/C89S/C283S containing C136 and C155 was inhibited as the wild-type. Mutants C23V/C58V/C155V/C89S/C283S and C23V/C58V/C136V/C89S/C283S containing only C136 or C155, respectively, were inhibited at a much lower extent respect to the wild-type, while the mutant C136S/C155S in which the two Cys were substituted and the C-less protein were virtually insensitive to inhibition. DTE reversed the inhibition of the H(2)O(2) sensitive proteins except that in the case of the mutants containing only C136 or C155 after long time of incubation with H(2)O(2). The IC(50) values obtained by dose-response curves of H(2)O(2) inhibition were 0.17 mM for the wild-type, 0.39 mM for the four replacement mutant containing C136 and C155, 2.23 or 1.8mM in the five replacement mutants containing the single C136 or C155, respectively. Carnitine and acetylcarnitine protected the protein from the inhibition by H(2)O(2). Inhibition kinetics showed a competitive behaviour of H(2)O(2) respect to carnitine. All the data concur to demonstrate that H(2)O(2) interacts with C136 and C155 and completely inactivates the transporter by inducing the formation of a disulphide.

Identification by site-directed mutagenesis of a hydrophobic binding site of the mitochondrial carnitine/acylcarnitine carrier involved in the interaction with acyl groups.

The role of hydrophobic residues of the mitochondrial carnitine/acylcarnitine carrier (CAC) in the inhibition by acylcarnitines has been investigated by site-directed mutagenesis. According to the homology model of CAC in cytosolic opened conformation (c-state), L14, G17, G21, V25, P78, V82, M85, C89, F93, A276, A279, C283, F287 are located in the 1st (H1), 2nd (H2) and 6th (H6) transmembrane α-helices and exposed in the central cavity, forming a hydrophobic half shell. These residues have been substituted with A (or G) and in some cases with M. Mutants have been assayed for transport activity measured as [(3)H]carnitine/carnitine antiport in proteoliposomes. With the exception of G17A and G21M, mutants exhibited activity from 20% to 100% of WT. Among the active mutants only G21A, V25M, P78A and P78M showed Vmax lower than half and/or Km more than two fold respect to WT. Acylcarnitines competitively inhibited carnitine antiport. The extent of inhibition of the mutants by acylcarnitines with acyl chain length of 2, 4, 8, 12, 14 and 16 has been compared with the WT. V25A, P78A, P78M and A279G showed reduced extent of inhibition by all the acylcarnitines; V25M showed reduced inhibition by shorter acylcarnitines; V82A, V82M, M85A, C89A and A276G showed reduced inhibition by longer acylcarnitines, respect to WT. C283A showed increased extent of inhibition by acylcarnitines. Variations of Ki of mutants for acylcarnitines reflected variations of the inhibition profiles. The data demonstrated that V25, P78, V82, M85 and C89 are involved in the acyl chain binding to the CAC in c-state.

Interaction of beta-lactam antibiotics with the mitochondrial carnitine/acylcarnitine transporter.

The interaction of beta-lactams with the purified mitochondrial carnitine/acylcarnitine transporter reconstituted in liposomes has been studied. Cefonicid, cefazolin, cephalothin, ampicillin, piperacillin externally added to the proteoliposomes, inhibited the carnitine/carnitine antiport catalysed by the reconstituted transporter. The most effective inhibitors were cefonicid and ampicillin with IC50 of 6.8 and 7.6mM, respectively. The other inhibitors exhibited IC50 values above 36 mM. Kinetic analysis performed with cefonicid and ampicillin revealed that the inhibition is completely competitive, i.e., the inhibitors interact with the substrate binding site. The Ki of the transporter is 4.9 mM for cefonicid and 9.9 mM for ampicillin. Cefonicid inhibited the transporter also on its internal side. The IC50 was 12.9 mM indicating that the inhibition was less pronounced than on the external side. Ampicillin and the other inhibitors were much less effective on the internal side. The beta-lactams were not transported by the carnitine/acylcarnitine transporter. Cephalosporins, and at much lower extent penicillins, caused irreversible inhibition of the transporter after prolonged time of incubation. The most effective among the tested antibiotics was cefonicid with IC50 of 0.12 mM after 60 h of incubation. The possible in vivo implications of the interaction of the beta-lactam antibiotics with the transporter are discussed.

Identification by site-directed mutagenesis and chemical modification of three vicinal cysteine residues in rat mitochondrial carnitine/acylcarnitine transporter.

The proximity of the Cys residues present in the mitochondrial rat carnitine/acylcarnitine carrier (CAC) primary structure was studied by using site-directed mutagenesis in combination with chemical modification. CAC mutants, in which one or more Cys residues had been replaced with Ser, were overexpressed in Escherichia coli and reconstituted into liposomes. The effect of SH oxidizing, cross-linking, and coordinating reagents was evaluated on the carnitine/carnitine exchange catalyzed by the recombinant reconstituted CAC proteins. All the tested reagents efficiently inhibited the wild-type CAC. The inhibitory effect of diamide, Cu(2+)-phenanthroline, or phenylarsine oxide was largely reduced or abolished by the double substitutions C136S/C155S, C58S/C136S, and C58S/C155S. The decrease in sensitivity to these reagents was much lower in double mutants in which Cys(23) was substituted with Cys(136) or Cys(155). No decrease in inhibition was found when Cys(89) and/or Cys(283) were replaced with Ser. Sb(3+), which coordinates three cysteines, inhibited only the Cys replacement mutants containing cysteines 58, 136, and 155 of the six native cysteines. In addition, the mutant C23S/C89S/C155S/C283S, in which double tandem fXa recognition sites were inserted in positions 65-72, i.e. between Cys(58) and Cys(136), was not cleaved into two fragments by fXa protease after treatment with diamide. These results are interpreted in light of the homology model of CAC based on the available x-ray structure of the ADP/ATP carrier. They indicate that Cys(58), Cys(136), and Cys(155) become close in the tertiary structure of the CAC during its catalytic cycle.

Identification of conserved amino acid residues in rat liver carnitine palmitoyltransferase I critical for malonyl-CoA inhibition. Mutation of methionine 593 abolishes malonyl-CoA inhibition.

Carnitine palmitoyltransferase (CPT) I, which catalyzes the conversion of palmitoyl-CoA to palmitoylcarnitine facilitating its transport through the mitochondrial membranes, is inhibited by malonyl-CoA. By using the SequenceSpace algorithm program to identify amino acids that participate in malonyl-CoA inhibition in all carnitine acyltransferases, we found 5 conserved amino acids (Thr(314), Asn(464), Ala(478), Met(593), and Cys(608), rat liver CPT I coordinates) common to inhibitable malonyl-CoA acyltransferases (carnitine octanoyltransferase and CPT I), and absent in noninhibitable malonyl-CoA acyltransferases (CPT II, carnitine acetyltransferase (CAT) and choline acetyltransferase (ChAT)). To determine the role of these amino acid residues in malonyl-CoA inhibition, we prepared the quintuple mutant CPT I T314S/N464D/A478G/M593S/C608A as well as five single mutants CPT I T314S, N464D, A478G, M593S, and C608A. In each case the CPT I amino acid selected was mutated to that present in the same homologous position in CPT II, CAT, and ChAT. Because mutant M593S nearly abolished the sensitivity to malonyl-CoA, two other Met(593) mutants were prepared: M593A and M593E. The catalytic efficiency (V(max)/K(m)) of CPT I in mutants A478G and C608A and all Met(593) mutants toward carnitine as substrate was clearly increased. In those CPT I proteins in which Met(593) had been mutated, the malonyl-CoA sensitivity was nearly abolished. Mutations in Ala(478), Cys(608), and Thr(314) to their homologous amino acid residues in CPT II, CAT, and ChAT caused various decreases in malonyl-CoA sensitivity. Ala(478) is located in the structural model of CPT I near the catalytic site and participates in the binding of malonyl-CoA in the low affinity site (Morillas, M., Gómez-Puertas, P., Rubi, B., Clotet, J., Ariño, J., Valencia, A., Hegardt, F. G., Serra, D., and Asins, G. (2002) J. Biol. Chem. 277, 11473-11480). Met(593) may participate in the interaction of malonyl-CoA in the second affinity site, whose location has not been reported.

Structural model of a malonyl-CoA-binding site of carnitine octanoyltransferase and carnitine palmitoyltransferase I: mutational analysis of a malonyl-CoA affinity domain.

Carnitine octanoyltransferase (COT) and carnitine palmitoyltransferase (CPT) I, which facilitate the transport of medium- and long-chain fatty acids through the peroxisomal and mitochondrial membranes, are physiologically inhibited by malonyl-CoA. Using an "in silico" macromolecular docking approach, we built a model in which malonyl-CoA could be attached near the catalytic core. This disrupts the positioning of the acyl-CoA substrate in the channel in the model reported for both proteins (Morillas, M., Gómez-Puertas, P., Roca, R., Serra, D., Asins, G., Valencia, A., and Hegardt, F. G. (2001) J. Biol. Chem. 276, 45001-45008). The putative malonyl-CoA domain contained His(340), implicated together with His(131) in COT malonyl-CoA sensitivity (Morillas, M., Clotet, J., Rubi, B., Serra, D., Asins, G., Ariño, J., and Hegardt F. G. (2000) FEBS Lett. 466, 183-186). When we mutated COT His(131) the IC(50) increased, and malonyl-CoA competed with the substrate decanoyl-CoA. Mutation of COT Ala(332), present in the domain 8 amino acids away from His(340), decreased the malonyl-CoA sensitivity of COT. The homologous histidine and alanine residues of L-CPT I, His(277), His(483), and Ala(478) were also mutated, which decreased malonyl-CoA sensitivity. Natural mutation of Pro(479), which is also located in the malonyl-CoA predicted site, to Leu in a patient with human L-CPT I hereditary deficiency, modified malonyl-CoA sensitivity. We conclude that this malonyl-CoA domain is present in both COT and L-CPT I proteins and might be the site at which malonyl-CoA interacts with the substrate acyl-CoA. Other malonyl-CoA non-inhibitable members of the family, CPT II and carnitine acetyltransferase, do not contain this domain.

Post-transcriptional regulation of rat carnitine octanoyltransferase.

Carnitine octanoyltransferase (COT) produces three different transcripts in rat through cis- and trans-splicing reactions, which can lead to the synthesis of two proteins. The occurrence of the three COT transcripts in rat has been found in all tissues examined and does not depend on sex, fat feeding, peroxisome proliferators or hyperinsulinaemia. Rat COT exon 2 contains a putative exonic splicing enhancer (ESE) sequence. Mutation of this ESE (GAAGAAG) to AAAAAAA decreased trans-splicing in vitro, from which it is deduced that this ESE sequence is partly responsible for the formation of the three transcripts. The protein encoded by cis-spliced mRNA of rat COT is inhibited by malonyl-CoA and etomoxir. cDNA species encoding full-length wild-type COT and one double mutant COT were expressed in Saccharomyces cerevisiae. The recombinant enzymes showed full activity towards both substrates, carnitine and decanoyl-CoA. The activity of the doubly mutated H131A/H340A enzyme was similar to that of the rat peroxisomal enzyme but was completely insensitive to malonyl-CoA and etomoxir. These results indicate that the histidine residues His-131 and His-340 are the sites responsible for the interaction of these two inhibitors, which inhibit COT by interacting with the same sites.

Inhibition by etomoxir of rat liver carnitine octanoyltransferase is produced through the co-ordinate interaction with two histidine residues.

Rat peroxisomal carnitine octanoyltransferase (COT), which facilitates the transport of medium-chain fatty acids through the peroxisomal membrane, is irreversibly inhibited by the hypoglycaemia-inducing drug etomoxir. To identify the molecular basis of this inhibition, cDNAs encoding full-length wild-type COT, two different variant point mutants and one variant double mutant from rat peroxisomal COT were expressed in Saccharomyces cerevisiae, an organism devoid of endogenous COT activity. The recombinant mutated enzymes showed activity towards both carnitine and decanoyl-CoA in the same range as the wild type. Whereas the wild-type version expressed in yeast was inhibited by etomoxir in an identical manner to COT from rat liver peroxisomes, the activity of the enzyme containing the double mutation H131A/H340A was completely insensitive to etomoxir. Individual point mutations H131A and H340A also drastically reduced sensitivity to etomoxir. Taken together, these results indicate that the two histidine residues, H131 and H340, are the sites responsible for inhibition by etomoxir and that the full inhibitory properties of the drug will be shown only if both histidines are intact at the same time. Our data demonstrate that both etomoxir and malonyl-CoA inhibit COT by interacting with the same sites.

Identification of the two histidine residues responsible for the inhibition by malonyl-CoA in peroxisomal carnitine octanoyltransferase from rat liver.

Carnitine octanoyltransferase (COT), an enzyme that facilitates the transport of medium chain fatty acids through peroxisomal membranes, is inhibited by malonyl-CoA. cDNAs encoding full-length wild-type COT and one double mutant variant from rat peroxisomal COT were expressed in Saccharomyces cerevisiae. Both expressed forms were expressed similarly in quantitative terms and exhibited full enzyme activity. The wild-type-expressed COT was inhibited by malonyl-CoA like the liver enzyme. The activity of the enzyme encoded by the double mutant H131A/H340A was completely insensitive to malonyl-CoA in the range assayed (2-200 microM). These results indicate that the two histidine residues, H131 and H340, are the sites responsible for inhibition by malonyl-CoA. Another mutant variant, H327A, abolishes the enzyme activity, from which it is concluded that it plays an important role in catalysis.

Selective modulation of carnitine long-chain acyltransferase activities. Kinetics, inhibitors, and active sites of COT and CPT-II.

Carnitine acyltransferases in mitochondria, peroxisomes and the endoplasmic reticulum are different gene products and serve different metabolic functions in the cell. Here we summarize briefly evidence that carnitine octanoyltransferase (COT) from the peroxisomes and carnitine palmitoyltransferase II (CPT-II) from the mitochondria (both matrix facing enzymes) differ kinetically and demonstrate that they differ in their sensitivity to conformationally constrained inhibitors that mimic the reaction intermediate. Medium chain inhibitors are 15 times more effective on COT than on CPT-II and long chain inhibitors, such as hemipalmitoylcarnitinium, 80 times more effective on the mitochondrial enzyme. Thus, it may be possible to develop inhibitors to inhibit mitochondrial beta-oxidation with minimal effects on peroxisomal beta-oxidation and other acyl-CoA dependent reactions.

Carnitine acyltransferases are not changed in Alzheimer disease.

We evaluated the activities of carnitine palmitoyltransferase (CPT), carnitine octanoyltransferase (COT), and carnitine acetyltransferase (CAT) in the frontal cortex, temporal cortex, parietal cortex, hippocampus, and cerebellum of Alzheimer disease (AD) patients and normal human brains. There were no significant differences in total CPT activity, its inhibition by malonyl-CoA, the effect of the detergent Triton X-100 on CPT activity, COT activity, and CAT activity in any of the brain regions examined whether activities were expressed as grams of wet weight or corrected for noncollagen protein content. The addition of Triton X-100 increased CAT activity by 50%. Our results suggest that there is no defect of fatty acid transport within the AD brain cell. Total CPT activity, COT activity, and CAT activity are not affected in AD nor is the ratio of CPT I to CPT II altered in the AD versus the normal human brain.

Carnitine palmitoyltransferase: a viable target for the treatment of NIDDM?

Inhibition of fatty acid oxidation is well recognized as a potentially effective mechanism for controlling glycemia in non-insulin-dependent diabetes mellitus (NIDDM). However, a direct targeting of inhibition of the intramitochondrial beta-oxidation pathway or an indirect modulation of fatty acid oxidation by inhibition of substrate release from adipose stores has been fraught with lack of efficacy, unacceptable side-effects or both. Focus has therefore recently been directed towards the carnitine palmitoyltransferase (CPT) system, a three-component system necessary for the transfer of long-chain fatty acids into the intramitochondrial matrix. This article will briefly review the background for fatty acid oxidation inhibition in NIDDM and then focus on the progress in the biological understanding and drug discovery targeting of the CPT system for the treatment of NIDDM. Based upon the review, it is concluded that mechanism-based hepatic and myocardial toxicities in normal animals and a potential for a lack of human efficacy may pose insurmountable hurdles for the development of CPT inhibitors for the treatment of NIDDM.

Effects of refeeding diets on emeriamine-induced fatty liver in fasting rats.

We recently reported that fatty liver and hypertriglyceridemia are easily induced by the administration of an inhibitor of fatty acid oxidation (emeriamine; (R)-3-amino-4-trimethylaminobutyric acid) to fasting rats, and that these conditions are not accompanied by the increased de novo synthesis of fatty acid [J. Nutr. Sci. Vitaminol., 42, 111-120, (1996)]. To study whether emeriamine-induced fatty liver is affected by nutrients during recovery from fatty acid oxidation inhibition, we fed rats with either a high-carbohydrate (HCHO) diet or a high-fat (HFAT) diet. Rats fed an HCHO diet following the administration of emeriamine showed a marked decrease in serum and hepatic triglycerides, and a marked increase in hepatic glycogen. The lower levels of serum and hepatic triglycerides were accompanied by decreased activities of the NADPH-generating enzymes such as malic enzyme and glucose-6-phosphate dehydrogenase. By contrast, rats fed an HFAT diet showed less significant changes in hepatic triglyceride and glycogen levels. These results suggest a reciprocal relationship between the triglyceride level and glycogen accumulation caused by HCHO diet during recovery from emeriamine.

Involvement of carnitine acyltransferases in peroxisomal fatty acid metabolism by the yeast Pichia guilliermondii.

This article provides information about peroxisomal fatty acid metabolism in the yeast Pichia guilliermondii. The existence of inducible mitochondrial carnitine palmitoyltransferase and peroxisomal carnitine octanoyl-transferase activities was demonstrated after culture of this yeast in a medium containing methyl oleate. The subcellular sites and induction patterns were studied. The inhibition of carnitine octanoyl- and palmitoyl-transferases by chlorpromazine to a large extent prevented the otherwise observed metabolism-dependent inactivation of thiolase by 2-bromofatty acids in vivo. We concluded that the metabolism of long- and medium-chain fatty acids in the peroxisome of this yeast involved carnitine intermediates.

Hypertriglyceridemia and fatty liver of fasting rats after administration of emeriamine.

The effect of emeriamine, a potent inhibitor of the entry of fatty acids into mitochondria on lipid metabolism, was examined. Emeriamine (10 mg/kg body weight) was orally administered to rats under the two different physiological conditions of a 2-day fast or refeeding with a high-carbohydrate diet after a 2-day fast. When rats were refed with a high-carbohydrate diet, serum and hepatic ketone bodies and the levels of free fatty acids decreased, and triglycerides significantly increased compared with fasting rats. However, no significant effect of emeriamine on serum and hepatic lipids was observed between two refeeding groups with or without emeriamine. Conversely, when emeriamine was administered to fasting rats, the levels of serum and hepatic triglycerides increased about 11- and 5-fold, respectively. However, the increased level of hepatic triglycerides was not accompanied by the activities of fatty acid synthetase and NADPH-generating enzymes. The analysis of serum lipoprotein revealed that very low-density lipoprotein consisted of triglyceride-rich particles and there were less apolipoproteins in the fasting rat given emeriamine. We also determined the 120-kDA protein content, which was probably dependent on lipogenesis. The level of 120-kDa protein was greatly increased with or without the administration of emeriamine after refeeding with a high-carbohydrate diet, but the concentration of 120-kDa protein was slight in the fasting rat with emeriamine. These results suggest that specific inhibition of fatty acid oxidation by emeriamine diverted the exogenous fatty acid to the esterification pathway, and induced fatty liver and hypertriglyceridemia under fasting conditions.

Effects of added l-carnitine, acetyl-CoA and CoA on peroxisomal beta-oxidation of [U-14C]hexadecanoate by isolated peroxisomal fractions.

(1) During peroxisomal beta-oxidation of [U-14C]hexadecanoate, at concentrations higher than 100 microM, long-chain 3-oxoacyl-CoA-esters and 3-oxobutyryl-CoA accumulate. Only 3-oxobutyryl-CoA accumulates at a low concentration of [U-14C]hexadecanoate. Accumulation of long chain 3-oxoacyl-CoA esters is most extensive when the supply of CoA can be considered limiting for beta-oxidation. (2) Added acetyl-CoA was found to inhibit peroxisomal beta-oxidation. This inhibition was not significantly relieved by added L-carnitine and carnitine acetyltransferase (EC 2.3.17). (3) Added L-carnitine, at concentrations below 0.2 mM, was found to stimulate peroxisomal beta-oxidation of [U-14C]hexadecanoate by up to 20%, causing the conversion of acetyl-CoA into acetylcarnitine. Higher concentrations of L-carnitine were progressively inhibitory to beta-oxidation. This effect was specific for L-carnitine as both D-carnitine and aminocarnitine neither caused stimulation at low concentrations, nor inhibition at higher concentrations. Added L-carnitine caused accumulation of acylcarnitines of chain-lengths ranging from 4 to 16 carbon-atoms. The inhibition observed with higher concentrations of added L-carnitine is likely due to conversion of [U-14C]hexadecanoate into [U-14C]hexadecanoylcarnitine. (4) Low concentrations of added hexadecanoylcarnitine was shown to inhibit peroxisomal beta-oxidation by about 15%, while added acetylcarnitine did not inhibit at concentrations up to 100 microM. (5) These data are interpreted to indicate significant control being exerted on flux at the stage of thiolysis either directly by means of CoA availability, or indirectly by means of the rate of acetyl-CoA generation.

Solubilization and separation of two distinct carnitine acyltransferases from hepatic microsomes: characterization of the malonyl-CoA-sensitive enzyme.

Conditions have been developed for the solubilization of hepatic microsomal carnitine acyltransferase activity in good yield, with excellent long-term stability and with retention of malonyl-CoA sensitivity. Solubilized microsomal carnitine acyltransferase activity can be separated into malonyl-CoA-sensitive and -insensitive activities either by gel filtration on Superdex 200 or by anion-exchange chromatography on Resource Q. On gel filtration the apparent molecular masses of the malonyl-CoA-sensitive and -insensitive activities are approx. 300 kDa and 60 kDa respectively. The malonyl-CoA-sensitive and -insensitive activities have different fatty-acyl-chain-length specificities and different stabilities in the detergent octyl glucoside. Together these findings indicate that the malonyl-CoA-sensitive and -insensitive activities are due to different enzymes. The malonyl-CoA sensitivity of the inhibitable enzyme is markedly increased on reconstitution into soybean L-alpha-lecithin liposomes, demonstrating that phospholipids play a crucial role in the inhibition by this metabolite. Evidence is also provided that the malonyl-CoA-sensitive microsomal carnitine acyltransferase is a different enzyme from the malonyl-CoA-sensitive carnitine palmitoyltransferase found in the mitochondrial outer membrane. The possible physiological role of the two microsomal acyltransferases is discussed.