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Symptom
Drug
Enzyme
Compound
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Target Concepts:
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Query: EC:2.3.1.21 (
CPT
)
4,580
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The objective of this article is to review primary and secondary causes of carnitine deficiency, emphasizing recent advances in our knowledge of fatty acid oxidation. It is now understood that the cellular metabolism of fatty acids requires the cytosolic carnitine cycle and the mitochondrial beta-oxidation cycle. Carnitine is central to the translocation of the
long chain
acyl-CoAs across the inner mitochondrial membrane. The mitochondrial beta-oxidation cycle is composed of a newly described membrane-bound system and the classic matrix compartment system. Very long chain acyl-CoA dehydrogenase and the trifunctional enzyme complex are embedded in the inner mitochondrial membrane, and metabolize the
long chain
acyl-CoAs. The chain shortened acyl-CoAs are further degraded by the well-known system in the mitochondrial matrix. Numerous metabolic errors have been described in the two cycles of fatty acid oxidation; all are transmitted as autosomal recessive traits. Primary or secondary carnitine deficiency is present in all these clinical conditions except
carnitine palmitoyltransferase
type I and the classic adult form of
carnitine palmitoyltransferase
type II deficiency. The sole example of primary carnitine deficiency is the genetic defect involving the active transport across the plasmalemmal membrane. This condition responds dramatically to oral carnitine therapy. The secondary carnitine deficiencies respond less obviously to carnitine replacement. These conditions are managed by high carbohydrate, low fat frequent feedings, and vitamin/cofactor supplementation (eg, carnitine, glycine, and riboflavin). Medium chain triglycerides may be useful in the dietary management of patients with inborn errors of the cytosolic carnitine cycle or the mitochondrial membrane-bound
long chain
specific beta-oxidation system.
...
PMID:Primary and secondary carnitine deficiency syndromes. 857 70
The mechanism of the anti-anginal effect of perhexiline is unclear but appears to involve a shift in cardiac metabolism from utilization of fatty acid to that of carbohydrate. We tested the hypothesis that perhexiline inhibits the enzyme
carnitine palmitoyltransferase
-1 (CPT-1), which controls access of
long chain
fatty acids to the mitochondrial site of beta-oxidation. Perhexiline produced a concentration-dependent inhibition of
CPT
-1 in rat cardiac and hepatic mitochondria in vitro, with half-maximal inhibition (IC50) at 77 and 148 mumol/L, respectively. Amiodarone, another drug with anti-anginal properties, also inhibited cardiac
CPT
-1 (IC50 = 228 mumol/L). The rank order of potency for inhibition was malonyl-CoA > 4-hydroxyphenylglyoxylate (HPG) = perhexiline > amiodarone = monohydroxy-perhexiline. Kinetic analysis revealed competitive inhibition of cardiac and hepatic
CPT
-1 by perhexiline with respect to palmitoyl-CoA but non-competitive inhibition with respect to carnitine. Curvilinear Dixon plots generated "apparent inhibitory constant (Ki)" values for perhexiline, which indicated a greater sensitivity of the cardiac than the hepatic enzyme to inhibition by perhexiline. Perhexiline inhibition of
CPT
-1, unlike that of malonyl-CoA and HPG, was unaffected by pretreatment with the protease nagarse. These data establish for the first time that two agents with proven anti-anginal effects inhibit cardiac
CPT
-1. This action is likely to contribute to the anti-ischaemic effects of both perhexiline and amiodarone.
...
PMID:Inhibition of carnitine palmitoyltransferase-1 in rat heart and liver by perhexiline and amiodarone. 869 52
Juvenile visceral steatosis (JVS) mice have been reported to have systemic carnitine deficiency, and the carnitine concentration in the liver of JVS mice was markedly lower than that of controls (11.6 +/- 2.6 versus 393.5 +/- 56.4 nmol/g of wet liver). To evaluate the role of carnitine in mitochondrial beta-oxidation in liver, we examined the effects of carnitine on ketogenesis in perfused liver from control and JVS mice. In control mice, ketogenesis was increased by the infusion of 0.3 mM oleate, but not by L-carnitine. In contrast, although ketogenesis in JVS mice was not increased by the infusion of oleate, it was increased 2.5-fold by the addition of 1000 microM L-carnitine. Addition of 50, 100, and 200 microM L-carnitine increased ketogenesis in a dose-dependent manner. The infusion of 0.3 mM octanoate or butyrate increased ketogenesis in a carnitine-independent fashion in both control and JVS mice. These findings suggest that endogenous
long chain
fatty acids from accumulated triglycerides may be used as substrates in the presence of carnitine in JVS mice. The relationship between ketogenesis and free carnitine concentration was examined in livers from JVS mice. Ketogenesis increased as free carnitine levels increased until concentrations exceeded about 100 nmol/g of wet liver (340 microM). The free carnitine concentration required for half-maximal ketone body production in liver of JVS mice was 45 microM (13 nmol/g of wet liver), which corresponds to a K(m) value of
carnitine palmitoyltransferase I
. We conclude that carnitine is a rate-limiting factor for beta-oxidation in liver only when the carnitine level in liver is very low.
...
PMID:The effect of carnitine on ketogenesis in perfused livers from juvenile visceral steatosis mice with systemic carnitine deficiency. 921 45
The role of inhibition of the
CPT
enzymes responsible for accumulation of
long chain
acylcarnitines (LCAC) during hypoxia in the proximal tubule has not been previously examined. We have characterized
CPT
enzyme activities in mitochondrial fractions of rabbit proximal tubules. Malonyl CoA-sensitive CPT I activity (1.1 +/- 0.3 nmol/min/mg protein), and detergent-solubilized, malonyl CoA-insensitive CPT II activity (2.3 +/- 0.4 nmol/min/mg protein) were readily detected in proximal tubule mitochondrial fractions. Subjecting rabbit proximal tubules to various periods of hypoxia did not significantly change mitochondrial CPT I or CPT II activities. Thirty minutes of hypoxia resulted in an increase in lysophospholipid mass from 440 +/- 105 to 720 +/- 93 pmol/mg protein, N = 5, LCAC mass from 79 +/- 11 to 618 +/- 34 pmol/mg protein, N = 5, and lactate dehydrogenase (LDH) release from 9 +/- 1% to 46 +/- 3%, N = 8. Pretreatment of proximal tubules with two different
CPT
inhibitors, glybenclamide (Glyb) 400 microM and oxfenicine (Oxfe) 1 mM, resulted in reduction in the magnitude of hypoxia-induced lysophospholipid formation 490 +/- 160 (Glyb), 342 +/- 150 pmol/mg protein (Oxfe), N = 4, hypoxia-induced LCAC formation 295 +/- 27 (Glyb), 128 +/- 16 pmol/mg protein (Oxfe). N = 5, and LDH release 25 +/- 1% (Glyb) and 19 +/- 2% (Oxfe), N = 8. The protective effect of
CPT
inhibition was also associated with increased production of lactate suggesting the modulation of a substrate-mediated metabolic switch. Immunoblots demonstrated that hypoxia caused a time dependent hydrolysis of fodrin-alpha subunit and that
CPT
inhibition protected against hypoxia-induced fodrin proteolysis. These data suggest a unifying hypothesis that links phospholipase A2 (PLA2) activation, and hypoxia-mediated fodrin proteolysis to the proximal tubule mitochondrial
CPT
system. I propose that
CPT
inhibition may represent a novel mechanism to ameliorate proximal tubule cell death during hypoxia.
...
PMID:Carnitine palmitoyl-transferase enzyme inhibition protects proximal tubules during hypoxia. 926 98
Carnitine palmitoyltransferase-I (CPT-I) plays a crucial role in regulating cardiac fatty acid oxidation which provides the primary source of energy for cardiac muscle contraction.
CPT
-I catalyzes the transfer of
long chain
fatty acids into mitochondria and is recognized as the primary rate controlling step in fatty acid oxidation. Molecular cloning techniques have demonstrated that two
CPT
-I isoforms exist as genes encoding the 'muscle' and 'liver' enzymes. Regulation of fatty acid oxidation rates depends on both short-term regulation of enzyme activity and long-term regulation of enzyme synthesis. Most early investigations into metabolic control of fatty acid oxidation at the
CPT
-I step concentrated on the hepatic enzyme which can be inhibited by malonyl-CoA and can undergo dramatic amplification or reduction of its sensitivity to inhibition by malonyl-CoA. The muscle
CPT
-I is inherently more sensitive to malonyl-CoA inhibition but has not been found to undergo any alteration of its sensitivity. Short-term control of activity of muscle
CPT
-I is apparently regulated by malonyl-CoA concentration in response to fuel supply (glucose, lactate, pyruvate and ketone bodies). The liver isoform is the only
CPT
-I enzyme present in the mitochondria of liver, kidney, brain and most other tissues while muscle
CPT
-I is the sole isoform expressed in skeletal muscle as well as white and brown adipocytes. The heart is unique in that it contains both muscle and liver isoforms. Liver
CPT
-I is highly expressed in the fetal heart, but at birth its activity begins to decline whereas the muscle isoform, which is very low at birth, becomes the predominant enzyme during postnatal development. In this paper, the differential regulation of the two
CPT
-I isoforms at the protein and the gene level will be discussed.
...
PMID:Differential regulation in the heart of mitochondrial carnitine palmitoyltransferase-I muscle and liver isoforms. 954 27
Carnitine palmitoyltransferases 1 and 2 (
CPT
-1 and
CPT
-2) catalyze the transfer of
long chain
fatty acids between carnitine and coenzyme A. Unlike
CPT
-2,
CPT
-1 exists in at least two isoforms with different physical and kinetic properties. Liver and skeletal muscle each contain a different isoform of
CPT
-1. Cardiac muscle contains both isoforms, and the minor component is identical to the isoform found in the liver. 2-[6-(2,4-Dinitrophenoxy)hexyl]oxiranecarboxylic acid (2) was reported to be a selective inhibitor for the liver isoform of
CPT
-1. A synthesis of 2 is described here which involves the reaction of diethyl malonate with 1-bromo-6-phenoxyhexane.
...
PMID:Synthesis of 2-[6-(2,4-dinitrophenoxy)hexyl]oxiranecarboxylic acid: a selective carnitine palmitoyltransferase-1 inhibitor. 988 Nov 3
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.
...
PMID:Selective modulation of carnitine long-chain acyltransferase activities. Kinetics, inhibitors, and active sites of COT and CPT-II. 1070 33
Carnitine palmitoyltransferase I (CPT-I) catalyzes the transfer of
long chain
fatty acyl groups from CoA to carnitine for translocation across the mitochondrial inner membrane.
CPT
-Ialpha is a key regulatory enzyme in the oxidation of fatty acids in the liver.
CPT
-Ialpha is expressed in all tissues except skeletal muscle and adipose tissue, which express
CPT
-Ibeta. Expression of
CPT
-Ialpha mRNA and enzyme activity are elevated in the liver in hyperthyroidism, fasting, and diabetes.
CPT
-Ialpha mRNA abundance is increased 40-fold in the liver of hyperthyroid compared with hypothyroid rats. Here, we examine the mechanisms by which thyroid hormone (T3) stimulates
CPT
-Ialpha gene expression. Four potential T3 response elements (TRE), which contain direct repeats separated by four nucleotides, are located 3000-4000 base pairs 5' to the start site of transcription in the
CPT
-Ialpha gene. However, only one of these elements functions as a TRE. This TRE binds the T3 receptor as well as other nuclear proteins. Surprisingly, the first intron of the
CPT
-Ialpha gene is required for the T3 induction of
CPT
-Ialpha expression, but this region of the gene does not contain a TRE. In addition, we show that
CPT
-Ialpha is induced by T3 in cell lines of hepatic origin but not in nonhepatic cell lines.
...
PMID:Thyroid hormone regulates carnitine palmitoyltransferase Ialpha gene expression through elements in the promoter and first intron. 1095 41
It is well established that medium and
long chain
(+)-acylcarnitines (i.e. fatty acid esters of the unnatural d-isomer of carnitine) inhibit the oxidation of
long chain
fatty acids in mammalian tissues by interfering with some component(s) of the mitochondrial
carnitine palmitoyltransferase
(
CPT
) system. However, whether their site of action is at the level of CPT I (outer membrane), CPT II (inner membrane), carnitine-acylcarnitine translocase (CACT, inner membrane), or some combination of these elements has never been resolved. We chose to readdress this question using rat liver mitochondria and employing a variety of assays that distinguish between the three enzyme activities. The effect on each of (+)-acetylcarnitine, (+)-hexanoylcarnitine, (+)-octanoylcarnitine, (+)-decanoylcarnitine, and (+)-palmitoylcarnitine was examined. Contrary to longstanding belief, none of these agents was found to impact significantly upon the activity of CPT I or CPT II. Whereas (+)-acetylcarnitine also failed to influence CACT, both (+)-octanoylcarnitine and (+)-palmitoylcarnitine strongly inhibited this enzyme with a similar IC(50) value ( approximately 35 microm) under the assay conditions employed. Remarkably, (+)-decanoylcarnitine was even more potent (IC(50) approximately 5 microm), whereas (+)-hexanoylcarnitine was far less potent (IC(50) >200 microm). These findings resolve a 35-year-old puzzle by establishing unambiguously that medium and
long chain
(+)-acylcarnitines suppress mitochondrial fatty acid transport solely through the inhibition of the CACT component. They also reveal a surprising rank order of potency among the various (+)-acylcarnitines in this respect and should prove useful in the design of future experiments in which selective blockade of CACT is desired.
...
PMID:Elucidation of the mechanism by which (+)-acylcarnitines inhibit mitochondrial fatty acid transport. 1098 94
To examine the relationship between mitochondrial energy coupling in skeletal muscle and change in uncoupling protein 3 (UCP3) expression during the transition from the fed to fasted state, we used a novel noninvasive (31)P/(13)C NMR spectroscopic approach to measure the degree of mitochondrial energy coupling in the hind limb muscles of awake rats before and after a 48-h fast. Compared with fed levels, UCP3 mRNA and protein levels in the gastrocnemius increased 1.7- (p < 0.01) and 2.9-fold (p < 0.001), respectively, following a 48-h fast. Tricarboxylic acid cycle flux measured using (13)C NMR as an index of mitochondrial substrate oxidation was 212 +/- 23 and 173 +/- 25 nmol/g/min (p not significant) in the fed and 48-h fasted groups, respectively. Unidirectional ATP synthesis flux measured using (31)P NMR was 79 +/- 15 and 57 +/- 9 nmol/g/s (p not significant) in the fed and 48-h fasted groups, respectively. Mitochondrial energy coupling as expressed by the ratio of ATP synthesis to tricarboxylic acid cycle flux was not different between the fed and fasted states. To test the hypothesis that UCP3 may be involved in the translocation of
long chain
free fatty acids (FFA) into the mitochondrial matrix under conditions of elevated FFA availability, [U-(13)C]palmitate/albumin was administered in a separate group of rats with (+) or without (-) etomoxir (an inhibitor of
carnitine palmitoyltransferase I
). The ratio of glutamate enrichment ((+) etomoxir/(-) etomoxir) in the hind limb muscles was the same between groups, indicating that UCP3 does not appear to function as a translocator for
long chain
FFA in skeletal muscle following a 48-h fast. In summary, these data demonstrate that despite a 2-3-fold increase in UCP3 mRNA and protein expression in skeletal muscle during the transition from the fed to fasted state, mitochondrial energy coupling does not change. Furthermore, UCP3 does not appear to have a major role in FFA translocation into the mitochondria. The physiological role of UCP3 following a 48-h fast in skeletal muscle remains to be elucidated.
...
PMID:13C/31P NMR assessment of mitochondrial energy coupling in skeletal muscle of awake fed and fasted rats. Relationship with uncoupling protein 3 expression. 1099 75
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