Hepatic mitochondrial inner-membrane properties, beta-oxidation and carnitine palmitoyltransferases A and B. Effects of genetic obesity and starvation.

Hepatic mitochondrial carnitine palmitoyltransferase (CPT) properties, beta-oxidation of palmitoyl-CoA and membrane polarization were measured in lean and obese Zucker rats. The Vmax. of the 'outer' carnitine palmitoyltransferase ('CPT-A') increased with starvation, with no change in the Km for either carnitine or palmitoyl-CoA. The Ki for malonyl-CoA increased with starvation in lean rats, but not in obese rats. The Vmax. of the 'inner' enzyme ('CPT-B'), as measured by using inverted submitochondrial vesicles, increased with starvation in obese rats only, with no change in the Km for either carnitine or palmitoyl-CoA. The Ki for malonyl-CoA was 2-5-fold higher in inverted vesicles than in intact mitochondria, and showed no alteration with starvation. The activities of both enzymes correlated positively with each other and with beta-oxidation, and inversely with membrane polarization. Malonyl-CoA had little effect on gross membrane fluidity in the Zucker rat, as reflected by diphenylhexatriene fluorescence polarization. The results indicate that both enzymes are related and respond similarly to alterations in membrane fluidity. Membrane fluidity may provide a mechanism for co-ordinated control of CPT activity on both sides of the mitochondrial inner membrane.     

Action in vivo and in vitro of 2-tetradecylglycidic acid, 2-tetradecylglycidyl-CoA and 2-tetradecylglycidylcarnitine on hepatic carnitine palmitoyltransferase.

The effects of 2-tetradecylglycidic acid (TDGA), TDGA-CoA and TDGA-carnitine were examined in purified hepatic CPT (carnitine palmitoyltransferase) and in hepatic mitochondria and inverted submitochondrial vesicles derived from Sprague-Dawley rats. Since TDGA has been reported as a specific inhibitor of carnitine palmitoyltransferase-A (CPT-A), the focus was on kinetics and inhibition of CPT-A, and the relationship of this key enzyme to beta-oxidation. After administration of TDGA in vivo to overnight-starved rats, the Vmax. of CPT in intact mitochondria and in inverted vesicles (CPT-B) was depressed by 66%. The S0.5 for palmitoyl-CoA and Km for carnitine were unchanged. The I50 (concn. giving 50% inhibition) for malonyl-CoA was significantly increased from 20 to 141 microM in intact mitochondria, but unchanged (199 versus 268 microM) in inverted vesicles. The addition in vitro of TDGA-CoA (0-1.0 microM) gave I50 values of 0.29 and 0.27 microM (S.E.M. = 0.19) in intact mitochondria from fed and 48 h-starved rats, and 0.81 and 1.57 microM (S.E.M. = 0.29) for inverted vesicles derived from fed and starved rats. Addition in vitro of TDGA-carnitine to mitochondria from starved rats yielded an I50 value of 27.7 mM (S.E.M. = 12.2) for L-[methyl-14C]carnitine release from palmitoyl-L-[methyl-14C]carnitine and 0.64 mM (S.E.M. = 0.07) for palmitoyl-L-[methyl-14C]carnitine formation from L-[methyl-14C]carnitine in intact mitochondria. Inverted vesicles were not measurably sensitive to TDGA-carnitine up to 500 microM for the assay of L-[methyl-14C]carnitine release, but were as sensitive as intact mitochondria when inhibition was determined in the direction of palmitoyl-L-[methyl-14C]carnitine formation (I50 = 0.54 +/- 0.07 microM). When TDGA-CoA was added to intact mitochondria, then incubated for 5 min at room temperature and subsequently washed out, Vmax. of CPT decreased from 5.8 to 3.5 (S.E.M. = 0.6) in intact mitochondria, and from 17.2 to 6.3 (S.E.M. = 4.8) in inverted vesicles. The Km for L-carnitine and the S0.5 for palmitoyl-CoA increased 2-fold with TDGA-CoA pretreatment in both intact mitochondria and inverted vesicles. Detergent solubilization (0.05% Triton X-100) resulted in a complete loss of TDGA-CoA sensitivity (up to 1.0 microM measured). Sonicated mitochondria exhibited an I50 of 0.72 +/- 0.03 microM.(ABSTRACT TRUNCATED AT 400 WORDS)     

Interacting effects of L-carnitine and malonyl-CoA on rat liver carnitine palmitoyltransferase.

Malonyl-CoA significantly increased the Km for L-carnitine of overt carnitine palmitoyltransferase in liver mitochondria from fed rats. This effect was observed when the molar palmitoyl-CoA/albumin concentration ratio was low (0.125-1.0), but not when it was higher (2.0). In the absence of malonyl-CoA, the Km for L-carnitine increased with increasing palmitoyl-CoA/albumin ratios. Malonyl-CoA did not increase the Km for L-carnitine in liver mitochondria from 24h-starved rats or in heart mitochondria from fed animals. The Km for L-carnitine of the latent form of carnitine palmitoyltransferase was 3-4 times that for the overt form of the enzyme. At low ratios of palmitoyl-CoA/albumin (0.5), the concentration of malonyl-CoA causing a 50% inhibition of overt carnitine palmitoyltransferase activity was decreased by 30% when assays with liver mitochondria from fed rats were performed at 100 microM-instead of 400 microM-carnitine. Such a decrease was not observed with liver mitochondria from starved animals. L-Carnitine displaced [14C]malonyl-CoA from liver mitochondrial binding sites. D-Carnitine was without effect. L-Carnitine did not displace [14C]malonyl-CoA from heart mitochondria. It is concluded that, under appropriate conditions, malonyl-CoA may decrease the effectiveness of L-carnitine as a substrate for the enzyme and that L-carnitine may decrease the effectiveness of malonyl-CoA to regulate the enzyme.     

Effects of thyroidectomy and starvation on the activity and properties of hepatic carnitine palmitoyltransferase.

1. Hepatic carnitine palmitoyltransferase activity was measured over a range of concentrations of palmitoyl-CoA and in the presence of several concentrations of the inhibitor malonyl-CoA. These measurements were made in mitochondria obtained from the livers of fed and starved (24 h) normal rats and of fed and starved thyroidectomized rats. 2. In the fed state thyroidectomy substantially decreased overt carnitine palmitoyltransferase activity and also decreased both the Hill coefficient and the s0.5 when palmitoyl-CoA concentration was varied as substrate. Thyroidectomy did not appreciably alter the inhibitory effect of malonyl-CoA on the enzyme. 3. Starvation increased overt carnitine palmitoyltransferase activity in both the fed and the thyroidectomized state. In percentage terms this response to starvation was substantially greater after thyroidectomy. In both the hypothyroid and normal states starvation decreased sensitivity to inhibition by malonyl-CoA.     

Rat liver mitochondrial carnitine palmitoyltransferase-I, hepatic carnitine, and malonyl-CoA: effect of starvation

Hepatic mitochondrial fatty acid oxidation and ketogenesis increase during starvation. Carnitine palmitoyltransferase I (CPT-I) catalyses the rate-controlling step in the overall pathway and retains its control over beta-oxidation under fed, starved and diabetic conditions. To determine the factors contributing to the reported several-fold increase in fatty acid oxidation in perfused livers, we measured the V(max) and K(m) values for palmitoyl-CoA and carnitine, the K(i) (and IC(50)) values for malonyl-CoA in isolated liver mitochondria as well as the hepatic malonyl-CoA and carnitine contents in control and 48 h starved rats. Since CPT-I is localized in the mitochondrial outer membrane and in contact sites, the kinetic properties of CPT-I also was determined in these submitochondrial structures. After 48 h starvation, there is: (a) a significant increase in K(i) and decrease in hepatic malonyl-CoA content; (b) a decreased K(m) for palmitoyl-CoA; and (c) increased catalytic activity (V(max)) and CPT-I protein abundance that is significantly greater in contact sites compared with outer membranes. Based on these changes the estimated increase in mitochondrial fatty acid oxidation is significantly less than that observed in perfused liver. This suggests that CPT-I is regulated in vivo by additional mechanism(s) lost during mitochondrial isolation or/and that mitochondrial oxidation of peroxisomal beta-oxidation products contribute to the increased ketogenesis by bypassing CPT-I. Furthermore, the greater increase in CPT-I protein in contact sites as compared to outer membranes emphasizes the significance of contact sites in hepatic fatty acid oxidation.     

Response to starvation of hepatic carnitine palmitoyltransferase activity and its regulation by malonyl-CoA. Sex differences and effects of pregnancy.

1. Hepatic carnitine palmitoyltransferase activity was measured over a range of concentrations of palmitoyl-CoA and in the presence of several concentrations of the inhibitor malonyl-CoA. These measurements were made in mitochondria obtained from the livers of fed and starved (24 h) virgin female and fed and starved pregnant rats. 2. In the fed state overt carnitine palmitoyltransferase activity was significantly lower in virgin females than in age-matched male rats. 3. Starvation increased overt carnitine palmitoyltransferase activity in both virgin and pregnant females. This increase was larger than in the male and was greater in pregnant than in virgin females. 4. In the fed state pregnancy had no effect on the Hill coefficient or the [S]0.5 when palmitoyl-CoA was varied as substrate. Pregnancy did not alter the sensitivity of the enzyme to inhibition by malonyl-CoA. 5. Starvation decreased the sensitivity of the enzyme to malonyl-CoA. The change in sensitivity was similar in male, virgin female and pregnant rats. 6. The possible relevance of these findings to known sex differences and changes with pregnancy in hepatic fatty acid oxidation and esterification are discussed.     

Observations on the affinity for carnitine, and malonyl-CoA sensitivity, of carnitine palmitoyltransferase I in animal and human tissues. Demonstration of the presence of malonyl-CoA in non-hepatic tissues of the rat.

The requirement for carnitine and the malonyl-CoA sensitivity of carnitine palmitoyl-transferase I (EC 2.3.1.21) were measured in isolated mitochondria from eight tissues of animal or human origin using fixed concentrations of palmitoyl-CoA (50 microM) and albumin (147 microM). The Km for carnitine spanned a 20-fold range, rising from about 35 microM in adult rat and human foetal liver to 700 microM in dog heart. Intermediate values of increasing magnitude were found for rat heart, guinea pig liver and skeletal muscle of rat, dog and man. Conversely, the concentration of malonyl-CoA required for 50% suppression of enzyme activity fell from the region of 2-3 microM in human and rat liver to only 20 nM in tissues displaying the highest Km for carnitine. Thus, the requirement for carnitine and sensitivity to malonyl-CoA appeared to be inversely related. The Km of carnitine palmitoyltransferase I for palmitoyl-CoA was similar in tissues showing large differences in requirement for carnitine. Other experiments established that, in addition to liver, heart and skeletal muscle of fed rats contain significant quantities of malonyl-CoA and that in all three tissues the level falls with starvation. Although its intracellular location in heart and skeletal muscle is not known, the possibility is raised that malonyl-CoA (or a related compound) could, under certain circumstances, interact with carnitine palmitoyltransferase I in non-hepatic tissues and thereby exert control over long chain fatty acid oxidation.     

Studies on the activation in vitro of carnitine palmitoyltransferase I in liver mitochondria from normal, diabetic and glucagon-treated rats.

The activation of overt carnitine palmitoyltransferase activity that occurs when rat liver mitochondria are incubated at near-physiological temperatures and ionic strengths was studied for mitochondria obtained from animals in different physiological states. In all instances, it was found to be due exclusively to an increase in the catalytic capacity of the enzyme and not to an increase in affinity of the enzyme for palmitoyl-CoA. The enzyme in mitochondria from fed animals always showed a larger degree of activation than that in mitochondria from starved animals. This was the case even for mitochondria (e.g. from fed diabetic animals) in which the kinetic characteristics of carnitine palmitoyltransferase were more similar to those for the enzyme in mitochondria from starved rats. Glucagon treatment of rats before isolation of the mitochondria did not affect the characteristics either of the kinetic parameters of overt carnitine palmitoyltransferase or of its activation in vitro.     

Effect of malonyl-CoA on the kinetics and substrate cooperativity of membrane-bound carnitine palmitoyltransferase of rat heart mitochondria

The effect of malonyl-CoA on the kinetic parameters of carnitine palmitoyltransferase (outer) the outer form of carnitine palmitoyltransferase (palmitoyl-CoA: L-carnitine O-palmitoyltransferase, EC 2.3.1.21) from rat heart mitochondria was investigated using a kinetic analyzer in the absence of bovine serum albumin with non-swelling conditions and decanoyl-CoA as the cosubstrate. The K0.5 for decanoyl-CoA is 3 microM for heart mitochondria from both fed and fasted rats. Membrane-bound carnitine palmitoyltransferase (outer) shows substrate cooperativity for both carnitine and acyl-CoA, similar to that exhibited by the enzyme purified from bovine heart mitochondria. The Hill coefficient for decanoyl-CoA varied from 1.5 to 2.0, depending on the method of assay and the preparation of mitochondria. Malonyl-CoA increased the K0.5 for decanoyl-CoA with no apparent increase in sigmoidicity or Vmax. With 20 microM malonyl-CoA and a Hill coefficient of n = 2.1, the K0.5 for decanoyl-CoA increased to 185 microM. Carnitine palmitoyltransferase (outer) from fed rats had an apparent Ki for malonyl-CoA of 0.3 microM, while that from 48-h-fasted rats was 2.5 microM. The kinetics with L-carnitine were variable: for different preparations of mitochondria, the K0.5 ranged from 0.2 to 0.7 mM and the Hill coefficient varied from 1.2 to 1.8. When an isotope forward assay was used to determine the effect of malonyl-CoA on carnitine palmitoyltransferase (outer) activity of heart mitochondria from fed and fasted animals, the difference was much less than that obtained using a continuous rate assay. Carnitine palmitoyltransferase (outer) was less sensitive to malonyl-CoA at low compared to high carnitine concentrations, particularly with mitochondria from fasted animals. The data show that carnitine palmitoyltransferase (outer) exhibits substrate cooperativity for both acyl-CoA and L-carnitine in its native state. The data show that membrane-bound carnitine palmitoyltransferase (outer) like carnitine palmitoyltransferase purified from heart mitochondria exhibits substrate cooperativity indicative of allosteric enzymes and indicate that malonyl-CoA acts like a negative allosteric modifier by shifting the acyl-CoA saturation to the right. A slow form of membrane-bound carnitine palmitoyltransferase (outer) was not detected, and thus, like purified carnitine palmitoyltransferase, substrate-induced hysteretic behavior is not the cause of the positive substrate cooperativity.     

Differential inhibition of ketogenesis by malonyl-CoA in mitochondria from fed and starved rats.

Rates of ketogenesis in mitochondria from fed or starved rats were identical at optimal substrate concentrations, but responded differently to inhibition by malonyl-CoA. Kinetic data suggest that the K1 for malonyl-CoA is greater in the starved animal. These results indicate that, for the regulation of ketogenesis in the starved state, the lower sensitivity of carnitine palmitoyltransferase to inhibition by malonyl-CoA may be more important than the concentration of malonyl-CoA.     

Carnitine acyltransferase activities in rat brain mitochondria. Bimodal distribution, kinetic constants, regulation by malonyl-CoA and developmental pattern.

Carnitine palmitoyltransferase and carnitine octanoyltransferase activities in brain mitochondrial fractions were approx. 3-4-fold lower than activities in liver. Estimated Km values of CPT1 and CPT2 (the overt and latent forms respectively of carnitine palmitoyltransferase) for L-carnitine were 80 microM and 326 microM, respectively, and K0.5 values for palmitoyl-CoA were 18.5 microM and 12 microM respectively. CPT1 activity was strongly inhibited by malonyl-CoA, with I50 values (concn. giving 50% of maximum inhibition) of approx. 1.5 microM. In the absence of other ligands, [2-14C]malonyl-CoA bound to intact brain mitochondria in a manner consistent with the presence of two independent classes of binding sites. Estimated values for KD(1), KD(2), N1 and N2 were 18 nM, 27 microM, 1.3 pmol/mg of protein and 168 pmol/mg of protein respectively. Neither CPT1 activity, nor its sensitivity towards malonyl-CoA, was affected by 72 h starvation. Rates of oxidation of palmitoyl-CoA (in the presence of L-carnitine) or of palmitoylcarnitine by non-synaptic mitochondria were extremely low, indicating that neither CPT1 nor CPT2 was likely to be rate-limiting for beta-oxidation in brain. CPT1 activity relative to mitochondrial protein increased slightly from birth to weaning (20 days) and thereafter decreased by approx. 50%.     

Interaction of malonyl-CoA and 2-tetradecylglycidyl-CoA with mitochondrial carnitine palmitoyltransferase I

Malonyl-CoA and 2-tetradecylglycidyl-CoA (TG-CoA) are potent inhibitors of mitochondrial carnitine palmitoyltransferase I (EC 2.3.1.21). To gain insight into their mode of action, the effects of both agents on mitochondria from rat liver and skeletal muscle were examined before and after membrane disruption with octylglucoside or digitonin. Pretreatment of intact mitochondria with TG-CoA caused almost total suppression of carnitine palmitoyltransferase I, with concomitant loss in malonyl-CoA binding capacity. However, subsequent membrane solubilization with octylglucoside resulted in high and equal carnitine palmitoyltransferase activity from control and TG-CoA pretreated mitochondria; neither solubilized preparation showed sensitivity to malonyl-CoA or TG-CoA. Upon removal of the detergent by dialysis the bulk of carnitine palmitoyltransferase was reincorporated into membrane vesicles, but the reinserted enzyme remained insensitive to both inhibitors. Carnitine palmitoyltransferase containing vesicles failed to bind malonyl-CoA. With increasing concentrations of digitonin, release of carnitine palmitoyltransferase paralleled disruption of the inner mitochondrial membrane, as reflected by the appearance of matrix enzymes in the soluble fraction. The profile of enzyme release was identical in control and TG-CoA pretreated mitochondria even though carnitine palmitoyltransferase I had been initially suppressed in the latter. Similar results were obtained when animals were treated with 2-tetradecylglycidate prior to the preparation of liver mitochondria. We conclude that malonyl-CoA and TG-CoA interact reversibly and irreversibly, respectively, with a common site on the mitochondrial (inner) membrane and that occupancy of this site causes inhibition of carnitine palmitoyltransferase I, but not of carnitine palmitoyltransferase II. Assuming that octylglucoside and digitonin do not selectively inactivate carnitine palmitoyltransferase I, the data suggest that both malonyl-CoA and TG-CoA interact with a regulatory locus that is closely juxtaposed to but distinct from the active site of the membrane-bound enzyme.     

Altered sensitivity of carnitine palmitoyltransferase to inhibition by malonyl-CoA in ketotic diabetic rats.

Carnitine palmitoyltransferase of liver mitochondria prepared from ketotic diabetic rats has a diminished sensitivity to inhibition by malonyl-CoA compared with carnitine palmitoyltransferase of mitochondria prepared from normal fed rats.     

Carnitine acyltransferase activities in rat liver and heart measured with palmitoyl-CoA and octanoyl-CoA. Latency, effects of K+, bivalent metal ions and malonyl-CoA.

1. Liver carnitine acyltransferase activities with palmitoyl-CoA and octanoyl-CoA as substrates and heart carnitine palmitoyltransferase were measured as overt activities in whole mitochondria or in mitochondria disrupted by sonication or detergent treatment. All measurements were made in sucrose/KCl-based media of 300 mosmol/litre. 2. In liver mitochondria, acyltransferase measured with octanoyl-CoA, like carnitine palmitoyltransferase, was found to have latent and overt activities. 3. Liver acyltransferase activities measured with octanoyl-CoA and palmitoyl-CoA differed in their response to changes in [K+], Triton X-100 treatment and, in particular, in their response to Mg2+. Mg2+ stimulated activity with octanoyl-CoA, but inhibited carnitine palmitoyltransferase. 4. The effects of K+ and Mg2+ on liver overt carnitine palmitoyltransferase activity were abolished by Triton X-100 treatment. 5. Heart overt carnitine palmitoyltransferase activity differed from the corresponding activity in liver in that it was more sensitive to changes in [K+] and was stimulated by Mg2+. Heart had less latent carnitine palmitoyltransferase activity than did liver. 6. Overt carnitine palmitoyltransferase in heart mitochondria was extremely sensitive to inhibition by malonyl-CoA. Triton X-100 abolished the effect of low concentrations of malonyl-CoA on this activity. 7. The inhibitory effect of malonyl-CoA on heart carnitine palmitoyltransferase could be overcome by increasing the concentration of palmitoyl-CoA.     

Differences in the sensitivity of carnitine palmitoyltransferase to inhibition by malonyl-CoA are due to differences in Ki values

The hepatic carnitine palmitoyltransferase that is present on the outer surface of the mitochondrial inner membrane demonstrates hyperbolic substrate saturation curves with oleoyl-CoA in both fasted and fed rats. However, the addition of malonyl-CoA resulted in sigmoid substrate saturation curves, suggesting that malonyl-CoA induced the cooperative behavior. There was more of the outer carnitine palmitoyltransferase in liver mitochondria derived from fasted rats and that enzyme had a much greater Ki for malonyl-CoA than the enzyme from fed rats, but the Km values were apparently not different. The Dixon plot with mitochondria from fed rats, but not fasted rats, was curved upward, indicating cooperative inhibition by malonyl-CoA. Carnitine palmitoyltransferase of heart mitochondria had a Ki for malonyl-CoA that was much less than that of the liver enzyme and it did not change on fasting. Furthermore, no evidence for cooperative inhibition was found in the heart. The results of these studies indicate that carnitine palmitoyltransferase is not subject to substrate cooperativity and that malonyl-CoA is not a simple competitive inhibitor of this enzyme but inhibits by a mechanism involving cooperative inhibition. The fasting-feeding cycle induces changes in the liver enzyme that alter its affinity for malonyl-CoA without changing its affinity for its acyl-CoA substrate. Carnitine palmitoyltransferase from heart appears to be different from that of liver and is apparently not subject to the same control mechanisms.     

Characterization of hepatic carnitine palmitoyltransferase. Use of bromoacyl derivatives and antibodies.

Carnitine palmitoyltransferase (CPT) is a mitochondrial-inner-membrane enzyme, with activities located on both the outer and inner sides of the membrane. The inhibition of CPT by bromopalmitate derivatives was studied in intact hepatic mitochondria (representing CPT-A activity, the outer enzyme), in inverted submitochondrial vesicles (representing CPT-B, the inner enzyme), and in purified hepatic CPT. Bromopalmitoyl-CoA had an I50 (concentration giving 50% inhibition of CPT activity) of 0.63 +/- 0.08 microM in intact mitochondria and 2.44 +/- 0.86 microM in inverted vesicles. Preincubation of mitochondria with bromopalmitoyl-CoA decreased V max. for both CPT-A and CPT-B. Sonication decreased sensitivity to bromopalmitoyl-CoA, and solubilization with Triton abolished sensitivity at the concentrations used (0-10 microM). Purified CPT had a bromopalmitoyl-CoA I50 of 353 microM in aqueous buffer, 67 microM in 20% dimethyl sulphoxide, 45 microM in phosphatidylcholine liposomes and 26 microM in cardiolipin liposomes. Increasing [carnitine] at constant bromopalmitoyl-CoA concentrations or increasing [bromopalmitoyl-CoA] in the preincubation resulted in increased inhibition of purified CPT. 2-Tetradecylglycidyl-CoA and malonyl-CoA did not offer measurable protection against bromopalmitoyl-CoA inhibition of the purified CPT, suggesting a different site of interaction of bromopalmitoyl-CoA with CPT. The data suggest that the sensitivity of CPT to bromopalmitoyl-CoA may be modulated by membrane environment and assay conditions.     

Effect of starvation and diabetes on the sensitivity of carnitine palmitoyltransferase I to inhibition by 4-hydroxyphenylglyoxylate.

The sensitivity of carnitine palmitoyltransferase I to inhibition by 4-hydroxyphenylglyoxylate was decreased markedly in liver mitochondria isolated from either 48 h-starved or streptozotocin-diabetic rats. These treatments of the rat also decreased the sensitivity of fatty acid oxidation by isolated hepatocytes to inhibition by this compound. Furthermore, incubation of hepatocytes prepared from fed rats with N6O2'-dibutyryl cyclic AMP also decreased the sensitivity, whereas incubation of hepatocytes prepared from starved rats with lactate plus pyruvate had the opposite effect on 4-hydroxyphenylglyoxylate inhibition of fatty acid oxidation. The sensitivity of carnitine palmitoyltransferase I of mitochondria to 4-hydroxyphenylglyoxylate increased in a time-dependent manner, as previously reported for malonyl-CoA. Likewise, oleoyl-CoA activated carnitine palmitoyltransferase I in a time-dependent manner and prevented the sensitization by 4-hydroxyphenylglyoxylate. Increased exogenous carnitine caused a moderate increase in fatty acid oxidation by hepatocytes under some conditions and a decreased 4-hydroxyphenylglyoxylate inhibition of fatty acid oxidation at low oleate concentration, without decreasing the difference in 4-hydroxyphenylglyoxylate inhibition between fed- and starved-rat hepatocytes. Time-dependent changes in the conformation of carnitine palmitoyltransferase I or the membrane environment may be involved in differences among nutritional states in 4-hydroxyphenylglyoxylate-sensitivity of carnitine palmitoyltransferase I.     

Carnitine palmitoyltransferase. Activation by palmitoyl-CoA and inactivation by malonyl-CoA

Extraction of rat liver mitochondria twice with 0.5% Triton X-100 in a salt-free medium leaves less than 10% of the carnitine palmitoyltransferase membrane bound. The remaining membrane-bound enzyme is inhibited virtually completely by 10 microM malonyl-CoA. Preincubation of the extracted membranes with palmitoyl-CoA and salts (KCI) for several minutes activates the enzyme and makes it increasingly insensitive to malonyl-CoA. Addition of malonyl-CoA to the preincubation reverses this desensitization. In albumin-containing media salts also decrease the binding of palmitoyl-CoA to albumin and stimulate carnitine palmitoyltransferase by increasing substrate availability in free solution. The reverse reaction shows accelerated desensitization by palmitoylcarnitine and resensitization by malonyl-CoA.     

Sigmoid kinetics of purified beef heart mitochondrial carnitine palmitoyltransferase. Effect of pH and malonyl-CoA

The kinetics of purified beef heart mitochondrial carnitine palmitoyltransferase have been extensively investigated with a semiautomated system and the computer program TANKIN and shown to be sigmoidal with both acyl-CoA and L-carnitine. In contrast, Michaelis-Menten kinetics were found with carnitine octanoyltransferase. The catalytic activity of carnitine palmitoyltransferase is strongly pH dependent. The K0.5 and Vmax are both greater at lower pH. The K0.5 for palmitoyl-CoA is 1.9 and 24.2 microM at pH 8 and 6, respectively. The K0.5 for L-carnitine is 0.2 and 2.9 mM at pH 8 and 6, respectively. Malonyl-CoA (20-600 microM) had no effect on the kinetic parameters for palmitoyl-CoA at both saturating and subsaturating levels of L-carnitine. We conclude that malonyl-CoA is not a competitive inhibitor of carnitine palmitoyltransferase. The purified enzyme contained 18.9 mol of bound phospholipid/mol of enzyme which were identified as cardiolipin, phosphatidylethanolamine, and phosphatidylcholine by thin-layer chromatography. The data are consistent with the conclusion that native carnitine palmitoyltransferase exhibits different catalytic properties on either side of the inner membrane of mitochondria due to its non-Michaelis-Menten kinetic behavior, which can be affected by pH differences and differences in membrane environment.     

Preventive effect of clofibrate on carnitine palmitoyltransferase I inhibition and mitochondrial membrane phospholipid depletion induced by galactosamine

We have previously reported that a D-galactosamine injection induces a decrease of carnitine palmitoyltransferase I activity correlated with a depletion of total phospholipid content in the mitochondrial membrane. The impact of a short-term clofibrate treatment on these membrane alterations is investigated, i.e., the kinetic properties of carnitine palmitoyltransferase I, including its sensitivity to malonyl-CoA and mitochondrial membrane content of the various phospholipids. A 4-day clofibrate treatment increases by 42% the apparent Km value of carnitine palmitoyltransferase I for palmitoyl-CoA, while the sensitivity of the enzyme to malonyl-CoA appears slightly decreased. Simultaneously, the cardiolipin content is increased by 70% in the mitochondrial membrane, whereas the phosphatidylethanolamine and phosphatidylcholine contents remain almost unaffected. This 4-day clofibrate treatment prevents the inhibition of carnitine palmitoyltransferase I activity subsequent to galactosamine administration but induces an increase in the apparent Km value for palmitoyl-CoA and a decrease of the sensitivity of the enzyme to malonyl-CoA. The contents of phospholipids which are decreased by galactosamine (phosphatidylcholine, -21%; phosphatidylethanolamine, -29%; cardiolipin, -40%) regain the control values when galactosamine administration is preceded by a clofibrate treatment. The data suggest that the clofibrate treatment counteracts the inhibition of activity of carnitine palmitoyltransferase I through the maintenance of mitochondrial membrane integrity.