Isabel Tavares de Almeida

Increased, homocysteine and S-adenosylhomocysteine concentrations and DNA hypomethylation in vascular disease

BACKGROUND The pathogenic mechanism of homocysteines effect on cardiovascular risk is poorly understood. Recent studies show that DNA hypomethylation induced by increases in S-adenosylhomocysteine (AdoHcy), an intermediate of Hcy metabolism and a potent inhibitor of methyltransferases, may be involved in homocysteine-related pathology. METHODS We measured fasting plasma total Hcy (tHcy), AdoHcy, and S-adenosylmethionine (AdoMet) and methylation in leukocytes in 17 patients with vascular disease and in 15 healthy, age- and sex-matched controls. RESULTS Patient with vascular disease had significantly higher plasma tHcy and AdoHcy concentrations and significantly lower plasma AdoMet/AdoHcy ratios and genomic DNA methylation. AdoMet concentrations were not significantly different between the two groups. More than 50% of the patients fell into the highest quartiles of plasma tHcy, AdoHcy, and [(3)H]dCTP incorporation/ micro g of DNA (meaning the lowest quartile of DNA methylation status) and into the lowest quartile of the AdoMet/AdoHcy ratios of the control group. Plasma tHcy was significantly correlated with plasma AdoHcy and AdoMet/AdoHcy ratios (n = 32; P < 0.001). DNA methylation status was significantly correlated with plasma tHcy and AdoHcy (n = 32; P < 0.01) but not with plasma AdoMet/AdoHcy ratios. CONCLUSION Global DNA methylation may be altered in vascular disease, with a concomitant increase in plasma tHcy and AdoHcy.

Quantitative acylcarnitine profiling in fibroblasts using [U-13C] palmitic acid: an improved tool for the diagnosis of fatty acid oxidation defects.

A method was developed for the investigation of mitochondrial fatty acid beta-oxidation in cultured fibroblasts. Monolayer cultures were incubated without foetal calf serum with commercially available [U-13C] palmitic acid and L-carnitine for 96 h. The acylcarnitines produced by the cells were extracted from the cell suspension and analysed either by quantitative stable isotope dilution gas chromatography chemical ionization mass spectrometry, or by fast atom bombardment mass spectrometry. Characteristic acylcarnitine profiles were obtained for all the different enzyme deficiencies investigated, with the exception of carnitine palmitoyltransferase II deficiency and carnitine/acylcarnitine carrier deficiency which showed similar patterns. Comparison between this method and the 3H-myristate and 3H-palmitate tritium release assays revealed that the method described here is superior, allowing unequivocal identification of patients.

New insights on the mechanisms of valproate-induced hyperammonemia: inhibition of hepatic N-acetylglutamate synthase activity by valproyl-CoA

BACKGROUND & AIMS Hyperammonemia is a frequent side-effect of valproic acid (VPA) therapy, which points to an imbalance between ammoniagenesis and ammonia disposal via the urea cycle. The impairment of this liver-specific metabolic pathway induced either by primary genetic defects or by secondary causes, namely associated with drugs administration, may result in accumulation of ammonia. To elucidate the mechanisms which underlie VPA-induced hyperammonemia, the aim of this study was to evaluate the effect of both VPA and its reactive intermediate, valproyl-CoA (VP-CoA), on the synthesis of N-acetylglutamate (NAG), a prime metabolite activator of the urea cycle. METHODS The amount of NAG in livers of rats treated with VPA was quantified by HPLC-MS/MS. The NAG synthase (NAGS) activity was evaluated in vitro in rat liver mitochondria, and the effect of both VPA and VP-CoA was characterized. RESULTS The present results clearly show that VP-CoA is a stronger inhibitor of NAGS activity in vitro than the parent drug VPA. The hepatic levels of NAG were significantly reduced in VPA-treated rats as compared with control tissues. CONCLUSIONS These data strongly suggest that the hyperammonemia observed in patients under VPA treatment may result from a direct inhibition of the NAGS activity by VP-CoA. The subsequent reduced availability of NAG will impair the flux through the urea cycle and compromise the major role of this pathway in ammonia detoxification.

Dynamic Changes of Plasma Acylcarnitine Levels Induced by Fasting and Sunflower Oil Challenge Test in Children

The dynamic changes of plasma acylcarnitine levels in 1- to 7-y-old children during fasting and after the ingestion of sunflower oil were studied. Glucose, 3-hydroxybutyrate, acetoacetate, FFA, and individual plasma acylcarnitine levels were monitored in both conditions. Fasting experiments lasted for 20 h, and acylcarnitine concentrations were analyzed at 0, 15, and 20 h of fasting. During the fat load, acylcarnitine levels were analyzed at 0, 60, 120, and 180 min. In both tests, a generalized increase of all plasma straight-chain acylcarnitines was observed. Acetylcarnitine contributed the most to the increase of total esterified carnitine. In addition, we demonstrated that the relative increase of each individual acylcarnitine during enhanced fatty acid oxidation is tightly related to its molecular structure and chain length. Fasting as well as the fat load primarily resulted in an increase of unsaturated acylcarnitines. During fasting, C12:1 and C14:1 showed a relatively high increase, whereas after the fat load C16:2 and C14:2, metabolites of linoleic acid (66% of the fat load), were the main acylcarnitines that increased.

Inhibition of hepatic carnitine palmitoyl-transferase I (CPT IA) by valproyl-CoA as a possible mechanism of valproate-induced steatosis

BACKGROUND/AIMS Carnitine palmitoyl-transferase I (CPT I) catalyses the synthesis of long-chain (LC)-acylcarnitines from LC-acyl-CoA esters. It is the rate-limiting enzyme of mitochondrial fatty acid beta-oxidation (FAO) pathway and its activity is regulated by malonyl-CoA. The antiepileptic drug valproic acid (VPA) is a branched chain fatty acid that is activated to the respective CoA ester in the intra- and extra-mitochondrial compartments. This drug has been associated with a clear inhibition of mitochondrial FAO, which motivated our study on its potential effect on hepatic CPT I. METHODS To investigate the effect of valproyl-CoA (VP-CoA) on CPT I, we performed in vitro studies using control human fibroblasts and rat CPT IA expressed in Saccharomyces cerevisiae. In addition to the wild-type enzyme, two mutant rCPT IAs were studied, one of which showing increased sensitivity towards malonyl-CoA (S24A/Q30A), whereas the other one is insensitive to malonyl-CoA (E3A). RESULTS We demonstrate that VP-CoA inhibits the CPT I activity in control fibroblasts. Similar results were obtained using rCPT IA WT and S24A/Q30A. Importantly, VP-CoA also inhibited the activity of the rCPT IA E3A. We show that VP-CoA inhibits CPT IA competitively with respect to palmitoyl-CoA, and non-competitively to carnitine. Evidence is provided that VP-CoA interferes at the catalytic domain of CPT IA affecting the sensitivity for malonyl-CoA. CONCLUSIONS The interference of VP-CoA with CPT IA, a pivotal enzyme in mitochondrial fatty acid beta-oxidation, may be a crucial mechanism in the drug-induced hepatotoxicity and the weight gain frequently observed in patients under VPA therapy.

Inhibition of oxidative phosphorylation by palmitoyl-CoA in digitonin permeabilized fibroblasts: implications for long-chain fatty acid β-oxidation disorders

Long-chain fatty acid oxidation deficient patients present early in life with more severe features than patients with a medium-chain fatty acid oxidation deficiency. This may be related to the more toxic effect of long-chain fatty acid derivatives. In this paper we have studied the effect of different acyl-CoA esters, and palmitoyl-CoA in particular, on succinate-driven oxidative phosphorylation, using digitonin permeabilized human fibroblasts. Palmitoyl-CoA was found to inhibit the succinate-driven oxidative phosphorylation in a concentration dependent manner. If the inhibition of the oxidative phosphorylation system is also expressed under in vivo conditions this might explain some of the abnormalities found in patients with defects in long-chain fatty acid beta-oxidation.

Differential effect of valproate and its Δ2- and Δ4-unsaturated metabolites, on the β-oxidation rate of long-chain and medium-chain fatty acids

Overall fatty acid oxidation rates were investigated in rat hepatocytes using [9,10-3H]-palmitic, [9,10-3H]-oleic, [9,10-3H]-myristic and [2,3-3H]-phenylpropionic acids. The effect of both valproate (VPA) (0-10 mM) and two of its unsaturated metabolites, Delta2(E)-VPA and Delta4-VPA (0-10 mM), on the overall 3H2O production rate was studied. The results give evidence of a general inhibitory effect of VPA on the beta-oxidation rate of all the tested substrates. Similar effects were observed with both VPA metabolites but these effects appeared to be dependent on the chain length of the substrate. When the effect on the oxidation of the medium-chain fatty acid 3-phenylpropionate (PPA) was studied, Delta2(E)-VPA at 0.5 mM caused a 94% inhibition of the overall beta-oxidation rate. However, with long-chain substrates, 0.5 mM Delta(4)-VPA was a more potent inhibitor (20-30% of control activity) than 0.5 mM Delta(2E)-VPA (60-80% of control activity). Our results suggest that VPA and/or its metabolites inhibit fatty acyl-CoA metabolism within the mitochondrion by two different mechanisms. The first mechanism involves CoASH sequestration, which affects the oxidation rate of all fatty acids with different chain length. The second mechanism is more specific in nature and involves selective inhibition of particular enzymes implicated in fatty acid beta-oxidation.

Complete beta-oxidation of valproate: cleavage of 3-oxovalproyl-CoA by a mitochondrial 3-oxoacyl-CoA thiolase

The beta-oxidation of valproic acid (VPA; 2-n-propylpentanoic acid) was investigated in vitro in intact rat liver mitochondria incubated with (3)H-labelled VPA. The metabolism of [4,5-(3)H(2)]VPA and [2-(3)H]VPA was studied by analysing the different acyl-CoA intermediates formed by reverse-phase HPLC with radiochemical detection. Valproyl-CoA, Delta(2(E))-valproyl-CoA,3-hydroxyvalproyl-CoA and 3-oxovalproyl-CoA (labelled and non-labelled) were determined using continuous on-line radiochemical and UV detection. The formation of these intermediates was investigated using the two tritiated precursors in respiratory states 3 and 4. Valproyl-CoA was present at highest concentrations under both conditions. Two distinct labelled peaks were found, which were identified as (3)H(2)O and [4,5-(3)H(2)]3-oxo-VPA. The formation of (3)H(2)O strongly suggested that VPA underwent complete beta-oxidation and that [4,5-(3)H(2)]3-oxo-VPA was formed by hydrolysis of the corresponding thioester. The hypothesis that 3-oxovalproyl-CoA undergoes thiolytic cleavage was investigated further. For this purpose a mito chondrial lysate was incubated with synthetic 3-oxovalproyl-CoA, carnitine and carnitine acetyltransferase for subsequent monitoring of the formation of propionylcarnitine and pentanoylcarnitine using electrospray ionization tandem MS. The detection of these compounds demonstrated unequivocally that the intermediate 3-oxovalproyl-CoA is a substrate of a mitochondrial thiolase, producing propionyl-CoA and pentanoyl-CoA, thus demonstrating the complete beta-oxidation of VPA in the mitochondrion. Our data should lead to a re-evaluation of the generally accepted concept that the biotransformation of VPA by mitochondrial beta-oxidation is incomplete.

Characterization of plasma acylcarnitines in patients under valproate monotherapy using ESI-MS/MS

OBJECTIVES The effect of administration of the antiepileptic drug valproate (VPA), on the composition of the plasma acylcarnitine profile (including free carnitine) was investigated. DESIGN AND METHODS Plasma samples were obtained from 18 individuals (13 males:5 females; 15-65 y) on long-term treatment with VPA (resulting in plasma levels of 14.6-135.0 mg/L; therapeutic conc.: 40-100 mg/L). Acylcarnitines (AC) in plasma were quantified by electrospray tandem mass spectrometry (ESI-MS/MS). RESULTS VPA was found to increase the levels (mean +/- SD, microM) of 3-hydroxy-isovalerylcarnitine (0.10 +/- 0.04; controls: 0.02-0.06), C14:2 acylcarnitine (0.11 +/- 0.05; controls: 0.02-0.08), propylglutarylcarnitine (0.06 +/- 0.05; controls: 0.00-0.04), and C18-0H-acylcarnitine (0.09 +/- 0.05; controls: 0.00-0.04). The free carnitine (C) (42.2 +/- 9.0; controls: 22.3-54.9) and the total carnitine (52.3 +/- 10.1; controls: 26.5-73.6) were not significantly altered by VPA. Other AC (C2-C18, monounsaturated and hydroxylated) were all within the control range and especially no increase of C8 (valproyl) carnitine was observed. A positive correlation was found between the ratios [AC] / [C] (p < 0.05) or [long-chain AC (C10-C18)] / [C] (p < 0.09) with the plasma VPA concentration. CONCLUSIONS The unequivocal increase in 3-hydroxy-isovalerylcarnitine is consistent with the increase of 3-hydroxy-isovaleric acid observed in urine of VPA treated patients. This finding suggests an interaction mechanism of VPA with specific enzymes, namely involved in leucine metabolism. Adult patients under VPA monotherapy do not suffer from carnitine deficiency; the effect of the accumulating acylcarnitines is ill-defined.

Carnitine palmitoyltransferase 2 and carnitine/acylcarnitine translocase are involved in the mitochondrial synthesis and export of acylcarnitines

Acylcarnitines are commonly used in the diagnosis of mitochondrial fatty acid β‐oxidation disorders (mFAODs). It is generally assumed that this plasma acylcarnitine profile reflects the mitochondrial accumulation of acyl‐CoAs. The identity of the enzymes and the mitochondrial and plasmalemmal transporters involved in the synthesis and export of these metabolites have remained undefined. We used lentiviral shRNA to knock down the expression of medium‐chain acyl‐CoA dehydrogenase (MCAD) in control and carnitine palmitoyltransferase 2 (CPT2)‐, carnitine/acylcarnitine translocase (CACT)‐, and plasmalemmal carnitine transporter (OCTN2)‐deficient human fibroblasts. These cell lines, including mock‐transduced controls, were loaded with decanoic acid and carnitine, followed by the measurement of the acylcarnitine profile in the extracellular medium. In control fibroblasts, MCAD knockdown markedly increased the production of octanoylcarnitine (3‐fold, P<0.01). OCTN2‐deficient cell lines also showed extracellular accumulation of octanoylcarnitine (2.8‐fold, P<0.01), suggesting that the cellular export of acylcarnitines does not depend on OCTN2. In contrast, in CPT2‐ and CACT‐deficient cells, the accumulation of octanoylcarnitine in the medium did not significantly increase in the MCAD knockdown. Similar results were obtained using pharmacological inhibition of CPT2 in fibroblasts from MCAD‐deficient individuals. This shows that CPT2 and CACT are crucial for mitochondrial acylcarnitine formation and export to the extracellular fluids in mFAOD.—Violante, S., IJlst, L., te Brinke, H., Tavares de Almeida, I., Wanders, R. J. A., Ventura, F. V., Houten, S. M. Carnitine palmitoyltransferase 2 and carnitine/acylcarnitine translocase are involved in the mitochondrial synthesis and export of acylcarnitines. FASEB J. 27, 2039–2044 (2013). www.fasebj.org