Henk Overmars

Quantitative plasma acylcarnitine analysis using electrospray tandem mass spectrometry for the diagnosis of organic acidaemias and fatty acid oxidation defects

Electrospray tandem mass spectrometry (ESI-MS/MS) of acylcarnitines has been successfully applied in newborn screening for defects in fatty acid oxidation and organic acidaemias (Millington et al 1990; Rashed et al 1995a, 1997). In addition, acylcarnitine analysis has also been applied for the selective screening for these disorders (Chace et al 1997; Van Hove et al 1993, 1995), for post-mortem diagnosis using bile fluid (Rashed et al 1995b) and for prenatal diagnosis of organic acidaemias and defects of fatty acid oxidation (Nada et al 1996; Shigematsu et al 1996). Since for selective screening for inborn errors of metabolism, apart from urine samples, mostly serum or plasma samples are sent in, we developed a quantitative ESI-MS/MS acylcarnitine analysis in plasma and included the analysis of free carnitine in the same assay. The results show that this analysis is highly sensitive and reproducible and therefore suitable for selective screening of fatty acid oxidation defects, organic acidaemias and secondary carnitine deficiency.

Mutations in the Gene Encoding Peroxisomal Sterol Carrier Protein X (SCPx) Cause Leukencephalopathy with Dystonia and Motor Neuropathy

In this report, we describe the first known patient with a deficiency of sterol carrier protein X (SCPx), a peroxisomal enzyme with thiolase activity, which is required for the breakdown of branched-chain fatty acids. The patient presented with torticollis and dystonic head tremor as well as slight cerebellar signs with intention tremor, nystagmus, hyposmia, and azoospermia. Magnetic resonance imaging showed leukencephalopathy and involvement of the thalamus and pons. Metabolite analyses of plasma revealed an accumulation of the branched-chain fatty acid pristanic acid, and abnormal bile alcohol glucuronides were excreted in urine. In cultured skin fibroblasts, the thiolytic activity of SCPx was deficient, and no SCPx protein could be detected by western blotting. Mutation analysis revealed a homozygous 1-nucleotide insertion, 545_546insA, leading to a frameshift and premature stop codon (I184fsX7).

Rapid stable isotope dilution analysis of very-long-chain fatty acids, pristanic acid and phytanic acid using gas chromatography-electron impact mass spectrometry.

A common feature of most peroxisomal disorders is the accumulation of very-long-chain fatty acids (VLCFAs) and/or pristanic and phytanic acid in plasma. Previously described methods utilizing either gas chromatography alone or gas chromatography-mass spectrometry are, in general, time-consuming and unable to analyze VLCFAs, pristanic and phytanic acid within a single analysis. We describe a simple, reproducible and rapid method using gas chromatography/mass spectrometry with deuterated internal standards. The method was evaluated by analysing 30 control samples and samples from 35 patients with defined peroxisomal disorders and showed good discrimination between controls and patients. This method is suitable for routine screening for peroxisomal disorders.

Rapid analysis of conjugated bile acids in plasma using electrospray tandem mass spectrometry: application for selective screening of peroxisomal disorders

The final step in bile acid biosynthesis takes place in peroxisomes and involves oxidative cleavage of the side-chain of C 27 -β-cholestanoic acids, leading to the formation of the primary bile acids cholic and chenodeoxycholic acid. Therefore, in a number of peroxisomal disorders, including both peroxisomal biogenesis defects and isolated defects of peroxisomal β-oxidation, the accumulation of serum C 27 -5β-cholestanoic acids can be observed (Bjorkhem 1994; Clayton et al 1987; Libert et al 1991; Wanders et al 1995). Since routine gas chromatography mass-spectrometry (GC-MS) analysis of plasma bile acids requires laborious sample preparation including enzymatic and/or chemical deconjugation of plasma bile acids prior to derivatization and GC-MS analysis, we have developed a rapid HPLC electrospray tandem mass spectrometry (ESI-MS/MS) method for analysing taurine- and glycine-conjugated bile acids.

Characterization of carnitine and fatty acid metabolism in the long-chain acyl-CoA dehydrogenase-deficient mouse.

In the present paper, we describe a novel method which enables the analysis of tissue acylcarnitines and carnitine biosynthesis intermediates in the same sample. This method was used to investigate the carnitine and fatty acid metabolism in wild-type and LCAD-/- (long-chain acyl-CoA dehydrogenase-deficient) mice. In agreement with previous results in plasma and bile, we found accumulation of the characteristic C14:1-acylcarnitine in all investigated tissues from LCAD-/- mice. Surprisingly, quantitatively relevant levels of 3-hydroxyacylcarnitines were found to be present in heart, muscle and brain in wild-type mice, suggesting that, in these tissues, long-chain 3-hydroxyacyl-CoA dehydrogenase is rate-limiting for mitochondrial beta-oxidation. The 3-hydroxyacylcarnitines were absent in LCAD-/- tissues, indicating that, in this situation, the beta-oxidation flux is limited by the LCAD deficiency. A profound deficiency of acetylcarnitine was observed in LCAD-/- hearts, which most likely corresponds with low cardiac levels of acetyl-CoA. Since there was no carnitine deficiency and only a marginal elevation of potentially cardiotoxic acylcarnitines, we conclude from these data that the cardiomyopathy in the LCAD-/- mouse is caused primarily by a severe energy deficiency in the heart, stressing the important role of LCAD in cardiac fatty acid metabolism in the mouse.

Molecular Characterization of Iodotyrosine Dehalogenase Deficiency in Patients with Hypothyroidism

CONTEXT The recent cloning of the human iodotyrosine deiodinase (IYD) gene enables the investigation of iodotyrosine dehalogenase deficiency, a form a primary hypothyroidism resulting from iodine wasting, at the molecular level. OBJECTIVE In the current study, we identify the genetic basis of dehalogenase deficiency in a consanguineous family. RESULTS Using HPLC tandem mass spectrometry, we developed a rapid, selective, and sensitive assay to detect 3-monoiodo-l-tyrosine and 3,5-diodo-l-tyrosine in urine and cell culture medium. Two subjects from a presumed dehalogenase-deficient family showed elevated urinary 3-monoiodo-l-tyrosine and 3,5-diodo-l-tyrosine levels compared with 57 normal subjects without thyroid disease. Subsequent analysis of IYD revealed a homozygous missense mutation in exon 4 (c.658G>A p.Ala220Thr) that co-segregates with the clinical phenotype in the family. Functional characterization of the mutant iodotyrosine dehalogenase protein showed that the mutation completely abolishes dehalogenase enzymatic activity. One of the heterozygous carriers for the inactivating mutation recently presented with overt hypothyroidism indicating dominant inheritance with incomplete penetration. Screening of 100 control alleles identified one allele positive for this mutation, suggesting that the c.658G>A nucleotide substitution might be a functional single nucleotide polymorphism. CONCLUSIONS This study describes a functional mutation within IYD, demonstrating the molecular basis of the iodine wasting form of congenital hypothyroidism. This familial genetic defect shows a dominant pattern of inheritance with incomplete penetration.

Bile acid treatment alters hepatic disease and bile acid transport in peroxisome‐deficient PEX2 Zellweger mice

The marked deficiency of peroxisomal organelle assembly in the PEX2−/− mouse model for Zellweger syndrome provides a unique opportunity to developmentally and biochemically characterize hepatic disease progression and bile acid products. The postnatal survival of homozygous mutants enabled us to evaluate the response to bile acid replenishment in this disease state. PEX2 mutant liver has severe but transient intrahepatic cholestasis that abates in the early postnatal period and progresses to steatohepatitis by postnatal day 36. We confirmed the expected reduction of mature C24 bile acids, accumulation of C27–bile acid intermediates, and low total bile acid level in liver and bile from these mutant mice. Treating the PEX2−/− mice with bile acids prolonged postnatal survival, alleviated intrahepatic cholestasis and intestinal malabsorption, reduced C27–bile acid intermediate production, and prevented older mutants from developing severe steatohepatitis. However, this therapy exacerbated the degree of hepatic steatosis and worsened the already severe mitochondrial and cellular damage in peroxisome‐deficient liver. Both untreated and bile acid–fed PEX2−/− mice accumulated high levels of predominantly unconjugated bile acids in plasma because of altered expression of hepatocyte bile acid transporters. Significant amounts of unconjugated bile acids were also found in the liver and bile of PEX2 mutants, indicating a generalized defect in bile acid conjugation. Conclusion: Peroxisome deficiency widely disturbs bile acid homeostasis and hepatic functioning in mice, and the high sensitivity of the peroxisome‐deficient liver to bile acid toxicity limits the effectiveness of bile acid therapy for preventing hepatic disease. (HEPATOLOGY 2007;45:982–997.)

Rapid diagnosis of organic acidemias and fatty-acid oxidation defects by quantitative electrospray tandem-MS acyl-carnitine analysis in plasma.

The analysis of circulating free carnitine and acyl-carnitines provides a powerful selective screening tool for genetic defects in mitochondrial fatty acid oxidation and defects in the catabolism of branched chain amino acids. Using electrospray tandem mass spectrometry (ESI/MS/MS) we developed a sensitive quantitative analysis of free carnitine and acyl-carnitines in plasma and/or serum. This method was evaluated by analyzing 250 control samples and 103 samples of patients suffering from twelve different defects in either mitochondrial fatty acid oxidation or the catabolism of branched chain amino acids. The reproducibility of the method was acceptable with a day-to-day coefficient of variation ranging from 6-15% for free carnitine and the different acylcarnitines. Except for one patient with a mild form of short chain acyl CoA dehydrogenase (SCAD) deficiency and a single sample from a patient with a mild form of multiple acyl CoA dehydrogenase (MAD) deficiency all patient samples were clearly abnormal under a wide variety of clinical conditions, illustrating the high sensitivity and specificity of the method.

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.