A novel mutation in medium chain acyl-CoA dehydrogenase causes sudden neonatal death

Assessment of candidate variants causative of inborn metabolic diseases in SUDI cases in South Africa, and a case report

Sudden unexpected death in infants (SUDI) is a devastating event, and unfortunately is still a burden in many parts of the world, including in South Africa. Due to the absence of routine testing for inborn metabolic diseases in newborns and in a post-mortem context, little is known about the presence of metabolic diseases in local SUDI cases. The aim of this study was to genotype five candidate variants previously associated with metabolic disorders in a cohort of SUDI cases (n = 169) from Salt River Mortuary, Cape Town. DNA was isolated from blood, and SNaPshot® PCR and Sanger sequencing were used to genotype the following variants: ACADM: c.583G > A, ACADM: c.985A > G, GCDH: c.877G > A/T, GALT: c.404C > G/T and GALT: c.563A > G. Four carriers of GCDH: c.877G > A/T were identified, while one infant was homozygous for the founder mutation GALT: c.404C > G/T; the latter which is causative of galactosaemia and was previously undiagnosed. During the follow-up with the family, it emerged that the affected infant's identical twin had subsequently demised. The findings in this study highlight possible new candidate variants to assess in South African SUDI cases, and these results directly contribute to the development of a molecular autopsy which is locally relevant. It is evident that until newborn screening becomes routine and accessible in South Africa, molecular autopsies should include testing for inherited metabolic disorders, as it holds potential to save lives.

A neonatal death due to medium-chain acyl-CoA dehydrogenase deficiency: utilization of the neonatal metabolic screen in a functional approach to sudden unexplained infant death

We report a perinatal death due to medium-chain acyl-CoA dehydrogenase deficiency, which was referred to the Coroner's Physician as sudden unexplained infant death. Detailed death investigation including the autopsy findings, and newborn biochemical and molecular studies revealed the cause and natural manner of death. This disorder affects fatty acid oxidation and results in decreased tolerance for fasting, which can be life threatening. This case illustrates the critical role of newborn screening in the investigation of perinatal death. A brief historical perspective of the origins of newborn biochemical screening is also presented.

Novel mutations causing medium chain acyl-CoA dehydrogenase deficiency: under-representation of the common c.985 A > G mutation in the New York state population

Medium chain acyl-CoA dehydrogenase deficiency (MCADD) is one of the most common fatty acid oxidation disorders. A subpopulation of children with MCADD present with metabolic crisis induced by fasting or illness, become lethargic, and can experience seizures or coma, culminating in a 20% mortality rate during the first episode. The frequency of these metabolic crises can be reduced with early diagnosis and treatment. The prevalence of MCADD in the United States is estimated to be 1 per 15,000 with p.K304E (c.985A > G) accounting for 90% of mutant alleles. In an 18-month period after initiating screening, the New York State Newborn Screening Mass Spectrometry Laboratory screened 385,893 newborns and referred 511 samples with elevated (>or=0.3 micromol/L) octanoylcarnitine (C8) levels for molecular testing. Of these referrals, six p.K304E homozygotes and 154 heterozygotes were identified. Twenty infants were biochemically confirmed with MCADD, per report from the child's pediatrician and/or treatment center. In these 20 cases, p.K304E accounted for only 47.5% of the mutant alleles. Further testing showed a second variant, p.Y42H, accounted for 7.5% of mutant alleles while the remaining 45% were unknown. Samples from all diagnosed non-p.K304E homozygous infants, and samples with C8 levels >or=1.0 micromol/L were sequenced (n = 16). Six novel and seven previously reported mutations were detected. These results suggest that p.K304E has a far lower representation in New York newborns with MCADD than current literature estimates and its full mutational spectrum is still unknown.

The natural history of medium-chain acyl CoA dehydrogenase deficiency in the Netherlands: clinical presentation and outcome

OBJECTIVES

To describe the clinical presentation and long-term follow-up of a large cohort of patients with medium-chain acyl-CoA dehydrogenase (MCAD) deficiency.

STUDY DESIGN

A nationwide, retrospective analysis of clinical presentation and follow-up in 155 Dutch patients with MCAD deficiency.

RESULTS

Most patients presented between 3 months and 5.1 years of age; 13% had symptoms as neonates not exclusively related to breast-feeding. An acute presentation before the diagnosis was made resulted in a mortality of 22% (25/114), whereas 21% (19/89) developed disabilities after the diagnosis. On follow-up, a total of 44 patients reported fatigue (35%; 28/80), muscle pain (31%; 25/80), and/or reduced exercise tolerance (39%; 31/80). Cardiac evaluation in 11 adult patients revealed no abnormalities in cardiac function explaining these complaints. Children with MCAD deficiency readily become overweight.

CONCLUSIONS

Mortality and morbidity were high in undiagnosed children with MCAD deficiency; establishment of the diagnosis significantly improves outcome. Strikingly, after the diagnosis and initiation of treatment, overweight and chronic complaints (fatigue, muscle pain, and reduced exercise tolerance) were prominent.

Two novel variants of human medium chain acyl-CoA dehydrogenase (MCAD). K364R, a folding mutation, and R256T, a catalytic-site mutation resulting in a well-folded but totally inactive protein

Two novel rare mutations, MCAD approximately 842G-->C (R256T) and MCAD approximately 1166A-->G (K364R), have been investigated to assess how far the biochemical properties of the mutant proteins correlate with the clinical phenotype of medium chain acyl-CoA dehydrogenase (MCAD) deficiency. When the gene for K364R was overexpressed in Escherichia coli, the synthesized mutant protein only exhibited activity when the gene for chaperonin GroELS was co-overexpressed. Levels of activity correlated with the amounts of native MCAD protein visible in western blots. The R256T mutant, by contrast, displayed no activity either with or without chaperonin, but in this case a strong MCAD protein band was seen in the western blots throughout. The proteins were also purified, and the enzyme function and thermostability investigated. The K364R protein showed only moderate kinetic impairment, whereas the R256T protein was again totally inactive. Neither mutant showed marked depletion of FAD. The pure K364R protein was considerably less thermostable than wild-type MCAD. Western blots indicated that, although the R256T mutant protein is less thermostable than normal MCAD, it is much more stable than K364R. Though clinically asymptomatic thus far, both mutations have a severe impact on the biochemical phenotype of the protein. K364R, like several previously described MCAD mutant proteins, appears to be defective in folding. R256T, by contrast, is a well-folded protein that is nevertheless devoid of catalytic activity. How the mutations specifically affect the catalytic activity and the folding is further discussed.

Enzymatic diagnosis of medium-chain acyl-CoA dehydrogenase deficiency by detecting 2-octenoyl-CoA production using high-performance liquid chromatography: a practical confirmatory test for tandem mass spectrometry newborn screening in Japan

Many of the previously described enzymatic assay methods for the diagnosis of medium-chain acyl-CoA dehydrogenase (MCAD) deficiency have been dependent upon the measurement of radioisotope-labeled co-products or reduction of electron acceptors. We have developed a direct assay method to detect 2-enoyl-CoA production using high-performance liquid chromatography (HPLC). Crude cell lysate prepared from lymphocytes were incubated with n-octanoyl-CoA and ferrocenium hexafluorophosphate. The detection of 2-octenoyl-CoA was significantly reproducible. We applied the assay to samples from four infants suspected to have MCAD deficiency by tandem mass spectrometry (MS/MS) newborn screening conducted in the Hiroshima area of Japan. Three of them were proved to have pathologically reduced residual enzyme activities, although they were associated with various clinical and biochemical phenotypes. In addition, another symptomatic Japanese patient and her presymptomatic sibling who were detected by MS/MS selective screening were successfully diagnosed by our enzymatic assay. These results indicate that the method can be a useful confirmatory test for MS/MS screening of MCAD deficiency.

Expanding screening for rare metabolic disease in the newborn: an analysis of costs, effect and ethical consequences for decision-making in Finland

AIM

Currently, the only metabolic disorder that newborns are screened for in Finland is congenital hypothyroidism. A proposal to start a pilot study on screening for other rare metabolic diseases using tandem mass spectrometry prompted a health technology assessment project on the effect and costs of expanded newborn screening programme options.

METHOD

A modelling study using data from current published studies, healthcare registers and expert opinion.

RESULTS

The annual running cost of screening 56,000 newborns for the chosen five disorders (congenital adrenal hyperplasia, medium-chain acyl-CoA dehydrogenase deficiency [MCADD], long chain 3-hydroxyacyl-CoA dehydrogenase deficiency [LCHADD], phenylketonuria [PKU] and glutaric aciduria type 1 [GA 1]) was estimated to be euros 2.5 million or euros 45 per newborn when starting costs were included. The costs per quality-adjusted life year (QALY) gained are a maximum of euros 25,500. Prevention of severe handicap in one newborn would reduce the costs to a maximum of euros 18,000 per QALY gained.

CONCLUSIONS

Expanding the Finnish neonatal screening programme would require a new organization. The cost-effectiveness, resources, ethics and equity need to be considered when deciding in favour of or against starting a new screening programme.

Abnormal concentrations of esterified carnitine in bile: a feature of pediatric acute liver failure with poor prognosis

The etiology of acute liver failure in children is unknown in a large number of cases. Defects in fatty acid oxidation have been shown to lead to severe liver injury. This retrospective analysis examined the bile acylcarnitine profiles of 27 children with acute liver failure who underwent liver transplantation or died. Results were compared with 758 postmortem samples from individuals without acute liver failure. Cumulative amounts of free carnitine, medium- or long-chain species in excess of the 95th percentile of the control group were considered abnormal. Fourteen samples had normal profiles. Three had markedly elevated concentrations of free carnitine, whereas ten showed elevations in medium- or long-chain species. The relative risk of death was 2.86 (95% confidence interval, 1.08-7.54, P = .01) in the 10 children with elevated concentrations of medium- or long-chain species compared with those with normal analyses. Overall, medium- and long-chain acylcarnitines were increased in those patients who died compared with survivors, (dead vs. alive; medium-chain, 187 +/- 74 vs. 32 +/- 12 micromol/L, P = .008; long-chain, 146 +/- 74 vs. 15 +/- 8 micromol/L, mean +/- standard error of the mean, P = .018). These studies describe biliary free and esterified carnitine profiles in children with acute liver failure. In conclusion, the findings raise the hypothesis that abnormalities in fatty acid oxidation may predispose to a worse outcome in acute liver failure.

Homozygosity for a severe novel medium-chain acyl-CoA dehydrogenase (MCAD) mutation IVS3-1G > C that leads to introduction of a premature termination codon by complete missplicing of the MCAD mRNA and is associated with phenotypic diversity ranging from sudden neonatal death to asymptomatic status

Virtually all patients with medium-chain acyl-CoA dehydrogenase deficiency (MCADD) are homozygous or compound heterozygous for the 985A > G mutation, which limits the study of a possible genotype/phenotype correlation. A newborn Palestinian infant died suddenly on the second day of life. A previous sibling had also died in similar circumstances aged 3 weeks. Urine organic acid and bloodspot acylcarnitine analysis were consistent with MCADD. He was homozygous for a novel MCAD splice mutation, IVS3-1G > C. This mutation leads to deletion of 7 bp and introduction of a premature termination codon as a result of complete missplicing of MCAD mRNA. This misspliced MCAD mRNA encodes a non-functional protein and is furthermore reduced in amounts due to nonsense-mediated decay, resulting in total lack of functional MCAD enzyme. This is the first molecular identification of MCADD in an Arab patient and the first reported splice mutation in the MCAD gene that has been functionally characterized. The association of homozygosity for a null mutation with lethal neonatal presentation in the index patient and presumably the previous infant suggested a genotype/phenotype correlation. However, a 6-year-old completely asymptomatic sibling also had the characteristic MCADD biochemical phenotype and was homozygous for the same IVS3-1G > C mutation. As a first candidate to modify the disease presentation, by modulating the overlapping enzyme activity, we tested the entire family for the prevalent SCAD gene 625G > A susceptibility variant. Interestingly, all family members were 625G > A homozygous. Additional genetic and/or environmental factors must play a major role in determining the phenotypic diversity of MCADD.

Incidence of autopsy findings in unexpected deaths of children and adolescents

Studies in various settings reveal that a significant percentage of autopsies demonstrate findings that were not previously clinically diagnosed. In the pediatric and adolescent age group, forensic examinations comprise a large percentage of total autopsies performed. We hypothesized that a similar number of previously undiagnosed findings would be present in this population and thus reviewed a series of autopsy reports from the Medical Examiners Office in the Arkansas Crime Laboratory. During 1997 through 1999, we performed 439 complete forensic autopsies on children and adolescents (age range 1 day to 19 years; median 18 months). Previously undiagnosed lesions were found in 173 (39%). Of these subjects, 68 (39%) had clinically significant pathology, 60 (35%) had insignificant pathology, and 45 (26%) had pathology of undetermined significance. Thirty-six subjects had lesions expected from a previously diagnosed condition. Of the total number of lesions found, 168 were inflammatory, 58 were congenital anomalies (48 unexpected), and 88 comprised miscellaneous other conditions. Infants <6 months of age were significantly more likely to have a previously undiagnosed lesson than children > 6 months (P <0.0001). Previously undiagnosed findings, mostly inflammatory, occur relatively frequently in pediatric and adolescent forensic autopsies and are more likely to occur in infants.

Accumulation of Free 3-Hydroxy Fatty Acids in the Culture Media of Fibroblasts from Patients Deficient in Long-Chain l-3-Hydroxyacyl-CoA Dehydrogenase: A Useful Diagnostic Aid

Background: The diagnosis of long-chain l-3-hydroxy-acyl-coenzyme A dehydrogenase (LCHAD) deficiency frequently requires the study of cultured fibroblasts. We developed such a test that does not require disruption and loss of the cells.

Methods: We measured free 3-hydroxy fatty acids (3-OHFAs) in media of skin fibroblasts cultures from 11 patients with a genetic deficiency of LCHAD and the associated disorder of mitochondrial trifunctional protein (MTFP). Fibroblasts were cultured for 24 h with 100 μmol/L nonisotopic palmitate added. 3-OHFAs were measured by selected-ion monitoring, stable-isotope dilution gas chromatography-mass spectrometry with [13C]-labeled internal standards.

Results: 3-OH-hexadecanoic and 3-OH-tetradecanoic FAs were increased 14- and 11-fold, respectively, in all patients with LCHAD or MTFP deficiency when compared with control fibroblast cell lines after overnight incubation with palmitate. 3-OH-dodecanoic FA demonstrated a modest, fivefold increase in LCHAD-deficient cells. The concentrations of all 3-OHFAs were similar whether or not the medium samples were hydrolyzed to release conjugated species such as acylcarnitines, suggesting that 3-OHFAs accumulate in the media as free FAs.

Conclusions: Measurement of 3-OHFA excretion from LCHAD- or MTFP-deficient cell lines can be used as a diagnostic tool. Free FAs are the predominant form of these abnormal metabolic intermediates in culture media.

Improved Stable Isotope Dilution-Gas Chromatography-Mass Spectrometry Method for Serum or Plasma Free 3-Hydroxy-Fatty Acids and Its Utility for the Study of Disorders of Mitochondrial Fatty Acid β-Oxidation

Background: Disorders of fatty acid oxidation (FAO) are difficult to diagnose, primarily because in many of the FAO disorders measurable biochemical intermediates accumulate in body fluids only during acute illness. Increased concentrations of 3-hydroxy-fatty acids (3-OH-FAs) in the blood are indicative of FAO disorders of the long- and short-chain 3-hydroxy-acyl-CoA dehydrogenases, LCHAD and SCHAD. We describe a serum/plasma assay for the measurement of 3-OH-FAs with carbon chain lengths from C6 to C16.

Methods: We used stable isotope dilution gas chromatography-mass spectrometry (GC-MS) with electron impact ionization and selected ion monitoring. Natural and isotope-labeled compounds were synthesized for the assay.

Results: The assay was linear from 0.2 to 50 μmol/L for all six 3-OH-FAs. CVs were 5–15% at concentrations near the upper limits seen in healthy subjects. In 43 subjects, the medians (and ranges) in μmol/L were as follows: 3-OH-C6, 0.8 (0.3–2.2); 3-OH-C8, 0.4 (0.2–1.0); 3-OH-C10, 0.3 (0.2–0.6); 3-OH-C12, 0.3 (0.2–0.6); 3-OH-C14, 0.2 (0.0–0.4); and 3-OH-C16, 0.2 (0.0–0.5). 3-OH-FAs were increased in infants receiving formula containing medium chain triglycerides. Two patients diagnosed with LCHAD deficiency showed marked increases in 3-OH-C14 and 3-OH-C16 concentrations. Two patients diagnosed with SCHAD deficiency showed increased shorter chain 3-OH-FAs but no increases in 3-OH-C14 to 3-OH-C16.

Conclusion: Measuring blood concentrations of the 3-OH-FAs with this assay may be a valuable tool for helping to rapidly identify deficiencies in LCHAD and SCHAD and may also provide useful information about the status of the FAO pathway.

Inherited long-chain 3-hydroxyacyl-CoA dehydrogenase deficiency and a fetal-maternal interaction cause maternal liver disease and other pregnancy complications

Fetal-maternal interactions are critical determinants of maternal health during pregnancy and perinatal outcome. This review explores the causative relationship of a fetal disorder of mitochondrial fatty acid oxidation, long-chain 3-hydroxyacyl-CoA dehydrogenase (LCHAD) deficiency, and the serious maternal liver diseases of pregnancy-preeclampsia, the HELLP syndrome (hemolysis, elevated liver enzymes, and low platelet counts), and acute fatty liver of pregnancy. Features of the metabolic adaptation necessitated during the fetal-neonatal transition; common phenotypes of pediatric fatty acid oxidation disorders, including neonatal hypoketotic, hypoglycemia and hepatic crisis; and clinical abnormalities of HELLP and acute fatty liver of pregnancy are presented. Evidence that a common mutation in the alpha-subunit (LCHAD) of trifunctional protein, E474Q, is always one of the mutant alleles in fetal isolated LCHAD deficiency associated with these disorders of pregnancy that cause high maternal, fetal, and newborn morbidity and mortality is reviewed. Recommendations for molecular testing for LCHAD deficiency in families with life-threatening maternal liver disease are given.

Sudden and unexpected neonatal death: a protocol for the postmortem diagnosis of fatty acid oxidation disorders

Fatty acid oxidation (FAO) disorders are frequently reported as the cause of sudden and unexpected death, but their postmortem identification remains difficult. Over a period of 5 years, the authors have identified 44 cases representing five FAO disorders and 19 additional cases without a diagnosis of a specific defect. Among the two groups, 13 patients died in the neonatal period, 10 in the FAO group, and three from the undetermined defect group. This outcome was consistently associated with exclusive breast feeding and presumably poor caloric intake. The diagnosis of FAO disorder in these cases was based on the analysis of postmortem liver and bile. In postmortem liver, informative findings are microvesicular steatosis, elevated fatty acid concentrations, glucose depletion, and low carnitine concentration. Bile carnitine analysis and acylcarnitine profiling have expanded significantly the effectiveness of the initial protocol and could lead, based on preliminary observations, to better identification of patients who may have been missed or left undetermined by the analysis of liver only. If an autopsy is not performed, informative findings can still be obtained by analysis of blood spots collected for newborn screenings and by biochemical testing of parents and asymptomatic siblings.

Molecular heterogeneity in very-long-chain acyl-CoA dehydrogenase deficiency causing pediatric cardiomyopathy and sudden death

BACKGROUND

Genetic defects are being increasingly recognized in the etiology of primary cardiomyopathy (CM). Very-long-chain acyl-CoA dehydrogenase (VLCAD) catalyzes the first step in the beta-oxidation spiral of fatty acid metabolism, the crucial pathway for cardiac energy production.

METHODS AND RESULTS

We studied 37 patients with CM, nonketotic hypoglycemia and hepatic dysfunction, skeletal myopathy, or sudden death in infancy with hepatic steatosis, features suggestive of fatty acid oxidation disorders. Single-stranded conformational variance was used to screen genomic DNA. DNA sequencing and mutational analysis revealed 21 different mutations on the VLCAD gene in 18 patients. Of the mutations, 80% were associated with CM. Severe CM in infancy was recognized in most patients (67%) at presentation. Hepatic dysfunction was common (33%). RNA blot analysis and VLCAD enzyme assays showed a severe reduction in VLCAD mRNA in patients with frame-shift or splice-site mutations and absent or severe reduction in enzyme activity in all.

CONCLUSIONS

Infantile CM is the most common clinical phenotype of VLCAD deficiency. Mutations in the human VLCAD gene are heterogeneous. Although mortality at presentation is high, both the metabolic disorder and cardiomyopathy are reversible.

Biochemical characterization of a variant human medium-chain acyl-CoA dehydrogenase with a disease-associated mutation localized in the active site

Medium-chain acyl-CoA dehydrogenase (MCADH) deficiency, an autosomal recessive inherited disorder, is the most common genetic disorder in mitochondrial beta-oxidation in humans. In addition to one prevalent disease-causing mutation (K304E), a series of rarer mutations has been reported, but none of these has yet been characterized in detail. We report here on the biochemical characterization of the purified recombinant mutant protein in which threonine is replaced by alanine at position 168 of the mature protein (T168A-MCADH). It is the first mutation to be found in patients that is located in the active site of the enzyme. Thr-168 is hydrogen-bonded to the flavin N(5) of the cofactor FAD. The thermostability of T168A-MCADH is markedly decreased compared with human wild-type MCADH (hwt-MCADH). Catalytic activity with ferricenium as acceptor is lowered by 80% and with the natural acceptor electron-transferring flavoprotein by over 90% compared with hwt-MCADH. In the mutant the extent of flavin semiquinone formed on reduction is approx. 50% that of hwt-MCADH. The pK reflected by the pH-dependence of Vmax is shifted from approx. 8.2 (hwt-MCADH) to approx. 7 (T168A-MCADH) and the rates of enzyme flavin reduction (stopped-flow measurements) are only approx. 1/10 those of the parent enzyme. These properties are discussed in the light of the possible mechanisms leading to disease in humans.

Mild trifunctional protein deficiency is associated with progressive neuropathy and myopathy and suggests a novel genotype-phenotype correlation

Human mitochondrial trifunctional protein (TFP) is a heterooctamer of four alpha- and four beta-subunits that catalyzes three steps in the beta-oxidation spiral of long-chain fatty acids. TFP deficiency causes a Reye-like syndrome, cardiomyopathy, or sudden, unexpected death. We delineated the molecular basis for TFP deficiency in two patients with a unique phenotype characterized by chronic progressive polyneuropathy and myopathy without hepatic or cardiac involvement. Single-stranded conformation variance and nucleotide sequencing identified all patient mutations in exon 9 of the alpha-subunit. One patient is homozygous for the T845A mutation that substitutes aspartic acid for valine at residue 246. The second patient is a compound heterozygote for the T914A that substitutes asparagine for isoleucine at residue 269 and a C871T that creates a premature termination at residue 255. Allele-specific oligonucleotide hybridization studies revealed undetectable levels of the mRNA corresponding to the mutant allele carrying the termination codon. This study suggests a novel genotype-phenotype correlation in TFP deficiency; that is, mutations in exon 9 of the alpha-subunit, which encodes a linker domain between the NH2-terminal hydratase and the COOH-terminal 3-hydroxyacyl-CoA dehydrogenase, result in a unique neuromuscular phenotype.

Rapid degradation of short-chain acyl-CoA dehydrogenase variants with temperature-sensitive folding defects occurs after import into mitochondria

Most disease-causing missense mutations in short-chain acyl-CoA dehydrogenase (SCAD) and medium-chain acyl-CoA dehydrogenase are thought to compromise the mitochondrial folding and/or stability of the mutant proteins. To address this question, we studied the biogenesis of SCAD proteins in COS-7 cells transfected with cDNA corresponding to two SCAD missense mutations, R22W (identified in a patient with SCAD deficiency) or R22C (homologous to a disease-associated R28C mutation in medium-chain acyl-CoA dehydrogenase deficiency). After cultivation at 37 degreesC the steady-state amounts of SCAD antigen and activity in extracts from cells transfected with mutant SCAD cDNAs were negligible compared with those of cells transfected with SCAD wild type cDNA, documenting the deleterious effect of the two mutations. Analysis of metabolically labeled and immunoprecipitated SCAD wild type and mutant proteins showed that the two mutant proteins were synthesized as the 44-kDa precursor form, imported into mitochondria and processed to the mature 41.7-kDa form in a normal fashion. However, the intramitochondrial level of matured mutant SCAD proteins decreased rapidly to very low levels, indicating a rapid degradation of the mutant proteins at 37 degreesC. A rapid initial elimination phase was also observed following cultivation at 26 degreesC; however, significantly higher amounts of metabolically labeled and immunoprecipitated mature mutant SCAD proteins remained detectable. This corresponds well with the appreciable steady-state levels of SCAD mutant enzyme activity observed at 26 degreesC. In addition, confocal laser scanning microscopy of immunostained cells showed that the SCAD mutant proteins were localized intramitochondrially. Together, these results show that newly synthesized SCAD R22W and R22C mutant proteins are imported and processed in the mitochondrial matrix, but that a fraction of the proteins is rapidly eliminated by a temperature-dependent degradation mechanism. Thermal stability profiles of wild type and mutant enzymes revealed no difference between the two mutants and the wild type protein. Furthermore, the turnover of the SCAD mutant enzymes in intact cells was comparable to that of the wild type, indicating that the rapid degradation of the mutant SCAD proteins is not due to lability of the correctly folded tetrameric structure but rather to elimination of partly folded or misfolded proteins along the folding pathway.

Influence of excision of a methylene group from Glu-376 (Glu376-->Asp mutation) in the medium chain acyl-CoA dehydrogenase-catalyzed reaction

The human liver medium chain acyl-CoA dehydrogenase (MCAD)-catalyzed reaction proceeds via abstraction of an alpha-proton from the acyl-CoA substrates by the carboxyl group of Glu-376. By using the methods of site-directed mutagenesis, we replaced Glu-376 by Asp (E376D mutation), expressed the wild-type and mutant enzymes in Escherichia coli, purified them to homogeneity, and compared their kinetic properties. The steady-state kinetic data revealed that the E376D mutation impaired (by about 15-20-fold) the turnover rate of the enzyme as well as its inactivation by 2-octynoyl-CoA. There was no selective solvent deuterium isotope effect on enzyme catalysis. These results lead to the suggestion that the carboxyl group of Asp-376 does not serve as efficient catalytic base as the carboxyl group of Glu-376. The E376D mutation impaired the octanoyl-CoA-dependent reductive half-reaction such that the rate-limiting step of enzyme catalysis shifted from the product dissociation step (in the case of the wild-type enzyme) to the flavin reduction step, and abolished the previously noted kinetic and thermodynamic correspondences between the octanoyl-CoA-dependent reductive half-reaction and the enzyme-octenoyl-CoA interaction [Kumar, N. R., and Srivastava, D. K. (1994) Biochemistry 33, 8833-8841]. Arguments are presented that the Glu-376-->Asp mutation results in uncoupling between the proton transfer and protein conformational change steps during enzyme catalysis.

Rapid diagnosis of MCAD deficiency: quantitative analysis of octanoylcarnitine and other acylcarnitines in newborn blood spots by tandem mass spectrometry

We report the application of tandem mass spectrometry to prospective newborn screening for medium-chain acyl-CoA dehydrogenase (MCAD) deficiency. MCAD deficiency is diagnosed from dried blood spots on filter paper cards from newborns on the basis of the increase of medium chain length acylcarnitines identified by isotope dilution mass spectrometry methods. A robust and accurate semiautomated method for the analysis of medium chain length acylcarnitines as their butyl esters was developed and validated. Quantitative data from the analyses of 113 randomly collected filter paper blood spots from healthy newborns showed low concentrations of medium chain length acylcarnitines such as octanoylcarnitine. The maximum concentration of octanoylcarnitine was 0.22 μmol/L, with the majority being at or below the detection limit. In all 16 blood spots from newborns with confirmed MCAD deficiency, octanoylcarnitine was highly increased [median 8.4 μmol/L (range 3.1–28.3 μmol/L)], allowing easy detection. The concentration of octanoylcarnitine was significantly higher in these 16 newborns (&lt;3 days of age) than in 16 older patients (ages 8 days to 7 years) with MCAD deficiency (median 1.57 μmol/L, range 0.33–4.4). The combined experience of prospective newborn screening in Pennsylvania and North Carolina has shown a disease frequency for MCAD deficiency of 1 in 17 706. No false-positive and no known false-negative results have been found. A validated method now exists for prospective newborn screening for MCAD deficiency.

Impaired folding and subunit assembly as disease mechanism: the example of medium-chain acyl-CoA dehydrogenase deficiency

Rapid progress in DNA technology has entailed the possibility of readily detecting mutations in disease genes. In contrast to this, techniques to characterize the effects of mutations are still very time consuming. It has turned out that many of the mutations detected in disease genes are missense mutations. Characterization of the effect of these mutations is particularly important in order to establish that they are disease causing and to estimate their severity. We use the experiences with investigation of medium-chain acyl-CoA dehydrogenase deficiency as an example to illustrate that (i) impaired folding is a common effect of missense mutations occurring in genetic diseases, (ii) increasing the level of available chaperones may augment the level of functional mutant protein in vivo, and (iii) one mutation may have multiple effects. The interplay between the chaperones assisting folding and proteases that attack folding intermediates is decisive for how large a proportion of a mutant polypeptide impaired in folding acquires the functional structure. This constitutes a protein quality control system, and the handling of a given mutant protein by this system may vary due to environmental conditions or genetic variability in its components. The possibility that intraindividual differences in the handling of mutant proteins may be a mechanism accounting for phenotypic variability is discussed.

Fatty acid oxidation disorders as primary cause of sudden and unexpected death in infants and young children: an investigation performed on cultured fibroblasts from 79 children who died aged between 0-4 years

BACKGROUND

Disorders of fatty acid metabolism are known to be responsible for cases of sudden and unexpected death in infancy. At least 14 disorders are known at present. 120 cases of sudden infant death syndrome (SIDS) had been examined for a prevalent mutation (G985) causing medium chain acyl CoA dehydrogenase deficiency, which is inherited in an autosomal recessive mode. No over-representation of either homozygous or heterozygous cases was found.

AIMS

To investigate a broader spectrum of fatty acid oxidation disorders in a wider range of sudden deaths in infants and young children.

METHODS

Seventy nine cases of unexpected death in infants and young children younger than 4 years old were examined for a minimum of nine fatty acid oxidation disorders, using the global [9, 10-3H] myristic acid oxidation assay in cultured fibroblasts from achilles tendon biopsies taken at postmortem examination.

RESULTS

Three cases with fatty acid oxidation disorders and two carriers of the G985 mutation were found, all categorized as non-SIDS or borderline SIDS. The global assay used has the advantage of simplicity.

CONCLUSIONS

These results indicate that disorders of fatty acid oxidation play a small but significant role in the cause of unexpected death in infants and young children, and that infants and children dying in this way should be regarded as high risk candidates for metabolic diseases.

The molecular basis of medium-chain acyl-CoA dehydrogenase (MCAD) deficiency in compound heterozygous patients: is there correlation between genotype and phenotype?

Medium-chain acyl-CoA dehydrogenase (MCAD) deficiency is the most commonly recognized defect of mitochondrial beta-oxidation. It is potentially fatal, but shows a wide clinical spectrum. The aim of the present study was to investigate whether any correlation exists between MCAD genotype and disease phenotype. We determined the prevalence of the 14 known and seven previously unknown non-G985 mutations in 52 families with MCAD deficiency not caused by homozygosity for the prevalent G985 mutation. This showed that none of the non-G985 mutations are prevalent, and led to the identification of both disease-causing mutations in 14 families in whom both mutations had not previously been reported. We then evaluated the severity of the mutations identified in these 14 families. Using expression of mutant MCAD in Escherichia coli with or without co-overexpression of the molecular chaperonins GroESL we showed that five of the missense mutations affect the folding and/or stability of the protein, and that the residual enzyme activity of some of them could be modulated to a different extent depending on the amounts of available chaperonins. Thus, some of the missense mutations may result in relatively high levels of residual enzyme activity, whereas the mutations leading to premature stop codons will result in no residual enzyme activity. By correlating the observed types of mutations identified to the clinical/biochemical data in the 14 patients in whom we identified both disease-causing mutations, we show that a genotype/phenotype correlation in MCAD deficiency is not straightforward. Different mutations may contribute with different susceptibilities for disease precipitation, when the patient is subjected to metabolic stress, but other genetic and environmental factors may play an equally important role.

Maternal acute fatty liver of pregnancy associated with fetal trifunctional protein deficiency: molecular characterization of a novel maternal mutant allele

Acute fatty liver of pregnancy (AFLP) is a devastating late gestational complication with many similarities to the inherited disorders of mitochondrial fatty acid oxidation. We report the molecular defects in a woman with AFLP and her infant who subsequently was diagnosed with trifunctional protein (TFP) deficiency. We used single-stranded conformation variance and DNA sequence analyses of the human TFP alpha-subunit gene, which encodes the long chain 3-hydroxyacyl-CoA dehydrogenase (LCHAD) activity, to demonstrate a C to T mutation (C1678T) in exon 16 present on one allele in the mother and the affected infant. This creates a premature termination codon (R524Stop) in the LCHAD domain. Using reverse transcriptase-PCR amplification of the alpha-subunit mRNA from cultured fibroblasts, we demonstrated that transcripts containing this R524Stop mutation are present at very low levels, presumably because of rapid mRNA degradation. The affected infant also had the common E474Q mutation (nucleotide G1528C) on the second allele. Thus, he is a compound heterozygote. The father and two normal siblings are heterozygous for this E474Q mutation. This initial delineation of the R524Stop mutation provides evidence of the heterogeneity of genetic defects responsible for TFP deficiency and AFLP.

Two alpha subunit donor splice site mutations cause human trifunctional protein deficiency

Human trifunctional protein catalyzes three steps in mitochondrial beta-oxidation of fatty acids, including the long chain 3-hydroxyacyl-CoA dehydrogenase step. Deficiency of this heterocomplex, which contains 4 alpha and 4 beta subunits, causes sudden unexplained infant death, a Reye-like syndrome, cardiomyopathy, or skeletal myopathy. We determined the molecular basis of this deficiency in a patient with neonatal presentation and later sudden death using reverse transcription and PCR amplification of his alpha subunit mRNA. We demonstrated a universal deletion of exon 3 (71 bp) in his mRNA. This deletion causes a frameshift and very early premature termination. Amplification of genomic DNA demonstrated that the patient was a compound heterozygote with two different mutations in the 5' donor splice site following exon 3: a paternally inherited G to A transversion at the invariant position +1 and a maternally inherited A to G mutation at position +3. Both allelic mutations apparently cause exon 3 skipping, resulting in undetectable levels of alpha subunit protein, and complete loss of trifunctional protein. This is the initial molecular characterization of trifunctional protein deficiency.