ACADS

Abstract: We describe two patients with short-chain acyl-coenzyme A (CoA) dehydrogenase (SCADH) deficiency. Neonate I excreted large amounts of ethylmalonate and methylsuccinate; ethylmalonate excretion increased after a medium-chain triglyceride load. Neonate II died postnatally and excreted ethylmalonate, butyrate, 3-hydroxybutyrate, adipate, and lactate. Both neonates' fibroblasts catabolized [1-14C]butyrate poorly (29-64% of control). Neonate I had moderately decreased [1-14C]octanoate catabolism (43-60% of control), while neonate II oxidized this substrate normally; both catabolized radiolabeled palmitate, succinate, and/or leucine normally. Cell sonicates from neonates I and II dehydrogenated [2,3-3H]butyryl-CoA poorly (41 and 53% of control) and [2,3-3H]octanoyl-CoA more effectively (59 and 95% of control). Mitochondrial acyl-CoA dehydrogenase (ADH) activities with butyryl- and octanoyl-CoAs were 37 and 56% of control in neonate I, and 47 and 81% of control in neonate II, respectively. Monospecific medium-chain ADH (MCADH) antisera inhibited MCADH activity towards both butyryl- and octanoyl-CoAs, revealing SCADH activities to be 1 and 11% of control for neonates I and II, respectively. Fibroblast SCADH and MCADH activities were normal in an adult female with muscular SCADH deficiency.

Abstract: Short-chain acyl-CoA dehydrogenase (SCAD) deficiency is considered a rare inherited mitochondrial fatty acid oxidation disorder. Less than 10 patients have been reported, diagnosed on the basis of ethylmalonic aciduria and low SCAD activity in cultured fibroblast. However, mild ethylmalonic aciduria, a biochemical marker of functional SCAD deficiency in vivo, is a common finding in patients suspected of having metabolic disorders. Based on previous observations, we have proposed that ethylmalonic aciduria in a small proportion of cases is caused by pathogenic SCAD gene mutations, and SCAD deficiency can be demonstrated in fibroblasts. Another - much more frequent - group of patients with mild ethylmalonic aciduria has functional SCAD deficiency due to the presence of susceptibility SCAD gene variations, i.e. 625G>A and 511C>T, in whom a variable or moderately reduced SCAD activity in fibroblasts may still be clinically relevant. To substantiate this notion we performed sequence analysis of the SCAD gene in 10 patients with ethylmalonic aciduria and diagnosed with SCAD deficiency in fibroblasts. Surprisingly, only one of the 10 patients carried pathogenic mutations in both alleles, while five were double heterozygotes for a pathogenic mutation in one allele and the 625G>A susceptibility variation in the other. The remaining four patients carried only either the 511C>T or the 625G>A variations in each allele. Our findings document that patients carrying these SCAD gene variations may develop clinically relevant SCAD deficiency, and that patients with even mild ethylmalonic aciduria should be tested for these variations.

Abstract: ContextShort-chain acyl-coenzyme A (CoA) dehydrogenase (SCAD) deficiency (SCADD) is an autosomal recessive, clinically heterogeneous disorder with only 22 case reports published so far. Screening for SCADD is included in expanded newborn screening programs in most US and Australian states.ObjectivesTo describe the genetic, biochemical, and clinical characteristics of SCADD patients in the Netherlands and their SCADD relatives and to explore the genotype to phenotype relation.Design, Setting, and ParticipantsRetrospective study involving 31 Dutch SCADD patients diagnosed between January 1987 and January 2006 and 8 SCADD relatives. SCADD was defined by the presence of (1) increased butyrylcarnitine (C4-C) levels in plasma and/or increased ethylmalonic acid (EMA) levels in urine under nonstressed conditions on at least 2 occasions, in combination with (2) a mutation and/or the c.511C>T or c.625G>A susceptibility variants on each SCAD-encoding (ACADS) allele. Patients were included only if the SCAD-encoding (ACADS) was fully sequenced and if current clinical information could be obtained. Relatives were included when they carried the same ACADS genotype as the proband, and had increased C4-C and/or EMA.Main Outcome MeasuresPrevalence, genotype (mutation/mutation, mutation/variant, variant/variant), C4-C and EMA levels, clinical signs and symptoms, and clinical course.ResultsA birth-prevalence of at least 1:50 000 was calculated. Most patients presented before the age of 3 years, with nonspecific, generally uncomplicated, and often transient symptoms. Developmental delay, epilepsy, behavioral disturbances, and hypoglycemia were the most frequently reported symptoms. The ACADS genotype showed a statistically significant association with EMA and C4-C levels, but not with clinical characteristics. Seven out of 8 SCADD relatives were free of symptoms.ConclusionsSCADD is far more common than assumed previously, and clinical symptoms in SCADD are nonspecific, generally uncomplicated, often transient, and not correlated with specific ACADS genotypes. Because SCADD does not meet major newborn screening criteria, including a lack of clinical significance in many patients and that it is not possible to differentiate diseased and nondiseased individuals, it is not suited for inclusion in newborn screening programs at the present time.

Abstract: The acyl-CoA dehydrogenases (ACADs) are enzymes that catalyze the α,β-dehydrogenation of acyl-CoA esters in fatty acid and amino acid catabolism. Eleven ACADs are now recognized in the sequenced human genome, and several homologs have been reported from bacteria, fungi, plants, and nematodes. We performed a systematic comparative genomic study, integrating homology searches with methods of phylogenetic reconstruction, to investigate the evolutionary history of this family. Sequence analyses indicate origin of the family in the common ancestor of Archaea, Bacteria, and Eukaryota, illustrating its essential role in the metabolism of early life. At least three ACADs were already present at that time: ancestral glutaryl-CoA dehydrogenase (GCD), isovaleryl-CoA dehydrogenase (IVD), and ACAD10/11. Two gene duplications were unique to the eukaryotic domain: one resulted in the VLCAD and ACAD9 paralogs and another in the ACAD10 and ACAD11 paralogs. The overall patchy distribution of specific ACADs across the tree of life is the result of dynamic evolution that includes numerous rounds of gene duplication and secondary losses, interdomain lateral gene transfer events, alteration of cellular localization, and evolution of novel proteins by domain acquisition. Our finding that eukaryotic ACAD species are more closely related to bacterial ACADs is consistent with endosymbiotic origin of ACADs in eukaryotes and further supported by the localization of all nine previously studied ACADs in mitochondria.