C. Charpentier

Clinical aspects of mitochondrial disorders

SummaryMitochondrial disorders have long been regarded as neuromuscular diseases only. In fact, owing to the ubiquitous nature of the oxidative phosphorylation, a broad spectrum of clinical features should be expected in mitochondrial disorders. Here, we present eight puzzling observations which give support to the view that a disorder of oxidative phosphorylation can give rise to any symptom in any organ or tissue with any apparent mode of inheritance. Consequently, we suggest giving consideration to the diagnosis of a mitochondrial disorder when dealing with an unexplained association of symptoms, with an early onset and a rapidly progressive course involving seemingly unrelated organs. Determination of lactate/pyruvate and ketone body molar ratios in plasma can help to select patients at risk for this condition.

Alpha-ketoglutarate dehydrogenase deficiency presenting as congenital lactic acidosis

We report an inborn error of the tricarboxylic acid cycle, alpha-ketoglutarate dehydrogenase deficiency, in three siblings with hypotonia, metabolic acidosis, and hyperlactatemia immediately after birth. Neurologic deterioration resulted in death at about 30 months of age. We propose low molar ratios of ketone bodies in plasma of neonates with congenital lactic acidosis as an indication of dysfunction of the tricarboxylic acid cycle.

CONGENITAL LACTIC ACIDOSIS, α-KETOGLUTARIC ACIDURIA AND VARIANT FORM OF MAPLE SYRUP URINE DISEASE DUE TO A SINGLE ENZYME DEFECT: DIHYDROLIPOYL DEHYDROGENASE DEFICIENCY

ABSTRACT. A 6 month‐old girl with vomiting, hypotonia and motor retardation was found to have elevated blood lactate, pyruvate, and branched chain amino acids essociated with ketoglutaric aciduria. The combination of a congenital lactic acidosis with a variant form of maple syrup urine disease and ketoglutaric aciduria suggested a defect of a single component, common to pyruvate dehydrogenase, to branched chain ketoacid dehydrogenase, and to α‐ketoglutarate dehydrogenase. Dihydrolipoyl dehydrogenase is the common component (E3). The three enzyme activities and the E3 component activity were found to be reduced in liver and cultured fibroblasts, thus confirming that a single defect of this component can result in a multiple deflciency involving several oxidative decarboxylation reactions.

Clinical Approach to Inherited Metabolic Diseases in the Neonatal Period: A 20-year Survey

SummaryEvery newborn with unexplained neurological deterioration, ketosis, metabolic acidosis or hypoglycaemia should be suspected of having an inherited error of intermediary metabolism. Many of these conditions can be diagnosed clinically with the aid of simple laboratory investigations. Since a substantial number of these diseases respond well to treatment but may otherwise be fatal, and in order to assure adequate prenatal diagnosis in subsequent pregnancies, a high index of suspicion and rapid diagnosis are necessary in the face of the clinical presentations described. According to three major clinical presentations observed in 218 neonates with inborn errors of intermediary metabolism (neurological distress ‘intoxication’ type, neurological distress ‘energy deficiency’ type and hypoglycaemia with liver dysfunction) and according to the proper use of few laboratory investigations, we propose a method of diagnosis which groups these children into five categories. Initial therapy, and sophisticated investigations can be planned on the basis of this grouping.

Decreased plasma ubiquinone-10 concentration in patients with mevalonate kinase deficiency

ABSTRACT: Patients with mevalonate kinase deficiency suffer from psychomotor retardation, ataxia with progredient cerebellar atrophy, and myopathy. The pathophysiology of the disease remains unclear. The mevalonate kinase product, cholesterol, is within the normal range in patient plasma and fibroblasts. In search of the pathophysiology of this disorder, another mevalonate kinase product, ubiquinone-10, was studied. The concentrations of ubiquinone-10 in patient plasma (n = 6) and ubiquinol-10 in patient LDL (n = 2) and the synthesis of ubiquinone-10 in patient fibroblasts (n = 4) were determined. After oxidative modification of LDL by copper in vitro, the concentrations of α-tocopherol and polyunsaturated fatty acids in LDL and the relative electrophoretic mobility of LDL were measured to determine the antioxidant capacity of LDL samples of two affected siblings. The ubiquinone-10 concentrations in plasma samples (median = 508 μg/L, range = 488–642 μg/L) versus controls (median = 613 μg/L, range = 564–809 μg/L; p < 0.005) were decreased. In LDL samples of two affected siblings, the concentration of ubiquinol-10 and the resistance to oxidation in vitro were found decreased during intercurrent patient crisis condition. In patient fibroblasts (median = 533 dpm/mg protein, range = 399–1 047 dpm/mg protein) versus controls (median = 40 731 dpm/mg protein, range = 12 774–54 739 dpm/mg protein), the synthesis of ubiquinone was found to be decreased. We conclude that mevalonate kinase deficiency leads to a decreased synthesis of ubiquinone-10 and that ubiquinone-10 deficiency is responsible for the clinical progression of this disease characterized by increased lipid peroxidation, cerebellar atrophy, cataract development, and myopathy with increased creatine kinase activity.

Variation in plasma ketone bodies during a 24-hour fast in normal and in hypoglycemic children: Relationship to age

The variations in blood ketone bodies, blood glucose, and insulin were studied in 19 normal and 14 hypoglycemic children, 4 months to 13 years of age, during a 24-hour fast. Except in four patients (two with hyperinsulinism and two with congenital defect in ketogenesis), a significant increase in blood ketone bodies was observed in both controls and patients. A progressive decrease in glucose concentrations was observed up to but not after 20 hours. A highly negative correlation between blood ketone bodies and blood glucose was found, with a large dispersion of blood ketone bodies, especially for those corresponding to the blood glucose between 45 and 65 mg/dl. This dispersion was consistently reduced in a homogenous age group of 4 to 6 years with similar glucose values. There was a positive correlation between age and blood glucose from hour 21 on, and an inverse relationship between age and blood ketone bodies from hour 15 on. The same high inverse relationship between age and blood ketone bodies was again observed when the variable of glucose concentration was factored out, demonstrating that the variation in blood ketone bodies is indeed related to age. These findings need to be taken into account in the interpretation of fasting blood ketone bodies, especially when used as an aid in the diagnosis of the various forms of childhood hypoglycemia, and of hypoketotic states.

Multiple acyl-CoA dehydrogenase deficiency occurring in pregnancy and caused by a defect in riboflavin metabolism in the mother: Study of a kindred with seven deaths in infancy: Value of riboflavin therapy in preventing this syndrome

Seven infants in one kindred died: one was stillborn; the others, who were floppy at birth and were breast-fed, developed a disorder with the odor of sweaty feet and died in early infancy. In two further pregnancies, 3-hydroxvisovaleric, glutaric, and C6-C10-dicarboxylic acids were demonstrated in the mothers urine during the seventh month. Riboflavin therapy in the last trimester of pregnancy and a riboflavin-rich diet given the infants prevented this syndrome. The presence of abnormal erythrocyte glutathione-reductase activity in the mother while she excreted normal amounts of riboflavin in her urine indicates a probable disorder of riboflavin metabolism resulting in multiple acyl-CoA dehydrogenase deficiency.

Neonatal glutaric aciduria type II: An X-linked recessive inherited disorder

SummaryA new case of neonatal glutaric aciduria type II is reported. Neonatal acidosis, hypoglycemia, and hyperammonemia were characteristic. The baby died at four days of age. Organic acid analysis revealed massive glutaric aciduria with elevated concentrations of butyric, isobutyric, n-butyric, and isovaleric acid in his urine. The babys pedigree suggested strongly an X-linked recessive mode of inheritance. Clinically, biochemically, and genetically glutaric aciduria type II is an heterogeneous disorder. The neonatal form is an X-linked inherited disorder which presents early in life, and is associated with metabolic acidosis, hypoglycemia, and hyperammonemia, and leads to death in the neonatal period. The mild form is an autosomal recessive inherited disease which may present even in adults, and is associated with recurrent hypoglycemia without ketosis and usually improves. Nevertheless the same unusual organic acid pattern is observed in both forms. The basic biochemical defect must be distinct and has not been elucidated.

Hudson Memorial Lecture Neonatal Management of Organic Acidurias. Clinical Update

Therapeutic guidelines have been obtained from a retrospective review of 41 patients affected with organic acidaemias, 16 patients with neonatal maple syrup urine disease (MSUD), 11 methylmalonic acidaemia, (MMA) seven propionic acidaemias (PA) and seven isovaleric acidaemias (IVA), and by comparing this personal series with similar reported cases. The emergency treatment of these organic acidurias in the neonate has to main goals: toxin removal and anabolism. Anabolism is always promoted by early diet therapy. The best method of toxin removal depends on the nature of the defect; peritoneal dialysis with exchange transfusions or multiple or prolonged exchange transfusions in MSUD and in PA, diuresis and exchange transfusions in MMA and glycine supplementation in IVA. Vitamin supplementation (thiamine 20 mg, biotin 10 mg, B12 2 mg and riboflavin 100 mg) should be tried in all cases although the neonatal forms of these defects are very rarely vitamin responsive. Additional treatments such as carnitine or insulin may prove to be useful.

Biotin dependent multiple carboxylase deficiency presenting as a congenital lactic acidosis

Two patients presented in early childhood with (i) alopecia, skin rashs, and candida dermatitis, (ii) severe hypotonia, ataxia and motor retardation, (iii) frequent episodes of ketoacidosis with hyperlactacidemia. Propionic and methylcrotonic aciduria only appeared on high protein diet. Mitochondrial biotin-dependent carboxylase activities were decreased in the liver and leukocytes, but were similar to control values in fibroblasts cultured in a biotin-free medium. In addition, the plasma biotin was found to be significantly lower than in control subjects. These disorders responded to biotin administration, pointing to biotin-dependent multiple carboxylase deficiencies (MCD). Our report stresses the polymorphism of MCD and suggests that MCD could be of two types: impaired vitamin metabolism (absorption, plasma transport), might result in low plasma biotin with generalized MCD involving acetyl CoA carboxylase. Defective mitochondrial holocarboxylase synthetase might lead to a pure mitochondrial MCD, with fibroblastic deficiency and presumably normal biotin metabolism.