Sabine Illsinger

Inborn Errors of Energy Metabolism Associated with Myopathies

Inherited neuromuscular disorders affect approximately one in 3,500 children. Structural muscular defects are most common; however functional impairment of skeletal and cardiac muscle in both children and adults may be caused by inborn errors of energy metabolism as well. Patients suffering from metabolic myopathies due to compromised energy metabolism may present with exercise intolerance, muscle pain, reversible or progressive muscle weakness, and myoglobinuria. In this review, the physiology of energy metabolism in muscle is described, followed by the presentation of distinct disorders affecting skeletal and cardiac muscle: glycogen storage diseases types III, V, VII, fatty acid oxidation defects, and respiratory chain defects (i.e., mitochondriopathies). The diagnostic work-up and therapeutic options in these disorders are discussed.

3-Methylglutaconic aciduria type I redefined A syndrome with late-onset leukoencephalopathy

Objective: 3-Methylglutaconic aciduria type I is a rare inborn error of leucine catabolism. It is thought to present in childhood with nonspecific symptoms; it was even speculated to be a nondisease. The natural course of disease is unknown. Methods: This is a study on 10 patients with 3-methylglutaconic aciduria type I. We present the clinical, neuroradiologic, biochemical, and genetic details on 2 new adult-onset patients and follow-up data on 2 patients from the literature. Results: Two unrelated patients with the characteristic biochemical findings of 3- methylglutaconic aciduria type I presented in adulthood with progressive ataxia. One patient additionally had optic atrophy, the other spasticity and dementia. Three novel mutations were found in conserved regions of the AUH gene. In both patients, MRI revealed extensive white matter disease. Follow-up MRI in a 10-year-old boy, who presented earlier with isolated febrile seizures, showed mild abnormalities in deep white matter. Conclusion: We define 3-methylglutaconic aciduria type I as an inborn error of metabolism with slowly progressive leukoencephalopathy clinically presenting in adulthood. In contrast to the nonspecific findings in pediatric cases, the clinical and neuroradiologic pattern in adult patients is highly characteristic. White matter abnormalities may already develop in the first decades of life. The variable features found in affected children may be coincidental. Long-term follow-up in children is essential to learn more about the natural course of this presumably slowly progressive disease. Dietary treatment with leucine restriction may be considered.

Preeclampsia and HELLP Syndrome: Impaired Mitochondrial Function in Umbilical Endothelial Cells

Preeclampsia (PE) and hemolysis, elevated liver enzymes, and low platelet count (HELLP) syndrome have been linked to congenital fetal disorders of mitochondrial fatty acid oxidation (FAO). Different incidences may argue for the association of noncongenital alterations of mitochondrial energy metabolism with PE/HELLP syndrome. We studied human umbilical vein endothelial cells [HUVEC] as selected part of the feto-placental unit from uncomplicated (n = 46) and diseased (n = 27; 17 PE and 10 HELLP) pregnancies by measuring the overall FAO, carnitine palmitoyltransferase 2 (CPT2), respiratory chain (RC) complexes I-V, citratesynthase (CS), lactatedehydrogenase (LDH), hexokinase (HK), phosphofructokinase (PFK), and energy rich phosphates. Maternal and infantile acylcarnitines in blood were investigated post partum. Overall FAO, RC complexes II-V, and CS were significantly compromised in HUVEC from complicated pregnancies; impairment of complexes I + III was not significant. CPT2 and energy charges were unaffected. Lactatedehydrogenase and PFK from complicated pregnancies were upregulated, and HK remained constant. In blood, carnitine was elevated in diseased women and their children, acylcarnitines were higher in affected infants. Impaired mitochondrial function in HUVEC is associated with PE/HELLP syndrome and may be involved in the pathophysiology of these diseases.

Impact of selected inborn errors of metabolism on prenatal and neonatal development

In general, data regarding maturational processes of different metabolic pathways in the very vulnerable fetal and neonatal period are rare. This review is to substantiate the impact of selected inborn errors of metabolism on this critical period of life and their clinical manifestation. Significant adaptation of mitochondrial/energy‐, carbohydrate‐, lysosomal‐, and amino acid‐metabolism occurs during early prenatal and neonatal development. In utero, metabolic environment has an impact on the development of the fetus as well as fetal organ maturation. Defects of distinct metabolic pathways could therefore already be of significant relevance in utero and for clinical manifestations in the early fetal and neonatal period. Disturbances of these pathways may influence intrauterine growth and health. Production of a toxic intrauterine milieu, energy‐deficiency, modification of membrane function, or disturbance of the normal intrauterine expression of genes may be responsible for fetal compromise and developmental disorders. Three categories of metabolic disorders will be discussed: the “intoxication type” (classical galactosemia, ornithine transcarbamylase deficiency, and “maternal phenylketonuria”), the “storage type” (Morbus Niemann Pick type C), and the “energy deficient type” (including long‐chain fatty acid oxidation disorders, pyruvate dehydrogenase deficiency, and respiratory chain defects). For these disorders, the pathophysiology of early manifestation, special aspects regarding the prenatal and neonatal period, and diagnostic as well as therapeutic options are presented.

BH4-sensitive hyperphenylalaninemia: new case and review of literature

We report a patient with BH(4)-sensitive phenylketonuria. In neonatal screening, phenylalanine levels above 10 mg/dl were detected. In the tetrahydrobiopterin- (BH(4)) loading test, phenylalanine concentrations in serum fell significantly. Dihydropteridine reductase activity in blood, pterines, and neurotransmitters in cerebrospinal fluid, as well as pterines in urine were all normal. Mutation analysis revealed compound-heterozygosity for the mutations R408W and K320N. Under BH(4)-supplementation without a specific phenylalanine-reduced diet, phenylalanine-concentrations are in the therapeutic range and our patient developed normally.

Prenatal benzoate treatment in urea cycle defects

Objective: In patients with severe urea cycle defects (UCD) metabolic decompensation with hyperammonaemia typically occurs during the first days of life resulting in severe neurological damage or death. Benzoate can eliminate nitrogen independent of the urea cycle. Usually, benzoate is started soon after birth, but prenatal administration might improve metabolic stability. Design: Two fetuses with a prenatal diagnosis of UCD (female: citrullinaemia; male: ornithine transcarbamylase deficiency) were loaded with benzoate prenatally via the placenta by infusing their mothers with benzoate. Benzoate concentrations were measured in umbilical cord blood and the blood of the mothers and their newborns. Results: Therapeutic concentrations of benzoate were found in umbilical cord blood and in the children’s blood. Thus, benzoate transfer across the placenta was demonstrated. Plasma ammonia and glutamine levels in the postnatal period were within the normal range. Conclusions: Benzoate infusion of the mother shortly before birth is safe and results in therapeutic levels of benzoate in umbilical cord blood.

Asymmetric dimethylarginine in children with homocystinuria or phenylketonuria

Plasma concentration of asymmetric dimethylarginine (ADMA), an endogenous inhibitor of nitric oxide (NO) synthesis from l-arginine and a cardiovascular risk factor, was found to be elevated in plasma of homocysteinemic adults. Enhanced cardiovascular risk due to homocystinuria and impaired renal function has been found in patients with phenylketonuria (PKU) on protein-restricted diet. However, it is still unknown whether ADMA synthesis is also elevated in children with homocystinuria due to cystathionine beta-synthase deficiency (classical homocystinuria), and whether ADMA may play a role in phenylketonuria in childhood. In the present study, we investigated the status of the l-arginine/NO pathway in six young patients with homocystinuria, in 52 young phenylketonuria patients on natural protein-restricted diet, and in age- and gender-matched healthy children serving as controls. ADMA in plasma and urine was determined by GC–MS/MS. The NO metabolites nitrate and nitrite in plasma and urine, and urinary dimethylamine (DMA), the dimethylarginine dimethylaminohydrolase (DDAH) metabolite of ADMA, were measured by GC–MS. Unlike urine ADMA excretion, plasma ADMA concentration in patients with homocystinuria was significantly higher than in controls (660xa0±xa0158 vs. 475xa0±xa077xa0nM, Pxa0=xa00.035). DMA excretion rate was considerably higher in children with homocystinuria as compared to controls (62.2xa0±xa024.5 vs. 6.5xa0±xa02.9xa0μmol/mmol creatinine, Pxa0=xa00.068), indicating enhanced DDAH activity in this disease. In contrast and unexpectedly, phenylketonuria patients had significantly lower ADMA plasma concentrations compared to controls (512xa0±xa0136 vs. 585xa0±xa0125xa0nM, Pxa0=xa00.009). Phenylketonuria patients and controls had similar l-arginine/ADMA molar ratios in plasma. Urinary nitrite excretion was significantly higher in phenylketonuria as compared to healthy controls (1.7xa0±xa01.7 vs. 0.7xa0±xa01.2xa0μmol/mmol creatinine, Pxa0=xa00.003). Our study shows that the l-arginine/NO pathway is differently altered in children with phenylketonuria and homocystinuria. Analogous to hyperhomocysteinemic adults, elevated ADMA plasma concentrations could be a cardiovascular risk factor in children with homocystinuria. In phenylketonuria, the l-arginine/NO pathway seems not be altered. Delineation of the role of ADMA in childhood phenylketonuria and homocystinuria demands further investigation.

Glycogen Storage Disease Type 1: Impact of Medium-Chain Triglycerides on Metabolic Control and Growth

Background/Objective: Hypoketotic hypoglycaemia and hypertriglyceridaemia are biochemical hallmarks of glycogen storage disease (GSD) 1. Increased malonyl coenzyme A production which compromises oxidation of long-chain fatty acids via carnitine palmitoyltransferase (CPT) 1 inhibition plays a crucial role in the pathogenesis of these complications. Therapy consists primarily of nutritional support including frequent carbohydrate-rich meals. We studied the effect of a diet enriched in medium-chain triglycerides (MCT) on metabolic control/growth in GSD 1 as medium-chain fatty acids can be oxidised independently of CPT 1. Methods: An adult female, a 1.6-year-old boy with GSD 1a and a 6.5-year-old girl with GSD 1b treated with a classical GSD diet were enrolled; their ‘classical GSD diet’ was supplemented with MCT fats. Concentrations of glucose, lactate, ketone bodies triglycerides, uric acid, acylcarnitines in blood and organic acids in urine were determined. Results: No clinical or biochemical side-effects were observed. The MCT diet led to a decrease in uric acid concentrations in all patients. Triglyceride levels were reduced only in the youngest patient, while lactate concentrations did not significantly decrease. The MCT diet allowed for a reduction in carbohydrate and caloric intake required to maintain euglycaemia and led to improvement in growth in the two prepubertal patients. Conclusions: MCT supplementation had a positive effect on metabolic control and growth in our patients suffering from GSD 1.

Branched chain amino acids as a parameter for catabolism in treated phenylketonuria

Summary.This study was performed to study an association between nutritional status on one hand and BCAA- and Phe-concentrations on the other hand in PKU patients free of infection. AA profiles from 70 PKU patients were measured. 9 patients (subgroup I) with elevated Phe- and BCAA-concentrations as well as 23 patients (subgroup II) with only elevated Phe-levels were included. Dietary records were obtained from both groups; low caloric intake in subgroup I was increased with Duocal® or p-am ANAMIX® without modifying total protein- and Phe-intake. AA profiles were controlled after 2 weeks.Additionally, we investigated AA profiles from 26 liver transplanted patients with increased carbohydrate and caloric intake as an example for anabolism.In subgroup I Phe- and Isoleu-concentrations decreased sign. after dietary intervention. Leu, Val and Tyr levels decreased not sign. Initial Phe-levels correlated negatively with protein and caloric intake.BCAA concentrations of liver transplanted patients receiving high amounts of carbohydrates were in the lower range of normal.Increased caloric intake lowered most of the elevated Phe- and BCAA- concentrations.

Cyclosporine A: impact on mitochondrial function in endothelial cells

Illsinger S, Janzen N, Lücke T, Bednarczyk J, Schmidt K‐H, Hoy L, Sander J, Das AM. Cyclosporine A: impact on mitochondrial function in endothelial cells.u2028Clin Transplant 2011: 25: 584–593.