Nuclear DNA origin of mitochondrial complex I deficiency in fatal infantile lactic acidosis evidenced by transnuclear complementation of cultured fibroblasts.

We have studied complex I (NADH-ubiquinone reductase) defects of the mitochondrial respiratory chain in 2 infants who died in the neonatal period from 2 different neurological forms of severe neonatal lactic acidosis. Specific and marked decrease in complex I activity was documented in muscle, liver, and cultured skin fibroblasts. Biochemical characterization and study of the genetic origin of this defect were performed using cultured fibroblasts. Immunodetection of 6 nuclear DNA-encoded (20, 23, 24, 30, 49, and 51 kDa) and 1 mitochondrial DNA-encoded (ND1) complex I subunits in fibroblast mitochondria revealed 2 distinct patterns. In 1 patient, complex I contained reduced amounts of the 24- and 51-kDa subunits and normal amounts of all the other investigated subunits. In the second patient, amounts of all the investigated subunits were severely decreased. The data suggest partial or extensive impairment of complex I assembly in both patients. Cell fusion experiments between 143B206 rho degrees cells, fully depleted of mitochondrial DNA, and fibroblasts from both patients led to phenotypic complementation of the complex I defects in mitochondria of the resulting cybrid cells. These results indicate that the complex I defects in the 2 reported cases are due to nuclear gene mutations.

Metabolic studies in a patient with severe carnitine palmitoyltransferase type II deficiency.

Here we report on a patient with severe ("non-classic") carnitine palmitoyltransferase type II (CPT II) deficiency. Hypoglycemia prompted by an infectious episode and associated with non-ketotic dicarboxylic aciduria orientated diagnosis towards beta-oxidation deficiency disorders. Blood carnitine levels revealed a secondary carnitine deficiency that was responsive to oral L-carnitine supplementation. Blood acylcarnitine profiles were abnormal and included acetyl (C2:0), butyryl/isobutyryl (C4:0), isovaleryl/2-methylbutyryl (C5:0), hexanoyl (C6:0), myristoyl (C14:0), palmitoyl (C16:0), hexadecenoyl (C16:1), oleyl (C18:1) and stearoyl (C18:0) carnitine. In urine, excess excretion of dicarboxylylcarnitines, mainly dodecanedioylcarnitine, was noticed. Upon carnitine supplementation, C8 to C12 fatty acylcarnitines, with decanoylcarnitine as well as C10 to C14 dicarboxylylcarnitines being prominent, were observed in urine. Biochemical measurements disclosed a severe reduction of mitochondrial CPT II activity (7% of normal values). Correlations of metabolic findings in the patient and physiological roles of CPT II are briefly discussed.

Serum 5'-nucleotidase and alkaline phosphatase activities after high dose chemotherapy and bone marrow transplantation in cases of malignancy in children.

After bone marrow transplantation in children, it is essential to detect secondary liver diseases and hepatotoxic effects of immunosuppressive therapy. These can be revealed by cytolytic syndromes sometimes associated with cholestasis. It is therefore important to find an early and specific cholestasis enzymatic marker. A retrospective study of the changes in levels of biological parameters has been carried out in 13 children who underwent one or more bone marrow transplantations. During the 3 months following bone marrow transplantation, all patients developed liver injury characterized by an early and very elevated 5'-nucleotidase activity (sometimes more than 40 times the upper reference limit), a moderate increase in alkaline phosphatase activity, a variable increase in alanine aminotransferase activity and inconstant changes in total bilirubin levels. These results show that cytolytic syndrome and cholestasis are often associated with increases in 5'-nucleotidase and alkaline phosphatase activities. These increases are not correlated, probably due to the influence of therapy on the synthesis and release of both enzymes in the liver. 5'-nucleotidase seems to be the best marker for the detection and follow-up of liver disease in this patient group.

Prevention of neonatal hypoglycaemia by oral lipid supplementation in low birth weight infants.

The effect of oral lipid supplementation (2.9 g/day containing 67% medium chain triglycerides) on the prevention of neonatal hypoglycaemia was evaluated in 28 low birth weight infants (mean +/- 1 SD for gestational age: 36 +/- 1.2 weeks and birth weight: 1778 +/- 230 g) and compared to a control group of 23 infants with similar gestational age, birth weight and sex. The incidence of hypoglycaemic patients with plasma glucose less than 1.72 mmol/l was 8/23 (35%) in the control group versus 2/28 (7%) in the supplemented group: chi 2 = 6.72; P less than 0.01. Determinations of plasma beta-hydroxybutyrate concentrations in 11 infants of the supplemented group did not show values higher than 1.2 mmol/l. This prospective study shows that supplementation with lipids can prevent the occurrence of hypoglycaemia in low birth weight infants.