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Research Notes: FumaraseThere are two types of fumarase found within human tissues, cytosolic and mitochondrial. The mitochondrial form is responsible for the reversible conversion of fumarate to S-malate in the Kreb's cycle, while the cytosolic form metabolizes fumarate, a by-product of the urea cycle. Am J Med Genet A. 2006 Nov 13. The neuropathologic abnormalities associated with Prader-Willi syndrome (PWS) are largely unknown. PWS is due to the loss of several paternally expressed genes in chromosome 15q11-q13 region. Several of the imprinted genes in the 15q11-q13 region are normally expressed in the brain and thought to be necessary for neuronal growth and development. Thus, we hypothesized that we would find abnormalities in gray and white matter growth in individuals with PWS. We evaluated three-dimensional (3-D) MRI scans of 20 individuals with PWS, aged three months to 39 years, and compared them to 3-D MRI scans of 21 normal weight sibling controls and 16 individuals with early-onset morbid obesity (EMO) of unknown etiology. The interpreters of the scans were blinded to the diagnosis of the subjects. Intracranial abnormalities in individuals with PWS included ventriculomegaly (100% of individuals), decreased volume of brain tissue in the parietal-occipital lobe (50%), sylvian fissure polymicrogyria (60%), and incomplete insular closure (65%). None of the EMO or normal weight control subjects had any of these findings. We found multiple morphologic brain abnormalities in subjects with PWS suggesting that the loss of paternally expressed genes in chromosome 15q11-q13 region may result in abnormalities of neuronal development. The specific mechanisms underlying these neuropathological abnormalities and their correlation with the clinical phenotype remain to be elucidated. Note: It's interesting that a number of these findings are also found in mitochondrial disorders and other impairments of energy metabolism. For example, ventriculomegaly is also found in Leigh syndrome, cytochrome oxidase deficiency, pyruvate dehydrogenase deficiency, holocarboxylase synthetase deficiency, and familial mitochondrial encephalopathy. Similarly, polymicrogyria is found in peroxisomal bifunctional enzyme defects and fumaric aciduria (fumaric acidemia, fumarase deficiency). J Inherit Metab Dis. 2006 Oct. Fumaric aciduria is a rare, autosomal recessive disorder caused by deficient activity of fumarate hydratase (FH). Common clinical features are hypotonia, failure to thrive, severe psychomotor retardation and seizures. Facial dysmorphism and brain malformations are frequent. Recently, some FH gene mutations have been associated with inherited cutaneous and uterine leiomyomas and papillary renal cell cancer. Our patient had a relatively mild phenotype, a previously not reported genotype and familial tumour predisposition. The mother and grandmother had uterine myomas. The paternal grandfather and his two brothers died from lung and laryngeal cancers. The pregnancy was complicated by bleeding and intrauterine growth retardation. Delivery was after 35 weeks, with normal Apgar score. The girl was hypotonic since birth. At age 2 months the parents noticed short apnoeic crises. She could sit at age 1.5 years, and walk with assistance at 4 years. At age 8 years highly increased excretion of fumaric acid was found twice (217 and 445 mmol/mol creatinine). Shortly before that the girl started to have leg and arm spasms. Grand mal seizures occurred twice. Facial dysmorphism included depressed nasal bridge, anteverted ears, hypertelorism and microcephaly. Speech was limited to few disyllables. She was atactic with spastic paraparesis. Brain MRI showed slight ventriculomegaly, white-matter atrophy and hypoplasia of corpus callosum. Activity of FH in fibroblasts was 1.9 nmol/min/mg protein (controls 40-80). Analysis of the FH gene revealed the maternally derived c.1029_1031delAGT mutation, resulting in Val deletion and substitution of Gln by His, and paternally derived c.976C > T mutation, resulting in substitution of Pro by Ser. Mol Genet Metab. 2006 Jun. Fumarase (FH) deficiency is a rare autosomal recessive disease of the Krebs cycle causing severe neurological impairment in early childhood, characterized by encephalopathy with seizures and muscular hypotonia. Only a handful of patients with various recessive mutations in the FH gene have been described so far. Interestingly, autosomal dominant mutations in the same gene are associated with hereditary leiomyomatosis and renal cell cancer (HLRCC). We investigated a boy with developmental and growth delay, microcephaly, and muscular hypotonia recognized at the age of 3 months. No leiomyomatosis or renal cancer is known in the parents. Investigation of the patient's urine revealed massive fumarate excretion. FH activity was severely reduced in muscle and fibroblasts. Respirometric investigation of fibroblasts showed only modest changes indicating that fumarate mediated inhibition of enzymatic pathways other than oxidative phosphorylation might be more relevant in pathophysiology of FH deficiency. Molecular analysis revealed a known 435insK mutation on the paternal allele and a novel H275L mutation due to an A to T transversion of nucleotide 824 on the maternal allele. This mutation affects the same codon as a C to T transition of nucleotide 823, resulting in a H275Y mutation that was found in two families with HLRCC. J Inherit Metab Dis. 2005. A fumarase-deficient patient expressed a novel phenotype of congenital cerebral ventricular dilatation and periventricular cysts. The patient was a compound heterozygote for two mutations that are the only ones among the 12 published mutations that have been found in multiple, unrelated, fumarase-deficient patients. Ann Neurol. 2000 May. Fumaric aciduria (fumaric acidemia, fumarase deficiency) is a rare inborn error of metabolism caused by deficient activity of fumarate hydratase, one of the constituent enzymes of the Krebs tricarboxylic acid cycle. We describe the clinical and imaging features of this disease arising from a consanguineous pedigree in 8 patients in the southwestern United States. Thirteen patients have been previously described in the medical literature. Our patients presented with an early infantile encephalopathy with profound developmental retardation and hypotonia, and most experienced seizures. Previously unreported characteristics described here include structural brain malformations, dysmorphic facial features, and neonatal polycythemia. Magnetic resonance imaging showed multiple abnormalities, including diffuse polymicrogyria, decreased cerebral white matter, large ventricles, and open opercula. Fumaric aciduria should be included in the differential diagnosis of inborn errors of metabolism that cause cerebral malformations and dysmorphic features. The possibility that inborn errors of energy metabolism may cause structural malformations deserves increased recognition. J Clin Invest. 1994 Jun. We report an inborn error of the tricarboxylic acid cycle, fumarase deficiency, in two siblings born to first cousin parents. They presented with progressive encephalopathy, dystonia, leucopenia, and neutropenia. Elevation of lactate in the cerebrospinal fluid and high fumarate excretion in the urine led us to investigate the activities of the respiratory chain and of the Krebs cycle, and to finally identify fumarase deficiency in these two children. The deficiency was profound and present in all tissues investigated, affecting the cytosolic and the mitochondrial fumarase isoenzymes to the same degree. Analysis of fumarase cDNA demonstrated that both patients were homozygous for a missense mutation, a G-955-->C transversion, predicting a Glu-319-->Gln substitution. This substitution occurred in a highly conserved region of the fumarase cDNA. Both parents exhibited half the expected fumarase activity in their lymphocytes and were found to be heterozygous for this substitution. The present study is to our knowledge the first molecular characterization of tricarboxylic acid deficiency, a rare inherited inborn error of metabolism in childhood. J Pediatr. 1992 Nov. A 5-year-old girl with a previous diagnosis of cerebral palsy, nonprogressive psychomotor retardation, and hypotonia was found to excrete excessive fumaric acid in urine. Fumarate hydratase activity in skin fibroblasts was 10% of the control value. This case underscores the clinical heterogeneity of neurometabolic disorders and the importance of organic acid analysis in the diagnosis of static encephalopathy. Pediatrics. 1992 Apr. A family having two boys with progressive encephalomyopathy and fumaric aciduria due to fumarase deficiency is described. Both patients initially presented with polyhydramnios and enlarged cerebral ventricles in utero, with subsequent cerebral atrophy, severe developmental delay, infantile spasms, and hypsarythmia on electroencephalogram. Fumarase activity in blood mononuclear cells and in the mitochondrial and cytosolic fractions of cultured skin fibroblasts was less than 0.5% of the control mean or undetectable. The older boy died at the age of 5 years and 4 months and the younger one is now 2 years and 10 months. The unrelated parents are symptomless and the other three children in the family are clinically healthy. Fumarase activities in the blood mononuclear cells of the father, mother, sister, and two brothers were 59%, 52%, 52%, 120%, and 44% of the control mean, respectively. The results strongly support autosomal recessive inheritance of fumarase deficiency and suggest its consideration in children with congenital hydrocephalus, progressive brain atrophy, and infantile spasms. Neurology. 1990 Mar. A 7-month-old boy died in a demented state after a clinical history characterized by generalized seizures, psychomotor deterioration, and fumaric aciduria. We found a marked deficiency of both mitochondrial and cytosolic fumarases in skeletal muscle, brain, cerebellum, heart, kidney, liver, and cultured fibroblasts. Fumarase activities were 30 to 50% compared with controls in both mitochondria and cytosol from cultured fibroblasts of the parents. Antifumarase cross-reacting material was present in negligible amounts in the patient's tissues. Our data indicate that this disease is an autosomal recessive encephalopathy, due to a single mutation affecting the gene encoding both forms of the enzyme. Anaesthesia. 1989 Dec. The anaesthetic management for an infant with mitochondrial encephalomyopathy due to fumarase deficiency is described. Mitochondrial myopathies may produce skeletal and cardiac muscle abnormalities, central nervous system effects and metabolic problems. The solutions to the anaesthetic problems posed by these patients are discussed. Am J Hum Genet. 1987 Mar. A male infant, whose parents were first cousins, presented at 6 mo of age with hypotonia, microcephaly, and delayed development. He was found to have large amounts of fumaric and succinic acids present in the urine. In lysed cultured skin-fibroblast preparations, the activity of fumarase was found to be 22.7% of that in controls. Cell fractionation by homogenization and by digitonin treatment indicated that the residual activity in the cells of the patient was primarily located in the mitochondrial fraction rather than in the cytosolic fraction. Isoelectric focusing of fibroblast extracts showed that six bands of fumarase activity were discernible in control cell lines, two of them cytosolic with pI's of 5.53 and 5.60 and four of them mitochondrial with a pI of 5.65-6.8. In contrast, isoelectric focusing of fibroblast extracts from the fumarase-deficient patient showed only a single band of activity with a pI corresponding to the mitochondrial type seen in the controls. Immunoprecipitation of proteins with rabbit antifumarase antibody in (35S)-methionine-labeled fibroblasts indicated that a protein of correct size (Mr = 44,000 daltons) corresponding to fumarase was synthesized in similar amounts in both the patients and controls. It is proposed that in the patient's cells a single active species of fumarase that is mitochondrial in location is synthesized. Since it is known that mitochondrial and cytosolic fumarases are encoded by the same gene but differ slightly in amino acid sequence, it is possible that a point mutation might explain these findings. N Engl J Med. 1986 Aug 21. We observed a deficiency of both the mitochondrial and cytosolic forms of fumarase in a male infant with mitochondrial encephalomyopathy who presented at one month of age with failure to thrive, developmental delay, hypotonia, cerebral atrophy, lactic and pyruvic acidemia, and fumaric aciduria. The patient died at eight months of age. Isolated skeletal-muscle mitochondria showed selective defects in the oxidation of glutamate (31 ng atoms of oxygen consumed per minute per milligram of mitochondrial protein, as compared with 94 +/- 19 [mean +/- SD] in five controls) and of succinate (18 vs. 145 +/- 18 ng atoms of oxygen per minute per milligram of protein), whereas isolated liver mitochondria oxidized these and other substrates normally. Fumarase activity was virtually absent in both liver mitochondria (53 vs. 2878 +/- 248 nmol per minute per milligram of protein [5 controls]) and skeletal-muscle mitochondria (23 vs. 1997 +/- 717 nmol per minute per milligram [12 controls]). Seventeen other mitochondrial enzymes had normal activity in both liver and muscle mitochondrial extracts. Fumarase activity was also significantly reduced in homogenates of liver tissue (less than 1 vs. 90 +/- 25 mumol per minute per gram of wet weight [five controls]) and skeletal muscle (less than 1 vs. 21 +/- 4 mumol per minute per gram [five controls]), indicating a deficiency of both mitochondrial and cytosolic fumarases. Organ differences in intramitochondrial accumulation of fumarate may have accounted for the selective oxidative defects observed in the skeletal-muscle mitochondria but not liver mitochondria. All these findings are consistent with a profound combined fumarase deficiency. |