Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0025362 (mental retardation)
 15,878 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A 5 9/12-year-old Mexican female with argininemia presented at 4 years of age with severe growth retardation, microcephaly, mental retardation, loss of ability to walk, spasticity and epileptiform electroencephalogram. At follow-up, blood ammonia was elevated only twice out of 30 determinations. Blood arginine was 544 to 1,074 mumol/l (normal 61 to 173); cerebrospinal fluid arginine was 88 mumol/l (normal 6 to 29); and urinary arginine, citruline and argininosuccinic acid were consistently elevated. Arginase activities in tissues from the propositus were 0.01 mU/mg hemoglobin in erythrocytes (normal 29.8 to 96.1); 9 mU/mg protein in liver (normal 1,522 to 5,491); and 5 mU/mg protein in stratum corneum (normal 2,856 to 7,556). The demonstration of arginase deficiency in liver and stratum corneum suggests a generalized deficiency and helps to explain the elevation of blood arginine. Therapeutic trials of orally administered lysine to enhance dibasic amino acid competition and of enzyme replacement using erythrocyte transfusion did not result in significantly decreased blood arginine or clinical improvement.
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PMID:Arginase deficiency in multiple tissues in argininemia. 62 88

A nationwide survey of transient hyperammonemia in newborns was carried out in Japan. A total of 18 patients, consisting of 12 male and 6 female infants, were reported from 11 facilities. These neonates exhibited hyperammonemia with plasma ammonia levels in the range from 124 to 6256 micrograms/dl. Four newborn infants of the 18 died in the neonatal period, and an additional one died in the early infancy. Among the 13 infants who were alive at the time of this survey, 6 had neurological sequelae, including mental retardation, spastic quadriplegia and epilepsy. The multivariate analysis revealed that the Apgar score at 1 minute, peak plasma ammonia concentration, birth weight and sex were significant factors affecting the prognosis of life.
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PMID:A nationwide survey on transient hyperammonemia in newborn infants in Japan: prognosis of life and neurological outcome. 177 16

Nutritional approaches are available for the management of several different classes of inborn metabolism errors. In phenylketonuria (PKU), phenylalanine is not properly metabolized; and its accumulation leads to neurologic dysfunction and metal retardation. Altering the diet to limit phenylalanine intake led to remarkable improvement in children with PKU. It was later found that instituting dietary therapy immediately after identification of the disorder in newborns prevented mental retardation. Throughout the 1960s nutritional therapies were found for other inborn disorders, including galactosemia, maple syrup urine disease, and homocystinuria. For the group of disorders associated with defects in the urea cycle, leading to profound hyperammonemia, therapy based on the concept of waste nitrogen excretion (i.e., by increasing excretion of urea cycle intermediates in the urine, nitrogen that would otherwise recycle as ammonia can be eliminated) dramatically produced better control of hyperammonemia and its consequences. Some inborn errors of metabolism respond to vitamin therapy. Biotin-related multiple carboxylase synthetase deficiency can be produced by either of two enzyme defects--holocarboxylase synthetase deficiency or biotinidase deficiency. Both are treatable with biotin supplementation. The symptoms of multiple carboxylase deficiency can also occur after intestinal resection or ingestion of raw eggs. Multiple carboxylase deficiency has been treated successfully in utero by giving the mother biotin supplements. Peroxisomal disorders may respond to dietary management. Liver disease in hereditary tyrosinemia may be accentuated by hypermethioninemia and treated by controlling the blood methionine level. Glycogen storage disease Type I, which causes hypoglycemia, can be controlled by oral administration of cornstarch.
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PMID:Nutritional therapy for selected inborn errors of metabolism. 268 28

Deficiency of ornithine transcarbamylase (OTC; EC 2.1.3.3), a hepatic mitochondrial enzyme involved in the detoxification of ammonia, is a severe inborn error of metabolism. It is an X-linked disorder which results characteristically in ammonia intoxication, protein intolerance and mental retardation. Early death of affected hemizygous male infants is common, while clinical manifestations in heterozygous females are variable due to random X-chromosome inactivation. Prenatal diagnosis by amniocentesis has not been feasible because OTC is not expressed in amniocytes and because no unusual metabolites can be detected in amniotic fluid. Fetal liver biopsy has been performed for some families at risk, but the dangers inherent in this procedure severely limit its usefulness. In this report, we describe the use of a nearly full-length cloned human cDNA to begin to characterize normal and mutant human OTC genes. One of 15 affected males was found to have a partial deletion of the OTC gene. Two distinct restriction fragment length polymorphisms (RFLPs) were identified at the OTC locus using the restriction endonuclease MspI; 69% of women tested were heterozygous for one or both polymorphisms. Identification of these common polymorphisms makes it possible to offer prenatal diagnosis to a large fraction of obligate carriers and to provide information on carrier status to some females at risk.
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PMID:Gene deletion and restriction fragment length polymorphisms at the human ornithine transcarbamylase locus. 298 25

Three female infants with citrullinemia were followed clinically, biochemically and by electroencephalography. All three had episodes of vomiting, lethargy and hyperammonemia shortly after birth. The two more severe cases developed convulsions. They were saved by peritoneal dialysis, or repeated exchange transfusions followed by dietary adjustment. Multifocal spikes or repetitive paroxysmal activity of various kinds were seen in the EEGs at times of crisis. There was a lag in the EEG returning to normal after ammonia levels had returned to normal. Citrulline remained elevated in all cases. Follow-up over years revealed mild spasticity, mental retardation and, in one case, cortical atrophy.
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PMID:The EEGs of infants with citrullinemia. 399 77

A simple enzyme-multiple auxotroph assay has been developed for the identification of newborn infants with several of the inherited metabolic defects in the Krebs cycle for the detoxification of ammonia and in the ornithine metabolic pathway. This mass screening test is used with dried filter paper blood specimens and can easily be added to existing multiple testing programs presently used in screening for phenylketonuria or congenital hypothyroidism. This assay can be used to detect patients with citrullinemia, argininosuccinic acid lyase deficiency, and argininemia. In addition to these urea cycle disorders, the several types of ornithinemia, which can result in gyrate atrophy of the retina or mental retardation, should be detectable with this assay. The strengths and weaknesses of this assay are discussed and a large-scale pilot screening trial is proposed.
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PMID:A neonatal screening test for argininosuccinic acid lyase deficiency and other urea cycle disorders. 712 51

Congenital ornithine transcarbamylase (OTC) deficiency in humans is associated with seizures and mental retardation. As part of a series of studies to delineate the neurochemical features of OTC deficiency, activities of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE), respectively, were measured in brain regions of the congenitally hyperammonemic sparse-fur (spf) mouse, a mutant with an X-linked inherited defect of OTC. ChAT activities were reduced by 63% (P < 0.01) in cerebral cortex of spf mice compared with CD-1/Y controls. Activities of the GABA nerve terminal marker enzyme, glutamic acid decarboxylase, on the other hand, were within normal limits. Using an immunohistochemical technique with a monoclonal antibody to ChAT, a significant loss of ChAT-positive neurons was observed throughout the cerebral cortex, septal area and diagonal band of spf mice. These results suggest that a loss of forebrain cholinergic neurons is a feature of congenital OTC deficiency in these mutants. Possible pathogenetic mechanisms responsible for the cholinergic neuronal loss in congenital OTC deficiency include neurotoxic effects of ammonia and accumulation of quinolinic acid.
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PMID:Evidence for cholinergic neuronal loss in brain in congenital ornithine transcarbamylase deficiency. 781 42

Congenital deficiencies of the urea cycle enzyme ornithine transcarbamylase (OTC) result in chronic hyperammonemia and severe neurological dysfunction including seizures and mental retardation. As part of a series of studies to elucidate the pathophysiologic mechanisms responsible for the CNS consequences of OTC deficiency, concentrations of ammonia-related and neurotransmitter amino acids were measured as their o-phthalaldehyde derivatives using high performance liquid chromatography with fluorescence detection in regions of the brains of sparse-fur (spf) mice, a mutant with an X-linked inherited defect of OTC. Compared to CD-1/Y controls, the brains of spf/Y mutant mice contained significant alterations of several amino acids. A generalized, up to 2-fold, increase of brain glutamine was observed, consistent with the exposure of these brains to increased concentrations of ammonia. Significant increases of brain alanine were also observed and, together with previous reports of increased concentrations of alpha-ketoglutarate, are consistent with ammonia-induced inhibition of alpha-ketoglutarate dehydrogenase in the brains of spf/Y mice. Increased brain content of the excitatory amino acid aspartate could be responsible for the seizures frequently encountered in congenital OTC deficiency.
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PMID:Regional amino acid neurotransmitter changes in brains of spf/Y mice with congenital ornithine transcarbamylase deficiency. 791 68

As a toxic metabolic byproduct in mammals, excess ammonia is converted into urea by a series of five enzymatic reactions in the liver that constitute the urea cycle. A portion of this cycle takes place in the mitochondria, while the remainder is cytosolic. Liver arginase (L-arginine ureahydrolase, A1) is the fifth enzyme of the cycle, catalyzing the hydrolysis of arginine to ornithine and urea within the cytosol. Patients deficient in this enzyme exhibit hyperargininemia with episodic hyperammonemia and long-term effects of mental retardation and spasticity. However, the hyperammonemic effects are not so catastrophic in arginase deficiency as compared to other urea cycle defects. Earlier studies have suggested that this is due to the mitigating effect of a second isozyme of arginase (AII) expressed predominantly in the kidney and localized within the mitochondria. In order to explore the curious dual evolution of these two isozymes, and the ways in which the intriguing, aspects of AII physiology might be exploited for gene replacement therapy of AI deficiency, the cloned cDNA for human AI was inserted into an expression vector downstream from the mitochondrial targeting leader sequence for the mitochondrial enzyme ornithine transcarbamylase and transfected into a variety of recipient cell types. AI expression in the target cells was confirmed by northern blot analysis, and competition and immunoprecipitation studies showed successful translocation of the exogenous AI enzyme into the transfected cell mitochondria. Stability studies demonstrated that the translocated enzyme had a longer half-life than either native cytosolic AI or mitochondrial AII. Incubation of the transfected cells with increasing amounts of arginine produced enhanced levels of mitochondrial AI activity, a substrate-induced effect that we have previously seen with native AII but never AI. Along with exploring the basic biological questions of regulation and subcellular localization in this unique dual-enzyme system, these results suggest that the mitochondrial matrix space may be a preferred site for delivery of enzymes in gene replacement therapy.
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PMID:Delivery of cytosolic liver arginase into the mitochondrial matrix space: a possible novel site for gene replacement therapy. 913 Oct 18

Ornithine transcarbamylase deficiency is an X linked disorder and the most common inherited cause of hyperammonaemia. Fluctuating concentrations of ammonia, glutamine, and other excitotoxic amino acids result in a chronic or episodically recurring encephalopathy. A heterozygous female patient first presented with protein intolerance, attacks of vomiting, and signs of mental retardation in early childhood. At the age of 16 complex partial seizures occurred which were treated with sodium valproate. Seven days after initiation of valproate therapy, she developed severe hyperammonaemic encephalopathy with deep somnolence. The maximum concentration of ammonia was 480 micromol/l. After withdrawal of valproate, three cycles of plasma dialysis, and initiation of a specific therapy for the inborn metabolic disease, ammonia concentrations fell to normal values. The patient remitted, returning to her premorbid state. Valproate can cause high concentrations of ammonia in serum in patients with normal urea cycle enzymes and may worsen a pre-existing hyperammonaemia caused by an enzymatic defect of the urea cycle. Sufficient diagnostic tests for the detection of metabolic disorders must be performed before prescribing valproate for patients with a history of encephalopathy.
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PMID:Hyperammonaemic encephalopathy after initiation of valproate therapy in unrecognised ornithine transcarbamylase deficiency. 959 92


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