Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0026838 (spasticity)
 6,471 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 7 1/2-year-old boy had progressive psychomotor retardation, behavior disturbance, and spasticity, and had growth arrest from age three. Plasma arginine on a self-selected protein-poor diet was increased (4.05 mg/dl; nl 0.4 to 2.6), whereas urinary amino acid excretion was normal. Red blood cell arginase was less than 1% of normal in the patient and was half normal in both parents, in two normal siblings, and in his paternal grandfather. Three hours after a meal providing 2 gm protein/kg body weight, the plasma arginine value rose to 13.2 mg/dl, dibasic aminoaciduria was seen clearly for the only time, but blood ammonia concentration remained normal. We conclude that arginase deficiency in the red blood cells and probably in the liver is inherited in an autosomal recessive manner and is responsible for the clinical syndrome in this patient.
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PMID:Hyperargininemia. 83 68

A third case of hyperargininaemia occurring in one family was studied from birth. In cord blood serum arginine concentration was only slightly raised, but arginase activity in red blood cell haemolysates was very low. In the urine on day 2 a typical cystinuria pattern was present. Arginine concentration in serum increased to 158 mumol/100 ml on the 41st day of life. Later determinations of the arginase activity in peripheral blood showed values below the sensitivity of the method. Blood ammonia was consistently high, and cystinuria was present. The enzymatic defect was further displayed by intravenous loading tests with arginine. Serum urea values were predominantly normal or near the lower limit of normal, suggesting the presence of other metabolic pathways of urea synthesis. In urine there was no excretion of guanidinosuccinic acid, while the excretion of other monosubstituted guanidine derivatives was increased, pointing to a connexion with hyperargininaemia. Owing to parental attitude, a low protein diet (1-5 g/kg) was introduced only late. The infant developed severe mental retardation, athetosis, and spasticity.
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PMID:Familial hyperargininaemia. 112 44

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

In a patient with hyperargininemia, oral administration of sodium benzoate or phenylacetic acid together with an essential amino acid mixture was used to prevent hyperammonemia and to decrease plasma and CSF concentrations of arginine. Sodium benzoate reduced the plasma ammonia levels, which was confirmed by the increase of urinary excretion of hippuric acid. Phenylacetic acid also controlled hyperammonemia, and EEG findings also improved. By these treatments, plasma and CSF concentrations of arginine showed a slight decrease, but were far above the normal range. There was no clinical improvement, and spasticity of the lower and upper extremities was progressive with mental deterioration.
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PMID:Hyperargininemia: clinical course and treatment with sodium benzoate and phenylacetic acid. 667 Jul 11

Deficiency of liver arginase (AI) is characterized clinically by hyperargininemia, progressive mental impairment, growth retardation, spasticity, and periodic episodes of hyperammonemia. The rarest of the inborn errors of urea cycle enzymes, it has been considered the least life-threatening, by virtue of the typical absence of catastrophic neonatal hyperammonemia and its compatibility with a longer life span. This has been attributed to the persistence of some ureagenesis in these patients through the activity of a second isozyme of arginase (AII) located predominantly in the kidney. We have treated a number of arginase-deficient patients into young adulthood. While they are severely retarded and wheelchair-bound, their general medical care has been quite tractable. Recently, however, two of the oldest (M.U., age 20, and M.O., age 22) underwent rapid deterioration, ending in hyperammonemic coma and death, precipitated by relatively minor viral respiratory illnesses inducing a catabolic state with increased endogenous nitrogen load. In both cases, postmortem examination revealed severe global cerebral edema and aspiration pneumonia. Enzyme assays confirmed the absence of AI activity in the livers of both patients. In contrast, AII activity (identified by its different cation cofactor requirements and lack of precipitation with anti-AI antibody) was markedly elevated in kidney tissues, 20-fold in M.O. and 34-fold in M.U. Terminal plasma arginine (1500 mumols/l) and ammonia (1693 mmol/l) levels of M.U. were substantially higher than those of M.O. (348 mumols/l and 259 mumols/l, respectively). By Northern blot analysis, AI mRNA was detected in M.O.'s liver but not in M.U.'s; similarly, anti-AI crossreacting material was observed by Western blot in M.O. only. These findings indicate that, despite their more long-lived course, patients with arginase deficiency remain vulnerable to the same catastrophic events of hyperammonemia that patients with other urea cycle disorders typically suffer in infancy. Further, unlike those other disorders, an attempt is made to compensate for the primary enzyme deficiency by induction of another isozyme in a different tissue. Such substrate-stimulated induction of an enzyme may be unique in a medical genetics setting and raises novel options for eventual gene therapy of this disorder.
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PMID:Arginase deficiency manifesting delayed clinical sequelae and induction of a kidney arginase isozyme. 845 80

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

Deficiency of liver arginase (AI) causes hyperargininemia (OMIM 207800), a disorder characterized by progressive mental impairment, growth retardation, and spasticity and punctuated by sometimes fatal episodes of hyperammonemia. We constructed a knockout mouse strain carrying a nonfunctional AI gene by homologous recombination. Arginase AI knockout mice completely lacked liver arginase (AI) activity, exhibited severe symptoms of hyperammonemia, and died between postnatal days 10 and 14. During hyperammonemic crisis, plasma ammonia levels of these mice increased >10-fold compared to those for normal animals. Livers of AI-deficient animals showed hepatocyte abnormalities, including cell swelling and inclusions. Plasma amino acid analysis showed the mean arginine level in knockouts to be approximately fourfold greater than that for the wild type and threefold greater than that for heterozygotes; the mean proline level was approximately one-third and the ornithine level was one-half of the proline and ornithine levels, respectively, for wild-type or heterozygote mice--understandable biochemical consequences of arginase deficiency. Glutamic acid, citrulline, and histidine levels were about 1.5-fold higher than those seen in the phenotypically normal animals. Concentrations of the branched-chain amino acids valine, isoleucine, and leucine were 0.4 to 0.5 times the concentrations seen in phenotypically normal animals. In summary, the AI-deficient mouse duplicates several pathobiological aspects of the human condition and should prove to be a useful model for further study of the disease mechanism(s) and to explore treatment options, such as pharmaceutical administration of sodium phenylbutyrate and/or ornithine and development of gene therapy protocols.
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PMID:Mouse model for human arginase deficiency. 1205 59

Urea cycle disorders (UCD) are human conditions caused by the dysregulation of nitrogen transfer from ammonia nitrogen into urea. The biochemistry and the genetics of these disorders were well elucidated. Earlier diagnosis and improved treatments led to an emerging, longer-lived cohort of patients. The natural history of some of these disorders began to point to pathophysiological processes that may be unrelated to the primary cause of acute morbidity and mortality, i.e., hyperammonemia. Carbamyl phosphate synthetase I single nucleotide polymorphisms may be associated with altered vascular resistance that becomes clinically relevant when specific environmental stressors are present. Patients with argininosuccinic aciduria due to a deficiency of argininosuccinic acid lyase are uniquely prone to chronic hepatitis, potentially leading to cirrhosis. Moreover, our recent observations suggest that there may be an increased prevalence of essential hypertension. In contrast, hyperargininemia found in patients with arginase 1 deficiency is associated with pyramidal tract findings and spasticity, without significant hyperammonemia. An intriguing potential pathophysiological link is the dysregulation of intracellular arginine availability and its potential effect on nitric oxide (NO) metabolism. By combining detailed natural history studies with the development of tissue-specific null mouse models for urea cycle enzymes and measurement of nitrogen flux through the cycle to urea and NO in UCD patients, we may begin to dissect the contribution of different sources of arginine to NO production and the consequences on both rare genetic and common multifactorial diseases.
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PMID:Clinical consequences of urea cycle enzyme deficiencies and potential links to arginine and nitric oxide metabolism. 1546 84

Portosystemic encephalopathy (PSE) is a well-known, common complication of portal hypertension. It is thought to be caused by nitrogenous substances such as ammonia, which are normally cleared from the blood stream by the liver. In cirrhosis and other hepatic disorders with portosystemic shunting (PSS)-- either surgical portosystemic anastomoses (PSA) or spontaneous PSS-- the collateral vessels bypass the liver allowing the accumulation of toxic, ammoniacal substances in the blood and tissues. PSE is characterized by encephalopathy; portosystemic myelopathy (PSM) is characterized by paresis of the extremities, Babinski signs and muscle spasticity in patients with cirrhosis and/or PSS. Usually only the lower extremities are involved. This report presents the first case of this syndrome observed 5 years after a transjugular intrahepatic portosystemic shunt. The 31 year old man with chronic Hepatitis B developed complete spastic paraparesis within 4 weeks after onset of clinical/neurological symptoms, accompanied by an episode of severe hepatic encephalopathy. The transcortical magnetic stimulation showed normal motoric stimulation times to the abductor digiti minimi muscles but no stimulation to the tibialis muscles was seen. Lumbar stimulation to the tibialis muscles, however, was normal. This indicates loss of motor neurons in the spinal cord, a characteristic finding in patients with portosystemic myelopathy. We performed a search of the literature for all reported cases of cirrhosis and/or PSS that developed PSM. However, the intervals between the construction of a shunt and the diagnosis of portosystemic myelopathy were shorter in total portacaval shunts (median 16 months) than in partial, non-portacaval shunts (median 60 months, p < 0.01). This suggests that not only the shunt itself but also the shunted volume contributes to the development of the syndrome Sixty-one patients with PSM have been reported in the literature since 1944. PSE had developed before PSM in almost all cases. PSM occurred from 1 month to 10 years after the creation of portacaval anastomoses (PCA) or splenorenal shunts (SRS) or in cirrhotic patients without shunts. No one type of liver disease or type of shunt appears to predispose to PSM. The mechanisms of PSE and PSM are thought to be similar and of nitrogenous origin, but their pathogenesis remains unknown. Lathyrism, a toxic syndrome with similar symptoms and signs, is caused by the ingestion of a legume, Lathyrus sativa, which contains beta-N-oxalo-L amino-L-alanine (BOAA). This animal model with or without BOAA appears to offer a reliable way of studying PSM experimentally.
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PMID:Portosystemic myelopathy: spastic paraparesis after portosystemic shunting. 1663 7


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