Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0917816 (mental retardation)
15,867 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

GLUT1 deficiency is caused by a defect in the facilitative glucose transporter GLUT1. Impaired glucose transport across brain tissue barriers is reflected by hypoglycorrhachia and results in an epileptic encephalopathy with developmental delay and motor disorders. Recently heterozygous mutations in the GLUT1 gene (1p35-31.3) have been reported in sporadic patients. Parents and siblings carried the GLUT1 wild-type, suggesting a de novo, autosomal dominant condition resulting from GLUT1 haploinsufficiency. We report a father and two children from separate marriages affected by GLUT1 deficiency and carrying a novel heterozygous missense mutation (G272A) in the GLUT1 gene. Mutations were identified by polymerase chain reaction and DNA sequencing and confirmed by restriction fragment digest. The predicted amino acid change (Gly91Asp) affects an Arg-X-Gly-Arg-Arg motif between helices 2 and 3 that represents a cytoplasmic anchor point and is highly conserved among transporters of the major facilitator superfamily down to yeast and bacteria. GLUT1 immunoreactivity was normal, but 3-O-methyl-D-glucose uptake into erythrocytes was significantly reduced, suggesting a quantitatively normal, but functionally impaired, GLUT1 protein at the cell membrane. This is the first report of autosomal dominant transmission of GLUT1 deficiency, confirming that this condition is the result of haploinsufficiency. The Gly-->Asp mutation within a highly conserved sequence highlights its importance for GLUT1 function. GLUT1 deficiency should be considered in patients with epilepsy, mental retardation and motor disorders. Our observations have bearing on the identification of this treatable disorder in pediatric and adult patients, will modify current biochemical protocols which use parental controls and will enable genetic counseling of affected families.
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PMID:Autosomal dominant transmission of GLUT1 deficiency. 1113 15

Rett syndrome (RTT) is an X-linked dominant neurodevelopmental disorder that manifests in females, typically after the first year of life. It is a leading cause of mental retardation and autistic behavior in girls and women; a hallmark of the disease is incessant hand movements in the form of wringing, twisting, or clapping. It was recently discovered that RTT is caused by mutations in the methyl-CpG-binding protein 2 (MECP2) gene. MECP2 assists in the transcriptional silencing process via DNA methylation; we hypothesize that disruption of this gene alters the normal developmental expression of various other genes, some of which must account for the peculiar neurologic phenotype of RTT. Molecular studies have identified MECP2 mutations in up to 80% of classic RTT patients; mutation type has some effect on the phenotypic manifestation of RTT, but the pattern of X inactivation seems to determine phenotypic severity. Favorable (skewed) X inactivation can so spare a patient from the effects of mutant MECP2 that they display only the mildest learning disability or no phenotype at all. The unmitigated impact of mutant MECP2 can be inferred from the few males who have been born into RTT kindreds with such severe neonatal encephalopathy that they did not survive their second year. MECP2 mutations thus manifest in a far broader array of phenotypes than classic RTT. This discovery should prove helpful in diagnosing cases of mild learning disability or severe neonatal encephalopathies of unknown cause and also should provide insight into the pathogenesis of RTT.
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PMID:Rett syndrome: methyl-CpG-binding protein 2 mutations and phenotype-genotype correlations. 1118 Feb 22

Rett syndrome, a neurodevelopmental disorder that is a leading cause of mental retardation in females, is caused by mutations in the X-linked gene encoding methyl-CpG-binding protein 2 (MeCP2). MECP2 mutations have subsequently been identified in patients with a variety of clinical syndromes ranging from mild learning disability in females to severe mental retardation, seizures, ataxia, and sometimes neonatal encephalopathy in males. In classic Rett syndrome, genotype-phenotype correlation studies suggest that X chromosome inactivation patterns have a more prominent effect on clinical severity than the type of mutation. When the full range of phenotypes associated with MECP2 mutations is considered, however, the mutation type strongly affects disease severity. MeCP2 is a transcriptional repressor that binds to methylated CpG dinucleotides throughout the genome, and mutations in Rett syndrome patients are thought to result in at least a partial loss of function. Abnormal gene expression may thus underlie the phenotype. Discovering which genes are misregulated in the absence of functional MeCP2 is crucial for understanding the pathogenesis of this disorder and related syndromes.
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PMID:Molecular genetics of Rett syndrome and clinical spectrum of MECP2 mutations. 1126 31

Rett syndrome is a neurodevelopmental disorder characterized by cognitive and adaptive regression with autistic features, loss of acquired skills, and stereotypic hand movements that almost exclusively affects females. It is an X-linked dominant disorder, with presumed lethality in males. Nonetheless, there are a few descriptions of males suspected of having Rett syndrome. With the recent discovery that the MECP2 gene is responsible for most cases of Rett syndrome, it is possible to molecularly assess cases of affected males by direct sequencing analysis. We describe an Israeli family consisting of a female having classic Rett syndrome and a male sibling with severe neonatal encephalopathy. Molecular analysis revealed that both sister and brother have the same MECP2 gene mutation; however, their mother does not. This case, as well as other published studies of males with MECP2 mutations, reveals that the clinical manifestations in viable males vary from neonates with severe encephalopathy to adults with mental retardation and demonstrate genotype-phenotype correlations.
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PMID:Rett syndrome: clinical manifestations in males with MECP2 mutations. 1191 64

Rett syndrome (RTT) is an X-linked neurodevelopmental disorder caused by mutations in the MECP2 gene, with apparent lethality in male embryos. However, recent studies indicate that mutations in the MECP2 gene can cause congenital encephalopathy, an Angelman-like phenotype and even nonspecific mental retardation in males. We report on a 10-year-old boy with moderate mental retardation, hypotonia, obesity and gynaecomastia and a de novo 2-bp deletion in the MECP2 gene that resulted in a frameshift and premature stop codon. As some of the clinical features were suggestive of the Prader-Willi syndrome, it might be worthwhile screening for MECP2 mutations in patients with an atypical Prader-Willi phenotype but without the characteristic abnormalities on chromosome 15q. This report contributes to the phenotypic knowledge of male patients with MECP2 mutations. Moreover, this is the first reported male case of a de novo MECP2 mutation.
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PMID:De novo MECP2 frameshift mutation in a boy with moderate mental retardation, obesity and gynaecomastia. 1208 20

Although MECP2 was initially identified as the causative gene in classic Rett syndrome (RTT), the gene has now been implicated in several phenotypes that extend well beyond the clinically defined disorder. MECP2 mutations have been found in people with various disorders, including neonatal onset encephalopathy, X-linked recessive mental retardation (MRX), classic and atypical RTT, autism, and Angelman syndrome, as well as mildly affected females and normal carrier females. To make matters more complex, in approximately 20% of classic sporadic RTT cases and more than 50% of affected sister pairs, no mutation in MECP2 has been found. X-chromosome inactivation patterns can clearly affect the phenotypic expression in females, while the effect of the type and position of the mutation is more apparent in the broader phenotype than in RTT. Both males and females are at risk, although an excess of paternally derived mutations are found in most cases of classic RTT. Thus, because of the range of disparate phenotypes, the gene may account for a relatively large portion of mental retardation in the population.
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PMID:The phenotypic consequences of MECP2 mutations extend beyond Rett syndrome. 1211 34

Infants with Down syndrome are known to have a high frequency of birth defects, particularly cardiac and gastrointestinal defects. Mental retardation of different degrees is common, but accompanying central nervous system malformations are rare. We report a boy born spontaneously in the 37th postconceptional week with multiple malformations: microcephaly, hypertelorism, blepharophimosis, medial cleft palate, micrognathia, omphalocele, and pathologic palmar and plantar creases. Cardial sonography revealed a ventricular septal defect and mild pulmonary stenosis. Cranial magnetic resonance imaging demonstrated a general but infratentorial stressed brain atrophy with widening of the inner and outer cerebrospinal fluid spaces and dysplasia of the corpus callosum. Chromosomal analysis showed a free trisomy 21. The boy had muscular hypotonia and developed severe motor and mental retardation, accompanied by microsomia and generalized epileptic seizures. At age 8 months, he died of sudden nocturnal respiratory and cardiac failure. The peculiarity of this case is the combination of Down syndrome with midline developmental defects (callosal dysplasia, medial cleft palate, omphalocele) accompanied by severe malformative encephalopathy. There are no previous reports of this combination, but there are genetic links between Down syndrome and midline defects concerning the Drosophila single-minded (sim) gene. The expression pattern of the human sim corresponding gene suggests that it might be involved in the pathogenesis of midline defects in Down syndrome.
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PMID:Midline developmental anomalies in Down syndrome. 1217 71

A number of environmental agents have been shown to demonstrate neurotoxic effects either in human or laboratory animal studies. Critical windows of vulnerability to the effects of these agents occur both pre- and postnatally. The nervous system is relatively unique in that different parts are responsible for different functional domains, and these develop at different times (e.g., motor control, sensory, intelligence and attention). In addition, the many cell types in the brain have different windows of vulnerability with varying sensitivities to environmental agents. This review focuses on two environmental agents, lead and methylmercury, to illustrate the neurobehavioral and cognitive effects that can result from early life exposures. Special attention is paid to distinguishing between the effects detected following episodes of poisoning and those detected following lower dose exposures. Perinatal and childhood exposure to high doses of lead results in encephalopathy and convulsions. Lower-dose lead exposures have been associated with impairment in intellectual function and attention. At high levels of prenatal exposure, methylmercury produces mental retardation, cerebral palsy and visual and auditory deficits in children of exposed mothers. At lower levels of methylmercury exposure, the effects in children have been more subtle. Other environmental neurotoxicants that have been shown to produce developmental neurotoxicity include polychlorinated biphenyls (PCBs), dioxins, pesticides, ionizing radiation, environmental tobacco smoke, and maternal use of alcohol, tobacco, marijuana and cocaine. Exposure to environmental agents with neurotoxic effects can result in a spectrum of adverse outcomes from severe mental retardation and disability to more subtle changes in function depending on the timing and dose of the chemical agent.
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PMID:Environmental factors associated with a spectrum of neurodevelopmental deficits. 1221 63

Inherited metabolic disorders can cause onset of epilepsy in the first year of life. Epilepsy rarely dominates the clinical presentation, which is more frequently associated with other neurologic symptoms, such as mental retardation, hypotonia and/or dystonia, or vigilance disturbances. The pathogenesis of seizures is multifaceted; inherited metabolic disorder can affect the balance between excitatory and inhibitory chemical mediators, eliminate an energetic substrate at the cerebral level, cause in utero brain malformation, or provoke acute brain lesions. Some clinical disorders that strongly suggest particular metabolic etiologies can be identified. For example, specific clinical signs and findings on electroencephalogram (EEG) are characteristic of pyridoxine-dependent seizures, and inherited metabolic disorders associated with early myoclonic encephalopathy are well defined. In most cases, however, epilepsy secondary to inherited metabolic disorders presents with polymorphic clinical and EEG features that are difficult to classify into precise epileptic syndromes. Common characteristics of these seizures include onset in the first months of life; usually partial, multifocal; simple partial motor semiology; successive appearance of tonic seizures, spasms, and massive myoclonus; and resistance to antiepilepsy drugs. Inherited metabolic disorders must be considered in patients presenting with epilepsy and progressive neurologic worsening.
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PMID:Infantile epileptic syndromes and metabolic etiologies. 1259 51

Mutations in the MECP2 (methyl-CpG-binding protein 2) gene are known to cause Rett syndrome, a well-known and clinically defined neurodevelopmental disorder. Rett syndrome occurs almost exclusively in females and for a long time was thought to be an X-linked dominant condition lethal in hemizygous males. Since the discovery of the MECP2 gene as the cause of Rett syndrome in 1999, MECP2 mutations have, however, also been reported in males. These males phenotypically have classical Rett syndrome when the mutation arises as somatic mosaicism or when they have an extra X chromosome. In all other cases, males with MECP2 mutations show diverse phenotypes different from classical Rett syndrome. The spectrum ranges from severe congenital encephalopathy, mental retardation with various neurological symptoms, occasionally in association with psychiatric illness, to mild mental retardation only. We present a 21-year-old male with severe mental retardation, spastic tetraplegia, dystonia, apraxia and neurogenic scoliosis. A history of early hypotonia evolving into severe spasticity, slowing of head growth, breathing irregularities and good visual interactive behaviour were highly suggestive of Rett syndrome. He has a de novo missense mutation in exon 3 of the MECP2 gene (P225L). The clinical spectrum and molecular findings in males with MECP2 mutations are reviewed.
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PMID:Neurodevelopmental disorders in males related to the gene causing Rett syndrome in females (MECP2). 1261 69


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