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)

Fragile X syndrome is the most common form of inherited mental retardation in man. The disease is associated with expansion in the number of tandem CGG trinucleotide repeats in the 5' untranslated region of the human FMR1 gene. Transmitting males, individuals who are unaffected carriers of the disease, show a moderate increase in the number of repeat units, while fully penetrant males show a major expansion in repeat number. Major expansion of the repeat in affected males is correlated with methylation of certain restriction enzyme recognition sites in the 5' CpG island containing the trinucleotide repeat in these patients. Phenotypic expression of the mutation appears to be due to transcriptional silencing of the FMR1 gene. We now report direct high resolution methylation analysis of the trinucleotide repeat and its flanking regions using ligation-mediated PCR genomic sequencing. We find the cytosine residue of all CpG dinucleotides examined within and surrounding the FMR1 trinucleotide repeat to be unmethylated in the DNA of normal male leukocytes and transmitting male lymphoblasts; these same cytosines are methylated in affected male lymphoblasts, in a somatic cell hybrid containing a fragile X chromosome from an affected male, and in a somatic cell hybrid containing a normal inactive X chromosome. The methylation pattern of the FMR1 5' CpG island in affected patients as determined by genomic sequencing is remarkably similar to that seen for the X-linked human phosphoglycerate kinase and hypoxanthine phosphoribosyltransferase gene 5' CpG islands on the inactive human X chromosome.(ABSTRACT TRUNCATED AT 250 WORDS)
Hum Mol Genet 1993 Oct
PMID:High resolution methylation analysis of the FMR1 gene trinucleotide repeat region in fragile X syndrome. 826 19

Duchenne and Becker muscular dystrophies (DMD/BMD) are caused by mutations in the human dystrophin gene. About two-thirds of DMD/BMD patients exhibit gross rearrangements in the gene whereas the mutations in the remaining one third are thought to be point mutations or minor structural lesions. By means of various progressive PCR-based techniques hitherto a number of point mutations has been described that in most cases should cause premature translational termination. These data indicate a particular functional importance for the C-terminal region of dystrophin and consequently for its gene products Dp 71 and Dp 116. To screen for microheterogeneities in this gene region we applied PCR-SSCP analysis to exons 60-79 of twenty-six DMD/BMD patients without detectable deletions. The study identified seven point mutations and one intron polymorphism. Six point mutations, found in DMD patients, should cause premature translational termination. One point mutation, identified in a BMD patient, results in an amino acid exchange. Five of the DMD patients bearing a point mutation are mentally retarded suggesting that a disruption of the translational reading frame in the C-terminal region is associated with this clinical finding in DMD cases. Therefore our data raise the possibility, that Dp 71 and/or Dp 116, the C-terminal translational products of dystrophin, may be causally involved in cases of mental retardation that are associated with DMD.
Hum Mol Genet 1993 Nov
PMID:Point mutations at the carboxy terminus of the human dystrophin gene: implications for an association with mental retardation in DMD patients. 828 Nov 50

Prader-Willi syndrome (PWS) and Angelman syndrome (AS) are distinct mental retardation disorders caused by a deficiency of paternal (PWS) or maternal (AS) contributions for chromosome 15 by either deletion or uniparental disomy (UPD). To further study the molecular mechanisms involved in these disorders and to improve molecular diagnostic methods, we have isolated three dinucleotide repeat markers in the PWS/AS critical region. An Alu-CA PCR method was used to isolate CA-repeat markers directly from yeast artificial chromosome (YAC) clones identified by probes IR4-3R (D15S11), LS6-1 (D15S113), and GABAA receptor B3 (GABRB3). Three markers with 6-11 alleles and 73-83% heterozygosities were identified and analyzed by multiplex PCR. Gene-centromere mapping was performed on a panel of ovarian teratomas of known meiotic origin, and showed the most proximal marker, IR4-3R, to be 13 cM (95% confidence limits: 7-19 cM) from the centromere of chromosome 15. Molecular diagnostic studies were performed on 20 PWS and 9 AS patients. In 17 patients with deletions, the parental origin of deletion was determined. Ten PWS patients were shown to have maternal heterodisomy. Since these markers are only 13 cM from the centromere, heterodisomy indicates that maternal meiosis I nondisjunction is involved in the origin of UPD. In contrast, two paternal disomy cases of AS showed isodisomy for all markers tested along the length of chromosome 15. This suggests a paternal meiosis II nondisjunction event (without crossing over) or, more likely, monosomic conception (due to maternal nondisjunction) followed by chromosome duplication.(ABSTRACT TRUNCATED AT 250 WORDS)
Hum Mol Genet 1993 Feb
PMID:Multiplex PCR of three dinucleotide repeats in the Prader-Willi/Angelman critical region (15q11-q13): molecular diagnosis and mechanism of uniparental disomy. 849 3

Mental handicap is a common clinical problem that has been a relatively neglected area of research. Though the causes are varied and complex, molecular biologists are making progress in understanding the mechanisms in some cases, particularly where there are distinguishing phenotypic or genetic markers. The fortuitous association of alpha thalassaemia with a form of mental retardation has allowed us to define a specific X-linked syndrome (ATR-X). Positional cloning was used to define a disease interval and examination of candidate genes demonstrated that mutations in a gene, XH2, showing homology to the SNF2 superfamily were responsible for this syndrome. The complex ATR-X phenotype suggests that this gene, when mutated, down-regulates the expression of several genes including the alpha-globin genes indicating that it could be a global transcriptional regulator. It is conceivable that this mechanism is involved in other forms of syndromal mental retardation.
Hum Mol Genet 1995
PMID:Syndromal mental retardation due to mutations in a regulator of gene expression. 854 68

The Norrie disease and MAO genes are tandemly arranged in the p11.4-p11.3 region of the human X chromosome in the order tel-MAOA-MAOB-NDP-cent. This relationship is conserved in the mouse in the order tel-MAOB-MAOA-NDP-cent. The MAO genes appear to have arisen by tandem duplication of an ancestral MAO gene, but their positional relationship to NDP appears to be random. Distinctive X-linked syndromes have been described for mutations in the MAOA and NDP genes, and in addition, individuals have been identified with contiguous gene syndromes due to chromosomal deletions which encompass two or three of these genes. Loss of function of the NDP gene causes a syndrome of congenital blindness and progressive hearing loss, sometimes accompanied by signs of CNS dysfunction, including variable mental retardation and psychiatric symptoms. Other mutations in the NDP gene have been found to underlie another X-linked eye disease, exudative vitreo-retinopathy. An MAOA deficiency state has been described in one family to date, with features of altered amine and amine metabolite levels, low normal intelligence, apparent difficulty in impulse control and cardiovascular difficulty in affected males. A contiguous gene syndrome in which all three genes are lacking, as well as other as yet unidentified flanking genes, results in severe mental retardation, small stature, seizures and congenital blindness, as well as altered amine and amine metabolites. Issues that remain to be resolved are the function of the NDP gene product, the frequency and phenotype of the MAOA deficiency state, and the possible occurrence and phenotype of an MAOB deficiency state.
Hum Mol Genet 1995
PMID:Norrie disease and MAO genes: nearest neighbors. 854 72

The fragile X(A) or FRAXA syndrome is the most common form of familial mental retardation and is associated with a fragile site at Xq27.3. The gene responsible for the FRAXA syndrome, the FMR1 gene, has been cloned. inactivation of the FMR1 gene is associated with amplification of a trinucle-otide CGG repeat sequence and methylation of an adjacent CpG island. Previous estimates for the prevalence of the FRAXA syndrome have been based on indirect methods of chromosome analysis in institutions and community workshops for the mentally handicapped. We have analyzed the frequency of premutations of the FMR1 gene in 3002 X chromosomes of 1000 male and 1000 female consecutive newborn nonautoclaved blood spots in an anonymous, unlinked survey. The CGG repeat sizes were calculated by measuring the length of products of the PCR reaction based on the molecular size of labeled markers in a denaturing sequencing gel assay. For consistent PCR amplification a DNA microextraction was necessary, including a phenol/chloroform series. In our population, the CGG allele ranged from 9 to 106 repeats: 97% of alleles had fewer than 40 repeats. The most frequent allele was a repeat of 28. Approximately 2.3% of alleles had CGG repeats ranging from 4 to 49 and 0.37% of alleles had repeats ranging from 50 to 59. The frequency of alleles > 60 repeats in the Manitoba male population is approximately 0.13%. The use of nonautoclaved Guthrie blood spots for population screening of FRAXA premutations is not recommended. The necessity of a phenol/chloroform DNA microextraction is tedious and time consuming. The low yield of DNA (250 ng) does not allow for reanalysis by Southern of apparently homozygous females with potentially unstable CGG alleles in the 40-60 repeat range and likely underestimates premutation carrier status.
Biochem Mol Med 1995 Oct
PMID:Frequency of FMR1 premutations in a consecutive newborn population by PCR screening of Guthrie blood spots. 859 39

Down syndrome is a major cause of mental retardation and congenital heart defects. While most of the affected individuals have three copies of chromosome 21, patients with partial trisomy 21 have also been described. These rare cases define a minimal region for the Down syndrome phenotype encompassing about 3 Mb around D21S55. By using a new method for the identification of coding sequences (Alu-splice PCR) we have identified a new gene, DSCR1, from region 21q22.1-q22.2. DSCR1 encodes a novel protein which has an acidic domain, a serine-proline motif, a putative DNA binding domain and a proline-rich region with the characteristics of a SH3 domain ligand. These features suggest that DSCR1 could be involved in transcriptional regulation and/or signal transduction. DSCR1 is highly expressed in human brain and heart, and increased expression in the brains of young rats compared with adults suggests a role for DSCR1 during central nervous system development. Structural characteristics, together with its particular expression in brain and heart, encourage us to suggest that the overexpression of DSCR1 may be involved in the pathogenesis of Down syndrome, in particular mental retardation and/or cardiac defects.
Hum Mol Genet 1995 Oct
PMID:A new human gene from the Down syndrome critical region encodes a proline-rich protein highly expressed in fetal brain and heart. 859 18

The FMR-1 gene for the human fragile-chi syndrome, a mental retardation disease inherited by non-Mendelian transmission, contains a genetically unstable CGG region in the 5' non-translated region. The severity of the disease is correlated with the length of the CGG tract. The cloning of 28 stable plasmids containing (CGG)n inserts (where n = 6 to 240) with different extents and types of sequence interruptions (polymorphisms), and in different orientations was accomplished by three strategies in Escherichia coli. Some shorter tracts were prepared by the direct cloning of synthetic oligonucleotides, and longer runs were clones of multimers of (CGG)61, (CGG)11AGG(CGG)60CAG(CGG)8, from a cDNA from a fragile-chi patient or from expansions or deletions of these sequences in E. coli. The genetic stability of the inserts, especially for the longer tracts, was dependent on the sequence length, the presence of polymorphisms, the host cell genotypes, the orientation of the inserts in the vector and the position of cloning in a vector. Two-dimensional agarose gel electrophoresis studies on fully methylated and on non-methylated plasmids as well as chemical probe studies revealed the absence of underwound structures or accessible base-pairs. These DNAs enable a range of genetic and biochemical investigations into the molecular basis of the fragile-chi syndrome.
J Mol Biol 1996 May 17
PMID:Cloning, characterization and properties of plasmids containing CGG triplet repeats from the FMR-1 gene. 863 96

Fragile X syndrome, the most common form of hereditary mental retardation, usually results from lack of expression of the FMR1 gene. The FMR1 protein is a cytoplasmic RNA-binding protein. The RNA-binding activity of FMR1 is an essential feature of FMR1, as fragile X syndrome can also result from the expression of mutant FMR1 protein that is impaired in RNA binding. Recently, we described two novel cytoplasmic proteins, FXR1 and FXR2, which are both very similar in amino acid sequence to FMR1 and which also interact strongly with FMR1 and with each other. To understand the function of FMR1 and the FXR proteins, we carried out cell fractionation and sedimentation experiments with monoclonal antibodies to these proteins to characterize the complexes they form. Here, we report that the FMR1 and FXR proteins are associated with ribosomes, predominantly with 60S large ribosomal subunits. The FXR proteins are associated with 60S ribosomal subunits even in cells that lack FMR1 and that are derived from a fragile X syndrome patient, indicating that FMR1 is not required for this association. We delineated the regions of FMR1 that mediate its binding to 60S ribosomal subunits and the interactions among the FMR1-FXR family members. Both regions contain sequences predicted to have a high propensity to form coiled coil interactions, and the sequences are highly evolutionarily conserved in this protein family. The association of the FMR1, FXR1, and FXR2 proteins with ribosomes suggests they have functions in translation or mRNA stability.
Mol Cell Biol 1996 Jul
PMID:Specific sequences in the fragile X syndrome protein FMR1 and the FXR proteins mediate their binding to 60S ribosomal subunits and the interactions among them. 866

Impaired expression of the FMR1 gene is responsible for the fragile X mental retardation syndrome. The FMR1 gene encodes a cytoplasmic protein with RNA-binding properties. Its complex alternative splicing leads to several isoforms, whose abundance and specific functions in the cell are not known. We have cloned in expression vectors, cDNAs corresponding to several isoforms. Western blot comparison of the pattern of endogenous FMR1 proteins with these transfected isoforms allowed the tentative identification of the major endogenous isoform as ISO 7 and of a minor band as an isoform lacking exon 14 sequences (ISO 6 or ISO 12), while some other isoforms (ISO 4, ISO 5) were not expressed at detectable levels. Surprisingly, in immunofluorescence studies, the transfected splice variants that exclude exon 14 sequences (and have alternate C-terminal regions) were shown to be nuclear. Such differential localisation was however not seen in subcellular fractionation studies. Analysis of various deletion mutants suggests the presence of a cytoplasmic retention domain encoded in exon 14 and of a nuclear association domain encoded within the first eight exons that appear however to lack a typical nuclear localisation signal.
Hum Mol Genet 1996 Jan
PMID:Alternative splicing of exon 14 determines nuclear or cytoplasmic localisation of fmr1 protein isoforms. 878 45


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