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Query: UMLS:C0025362 (mental retardation)
 15,878 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Mental retardation affects 2 to 3% of the population and is marked by significant etiological heterogeneity, including genetic and non genetic causes. FRAXA (FMR1) trinucleotide expansion is widely searched in routine screening, but found in only about 2% of the patients tested. Mutations of the MECP2 (methyl-CpG-binding protein) gene mainly cause Rett syndrome but were also shown to be involved in mental retardation. This study aimed to estimate the frequency of MECP2 gene mutations in a large group of mentally retarded patients without FRAXA expansion. Screening by heteroduplex analysis and SSCP followed by DNA sequencing of shifted bands were performed on 613 patients, including 442 males and 171 females. Eleven sequence variants were found, including nine polymorphisms. The two others may be pathogenetic. The first one, the double nucleotide substitution c.1162_1163delinsTA leading to a premature stop codon (p.Pro388X) was found in a female patient with random X-inactivation, presenting with borderline mental impairment without any features of Rett syndrome. The second one, the c.679C>G substitution, changing a glutamine to a glutamate in the transcriptional repression functional domain (p.Gln227Glu), was found in a female patient with a moderately biased X-chromosome inactivation profile and presenting with mild intellectual delay and minor psychotic features. The low mutation rate suggests that a large-scale routine screening for MECP2 in mentally retarded subjects is not cost-effective in clinical practice. Screening may be improved by a pre-selection based on clinical features that remain to be established.
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PMID:Mutation screening of the MECP2 gene in a large cohort of 613 fragile-X negative patients with mental retardation. 1738 48

A relationship between fragile sites, specific genomic regions visible as gaps or breaks on cultivated chromosomes, and human disease has been proposed many years ago. Evidence for a role of the ubiquitously expressed common fragile sites characterized by peculiar genome architecture in cancer has been accumulated over the last years. In contrast, a relationship between the second main group of fragile sites characterized by repeat expansion, the rare fragile sites, and mental retardation has been proposed many years ago, but after the molecular cloning of FRAXA and FRAXE both unequivocally involved in mental retardation, no additional fragile sites linked with mental retardation have been cloned for over a decade. The recent cloning of new fragile sites and the identification of the associated genes allow us to readdress this old paradigm and to speculate on the role these might play in human disease.
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PMID:Fragile sites and human disease. 1756 80

In its expanded form, the fragile X triplet repeat at Xq27.3 gives rise to the most common form of inherited mental retardation, fragile X syndrome. This high population frequency persists despite strong selective pressure against mutation-bearing chromosomes. Males carrying the full mutation rarely reproduce and females heterozygous for the premutation allele are at risk of premature ovarian failure. Our diagnostic facility and previous research have provided a large databank of X chromosomes that have been tested for the FRAXA allele. Using this resource, we have conducted a detailed genetic association study of the FRAXA region to determine any cis-acting factors that predispose to expansion of the CGG triplet repeat. We have genotyped SNP variants across a 650-kb tract centered on FRAXA in a sample of 877 expanded and normal X chromosomes. These chromosomes were selected to be representative of the haplotypic diversity encountered in our population. We found expansion status to be strongly associated with a approximately 50-kb region proximal to the fragile site. Subsequent detailed analyses of this region revealed no specific genetic determinants for the whole population. However, stratification of chromosomes by risk subgroups enabled us to identify a common SNP variant which cosegregates with the subset of D group haplotypes at highest risk of expansion (chi(1)(2)=17.84, p=0.00002). We have verified that this SNP acts as a marker of repeat expansion in three independent samples.
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PMID:Closely linked cis-acting modifier of expansion of the CGG repeat in high risk FMR1 haplotypes. 1767 8

Fragile sites are heritable specific chromosome loci that exhibit an increased frequency of gaps, poor staining, constrictions or breaks when chromosomes are exposed to partial DNA replication inhibition. They constitute areas of chromatin that fail to compact during mitosis. They are classified as rare or common depending on their frequency within the population and are further subdivided on the basis of their specific induction chemistry into different groups differentiated as folate sensitive or non-folate sensitive rare fragile sites, and as aphidicolin, bromodeoxyuridine (BrdU) or 5-azacytidine inducible common fragile sites. Most of the known inducers of fragility share in common their potentiality to inhibit the elongation of DNA replication, particularly at fragile site loci. Seven folate sensitive (FRA10A, FRA11B, FRA12A, FRA16A, FRAXA, FRAXE and FRAXF) and two non-folate sensitive (FRA10B and FRA16B) fragile sites have been molecularly characterized. All have been found to represent expanded DNA repeat sequences resulting from a dynamic mutation involving the normally occurring polymorphic CCG/CGG trinucleotide repeats at the folate sensitive and AT-rich minisatellite repeats at the non-folate sensitive fragile sites. These expanded repeats were demonstrated, first, to have the potential, under certain conditions, to form stable secondary non-B DNA structures (intra-strand hairpins, slipped strand DNA or tetrahelical structures) and to present highly flexible repeat sequences, both conditions which are expected to affect the replication dynamics, and second, to decrease the efficiency of nucleosome assembly, resulting in decondensation defects seen as fragile sites. Thirteen aphidicolin inducible common fragile sites (FRA2G, FRA3B, FRA4F, FRA6E, FRA6F, FRA7E, FRA7G, FRA7H, FRA7I, FRA8C, FRA9E, FRA16D and FRAXB) have been characterized at a molecular level and found to represent relatively AT-rich DNA areas, but without any expanded repeat motifs. Analysis of structural characteristics of the DNA at some of these sites (FRA2G, FRA3B, FRA6F, FRA7E, FRA7G, FRA7H, FRA7I, FRA16D and FRAXB) showed that they contained more areas of high DNA torsional flexibility with more highly AT-dinucleotide-rich islands than neighbouring non-fragile regions. These islands were shown to have the potential to form secondary non-B DNA structures and to interfere with higher-order chromatin folding. Therefore, a common fragility mechanism, characterized by high flexibility and the potential to form secondary structures and interfere with nucleosome assembly, is shared by all the cloned classes of fragile sites. From the clinical point of view, the folate sensitive rare fragile site FRAXA is the most important fragile site as it is associated with the fragile X syndrome, the most common form of familial mental retardation, affecting about 1/4000 males and 1/6000 females. Mental retardation in this syndrome is considered as resulting from the abolition of the FMR1 gene expression due to hypermethylation of the gene CpG islands adjacent to the expanded methylated trinucleotide repeat. FRAXE is associated with X-linked non-specific mental retardation, and FRA11B with Jacobsen syndrome. There is also some evidence that fragile sites, especially common fragile sites, are consistently involved in the in vivo chromosomal rearrangements related to cancer, whereas the possible implication of common fragile sites in neuropsychiatric and developmental disorders is still poorly documented.
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PMID:Human chromosome fragility. 1807 40

The fragile X syndrome (FRAXA) is the most widespread heritable form of mental retardation caused by the lack of expression of the fragile X mental retardation protein (FMRP). This lack has been related to deficits in cerebellum-mediated acquisition of conditioned eyelid responses in individuals with FRAXA. In the present behavioral study, long-term effects of deficiency of FMRP were investigated by examining the acquisition, savings and extinction of delay eyeblink conditioning in male individuals with FRAXA. In the acquisition experiment, subjects with FRAXA displayed a significantly poor performance compared with controls. In the savings experiment performed at least 6 months later, subjects with FRAXA and controls showed similar levels of savings of conditioned responses. Subsequently, extinction was faster in subjects with FRAXA than in controls. These findings confirm that absence of the FMRP affects cerebellar motor learning. The normal performance in the savings experiment and aberrant performance in the acquisition and extinction experiments of individuals with FRAXA suggest that different mechanisms underlie acquisition, savings and extinction of cerebellar motor learning.
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PMID:Savings and extinction of conditioned eyeblink responses in fragile X syndrome. 1861 11

The FRAXA locus is flanked by three polymorphic STR markers DXS548, FRAXAC1, and FRAXAC2. Allele frequencies of these markers were determined on a population representing the eastern part of India comprising of 69 normal controls and 69 unrelated subjects with mental retardation, among whom 21 were fragile X patients. These frequencies were compared with published data on other Indian population and the major populations of the world. The allele and haplotype distribution of the studied population were significantly different in some respects from the major populations of the world. The increase of heterozygosities in fragile X samples (DXS548 67.5%, FRAXAC1 63.5%, FRAXAC2 68.5%) relative to the controls (DXS548 63.3%, FRAXAC1 51.0%, FRAXAC2 67.2%) suggests a multimodal distribution of fragile X associated alleles. Haplotype analyses with DXS548 and FRAXAC1 markers revealed that haplotype distribution in the normal controls and fragile X groups were significantly different, suggesting a weak founder effect.
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PMID:Haplotype analysis at the FRAXA locus in an Indian population. 1862 41

The high concordance for autism symptoms in monozygotic twin-pairs compared to di-zygotic twins and/or non-twin sib-ships suggests a high genetic determinism in autism. Those results have hypothesized multi-factorial determinism in accordance with family studies and mathematical models. However, linkage and association or candidate gene strategies have failed to-date to identify clearly involved mechanisms. Mental retardation (MR) is known as frequently associated to autism. Multiplex XLMR pedigrees have been reported with only one mutated patient having autism and MR: different X-located MR genes have been shown to be involved (NLGN4, MECP2, OPHN1, ZNF674 and FRAXA) which does not suggest that they could be "autism genes". Tuberous sclerosis studies and report of numerous autosomal domains shown deleted in MR-autistic subjects suggest that several autosomal dominant (AD) genes could be also involved in MR with autism. Whereas multiplex AD-MR families are rare, AD de novo mutations could explain numerous sporadic situations of non-specific MR and of autism with MR, in accordance with twin studies. Finally, we hypothesize that in those autistic subjects with mendelian MR, the XL-MR or AD-MR gene (G1) would pave the way for a second Mendelian factor (G2) responsible for autism symptoms.
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PMID:Could autism with mental retardation result from digenism and frequent de novo mutations? 1916 Jan 28

Several studies have suggested that fragile X syndrome (FRAXA), the most common inherited form of mental retardation, originated from a limited number of founder chromosomes. The aim of this study is to assess the genetic origin of fragile X syndrome in a Croatian population. We performed a haplotype analysis of the polymorphic loci DXS548 and FRAXAC1 in 18 unrelated fragile X and 56 control chromosomes. The AGG interspersion pattern of the FMR1 CGG repeat region was analyzed by sequencing. This is the first report on haplotype and AGG interspersion analysis of the fragile X syndrome gene in a Croatian population-the only eastern European population of Slavic origin analyzed so far. Our findings are intriguing, because they show a distinct distribution of the DXS548 and FRAXAC1 alleles in our fragile X population compared to other European fragile X populations. The DXS548/FRAXAC1 haplotype 194/154 (7-3), which is common among normal populations, was found to be the most frequent haplotype in our fragile X population as well. The AGG interspersion analysis indicated that AGG loss rather than haplotype may determine FMR1 allele instability. Our results suggest that no common ancestral X chromosome is associated with fragile X syndrome in the Croatian population studied. Further analysis of the origin of fragile X syndrome among other Slavic populations will be necessary to better define its eastern European distribution.
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PMID:Haplotype and AGG interspersion analysis of FMR1 alleles in a Croatian population: no founder effect detected in patients with fragile X syndrome. 1934 25

Fragile X syndrome (FRAXA) is one of the most common forms of mental retardation. It is caused by the expansion of cytosine-guanine-guanine (CGG) repeats in the 5' untranslated region of the fragile X mental retardation 1 (FMR1) gene, located at Xq27.3. The number of CGG repeats in the FMR1 gene occurs in four distinct ranges: 2-50 (normal), 50-60 (gray zone), 60-200 (premutation), and > 200 (full mutation). When the number of CGG repeats exceeds 200, the gene becomes hypermethylated and transcriptionally silenced, which results in the loss of FMR protein and causes FRAXA. The key clinical features of FRAXA are mental retardation, macro-orchidism, long face, prominent jaw, connective tissue abnormalities, and behavioral problems. A modified 15-item checklist was used to assess the clinical features in 337 individuals (316 males and 21 females) who have mental retardation of unknown etiology. These patients were in institutions. Molecular diagnosis was performed using polymerase chain reaction and Southern blot analysis and revealed that 14 males were positive for FRAXA. Studies of the families of the affected males revealed an additional 11 affected males and 20 carrier females. Retrospective analysis of clinical features was performed in a total of 327 males and 41 females. Six clinical features were statistically significant in FRAXA individuals when compared to non-FRAXA individuals. These features were hyperactivity (p<0.05), poor eye contact (p<0.001), hyper extensibility of joints (p<0.001), large ears (p<0.001), macro-orchidism (p<0.001), and a family history of mental retardation (p<0.001). When a total score of 5 out of 15 was used as the threshold clinical score, 73.18% of the patients with total scores < 5 could be eliminated as FRAXA-negative patients, thereby improving the reliability of FRAXA testing using the clinical checklist.
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PMID:Assessment of a clinical checklist in the diagnosis of fragile X syndrome in India. 1956 Sep 28

The association between fragile sites and human genetic diseases is still debatable. Although FRAXA and FRAXE have been found to be associated with mental retardation and FRA11B possibly with Jacobsen syndrome, no other autosomal fragile site has yet been found to have a direct correlation with a genetic disorder; however, the frequency of fragile sites in infertile couples has been reported to be higher than in a control group. The occurrence of a fragile site can therefore be a possible risk factor causing considerable anxiety to the clinician and probably requires follow up with appropriate genetic counseling. The present study reports heterozygosity for FRA16B in both partners of an infertile non-consanguineous couple married for 9 years. They had been referred for cytogenetic evaluation with the complaint of multiple fetal losses.
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PMID:Spontaneous expression of FRA16B in a non-consanguineous couple experiencing multiple fetal losses. 2256 72


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