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: UNIPROT:P06889 (Mol)
630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The fragile X syndrome is the most frequent cause of inherited mental retardation. The molecular mechanism of the disorder is based on the expansion of a CGG repeat in the 5' UTR of the FMR1 gene in the majority of fragile X patients. The instability of this CGG repeat containing region is not restricted to the CGG repeat itself but expands to the flanking region as well. We describe four unrelated fragile X patients that are mosaic for both a full mutation and a small deletion in the CGG repeat containing region. Sequence analysis of the regions surrounding the deletions showed that both the (CGG)n repeat and some flanking sequences were missing in all four patients. The 5' breakpoints of the deletions were found to be located between 75-53 bp proximal to the CGG repeat. This suggests the presence of a hot spot region for deletions in the CGG repeat region of the FMR1 gene and emphasizes the instability of this region in the presence of an expanded CGG repeat.
Hum Mol Genet 1995 Jan
PMID:Hotspot for deletions in the CGG repeat region of FMR1 in fragile X patients. 771 33

Fragile X syndrome is one of the most common genetic causes of mental retardation, yet the mechanisms controlling expression of the fragile X mental retardation gene FMR1 are poorly understood. To identify sequences regulating FMR1 transcription, transgenic mouse lines were established using a fusion gene consisting of an E.coli beta-galactosidase reporter gene (lacZ) linked to a 2.8 kb fragment spanning the 5'-region of FMR1. Five transgenic mouse lines showed lacZ expression in brain, in particular in neurons of the hippocampus and the granular layer of the cerebellum. Expression of the reporter gene was also detected in Leydig cells and spermatogonia in the testis, in many epithelia of adult mice, and in the two other steroidogenic cell types, adrenal cortex cells and ovarian follicle cells. Embryonic tissues which showed strong activity of the reporter gene included the telencephalon, the genital ridge, and the notochord. This expression pattern closely resembles the endogenous one, indicating that the 5' FMR1 gene promoter region used in this study contains most cis-acting elements regulating FMR1 transcription.
Hum Mol Genet 1995 Mar
PMID:Tissue-specific expression of a FMR1/beta-galactosidase fusion gene in transgenic mice. 779 88

The mutation observed in the fragile X syndrome, an X-linked inherited disorder causing mental retardation, is almost exclusively an expanded CGG repeat in the first exon of the FMR1 gene. Here we describe a daughter of a female carrier, who inherited the fragile X premutation chromosome based on haplotype analysis using flanking markers. However, the CGG repeat sequence and the intragenic polymorphic marker FMRb showed the normal maternal alleles, while two other intragenic markers, FMRa and FRAXAC2 and other, more distant markers, showed the risk haplotype. Since FMRa and FRAXAC2 are located in between the markers CGG and FMRb, this results in patches of normal and fragile X sequences in the FMR1 gene of the daughter. This observation is very likely due to gene conversion. As this daughter received a normal CGG repeat region, we expect that her risk to have affected offspring is the same as the population risk. The observed phenomenon would therefore represent a back mutation at the FMR1 locus.
Hum Mol Genet 1994 Oct
PMID:Loss of mutation at the FMR1 locus through multiple exchanges between maternal X chromosomes. 784 7

Three fragile sites, FRAXA, FRAXE and FRAXF lie in the Xq27-28 region of the human X chromosome. The expression of FRAXA is associated with the fragile X syndrome, the most prevalent form of inherited mental retardation whilst the expression of FRAXE is associated with a rarer and comparatively milder form of mental handicap. Both the FRAXA and FRAXE sites have been cloned and the fragile site expression found to be due to the expansion of analogous CGG/GCC trinucleotide repeat arrays. We describe here the cloning of the third fragile site, FRAXF, and demonstrate that it involves the expansion of a (GCCGTC)n(GCC)n compound array. PCR analyses across the repeat of normal individuals show that the number of triplets in the array ranges from 12-26 and the most common allele consists of 14 triplet units. Sequencing analyses show that 95% of normal individuals have three copies of the GCCGTC motif and in these individuals, the size variation observed by PCR is due to copy number alterations in the GCC array. In a cytogenetically positive male with developmental delay, the array is expanded by > 900 triplets and the adjacent CpG-rich region is methylated. The array is also expanded in cytogenetically positive carrier females from the family originally used to define the FRAXF site. We conclude that the expanded array corresponds to the FRAXF fragile site.
Hum Mol Genet 1994 Dec
PMID:The cloning of FRAXF: trinucleotide repeat expansion and methylation at a third fragile site in distal Xqter. 788 7

The mutation causing myotonic dystrophy (DM) has been identified as an amplification of an unstable trinucleotide (CTG)n repeat in over 99% of the global DM population. It is in complete linkage disequilibrium with an Alu element polymorphism within the DM kinase gene, suggesting that DM is a consequence of one or few ancestral mutations. A recent analysis utilizing this polymorphism as well as a flanking dinucleotide marker, suggested that similar to Fragile X syndrome, DM exhibited a founder effect (Imbert et al., 1993 Nature Genet. 4, 72-76). In contrast, the low reproductive fitness of individuals with congenital DM (the endpoint of genetic anticipation in myotonic dystrophy) suggests a higher rate of new mutations. We present a high resolution genetic analysis of the DM locus using PCR based assays of nine polymorphisms, spanning a physical distance of 30 kb, within and immediately flanking the DM kinase gene. The persistent complete allelic association of the DM mutation with all these polymorphisms provides further support to previous observations and suggests more strongly that the DM mutation occurred on the background of a particular haplotype in which the (CTG)n repeat became inherently unstable and therefore predisposed to amplification.
Hum Mol Genet 1994 Jan
PMID:High resolution genetic analysis suggests one ancestral predisposing haplotype for the origin of the myotonic dystrophy mutation. 790 52

Runs of G residues on the G-rich strands of 30mers from the region spanning codon 12 of c-Ha-ras appear to be protected against chemical modification by dimethylsulfate. This suggests that the G-rich strand might spontaneously form a Hoogsteen-paired quadruplex, which is characteristic of telomere-like DNA sequences. In this report we show that the predominant species in 1:1 mixtures of complementary 30mers from this region are duplex DNA and a smaller amount of unimolecular foldback formed by the C-rich strand. Foldbacks of this type resemble structures first observed in the C-rich strand of telomeric DNA and also occur at the CCG triplet repeat present in the FMR-1 gene of human fragile X syndrome. Foldbacks from the C-rich strand of c-Ha-ras and the FMR-1 triplet repeat are exceptional substrates for the human methyltransferase in isolation. Substituting inosine for guanosine alters the secondary structure of the folded oligomers and dramatically reduces their ability to serve as substrates for the human methyltransferase, suggesting that secondary structure is required for recognition by the enzyme. These findings suggest that one mechanism by which methyl groups accumulate in the c-Ha-ras region of chromosome 11 during carcinogenesis and at the FMR-1 locus during repeat expansion at fragile X may be structurally induced de novo methylation at sites undergoing local conformational change. Such methylation might serve to mark unusual structures for repair. In the absence of repair, asymmetrically methylated duplexes produced by resolution of the unusual structures would be rapidly converted to symmetrically methylated duplexes through the methyl-directed activity also carried by the human methyltransferase.
J Mol Biol 1994 Oct 21
PMID:Hypermethylation of telomere-like foldbacks at codon 12 of the human c-Ha-ras gene and the trinucleotide repeat of the FMR-1 gene of fragile X. 793 45

A deazaguanine-substituted DNA PCR product from FMR-1 (the fragile X mental retardation syndrome gene) can be efficiently visualized with ethidium bromide on standard agarose gels. Normal-sized alleles (less than 54 CGG repeats) generated strong, easily visible bands in the expected size range of 491-635 bp. Southern blot analysis and radioactive PCR on sequencing gels were used to verify that the 74 males (out of 245 total tested) whose DNA failed to generate a visible band contained premutations or full mutations. This technique can be used as an inexpensive screen for fragile X syndrome among developmentally delayed males.
Mol Cell Probes 1994 Apr
PMID:A simple fragile X PCR assay with 7-deazaguanine-substituted DNA visualized by ethidium bromide. 793 15

A 2-year-old boy with manifestations of the fragile X syndrome was found to have a cytogenetically visible deletion of Xq27-q28 including deletion of FMR-1. Molecular analysis of the patient was recently described in Tarleton et al. [1993: Hum Mol Genet 2(11): 1973-1974] and the deletion was estimated to be at least 3 megabases (Mb). His mother had 2 FMR-1 alleles with normal numbers of CGG repeats, 20 and 32, respectively. Thus, the deletion occurred as a de novo event. The patient does not appear to have clinical or laboratory findings other than those typically associated with fragile X syndrome, suggesting that the deletion does not remove other contiguous genes. This report describes the phenotype of the patient, including psychological studies.
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PMID:Fragile X phenotype in a patient with a large de novo deletion in Xq27-q28. 794 90

We report the case of a mentally normal male carrier of a fragile X full mutation with a 'methylation mosaic' hybridization pattern, who carried premutation-size mutations in his sperm cells and transmitted one of them to a daughter. Clinical evaluation of the father revealed a phenotype resembling that of the fragile X syndrome but without mental impairment and 4% fragile sites on cytogenetic analysis. Direct FRAXA genotyping revealed 40% abnormal methylation at the classical EagI FMR-1 restriction site, a delta of 400 bp to 1400 bp associated, in the non-methylated region, to a widely spread smear. This is thus a rare occurrence of a male carrier of a fragile X full mutation with significant methylation of the EagI site and no mental impairment. A premutation of 400 bp was detected in his daughter's leukocytes and analysis of sperm cells from the father revealed a normal spermogram and only 400 bp premutations. This is the first documented case of transmission (with analysis of sperm DNA) of a fragile X mutation from a male carrier of a full fragile X mutation to a girl. This may be due to the early setting apart of progenitor germ cells in males having inherited a premutation from their mother. It is more likely that there could be a strong selection process favouring those cells with a reverted full mutation which produced a small and unmethylated FMR-1 CpG island allowing for re-expression of the FMR-1 gene, especially in male germ cells.
Hum Mol Genet 1994 Jun
PMID:No mental retardation in a man with 40% abnormal methylation at the FMR-1 locus and transmission of sperm cell mutations as premutations. 795 Dec 39

The vast majority of individuals with the fragile X syndrome show expanded stretches of CGG repeats in the 5' non-coding region of FMR1. This expansion coincides with abnormal methylation patterns in that area resulting in the silencing of the FMR1 gene. Evidence is accumulating that this directly causes the fragile X phenotype. Very few other mutations in FMR1, causing the fragile X phenotype have been reported thus far and all concerned isolated cases. We, however, report a family, in which 11 individuals have a deletion of 1.6 kb proximal to the CGG repeat of the FMR1 gene. Although fragile X chromosomes were not detected, all 4 affected males and 2 of the carrier females show characteristics of the fragile X phenotype. Using RT-PCR we could demonstrate that FMR1 is not expressed in the affected males, strongly suggesting that the FMR1 promoter sequences 5' to the CGG repeat are missing. The deletion patients have approximately 45 CGG repeats in their FMR1 gene, though not interspersed by AGG triplets that are usually present in both normal and expanded repeats. It is hypothesized that prior to the occurrence of the deletion, an expansion of the repeat occurred, and that the deletion removed the 5' part of the CGG repeat containing the AGG triplets. Transmission of the deletion through the family could be traced back to the deceased grandfather of the affected males, which supports the hypothesis that the FMR1 gene product is not required for spermatogenesis. Finally, the data provide additional evidence that the fragile X syndrome is a single gene disorder.
Hum Mol Genet 1994 Apr
PMID:A deletion of 1.6 kb proximal to the CGG repeat of the FMR1 gene causes the clinical phenotype of the fragile X syndrome. 806 7


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