Claude T. Ashley scite author profile

Fragile X syndrome is the result of transcriptional suppression of the gene FMR1 as a result of a trinucleotide repeat expansion mutation. The normal function of the FMR1 protein (FMRP) and the mechanism by which its absence leads to mental retardation are unknown. Ribonucleoprotein particle (RNP) domains were identified within FMRP, and RNA was shown to bind in stoichiometric ratios, which suggests that there are two RNA binding sites per FMRP molecule. FMRP was able to bind to its own message with high affinity (dissociation constant = 5.7 nM) and interacted with approximately 4 percent of human fetal brain messages. The absence of the normal interaction of FMRP with a subset of RNA molecules might result in the pleiotropic phenotype associated with fragile X syndrome.

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Tissue specific expression of FMR–1 provides evidence for a functional role in fragile X syndrome

Hinds

et al. 1993

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We have performed mRNA in situ hybridization studies and northern blot analysis in the mouse and human, respectively, to determine the normal gene expression patterns of FMR-1. Expression in the adult mouse was localized to several regions of the brain and the tubules of the testes, which are two of the major organs affected in fragile X syndrome. Universal and very strong expression was observed in early mouse embryos, with differentially decreasing expression during subsequent stages of embryonic development. The early embryonic onset and tissue specificity of FMR-1 gene expression is consistent with involvement in the fragile X phenotype, and also suggests additional organ systems in which clinical manifestations of reduced FMR-1 gene expression may occur.

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Human and murine FMR-1: alternative splicing and translational initiation downstream of the CGG–repeat

et al. 1993

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Fragile X syndrome is associated with massive expansion of a CGG trinucleotide repeat within the FMR-1 gene and transcriptional silencing of the gene due to abnormal methylation. Partial cDNA sequence of the human FMR-1 has been reported. We report here the isolation and characterization of cDNA clones encoding the murine homologue, fmr-1, which exhibit marked sequence identity with the human gene, including the conservation of the CGG repeat. A conserved ATG downstream of the CGG repeat in human and mouse and an in-frame stop codon in other human 5' cDNA sequences demarcate the FMR-1 coding region and confine the CGG repeat to the 5' untranslated region. We also present evidence for alternative splicing of the FMR-1 gene in mouse and human brain and show that one of these splicing events alters the FMR-1 reading frame, predicting isoforms with novel carboxy termini.

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Claude T. Ashley

FMR1 Protein: Conserved RNP Family Domains and Selective RNA Binding

Tissue specific expression of FMR–1 provides evidence for a functional role in fragile X syndrome

Human and murine FMR-1: alternative splicing and translational initiation downstream of the CGG–repeat

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