Aberrant splicing of the CHM gene is a significant cause of choroideremia

Em, Sankila; Tolvanen, Riina; Ja, van den Hurk; Fp, Cremers; A, de la Chapelle

doi:10.1038/ng0592-109

Cited by 85 publications

(39 citation statements)

References 10 publications

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“…Splice-donor site +3 mutations have been incriminated as the cause of human genetic disease in 14 other cases [6-17 and references therein]. Of the total, 3 are+3 A>T [8,12,17],as in our subject 4479, and 4 are +3insT [6,9,11,14], as in our subject 926203. The phenotypic consequence of the AR Intl(+3insT) or the Int6(+3A > T) mutation is complete androgen insensitivity.…”

Section: Discussionmentioning

confidence: 93%

See 1 more Smart Citation

Altered mRNA Expression due to Insertion or Substitution of Thymine at Position +3 of Two Splice-Donor Sites in the Androgen Receptor Gene

Trifiro¹,

Lumbroso²,

Beitel³

et al. 1997

Eur J Hum Genet

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Section: Discussionmentioning

confidence: 93%

“…The critical nature of the +3 splicedonor site position in normal mRNA processing is high lighted by the identification of 14 other +3 splice-donor site mutations in a variety of human genetic diseases [6][7][8][9][10][11][12][13][14][15][16][17], and references to +3 mutations therein].…”

Section: Introductionmentioning

confidence: 99%

Altered mRNA Expression due to Insertion or Substitution of Thymine at Position +3 of Two Splice-Donor Sites in the Androgen Receptor Gene

Trifiro¹,

Lumbroso²,

Beitel³

et al. 1997

Eur J Hum Genet

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“…Out of some 33 diseases, the chromosomal locus is known for 17, and the mutated gene identified for 15, (AGU, 208400) aspartylglucosaminidase [Ikonen et al, 1991] Choroideremia (303100) Rab geranylgeranyl transferase [Sankila et al, 1992] Congenital chloride diarrhea (CCD, 214700) chloride transporter [Höglund et al, 1996] Congenital nephrosis (CNF, 256300) nephrin ] Diastrophic dysplasia (DTD, 222600) sulfate transporter [Hästbacka et al, 1994b] Familial amyloidosis, Finnish type (FAF, 105120) gelsolin [Levy et al, 1990] Gyrate atrophy of choroid & retina (HOGA, 258870) ornithine Á-aminotransferase [Mitchell et al, 1989] Hypergonadotrophic ovarial dysgenesis (233300) follicle-stimulating hormone receptor [Aittomäki et al, 1995] Infantile neuronal ceroid lipofuscinosis (INCL, 256730) palmitoyl protein thioesterase [Vesa et al, 1995] Lysinuric protein intolerance (LPI, 222700) L-amino acid transporter [Lauteala et al, 1997] Nonketotic hyperglycinemia (NKH, 238300) glycine cleavage system; protein P [Kure et al, 1992 (600334) 2q [Haravuori et al, 1998] Usher syndrome, type III (276902) 3q most of them by positional cloning (table 1). According to expectations, all these disorders have shown extreme locus and allelic homogeneity.…”

Section: Finnish Disease Heritagementioning

confidence: 99%

Positional Cloning of Disease Genes: Advantages of Genetic Isolates

Peltonen

1999

Hum Hered

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Genetic isolates with a history of a small founder population, long-lasting isolation and population bottlenecks represent exceptional resources in the identification of disease genes. Specific rare, monogenic diseases become enriched, and families with multiple affected individuals occur frequently enough to be used in linkage analyses for locus identification. Further, the vast majority of cases are caused by the same mutation, and disease alleles reveal linkage disequilibrium (LD) with markers over significant genetic intervals; this facilitates disease locus identification by similarity search for a shared genotype or haplotype in small study samples consisting of few affected individuals. LD observed in disease alleles adds power to linkage analyses and helps to define the exact location of disease loci on the genetic map. Typically, based on the linkage disequilibrium and the ancient haplotype, the critical DNA region can be defined from the original 1- to 2-cM resolution obtained in linkage analysis to 50–200 kb, greatly facilitating the targeting of physical cloning and sequencing efforts. These advantages have been well demonstrated in the positional cloning of several rare monogenic diseases enriched in population isolates like the example of Finland used here. How useful genetic isolates will prove to be in the identification of complex disease genes is dependent on the genealogical history of the isolate, including the size of the founding population and the expansion rate during the history of the population.

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“…In studies of European families with CHM, a total of 15 different mutations have been reported Sankila et al, 1992;Schwartz et al, 1993;Donnelly et al, 1994;van Bokhoven et al, 1994b) in the CHM gene. All the mutations, except one, result in the formation of a stop codon at the site of the mutation or create frameshift mutations that lead to premature stop codons.…”

Section: Introductionmentioning

confidence: 99%