Mendelian segregation of normal CAG trinucleotide repeat alleles at three autosomal loci

Segregation ratio distortion (SRD) with preferential transmission of expanded CAG alleles has been reported in Machado-Joseph disease (MJD/SCA3), spinocerebellar ataxia type I (SCA1), and dentatorubral-pallidoluysian atrophy (DRPLA). We have examined the transmission frequencies of alleles in normal heterozygotes at these disease loci in 377 pairs of twins and their parents and find no evidence for SRD.     

YAC transgenic mice carrying pathological alleles of the MJD1 locus exhibit a mild and slowly progressive cerebellar deficit

Machado-Joseph disease (MJD; MIM 109150) is a late-onset neurodegenerative disorder caused by the expansion of a polyglutamine tract within the MJD1 gene. We have previously reported the generation of human yeast artificial chromosome (YAC) constructs encompassing the MJD1 locus into which expanded (CAG)(76) and (CAG)(84) repeat motifs have been introduced by homologous recombination. Transgenic mice containing pathological alleles with polyglutamine tract lengths of 64, 67, 72, 76 and 84 repeats, as well as the wild type with 15 repeats, have now been generated using these YAC constructs. The mice with expanded alleles demonstrate a mild and slowly progressive cerebellar deficit, manifesting as early as 4 weeks of age. As the disease progresses, pelvic elevation becomes markedly flattened, accompanied by hypotonia, and motor and sensory loss. Neuronal intranuclear inclusion (NII) formation and cell loss is prominent in the pontine and dentate nuclei, with variable cell loss in other regions of the cerebellum from 4 weeks of age. Interestingly, peripheral nerve demyelination and axonal loss is detected in symptomatic mice from 26 weeks of age. In contrast, transgenic mice carrying the wild-type (CAG)(15) allele of the MJD1 locus appear completely normal at 20 months. Disease severity increases with the level of expression of the expanded protein and the size of the repeat. These mice are representative of MJD and will be a valuable resource for the detailed analysis of the roles of repeat length, tissue specificity and level of expression in the neurodegenerative processes underlying MJD pathogenesis.     

Somatic instability of the androgen receptor CAG repeat in a normal female

The polyglutamine repeat disorders represent a family of degenerative neurological diseases which are characterized by expansions of tandemly repeated CAG repeats. Investigations have demonstrated that in Huntington disease, dentatorubral pallidoluysian atrophy, and the spinocerebellar ataxias type 1, 2, and 3, the polyglutamine expansions show both meiotic and mitotic instability. However, previous studies have suggested that the polyglutamine motif within exon 1 of the androgen receptor gene (AR) which expands in cases of spinobulbar muscular atrophy differs in that it is apparently mitotically stable. During linkage analysis in a family with FG syndrome, a rare condition mapped to Xq12-q22.1, we detected the presence of an unusually small AR allele segregating within the pedigree. Sequencing, cytogenetic analysis, and PCR of flanking markers indicate that this allele arose by a somatic contraction of seven CAG repeats in the proband's mother, representing the first report of mitotic instability of an AR CAG repeat of normal size.     

An integrated map of chromosome 18 CAG trinucleotide repeat loci

Expansions of trinucleotide CAG repeats have been demonstrated in at least eight neurodegenerative disorders, and suggested to occur in several others, including bipolar disorder and schizophrenia. Chromosome 18 loci have been implicated in bipolar disorder pedigrees by linkage analysis. To address this putative link between chromosome 18 CAG trinucleotide repeats and neuropsychiatric illness, we have screened a chromosome 18 cosmid library (LL18NCO2" AD") and identified 14 novel candidate loci. Characterisation of these loci involved repeat flank sequencing, estimation of polymorphism frequency and mapping using FISH as well as radiation hybrid panels. These mapped trinucleotide loci will be useful in the investigation of chromosome 18 in neurodegenerative or psychiatric conditions, and will serve to integrate physical and radiation hybrid maps of chromosome 18.     

Transgenic mice carrying an Xist-containing YAC

The initiation of X-chromosome inactivation in female mammals is controlled by a key locus, the X-inactivation centre (Xic). The Xist gene, which maps to the candidate region for Xic and is expressed exclusively from the inactive X chromosome, is thought to be an essential component of the Xic. To test whether sequences spanning several hundred kilobases and including Xist from the Xic region are capable of initiating inactivation, we have created a series of transgenic mice using a 460 kb yeast artificial chromosome (YAC). Analysis in these mice of the expression of Xist, of a LacZ reporter gene and of two genes in the region that are normally silent on the inactive X chromosome, suggests that essential sequences for Xist expression and X-inactivation may be absent in these transgenic animals.      

Increased trinucleotide repeat instability with advanced maternal age

Nucleotide repeat instability is associated with an increasing number of cancers and neurological disorders. The mechanisms that govern repeat instability in these biological disorders are not well understood. To examine genetic aspects of repeat instability we have introduced an expanded CAG trinucleotide repeat into transgenic mice. We have detected intergenerational CAG repeat instability in transgenic mice only when the transgene was maternally transmitted. These intergenerational instabilities increased in frequency and magnitude as the transgenic mother aged. Furthermore, triplet repeat variations were detected in unfertilized oocytes and were comparable with those in the offspring. These data show that maternal repeat instability in the transgenic mice occurs after meiotic DNA replication and prior to oocyte fertilization. Thus, these findings demonstrate that advanced maternal age is an important factor for instability of nucleotide repeats in mammalian DNA.      

Androgen receptor CAG and GGC polymorphisms in Mediterraneans: repeat dynamics and population relationships

Microsatellite variation (CAG and GGC repeats) of the androgen receptor (AR) gene shows remarkable differences among African and non-African populations. In vitro studies have demonstrated an inverse relationship between the length of both microsatellites and AR activity. This fact may explain the observed association of the AR gene with prostate cancer and the strong ethnic differences in the incidence of this cancer. CAG and GGC genetic variation has been tested in a large set of populations from the Ivory Coast as well as 12 Mediterranean samples whose variation is described for the first time. The pattern of frequencies observed in the Ivory Coast agrees with data previously reported for other Sub-Saharan populations. Concerning the Mediterranean variation, Sardinian samples are characterised by low genetic diversities, and Egyptian Siwa Berbers by a particular pattern of GGC frequencies. High and Middle Atlas Moroccan Berbers are the most closely related to the Sub-Saharan variation. For both the CAG and GGC repeats, the Ivory Coast and some Moroccan samples exhibit high frequencies of low size alleles (CAG under 18 repeats, and GGC under 15 repeats) that have been associated with prostate cancer.Electronic Supplementary Material Supplementary material is available for this article at and is accessible for authorized users     

Genome wide screening of CAG trinucleotide repeat lengths in breast cancer

Trinucleotide repeat sequences are widely present in the human genome. The expansion of CAG repeats have been studied very extensively, and shown to be the causative mechanism of more than 40 neuromuscular and neurodegenerative diseases. In the present study, we performed a genome wide screening of CAG repeat expansions in non-neoplastic tissues of 212 breast cancer cases and 196 healthy population controls using the Repeat Expansion Detection (RED) method. Distribution of CAG repeat lengths in cases was not significantly different from controls. However, dramatically expanded CAG repeats were detected in 2.4% (n=5) of breast cancer cases where no repeats of similar size were detected in any of the healthy population controls. Although this trend shows only borderline significance (p=0.06), this finding suggests a potential involvement of CAG repeat expansion in breast cancer susceptibility. These repeats may potentially affect the function of cancer predisposition genes, with a similar mechanism as in neurodegenerative and neuromuscular disorders.     

Genomic context drives SCA7 CAG repeat instability,while expressed SCA7 cDNAs are intergenerationally and somatically stable in transgenic mice

Spinocerebellar ataxia type 7 (SCA7) is an autosomal dominant cerebellar ataxia caused by a CAG repeat expansion in the ataxin-7 gene. In humans, SCA7 is characterized by marked anticipation due to intergenerational repeat instability with a bias toward expansion, and is thus regarded as the most unstable of the polyglutamine diseases. To study the molecular basis of CAG/CTG repeat instability and its pathological significance, we generated lines of transgenic mice carrying either a SCA7 cDNA construct or a 13.5 kb SCA7 genomic fragment with 92 CAG repeats. While the cDNA transgenic mice showed little intergenerational repeat instability, the genomic fragment transgenic mice displayed marked intergenerational instability with an obvious expansion bias. We then went on to generate additional lines of genomic fragment transgenic mice, and observed that deletion of the 3' genomic region significantly stabilized intergenerational transmission of the SCA7 CAG92 repeat. These results suggest that cis-information present on the genomic fragment is driving the instability process. As the SCA7 genomic fragment contains a large number of replication-associated motifs, the presence of such sequence elements may make the SCA7 CAG repeat region more susceptible to instability. Small-pool and standard PCR analysis of tissues from genomic fragment mice revealed large repeat expansions in their brains and livers, but no such changes were found in any tissues from cDNA transgenic mice that have been shown to undergo neurodegeneration. As large somatic repeat expansions are absent from the brains of SCA7 cDNA mice, our results indicate that neurodegeneration can occur without marked somatic mosaicism, at least in these mice.     

安徽入亨廷顿病CAG三核苷酸重复的分子分析

为在分子水平了解安徽人亨廷顿病(HD)的发病机制,为该病的基因诊断和遗传咨询提供科学依据.应用巢式PCR,变性聚丙烯酰胺凝胶电泳以及DNA测序等方法,对6例正常安徽人以及6例HD家系的研究结果表明中国人正常IT15基因(CAG)n重复序列的拷贝数为13-26,而所有被分析的HD患者都携带一个CAG序列高度重复的IT15基因,其(CAG)n的拷贝数为40-94;且CAG重复序列的拷贝数与发病年龄呈现一定的相关性.     

Factors associated with HD CAG repeat instability in Huntington disease

Background

The Huntington disease (HD) CAG repeat exhibits dramatic instability when transmitted to subsequent generations. The instability of the HD disease allele in male intergenerational transmissions is reflected in the variability of the CAG repeat in DNA from the sperm of male carriers of the HD gene.

Results

In this study, we used a collection of 112 sperm DNAs from male HD gene‐positive members of a large Venezuelan cohort to investigate the factors associated with repeat instability. We confirm previous observations that CAG repeat length is the strongest predictor of repeat‐length variability in sperm, but we did not find any correlation between CAG repeat instability and either age at the time of sperm donation or affectedness status. We also investigated transmission instability for 184 father–offspring and 311 mother–offspring pairs in this Venezuelan pedigree. Repeat‐length changes were dependent upon the sex of the transmitting parent and parental CAG repeat length but not parental age or birth order. Unexpectedly, in maternal transmissions, repeat‐length changes were also dependent upon the sex of the offspring, with a tendency for expansion in male offspring and contraction in female offspring.

Conclusion

Significant sibling–sibling correlation for repeat instability suggests that genetic factors play a role in intergenerational CAG repeat instability.     

Moderate instability of the trinucleotide repeat in spino bulbar muscular atrophy.

Increased length of a protein-coding CAG repeat within the androgen receptor gene appears to be the only type of mutation responsible for spino-bulbal muscular atrophy (SBMA or Kennedy disease). We have analysed a large 4-generation SBMA family and found that the mutant allele was unstable upon transmission from parent to child, with a documented variation from 46 to 53 repeats and a tendency to increase in size (7 increases and a single decrease in 17 events), which appeared stronger upon transmission from a male than from a female. Our results suggest also limited somatic instability of the abnormal allele, with observable variation of up to 2-3 repeats. This indicates that the behavior of the CAG repeat is similar to that observed for small premutations in the fragile X syndrome, or small abnormal alleles in myotonic dystrophy, two diseases which are caused by expansion of an unstable trinucleotide repeat.     

Gender of the embryo contributes to CAG instability in transgenic mice containing a Huntington's disease gene

Gender is known to influence the transmission of trinucleotide repeats in human disease. However, the molecular basis for the parent-of-origin effect associated with trinucleotide repeat expansion is not known. We have followed, during transmission, the fate of the CAG trinucleotide repeat in a transgene containing the exon 1 portion of the human Huntington's disease (HD) gene. Similar to humans, the mouse transmits expansions predominantly through the male germ line. Surprisingly, we find that the CAG repeat size of the mutant human HD gene is different in male and female progeny from identical fathers. Males predominantly expand the repeat whereas females predominantly contract the repeat. In contrast to the classic definition of imprinting, CAG expansion is influenced by the gender of the embryo. Our results raise the possibility that there are X- or Y-encoded factors that influence repair or replication of DNA in the embryo. Gender dependence in the embryo may explain why expansion in HD from premutation to disease primarily occurs through the paternal line.