Novel proteins with binding specificity for DNA CTG repeats and RNA CUG repeats: implications for myotonic dystrophy

While an unstable CTG triplet repeat expansion is responsible for myotonic dystrophy, the mechanism whereby this genetic defect induces the disease remains unknown. To detect proteins binding to CTG triplet repeats, we performed bandshift analysis using as probes double- stranded DNA fragments having CTG repeats [ds(CTG)6-10] and single- stranded oligonucleotides having CTG repeats ss(CTG)8 or RNA CUG triplet repeats (CUG)8. The source of protein was nuclear and cytoplasmic extracts of HeLa cells, fibroblasts and myotubes. Proteins binding to the double-stranded DNA repeat [ds(CTG)6-10], were inhibited by nonlabeled ds(CTG)6-10, but not by a non-specific DNA fragment (USF/AD-ML). Another protein binding to ssCTG probe and RNA CUG probe was inhibited by nonlabeled (CTG)8 and (CUG)8. Nonlabeled oligos with different triplet repeat sequences, ss(CAG)8 or ss(CGG)8, did not inhibit binding to the ss(CTG)8 probe. However, when labeled as probes, the (CAG)8 and (CGG)8 bound to proteins distinct from the CTG proteins and binding was inhibited by nonlabeled (CAG)8 or (CGG)8 respectively. The protein binding only to the RNA repeat (CUG)8 was inhibited by nonlabeled (CUG)8 but not by nonlabeled single- or double-stranded CTG repeats. Furthermore, the CUG-BP exhibited no binding to an RNA oligonucleotide of triplet repeats of the same length but having a different sequence, CGG. The CUG binding protein was localized to the cytoplasm, whereas dsDNA binding proteins were localized to the nuclear extract. Thus, several trinucleotide binding proteins exist and their specificity is determined by the triplet sequence. The novel protein, CUG-BP, is particularly interesting since it binds to triplet repeats known to be present in myotonin protein kinase mRNA which is responsible for myotonic dystrophy.      

Eleven trinucleotide repeat loci that map to chromosome 12 excluded from involvement in the pathogenesis of bipolar disorder

The hypothesis that one or more genes containing expanded trinucleotide repeats contribute to the pathogenesis of bipolar disorder has received support from three independent studies demonstrating that bipolar patients tend to have larger CAG/CTG repeat expansion detection products than controls. In an attempt to identify the specific expanded CAG/CTG locus or loci which are associated with bipolar disorder, we determined repeat size at CAG/CTG loci mapping to candidate regions for bipolar disorder. Recent linkage studies suggest the existence of a bipolar susceptibility gene on chromosome 12q23-q24.1 in the region of the Darier's disease (DAR) gene. In this study we report our findings from 11 loci which map to chromosome 12, including CAG repeat polymorphisms within the genes SCA2 and ASH1. We conclude that all of these loci are excluded as candidates for CAG/CTG repeat expansion in bipolar disorder.     

Cis-acting modifiers of expanded CAG/CTG triplet repeat expandability: associations with flanking GC content and proximity to CpG islands.

An increasing number of human genetic disorders are associated with the expansion of trinucleotide repeats. The majority of these diseases are associated with CAG/CTG expansions, including Huntington's disease, myotonic dystrophy and many of the spinocerebellar ataxias. Recently, two new expanded CAG/CTG repeats have been identified that are not associated with a phenotype. Expanded alleles at all of these loci are unstable, with frequent length changes during intergenerational transmission. However, variation in the relative levels of instability, and the size and direction of the length change mutations observed, between the CAG/CTG loci is apparent. We have quantified these differences, taking into account effects of progenitor allele length, by calculating the relative expandability of each repeat. Since the repeat motifs are the same, these differences must be a result of flanking sequence modifiers. We present data that indicate a strong correlation between the relative expandability of these repeats and the flanking GC content. Moreover, we demonstrate that the most expandable loci are all located within CpG islands. These data provide the first insights into the molecular bases of cis -acting flanking sequences modifying the relative mutability of dispersed expanded human triplet repeats.     

Expansions of CAG.CTG repeats in immortalized human astrocytes

Expansions of trinucleotide repeats (TNRs) are the genetic cause for a number of neurodegenerative disorders. In some of these diseases, ongoing somatic expansions in the brain are thought to contribute to disease progression. Expansions can occur in both neurons and supporting glial cells, but little is known about molecular mechanisms of expansion in these cells, particularly glia. To help address this issue, a cultured human astrocyte cell line called SVG-A was tested for expansions of CAG*CTG repeats present on a shuttle vector. A quantitative genetic selection showed that +4 to +15 repeat expansions occur readily for starting alleles of 25 repeats, thereby spanning the important boundary between short stable repeats and longer more unstable CAG*CTG tracts. These expansions in glial cell culture, as in humans, were sequence and length-dependent, and were inhibited by the presence of a sequence interruption within the triplet repeat tract. These findings suggest that the mutations seen in cell culture reflect at least some of the in vivo expansions seen in glia. Mechanistically, it was found that the direction of DNA replication through the TNR influenced the frequency of expansions, suggesting that either replication or a replication-associated process, such as DNA repair, contributes to CAG*CTG tract instability in SVG-A cells. This finding is consistent with the idea that replication-based mechanisms can be a source of TNR expansions in astrocytes, which, unlike neurons, retain proliferative capacity throughout life.     

Genome-Wide Scan for CAG/CTG Repeat Expansions in Pimas with Early Onset of Type 2 Diabetes Mellitus

The expansion of polymorphic CAG/CTG repeats in specific genes causes several neurodegenerative disorders and in many instances the length of the disease-causing repeat correlates with the onset age and/or severity of symptoms. Type 2 diabetes mellitus has features in common with diseases resulting from trinucleotide repeat expansion, including a variable age of disease onset and penetrance. We have investigated whether CAG/CTG repeat expansion contributes to the genetic etiology of type 2 diabetes in the Pima Indians, a population with the highest reported prevalence of this disease. Using the Repeat Expansion Detection (RED) method, we determined the size range in nondiabetic Pimas to be between (CAG)₂₀and (CAG)₁₃₀(mean repeat length = 195 bp), which is significantly larger than the mean size reported in Caucasians (150 bp). We compared the distribution of CAG/CTG repeat lengths among 40 Pimas with an early onset of type 2 diabetes (<22 years) and 38 nondiabetic subjects (>55 years). A 240-bp CAG/CTG RED product was found more frequently in early onset diabetics relative to nondiabetic controls (26% vs 11%), whereas a 210-bp band was more prominent in unaffected subjects (29% vs 13%); however, these differences were not statistically significant. In one Pima kindred, we also identified large RED products (≥360 bp) that displayed intergenerational instability among family members. However, these expansions were not associated with diabetes or any other clinical abnormalities in the carriers. We conclude that this unstable CAG/CTG repeat may represent a novel locus, consisting of large, but apparently nonpathogenic, unstable sequences.     

Trinucleotide repeats in the human genome: size distributions for all possible triplets and detection of expanded disease alleles in a group of Huntington disease individuals by the repeat expansion detection method

Using a modified Repeat Expansion Detection (RED) assay, that was optimized for individual oligonucleotides, unrelated individuals were systematically screened for maximal repeat sizes of each of the ten possible trinucleotide repeats. Cloned trinucleotide repeats were generated and used as standards for the detectability of single copy trinucleotide repeat fragments. When the size distributions of trinucleotide repeats were compared to previously reported data, significant differences were found for the CTT repeat, which corresponds to the expanded GAA repeat in Friedreich ataxia, as well as for ATT, CCT and GTT repeats. Since 30-35% of normal individuals have CTG/CAG trinucleotide repeat sizes of 180 bp or more, we investigated the question whether small-scale CTG/CAG repeat expansions are detectable on a population basis by using the RED technique. We blindly screened 20 HD probands with CAG expansions of the HD gene, ranging in size between 120 and 174 bp, and found that a shift to larger CAG size ranges is clearly detectable when comparing the distribution of maximal repeat sizes in the disease group to a control group. Our study, therefore, demonstrates that the application of the RED assay to a population of probands and a population of controls allows the detection of small-scale CTG/CAG repeat expansions in the size range of the expanded HD gene and present in a single allele. We also provide standards and control data for the detection of other trinucleotide repeat expansions.      

Exclusion of CAG/CTG trinucleotide repeat loci which map to chromosome 4 in bipolar disorder and schizophrenia

The hypothesis that expanded trinucleotide repeats contribute to the pathogenesis of schizophrenia and bipolar disorder has been recently supported by three independent studies which have shown that patients with either disorder tend to have larger CAG/CTG repeat expansion detection products than controls. In an attempt to identify the specific expanded CAG/CTG locus or loci which are associated with schizophrenia and bipolar disorder, we determined the repeat size at CAG/CTG loci mapping to candidate regions for psychosis. In this study we report our findings from eight loci which map to chromosome 4. We conclude that these loci are unlikely candidates for CAG/CTG repeat expansion in schizophrenia and bipolar disorder. Am. J. Med. Genet. 74:204–206, 1997. © 1997 Wiley-Liss, Inc.     

Characterization of CTG/CAG repeats on chromosome 18: a study of bipolar disorder

Anticipation has been frequently found in bipolar families ascertained for linkage studies. An association of polymorphic triplet repeats with the bipolar phenotype in some pedigrees has been proposed. We have previously found linkage to chromosome 18 in a set of families with evidence of anticipation. As part of a search for CAG/CTG motifs on chromosome 18, we screened a genomic chromosome 18 cosmid library and identified 65 loci with trinucleotide repeats. Eleven of 33 genotyped loci were polymorphic, though none of these showed any evidence of instability. We performed genetic analysis of six loci in the Hopkins/Dana bipolar pedigrees ascertained for a genetic linkage study of bipolar disorder and found that the CAG repeat within the AD4D2 clone on 18q21.1 showed nominally significant over-transmission of the rare CAG23 allele (P=0.034). We have characterized all 65 trinucleotide repeats and flanking sequences with GENSCAN analysis and find that 29 were predicted to be in coding regions. These 29 trinucleotide-repeat-containing genes may be involved in functional modulation of their respective proteins, and may be candidates for other diseases or disease mechanisms that map to this region.     

The repeat expansion detection method in the analysis of diseases with CAG/CTG repeat expansion: Usefulness and limitations

The repeat expansion detection (RED) method was described to detect expansions of trinucleotide repeats of unknown chromosomal location. We have improved the RED method by the use of 8-mer oligonucleotides and assessed its usefulness in 30 samples from patients with spinocerebellar ataxia type 1 (SCA1), Huntington's disease (HD), and Machado Joseph's disease (MJD), for which the number of CAG/CTG repeats was determined by sequencing. There was a good correlation between the number of repeats detected by sequencing and those identified by RED. However, in 17% of samples, the RED gave additional fragments for ligation products of different size than the CAG/CTG repeat expansion detected in the sample by sequencing. The same was observed in a group of control subjects (n = 78) without known clinical abnormalities in which products of more than 40 repeats were detected in 27% of them, indicating that CAG/CTG repeat expansions are common in the general population. Wether this corresponds to unidentified loci with expansions deserves further investigation. Hum Mutat 10:486–488, 1997. © 1997 Wiley-Liss, Inc.     

Intergenerational CAG repeat expansion at ERDA1 in a family with childhood-onset depression, schizoaffective disorder, and recurrent major depression

Reported evidence of anticipation for schizophrenia and bipolar disorder has recently precipitated a search for unstable trinucleotide repeats for these diseases. Several initial studies suggested an increase in the frequency of large CAG/CTG repeats in the genomes of schizophrenic and bipolar individuals. Published reports do not demonstrate expansion per se, and may be suggestive of allelic association with the disease rather than actual dynamic DNA mutations. This report documents evidence of a significant expansion of CAG/CTG repeats from one generation to the next in a family demonstrating evidence of anticipation for psychiatric disorders. Using the repeat expansion detection (RED) technique, we observed that a proband with multiple psychiatric diagnoses, including childhood-onset depression, inherited a larger CAG/CTG repeat than either parent. Analysis of the ERDA1 locus on 17q21.3 revealed that the proband inherited a very large allele from the father which increased in repeat number through transmission. The mother was diagnosed with schizoaffective disorder and the father with depression. While this DNA mutation may be a stochastic event unconnected with the disease, it could represent DNA instability as an etiologic factor in psychiatric diseases.     

Bias in the genomic distribution of CAG and CTG trinucleotide repeats

We investigated the hypothesis that the trinucleotide repeat CAG is disproportionately located in exons in genomic DNA by analyzing unbiased genomic sequences with the Gene Recognition and Analysis Internet Link program ( http//avalon.epm.ornl.gov/ ). Forty percent of CAG/CTG repeats were predicted to lie within exons. This is significantly greater than would be expected by chance, and is also greater than we have observed for ATT/AAT repeats. Therefore, our data support the hypothesis. Furthermore, the data support the utility of a recently reported CAG/CTG PCR genomic screening set for identifying pathogenic expanded CAG/CTG repeats. Am. J. Med. Genet. 74:62–64, 1997. © 1997 Wiley-Liss, Inc.     

Direct detection of expanded trinucleotide repeats using PCR and DNA hybridization techniques

Recently, unstable trinucleotide repeats have been shown to be the etiologic factor in seven neuropsychiatric diseases, and they may play a similar role in other genetic disorders which exhibit genetic anticipation. We have tested one polymerase chain reaction (PCR)-based and two hybridization-based methods for direct detection of unstable DNA expansion in genomic DNA. This technique employs a single primer (asymmetric) PCR using total genomic DNA as a template to efficiently screen for the presence of large trinucleotide repeat expansions. High-stringency Southern blot hybridization with a PCR-generated trinucleotide repeat probe allowed detection of the DNA fragment containing the expansion. Analysis of myotonic dystrophy patients containing different degrees of (CTG)_n expansion demonstrated the identification of the site of trinucleotide instability in some affected individuals without any prior information regarding genetic map location. The same probe was used for fluorescent in situ hybridization and several regions of (CTG)_n/(CAG)_n repeats in the human genome were detected, including the myotonic dystrophy locus on chromosome 19q. Although limited at present to large trinucleotide repeat expansions, these strategies can be applied to directly clone genes involved in disorders caused by large expansions of unstable DNA. © 1996 Wiley-Liss, Inc.     

Androgen receptor YAC transgenic mice carrying CAG 45 alleles show trinucleotide repeat instability

X-linked spinal and bulbar muscular atrophy (SBMA) is caused by a CAG repeat expansion in the first exon of the androgen receptor (AR) gene. Disease-associated alleles (37-66 CAGs) change in length when transmitted from parents to offspring, with a significantly greater tendency to shift size when inherited paternally. As transgenic mice carrying human AR cDNAs with 45 and 66 CAG repeats do not display repeat instability, we attempted to model trinucleotide repeat instability by generating transgenic mice with yeast artificial chromosomes (YACs) carrying AR CAG repeat expansions in their genomic context. Studies of independent lines of AR YAC transgenic mice with CAG 45 alleles reveal intergenerational instability at an overall rate of approximately 10%. We also find that the 45 CAG repeat tracts are significantly more unstable with maternal transmission and as the transmitting mother ages. Of all the CAG/CTG repeat transgenic mice produced to date the AR YAC CAG 45 mice are unstable with the smallest trinucleotide repeat mutations, suggesting that the length threshold for repeat instability in the mouse may be lowered by including the appropriate flanking human DNA sequences. By sequence-tagged site content analysis and long range mapping we determined that one unstable transgenic line has integrated an approximately 70 kb segment of the AR locus due to fragmentation of the AR YAC. Identification of the cis - acting elements that permit CAG tract instability and the trans -acting factors that modulate repeat instability in the AR YAC CAG 45 mice may provide insights into the molecular basis of trinucleotide repeat instability in humans.      

Detection of CAG repeats in pre-eclampsia/eclampsia using the repeat expansion detection method

Pre-eclampsia/eclampsia is a serious disorder of human pregnancy that has a worldwide incidence of 2-10% and carries a severe morbidity and mortality risk for both mother and child. Its precise cause remains unknown. However, there is increasing evidence of an underlying complex maternal genetic susceptibility. Its high population incidence in the face of strong negative selection pressure suggests that the gene(s) involved have a selective advantage and/or a high mutation rate. One class of genetic diseases that involve a high mutation rate are the trinucleotide repeat expansion diseases. Thus, the aim of this study was to determine whether there is an association between a trinucleotide (CAG) repeat expansion and pre-eclampsia/eclampsia. We have used the repeat expansion detection (RED) method, which was developed to directly identify clinically significant repeat expansions, to analyse genomic DNA from an Australian and New Zealand population. The maximal CAG repeat length for each individual was recorded and the Mann-Whitney U and Wilcoxon rank sum test for independent samples were used to compare distributions for CAG/CTG repeats between two populations. There were no statistically significant differences between the distribution of CAG repeats in normotensive (n = 59) and severe pre-eclampsia (n = 69) (Mann-Whitney U = 1732; P = 0.14), and normotensive (n = 59) and eclamptic (n = 15) populations (Mann-Whitney U = 417, P = 0.726). Therefore, these RED results do not support a role for a large CAG expansion in pre-eclampsia/eclampsia. However, these data do not preclude the possibility that a small CAG expansion is associated with the disorder nor do they negate the hypothesis that a highly mutable gene contributes to the genetic component of pre-eclampsia/eclampsia.     

Increased (CTG/CAG)(n) lengths in myotonic dystrophy type 1 and Machado-Joseph disease genes in idiopathic azoospermia patients

BACKGROUND: An increase in CAG trinucleotide repeat length in the androgen receptor (AR) gene has been linked to idiopathic azoospermia. METHODS: In order to test whether other (CAG/CTG)(n) loci are also affected, the (CAG/CTG)(n) frequency distribution at myotonic dystrophy type 1 (DM1), Machado-Joseph disease (MJD), dentatorubral-pallidoluysian atrophy (DRPLA) and spinocerebellar ataxia type 8 (SCA8) loci, in addition to the AR gene, was investigated in 48 azoospermia patients and 47 controls. RESULTS: The median CAG repeat length in the AR gene was significantly longer in azoospermia patients than in controls (23 versus 21, P < 0.001). Significant differences were also noted in the upper tails of trinucleotide repeat length distributions at both DM1 and MJD loci between the two populations. At the DM1 locus, alleles of more than 18 repeats were observed only in azoospermia patients, and not in controls (P = 0.014). At the MJD locus, the frequency of normal alleles (ANs) with 29 or more CAG repeats was also much higher in azoospermia patients (29.2 versus 7.4%; P = 0.0001). However, the repeat length distribution at DRPLA and SCA8 loci did not differ in the two groups. CONCLUSIONS: These data indicated that, at least in a subset of azoospermia patients, there was an increase in the number of trinucleotide repeats in some disease loci. Thus, it is noteworthy to evaluate whether offspring of these azoospermia patients, if born by assisted reproductive technologies, have an increased risk of trinucleotide repeat diseases.     

No evidence for the involvement of CAG/CTG repeats from within 18q21.33-q23 in bipolar disorder

We previously identified 18q21.33-q23 as a candidate region in one BP family and constructed a yeast artificial chromosome (YAC) contig map. Here, we mapped eight known CAG/CTG repeats relative to 18q21.33-q23. We also isolated four CAG/CTG repeats from within the region using CAG/CTG YAC fragmentation, one of which is located in the 5' untranslated region of the CAP2 gene coding for a brain-expressed serine proteinase inhibitor. The triplet repeats located in the 18q21.33-q23 BP candidate region showed no expanded alleles in the linked BP family nor in a BP case-control sample. Moreover, only the CAP2 triplet repeat was polymorphic but no genetic association with BP disorder was observed.     

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.     

Genomic instability and neurodegenerative disease

The discovery of unstable DNA sequences as the cause of genetic disease is a fascinating new area in human genetics, raising a number of important questions addressing the understanding of both the mechanisms and the effects of this new type of mutation. Trinucleotide repeat expansion mutations have been identified in a number of neurodegenerative diseases, including spinal and bulbar muscular atrophy (SBMA), fragile X syndrome (FRAXA and FRAXE), myotonic dystrophy (DM), Huntington's disease (HD), spinocerebellar ataxia types 1, 2, 3, 6, 7 (SCA1, SCA2, SCA3, SCA6, SCA7), dentatorubral-pallidoluysian atrophy (DRPLA), Friedreich's ataxia (FRDA) and autosomal dominant pure spastic paraplegia (ADPSP). They have been traced to genetic variation in the length of (CTG)n/(CAG)n, (CGG)n/(CCG)n, or (GAA)n/(TTC)n triplet repeats in DNA. In normal individuals these loci contain a short length of triplet repeats (usually 5-40), which is polymorphic within the population. Increases in the lengths of the translated triplet repeats to 40-100 are associated with disease symptoms, whereas the untranslated triplet repeats to 200-3000 are associated with the disease. We concentrated on repeat expansions in myotonic dystrophy. In this symposium, we outline the molecular aspects of myotonic dystrophy including DNA diagnosis and anticipation, and review the similarities and differences among these triplet repeat diseases.