An integrated map of chromosome 18 CAG trinucleotide repeat loci

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.

Structures of trinucleotide repeats in human transcripts and their functional implications

Among the goals of RNA structural and functional genomics is determining structures and establishing the functions of a rich repertoire of simple sequence repeats in transcripts. These repeats are present in transcripts from their 'birth' in the nucleus to their 'death' in cytoplasm and have the potential of being involved in many steps of RNA regulation. The knowledge of their structural features and functional roles will also shed more light on the postulated mechanisms of RNA pathogenesis in a growing list of neurological diseases caused by simple sequence repeat expansions. Here, we discuss several different lines of research to support the hypothesis that the mechanism of RNA pathogenesis may be a more common phenomenon triggered or modulated also by abundant long normal repeats. We propose structures of the repeat regions in transcripts of genes involved in Triplet Repeat Expansion Diseases. We have classified the polymorphic repeat alleles of these genes according to their ability to form hairpin structures in transcripts, and describe the distribution of different structural forms of the repeats in the human population. We have also reported the results of a systematic survey of the human transcriptome to identify mRNAs containing triplet repeats and to classify them according to structural and functional criteria. Based on this knowledge, we discuss the putative wider role of triplet repeat RNA hairpins in human diseases. A hypothetical model is proposed in which long normal RNA hairpins formed by the repeats may also be involved in pathogenesis.

Trinucleotide repeat expansions: do they contribute to bipolar disorder?

It has long been known that bipolar disorder has a true but complex genetic background. Reports on genetic anticipation in bipolar disorder opened the way to a new approach for genetic studies. Indeed, anticipation, a decreasing age at onset, and/or increasing disease severity in successive generations, were recently explained by an expansion of trinucleotide repeats in monogenic diseases like Huntington's disease and Fragile X syndrome. The involvement of trinucleotide repeat expansions in bipolar disorder received even more support when studies reported association of large CAG/CTG repeats with bipolar disorder. Even though a large number of studies have been conducted, this association is still unexplained. Here, we review the studies investigating the trinucleotide repeat expansion hypothesis in bipolar disorder. Studies on anticipation, on association of anonymous large CAG/CTG repeats and on specific trinucleotide repeats are critically analysed and discussed, showing a field with precipitate conclusions or inconclusive results. The analysis suggests that there are indications, though disputable, supporting the trinucleotide repeat expansion hypothesis in bipolar disorder, but no conclusive evidence has been hitherto provided.

Genetic basis of schizophrenia: trinucleotide repeats. An update

1. Recent developments in technologies permit systematic screening of the entire human genome as a strategy for identification of susceptibility genes of small effect that influence risk to complex traits, like schizophrenia (Schz), inflammatory bowel disease, bipolar affective disorder (BPAD) etc. 2. Schizophrenia is known to have a high heritability and a complex inheritance pattern. Several studies provide evidence that both genes and environment play a role in the etiology of schizophrenia. Linkage studies have observed racial and sex bias in the genetic constitution of schizophrenia. Schizophrenia also manifests clinical anticipation and genomic imprinting. 3. "Dynamic mutations" or "tandem repeat expansions" in DNA, explain a number of observations associated with clinical anticipation and genomic imprinting. In patient populations, the repeat expands well beyond the normal range, altering the biological function of the gene. These sequence are unstable and increase in size between family members in successive generations, giving rise to greater severity of disease. 4. Several workers have reported an association of trinucleotide repeat length with adult- and child-onset schizophrenia. One such expanded allele has been found at the CTG18.1 locus on the 18th chromosome. Other genes known to have similar mutation are SEF2-1, which codes for a helix-loop-helix protein, hSKCa3 gene, which codes for a calcium-activated potassium channel and the transthyretin gene. In schizophrenic patients, significant difference in allele frequency distribution of these genes has been reported. 5. Population based genetic research would not only help identify different subgroups of this of schizophrenia.