Effects of losartan on hypertension and left ventricular mass: a long-term study

Trinucleotide repeat expansions are involved in an increasing number of neurodegenerative disorders. Eight disorders are caused by translated CAG expansions with sizes usually below 100-200 repeats. Expansions are observed in unrelated genes, and the threshold above which the disease becomes manifest varies according to the locus. There is a strong negative correlation between age at onset and the number of repeats. Direct molecular diagnosis, which is now possible, allows classification according to genotype, thereby multiplying the number of related disorders. Molecular analysis is also useful to diagnose disorders with variable and overlapping clinical features. Recent findings suggest that intranuclear inclusions are a characteristic of disorders with translated CAG expansions. Their formation might constitute an important step in the pathological process. Friedreich ataxia is the first disorder caused by a trinucleotide repeat expansion located within an intron. The clinical spectrum of the disease and its diagnostic criteria have been recently reevaluated in a large series of patients. Interestingly, Friedreich's ataxia is now thought to be associated with intramitochondrial iron accumulation. Frataxin, the protein that is mutated, might normally be responsible for mitochondrial iron homeostasis in tissues that are affected by the disease.     

Trinucleotide repeat instability: genetic features and molecular mechanisms

Trinucleotide repeat expansions are an important cause of inherited neurodegenerative disease. The expanded repeats are unstable, changing in size when transmitted from parents to offspring (intergenerational instability, "meiotic instability") and often showing size variation within the tissues of an affected individual (somatic mosaicism, "mitotic instability"). Repeat instability is a clinically important phenomenon, as increasing repeat lengths correlate with an earlier age of onset and a more severe disease phenotype. The tendency of expanded trinucleotide repeats to increase in length during their transmission from parent to offspring in these diseases provides a molecular explanation for anticipation (increasing disease severity in successive affected generations). In this review, I explore the genetic and molecular basis of trinucleotide repeat instability. Studies of patients and families with trinucleotide repeat disorders have revealed a number of factors that determine the rate and magnitude of trinucleotide repeat change. Analysis of trinucleotide repeat instability in bacteria, yeast, and mice has yielded additional insights. Despite these advances, the pathways and mechanisms underlying trinucleotide repeat instability in humans remain largely unknown. There are many reasons to suspect that this uniquely human phenomenon will significantly impact upon our understanding of development, differentiation and neurobiology.     

Diameter of the inferior vena cava as an index of dry weight in patients undergoing CAPD

Trinucleotide microsatellites are widespread in the human and other mammalian genomes. Expansions of unstable trinucleotide repeats have been associated so far with a number of different genetic diseases including fragile X, myotonic dystrophy (DM) and Huntington disease. While ten possible trinucleotides can occur at the DNA level, only CTG and CCG repeats are involved in the disorders described so far. However, the repeat expansion detection (RED) technique has identified additional large repeats of ATG, CCT, CTT, and TGG of potentially pathological significance in the human genome. We now show that conclusive information about the chromosomal localization of long trinucleotide repeats can be achieved in a relatively short time using fluorescence in situ hybridization (FISH) with biotin-labelled trinucleotide polymers. Large CTG expansions (> 1 kb) in DM and an unstable (CTG)306 repeat in a patient with schizophrenia were detected by eye through the microscope without electronic enhancement. Digital imaging was used to analyse the chromosomal distribution of long CCA and AGG repeats. Our results suggest that long trinucleotide repeats occur in the normal human genome and that the size of individual repeat loci may be polymorphic.     

Relative stability of a minimal CTG repeat expansion in a large kindred with myotonic dystrophy

The genetic basis for myotonic dystrophy (DM) is a CTG trinucleotide repeat expansion. The number of CTG repeats commonly increases in affected individuals of successive generations, in association with anticipation. We identified a large DM family in which multiple members had minimal CTG repeat expansions, and in which the number of CTG repeats remained in the minimally expanded range through at least three, and possibly four, generations. This relative stability of minimal CTG repeat expansions may help to maintain the DM mutation in the population.     

The effectiveness of topical diclofenac for lateral epicondylitis

Clinical evidence for a dominant mode of inheritance and anticipation in periodic catatonia, a distinct subtype of schizophrenia, suggests that trinucleotide repeat expansions may be involved in the aetiology of this disorder. Since genes with triplet repeats are putative canditates for causing schizophrenia, we have analysed the polymorphic B33 CTG repeat locus on chromosome 3 in 45 patients with periodic catatonia and 43 control subjects. The B33 CTG repeat locus was highly polymorphic, but all alleles in both the patient and control groups had repeat lengths within the normal range. We conclude that susceptibility to periodic catatonia is not influenced by variation at the B33 CTG repeat locus. Nevertheless, that periodic catatonia displays dominant inheritance and anticipation, characteristic of genetic disorders involving trinucleotide repeats, justifies further screening for triplet repeat expansions in this illness.     

Human MSH2 binds to trinucleotide repeat DNA structures associated with neurodegenerative diseases

The expansion of trinucleotide repeat sequences is associated with several neurodegenerative diseases. The mechanism of this expansion is unknown but may involve slipped-strand structures where adjacent rather than perfect complementary sequences of a trinucleotide repeat become paired. Here, we have studied the interaction of the human mismatch repair protein MSH2 with slipped-strand structures formed from a triplet repeat sequence in order to address the possible role of MSH2 in trinucleotide expansion. Genomic clones of the myotonic dystrophy locus containing disease-relevant lengths of (CTG)n x (CAG)n triplet repeats were examined. We have constructed two types of slipped-strand structures by annealing complementary strands of DNA containing: (i) equal numbers of trinucleotide repeats (homoduplex slipped structures or S-DNA) or (ii) different numbers of repeats (heteroduplex slipped intermediates or SI-DNA). SI-DNAs having an excess of either CTG or CAG repeats were structurally distinct and could be separated electrophoretically and studied individually. Using a band-shift assay, the MSH2 was shown to bind to both S-DNA and SI-DNA in a structure-specific manner. The affinity of MSH2 increased with the length of the repeat sequence. Furthermore, MSH2 bound preferentially to looped-out CAG repeat sequences, implicating a strand asymmetry in MSH2 recognition. Our results are consistent with the idea that MSH2 may participate in trinucleotide repeat expansion via its role in repair and/or recombination.     

cDNA cloning of a human homologue of the Caenorhabditis elegans cell fate-determining gene mab-21: expression, chromosomal localization and analysis of a highly polymorphic (CAG)n trinucleotide repeat

The two most consistent features of the diseases caused by trinucleotide repeat expansion-neuropsychiatric symptoms and the phenomenon of genetic anticipation-may be present in forms of dementia, hereditary ataxia, Parkinsonism, bipolar affective disorder, schizophrenia and autism. To identify candidate genes for these disorders, we have screened human brain cDNA libraries for the presence of gene fragments containing polymorphic trinucleotide repeats. Here we report the cDNA cloning of CAGR1, originally detected in a retinal cDNA library. The 2743 bp cDNA contains a 1077 bp open reading frame encoding 359 amino acids. This amino acid sequence is homologous (56% amino acid identify and 81% amino acid conservation) to the Caenorhabditis elegans cell fate-determining protein mab-21. CAGR1 is expressed in several human tissues, most prominently in the cerebellum, as a message of approximately 3.0 kb. The gene was mapped to 13q13, just telomeric to D13S220. A 5'-untranslated CAG trinucleotide repeat is highly polymorphic, with repeat length ranging from six to 31 triplets and a heterozygosity of 87-88% in 684 chromosomes from several human populations. One allele from an individual with an atypical movement disorder and bipolar affective disorder type II contains 46 triplets, 15 triplets longer than any other allele detected. Though insufficient data are available to link the long repeat to this clinical phenotype, an expansion mutation of the CAGR1 repeat can be considered a candidate for the etiology of disorders with anticipation or developmental abnormalities, and particularly any such disorders linked to chromosome 13.     

CAG repeat expansion in autosomal dominant familial spastic paraparesis: novel expansion in a subset of patients

Autosomal dominant familial spastic paraplegia (FSP) is a genetically heterogeneous neurodegenerative disorder displaying anticipation for which three loci have been mapped to the chromosomal positions 14q11.2-q24.3 (SPG3), 2p21-p24 (SPG4) and 15q11.1 (SPG6). The repeat expansion detection (RED) method has been used to demonstrate expanded CAG repeats in some FSP families that map to SPG4. We analyzed 20 FSP families, including four for which there is evidence for linkage to SPG4, and found that in most cases the repeat expansion detected by RED is due to non-pathogenic expansions of the chromosome 18q21.1 SEF2-1 or 17q21.3 ERDA1 locus. Polymorphic expansions at SEF2-1 and ERDA1 appear frequent and may confound RED studies in the search for genes causing disorders demonstrating anticipation. In six FSP families, however, CAG repeat expansion was detected in a subset of affected and at-risk individuals that did not result from expansion of the SEF2-1 and ERDA1 loci. Overall, 11 of 37 (30%) of the FSP patients with a CAG/CTG repeat expansion are unaccounted for by the SEF2-1 and ERDA1 loci, compared with two of 23 (9%) of the unaffected at-risk individuals and none of 19 controls. In the majority of cases these novel expansions were shorter than those previously reported.     

Expanding complexity in myotonic dystrophy

Myotonic dystrophy (DM) is a highly variable multisystemic disease belonging to the rather special class of trinucleotide expansion disorders. DM results from dynamic expansion of a perfect (CTG)n repeat situated in a gene-dense region on chromosome 19q. Based on findings in patient materials or cellular and animal models, many mechanisms for the causes and consequences of repeat expansion have been proposed; however, none of them has enjoyed prolonged support. There is now circumstantial evidence that long (CTG)n repeats may affect the expression of any of at least three genes, myotonic dystrophy protein kinase (DMPK), DMR-N9 (gene 59), and a DM-associated homeodomain protein (DMAHP). Furthermore, the new findings suggest that DM is not a simple gene-dosage or gain-or-loss-of-function disorder but that entirely new pathological pathways at the DNA, RNA, or protein level may play a role in its manifestation.     

Aortocoronary bypass grafting with expanded polytetrafluoroethylene: 12-year patency

The size of CAG repeats was compared in lymphocytes and skeletal muscle from nine patients with Huntington disease (HD) and two patients with Kennedy disease (KD). In HD, the number of CAG repeats did not differ between lymphocytes and skeletal muscle. In the two KD patients, however, the CAG expansion was larger in muscle than in lymphocytes. The difference in trinucleotide expansion between lymphocytes and muscle cells is not a universal phenomenon in trinucleotide repeat disorders, but seems to occur in disorders primarily affecting the neuromuscular system.     

CAG trinucleotide RNA repeats interact with RNA-binding proteins

Genes associated with several neurological diseases are characterized by the presence of an abnormally long trinucleotide repeat sequence. By way of example, Huntington's disease (HD), is characterized by selective neuronal degeneration associated with the expansion of a polyglutamine-encoding CAG tract. Normally, this CAG tract is comprised of 11-34 repeats, but in HD it is expanded to > 37 repeats in affected individuals. The mechanism by which CAG repeats cause neuronal degeneration is unknown, but it has been speculated that the expansion primarily causes abnormal protein functioning, which in turn causes HD pathology. Other mechanisms, however, have not been ruled out. Interactions between RNA and RNA-binding proteins have previously been shown to play a role in the expression of several eukaryotic genes. Herein, we report the association of cytoplasmic proteins with normal length and extended CAG repeats, using gel shift and UV crosslinking assays. Cytoplasmic protein extracts from several rat brain regions, including the striatum and cortex, sites of neuronal degeneration in HD, contain a 63-kD RNA-binding protein that specifically interacts with these CAG-repeat sequences. These protein-RNA interactions are dependent on the length of the CAG repeat, with longer repeats binding substantially more protein. Two CAG repeat-binding proteins are present in human cortex and striatum; one comigrates with the rat protein at 63 kD, while the other migrates at 49 kD. These data suggest mechanisms by which RNA-binding proteins may be involved in the pathological course of trinucleotide repeat-associated neurological diseases.     

Structures of new acylated oleanene-type triterpene oligoglycosides, theasaponins E1 and E2, from the seeds of tea plant, Camellia sinensis (L.) O. Kuntze

Friedreich's ataxia is the first known autosomal recessive disease caused by an unstable trinucleotide expansion mutation. The most frequent mutation is expansion of a GAA repeat in the first intron of gene X25. We studied transmission of the expanded GAA repeat in 37 Friedreich's ataxia pedigrees and analysed blood and sperm alleles in eight patients. We showed intergenerational instability in 84% of the alleles with an overall excess of contractions. Both contractions and expansions of the GAA repeat occurred in maternal transmission with a stronger tendency to expand for smaller repeats and to contract for longer repeats. Paternally transmitted alleles contracted only. Parental age and the intergenerational change in expansion size were directly correlated in maternal transmission and inversely in paternal transmission. The size of the GAA expansion was slightly lower in patients than heterozygous carriers. Sperm analysis confirmed the tendency to contract of paternal alleles, which was more marked with ageing. The degree of contraction of the GAA repeat in sperm was much higher than that found in intergenerational transmission and was directly related to the repeat size. A blood expanded allele reverted to normal size in the sperm of one patient. This study suggests the existence of different mutational mechanisms in Friedreich's ataxia alleles, which occur both pre- and post-zygotically.     

Trinucleotide expansion within the MJD1 gene presents clinically as spinocerebellar ataxia and occurs most frequently in German SCA patients

Autosomal dominant spinocerebellar ataxia (SCA) is a clinically and genetically heterogeneous neurodegenerative disorder which leads to progressive cerebellar ataxia. A gene responsible for SCA type 3 has been mapped to human chromosome 14q, close to the Machado-Joseph disease (MJD) locus. The MJD1 gene has recently been cloned and the disease causing mutation has been identified as an unstable and expanded (CAG)n trinucleotide repeat. As some clinical features of MJD overlap with those of SCA we investigated the MJD mutation in 38 German families with dominantly inherited SCA. The MJD1 (CAG)n expansion was identified in 19 families. In contrast, the trinucleotide expansion was not observed in 21 ataxia patients without family history of the disease. Analysis of the (CAG)n repeat length in 30 patients revealed an inverse correlation with the age of onset. The (CAG)n stretch of the affected allele varied between 67 and 78 trinucleotide units, the normal alleles carried between 12 and 28 simple repeats. These results demonstrate that the MJD mutation causes the disease phenotype of most SCA patients in Germany.     

Filamentous nerve cell inclusions in neurodegenerative diseases

Recent work has shown that abnormal filamentous inclusions within some nerve cells is a characteristic shared by Alzheimer's disease, some frontotemporal dementias, Parkinson's disease, dementia with Lewy bodies, multiple system atrophy, as well as Huntington's disease and other trinucleotide repeat disorders. This suggests that in each of these disorders, the affected nerve cells degenerate as a result of these abnormal inclusions. Except for trinucleotide repeat disorders, the filaments involved have been shown to consist of either the microtubule-associated protein tau or alpha-synuclein. Over the past year, mutations in the genes for tau and alpha-synuclein have been identified as the genetic causes of some familial forms of frontotemporal dementia and Parkinson's disease, respectively. The discovery last year of neuronal intranuclear inclusions in Huntington's disease and other disorders with expanded glutamine repeats has suggested a unifying mechanism underlying the pathogenesis of this class of neurodegenerative diseases.     

The interaction of shikimic acid and protein phosphorylation with PEP carboxylase from the C4 dicot Amaranthus viridis

CAG repeat expansions cause spinocerebellar ataxia type 1 (SCA1), SCA2, SCA3, SCA6 and dentatorubral-pallidoluysian atrophy (DRPLA). So far these expansions have been examined mainly in ataxia patients with a family history. However, some sporadic cases with SCA have recently been reported. To elucidate the frequency and characteristics of sporadic SCAs, we screened 85 Japanese ataxia patients without a family history for the SCA1, SCA2, SCA3, SCA6 and DRPLA mutations. As a result, 19 patients (22%) were found to have expanded CAG repeats. Among sporadic SCAs, the SCA6 mutation was most frequently observed. The sporadic SCA6 patients had smaller CAG repeats and a later age of onset than SCA6 patients with an established family history. We also identified one father-child pair in which intermediate sized CAG repeats expanded into the SCA2 disease range during transmission. These findings suggest that patients with ataxia even without a family history should be examined for a CAG repeat expansion.     

Occlusal trauma: a case in perspective

Spinocerebellar ataxia type 1 (SCA1) is an autosomal dominant neurodegenerative disorder caused by expansion of a CAG trinucleotide repeat which codes for glutamine in the protein ataxin-1. We have investigated the effect of this expansion on ataxin-1 by immunoblot analysis. The wild-type protein is detected in both normal and affected individuals; however, a mutant protein which varies in its migration properties according to the size of the CAG repeat is detected in cultured cells and tissues from SCA1 individuals. The protein has a nuclear localization in all normal and SCA1 brain regions examined but a cytoplasmic localization of ataxin-1 was also observed in cerebellar Purkinje cells. Our data show that in SCA1, the expanded alleles are faithfully translated into proteins of apparently normal stability and distribution.     

Mapping the polarity of changes that occur in interrupted CAG repeat tracts in yeast

To explore the mechanisms by which CAG trinucleotide repeat tracts undergo length changes in yeast cells, we examined the polarity of alterations with respect to an interrupting CAT trinucleotide near the center of the tract. In wild-type cells, in which most tract changes are large contractions, the changes that retain the interruption are biased toward the 3' end of the repeat tract (in reference to the direction of lagging-strand synthesis). In rth1/rad27 mutant cells that are defective in Okazaki fragment maturation, the tract expansions are biased to the 5' end of the repeat tract, while the tract contractions that do not remove the interruption occur randomly on either side of the interruption. In msh2 mutant cells that are defective in the mismatch repair machinery, neither the small changes of one or two repeat units nor the larger contractions attributable to this mutation are biased to either side of the interruption. The results of this study are discussed in terms of the molecular paths leading to expansions and contractions of repeat tracts.     

Cloned human FMR1 trinucleotide repeats exhibit a length- and orientation-dependent instability suggestive of in vivo lagging strand secondary structure

The normal human FMR1 gene contains a genetically stable (CGG) n trinucleotide repeat which usually carries interspersed AGG triplets. An increase in repeat number and the loss of interspersions results in array instability, predominantly expansion, leading to FMR1 gene silencing. Instability is directly related to the length of the uninterrupted (CGG) n repeat and is widely assumed to be related to an increased propensity to form G-rich secondary structures which lead to expansion through replication slippage. In order to investigate this we have cloned human FMR1 arrays with internal structures representing the normal, intermediate and unstable states. In one replicative orientation, arrays show a length-dependent instability, deletions occurring in a polar manner. With longer arrays these extend into the FMR1 5'-flanking DNA, terminating at either of two short CGG triplet arrays. The orientation-dependent instability suggests that secondary structure forms in the G-rich lagging strand template, resolution of which results in intra-array deletion. These data provide direct in vivo evidence for a G-rich lagging strand secondary structure which is believed to be involved in the process of triplet expansion in humans.     

Analysis of CAG/CTG repeat size in Chinese subjects with schizophrenia and bipolar affective disorder using the repeat expansion detection method

BACKGROUND: Family studies of schizophrenia and bipolar affective disorder provide evidence for genetic anticipation, which (in common with a number of mendelian disorders), may be caused by triplet repeat expansion. This hypothesis is strengthened by evidence from repeat expansion detection (RED) analysis revealing association between the psychoses and long CAG/CTG trinucleotide repeats. METHODS: We performed RED on Han Chinese subjects with schizophrenia (82), bipolar affective disorder (43), and normal controls (61), using a CTG10 oligonucleotide. RESULTS: Comparison between cases and controls revealed no significant association between long repeats and affected status. We also found no detectable association with age at onset and repeat length in either bipolar affective disorder or schizophrenia. Overall, the size distribution of CAG/CTG repeats in Chinese subjects was not significantly different from those reported previously for Caucasian subjects. CONCLUSIONS: These findings indicate that CAG/CTG repeat expansion is not likely to be a major etiological factor for psychosis in Chinese populations.     

Effect of nitrates and nitrites on small intestine

Models for the disease-associated expansion of (CTG)n.(CAG)n, (CGG)n.(CCG)n, and (GAA)n.(TTC)n trinucleotide repeats involve alternative DNA structures formed during DNA replication, repair and recombination. These repeat sequences are inherently flexible and can form a variety of hairpins, intramolecular triplexes, quadruplexes, and slipped-strand structures that may be important intermediates and result in their genetic instability.