Use this URL to cite or link to this record in EThOS: https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.247761
Title: Genetic and environmental modifiers of somatic trinucleotide repeat dynamics
Author: Gomes-Pereira, Mario
ISNI:       0000 0001 3502 5337
Awarding Body: University of Glasgow
Current Institution: University of Glasgow
Date of Award: 2002
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Abstract:
The expansion of CAG•CTG trinucleotide repeat sequences has been identified as the genetic cause of several human diseases, including myotonic dystrophy type 1, Huntington disease, and an ever-increasing number of spinocerebellar ataxias. Once above a size threshold, the repeats become dramatically unstable in the germline and also throughout the soma, with a marked bias towards further expansion. Such expansions constitute a unique form of dynamic mutation, whose mechanism is poorly understood. While germline instability serves as the molecular basis for genetic anticipation; age-dependent, tissue-specific somatic instability most likely contributes to the tissue specificity, phenotypic variability and progressive nature of these conditions. The study of the mutation mechanism is therefore of major interest, as it may provide valuable clues towards a better understanding of disease pathophysiology. It is generally assumed that the repeat length changes arise through DNA polymerase slippage during DNA replication, however no direct evidence exists to support this hypothesis in mammalian systems. Transgenic mouse models of unstable CAG•CTG repeats have been previously generated, and shown to recreate the dynamic nature of somatic mosaicism observed in humans. Tissues from these mice have now been used in order to establish an in vitro cell culture system, where the repeat dynamics could be investigated under controlled conditions. Monitoring of repeat stability in these cells over long periods of time, and numerous population doublings, has revealed the progressive accumulation of larger alleles, as a result of repeat length changes in vitro, confirmed by single cell cloning. Selection of cells carrying longer repeats was observed during the first few passages of the cultures, and frequent additional selective sweeps were also detected at later stages. The highest levels of instability were observed in cultured kidney cells, whilst the transgene remained relatively stable in eye cells and very stable in lung cells, paralleling previous in vivo observations. More importantly, the levels of repeat instability in cultured cells did not correlate with cell proliferation rates, rejecting a simple association between length change mutations and cell division, and suggesting an important role for additional cell type-specific and possibly environmental trans-acting modifiers of repeat metabolism. The effects of multiple genotoxic agents on the mutational dynamics of expanded trinucleotide repeats were assessed in this tissue culture model of unstable DNA. The drugs tested were selected based on their ability to affect cell cycle progression, DNA polymerase activity, DNA methylation, intracellular levels of oxidative stress or DNA conformational metabolism. The analysis led to the identification of chemicals, such as aspirin, 5-azacytidine and 1-beta-D-arabinofuranosyl-cytosine that resulted in the deceleration of the rate of trinucleotide repeat expansion, particularly in a kidney clonal cell line carrying rapidly expanding repetitive tracts. These observations were reported in the absence of major changes in the rates of cell turnover. In contrast, forced cell cycle progression by exposure to caffeine resulted in a significantly higher rate of triplet repeat expansion. Increased levels of oxidative stress, generated in culture by exposure to a variety of drugs, were associated with reduced levels of repeat size variability, most likely through means of cell selection in culture. Since pathology in CAG'CTG-associated diseases is mediated by a variety of complex and unrelated molecular pathways, drug induced modification of DNA dynamics could present a possible therapeutical route for these disorders. Specifically, chemical treatments that resulted in suppression of somatic repeat expansion would be expected to be beneficial, whilst reversion of the expanded mutant repeat to the normal repeat size range, observed in the general population, would be predicted to be curative. Although preliminary, the findings described in this study may open new avenues in the search for novel therapeutical strategies. Mechanistic models of repeat length mutation based on DNA replication, recombination and repair have been proposed. The latter have implied the involvement of mammalian MutS homologues (Msh2, Msh3 and Msh6). In order to gain further insight into the molecular mechanisms driving trinucleotide repeat mutation, the involvement of a mammalian MutL homologue (Pms2) in the mutation dynamics was investigated. No significant differences were observed between Pms2+/+ and Pms2+/+ mice, suggesting that a single functional Pms2 allele is sufficient to maintain high levels of somatic mosaicism. The levels of Pms2 mRNA and protein in heterozygotes deficient for Pms2 have not yet been investigated. In contrast to what would be predicted by the replication slippage model, lower levels of trinucleotide somatic mosaicism were detected in homozygous Pms2-null mice, compared with age-matched controls, carrying either one or two functional copies of the Pms2 allele. In addition, a higher frequency of rare but large deletion events was detected in Pms2-/- animals. Both results proved statistically significant by single molecule analysis. These findings imply that, not only MMR enzymes that directly bind to DNA, but also proteins that are subsequently recruited by MutS proteins, play a central role in the accumulation of repeat length changes, arguing against a mutation mechanism mediated by stabilisation of alternative DNA secondary structures by MMR proteins. MMR gene polymorphisms and variants might therefore be considered potential determinants of trinucleotide repeat instability in humans, predicted to affect both age of onset and disease progression.
Supervisor: Not available Sponsor: Not available
Qualification Name: Thesis (Ph.D.) Qualification Level: Doctoral
EThOS ID: uk.bl.ethos.247761  DOI: Not available
Keywords: Huntingdon disease
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