Nadiya Kazachkova scite author profile

Background: Machado-Joseph disease (MJD) is an autosomal dominant spinocerebellar ataxia caused by a CAG tract expansions in the ATXN3 gene. Patterns of mitochondrial damage associated with pathological findings of brain tissues could provide molecular biomarkers of this disorder. Objective: The potential of mitochondrial DNA (mtDNA) damage as a biomarker of MJD progression was investigated using a transgenic mouse model. Methods: DNA was obtained from affected (pontine nuclei) and nonaffected tissues (hippocampus and blood) of transgenic animals of three distinct age groups: 8 weeks, before onset of the phenotype; 16 weeks, at onset, and 24 weeks, at well-established phenotype. Wild-type littermate mice, serving as controls, were analyzed for the same tissues and age groups. mtDNA damage was studied by fluorescence-based quantitative PCR in 84 transgenic and 93 wild-type samples. Results: A clear pattern of decrease in mtDNA copy number with age and accumulation of 3,867-bp deletions at the initial stages (both being more pronounced in transgenic mice) was observed. Pontine nuclei, the affected tissue in transgenic mice, displayed 1.5 times less copies of mtDNA than nonaffected brain tissue hippocampus (odds ratio = 1.21). Pontine nuclei displayed the highest percentage of mtDNA deletions (6.05% more in transgenic mice). Conclusion: These results suggest that mtDNA damage is related to the initiation of the phenotype in transgenic mice; mtDNA 3,867-bp deletions may be a biomarker of the initial stages of the disease.

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Mitochondrial DNA Damage Patterns and Aging: Revising the Evidences for Humans and Mice

Kazachkova

Ramos

Santos³

et al. 2013

A&D

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A significant body of work, accumulated over the years, strongly suggests that damage in mitochondrial DNA (mtDNA) contributes to aging in humans. Contradictory results, however, are reported in the literature, with some studies failing to provide support to this hypothesis. With the purpose of further understanding the aging process, several models, among which mouse models, have been frequently used. Although important affinities are recognized between humans and mice, differences on what concerns physiological properties, disease pathogenesis as well as life-history exist between the two; the extent to which such differences limit the translation, from mice to humans, of insights on the association between mtDNA damage and aging remains to be established. In this paper we revise the studies that analyze the association between patterns of mtDNA damage and aging, investigating putative alterations in mtDNA copy number as well as accumulation of deletions and of point mutations. Reports from the literature do not allow the establishment of a clear association between mtDNA copy number and age, either in humans or in mice. Further analysis, using a wide spectrum of tissues and a high number of individuals would be necessary to elucidate this pattern. Likewise humans, mice demonstrated a clear pattern of age-dependent and tissue-specific accumulation of mtDNA deletions. Deletions increase with age, and the highest amount of deletions has been observed in brain tissues both in humans and mice. On the other hand, mtDNA point mutations accumulation has been clearly associated with age in humans, but not in mice. Although further studies, using the same methodologies and targeting a larger number of samples would be mandatory to draw definitive conclusions, the revision of the available data raises concerns on the ability of mouse models to mimic the mtDNA damage patterns of humans, a fact with implications not only for the study of the aging process, but also for investigations of other processes in which mtDNA dysfunction is a hallmark, such as neurodegeneration.

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Novel candidate blood‐based transcriptional biomarkers of machado‐joseph disease

Raposo

Bettencourt²,

Maciel

et al. 2015

Movement Disorders

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The <emph type="ital">APOE</emph> ε2 Allele Increases the Risk of Earlier Age at Onset in Machado-Joseph Disease

Bettencourt

Raposo²,

Kazachkova³

et al. 2011

Arch Neurol

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Background. Machado-Joseph disease (MJD) is an autosomal dominant neurodegenerative disorder of late onset, caused by a (CAG) n expansion at the ATXN3 gene (14q32.1). Variation in age-at-onset is partially explained by the size of the (CAG) n tract in expanded alleles. The remaining variation should be the product of other factors, namely modifier genes. The genotype at the APOE locus has been described as a possible modifier in different neurological disorders, namely Parkinson (PD) and Huntington disease (HD). In the CNS, apolipoprotein E constitutes an important mediator of cholesterol transport/metabolism, which is essential for synaptic integrity and neuronal function.Objective. To investigate a modulating effect of the APOE polymorphism on ageat-onset of MJD. Design and Subjects.The APOE polymorphism was typed in a series of 192 MJD patients. Results.Cases with the ε2/ε3 genotype presented an earlier onset, when compared with those with ε3/ε3 or ε3/ε4. In this series of patients, the presence of an APOE ε2 allele implies a decrease of nearly 5 years in the age-at-onset. When combining, in a general linear model, several other predictors, namely the presence/absence of the APOE ε2 allele, with the size of the (CAG) n in expanded alleles, the model was significantly improved and the explanation of onset variance was raised from 59.8% to 66.5%. Furthermore, the presence of the ε2 allele was associated with an onset below 39 years (OR=5.00; 95% CI: 1.18-21.14). Conclusions.These findings indicate that the polymorphism at the APOE gene plays a role as a genetic modifier of MJD phenotype.

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