Population variation in oxidative stress and astrocyte DNA damage in relation to Alzheimer-type pathology in the ageing brain.

AIMS: Increasing evidence suggests a role for oxidative damage to DNA in brain ageing and in neurodegenerative disorders, including Alzheimer's disease. Most studies have focussed on the reduced capacity for DNA repair by neurones, and have not taken into account the effect of oxidative stress on astrocytes, and their contribution to pathology. METHODS: We examined levels of oxidative stress, DNA damage and DNA repair mechanisms in astrocytes in a population-based sample derived from the Medical Research Council Cognitive Function and Ageing Neuropathology Study. RESULTS: We demonstrate wide variation in parameters for oxidative stress and DNA damage in astrocytes in the ageing population. We show that there is a significant reduction (P = 0.002) in the lipid peroxidation marker malondialdehyde with increasing Braak stage in Alzheimer's disease. Furthermore, we demonstrate that expression of the DNA damage-associated molecules H2AX and DNA-dependent protein kinase do not increase with increasing Braak stage, rather there is evidence of a nonsignificant reduction in DNA-dependent protein kinase expression by neurones and astrocytes, and in H2AX by neurones with increasing levels of Alzheimer's type pathology. CONCLUSIONS: These findings suggest that the changes in oxidative stress and the astrocyte DNA damage response are not accounted for as an accumulating effect due to established Alzheimer-type pathology. We hypothesize that astrocyte damage, leading to impaired function, may contribute to the development of ageing brain pathology in some individuals.

A brief history of tau: the evolving view of the microtubule-associated protein tau in neurodegenerative diseases.

The major historical milestones in tau-research are reviewed, with their implications for changing perspectives about the significance of tau-pathology in neurodegeneration. Abnormalities of tau-protein characterize the pathology of numerous neurodegenerative disorders, both sporadic and inherited. Over the years, opinions regarding the significance of tau in disease pathogenesis, particularly in Alzheimer's disease, have fluctuated. Early caution about the role of tau as a significant factor in neurodegenerative disease, especially Alzheimer's disease, has been superseded by acceptance of its key involvement in pathways which led to cell dysfunction and death. The discovery of familial "tauopathies", associated with tau-gene mutations, has confirmed that tau-dysmetabolism can independently lead to neurodegeneration. Debate about the centrality of its role remains, but current evidence makes it difficult to ignore the importance of tau in many neurodegenerative diseases. By examining the evolution of research on tau, related to advances in technology and the emergence of new diseases, the future developments needed to resolve remaining issues in the tau-story may be discerned.