The Impact of DNA damage and nutrition on transcription, ageing and neurodegeneration in mice and patients


Those who are interested in meeting Prof. Hoeijmakers virtually after the talk may get in touch with Amy Chu at amy.chu@hertford.ox.ac.uk.

Aging appears remarkably plastic: e.g. suppressing insulin signalling extends lifespan in numerous species. However, virtually all premature aging syndromes link with genome instability. We have generated mouse models which strikingly mimic human DNA repair deficiency syndromes and display wide-spread accelerated aging. For instance, Ercc1∆/- mice defective in four repair pathways show multi-morbidity in both proliferative and post-mitotic tissues, limiting lifespan to 4-6 month. Simultaneously, they exhibit an anti-aging ‘survival response’, which suppresses growth and enhances maintenance, resembling the longevity response induced by dietary restriction (DR) and providing a link with insulin signalling. Interestingly, subjecting these progeroid mutants to actual (30%) DR tripled lifespan, and drastically retarded accelerated aging, e.g. DR animals retained 50% more neurons and maintained full motoric function. The DR response in these mice resembled DR in wild type animals including reduced insulin signaling and reduced DNA damage load, explaining why DNA repair mutants overrespond to DR. Interestingly, Ercc1∆/- liver expression profiles showed gradual decline of expression preferentially of long genes, consistent with genome-wide accumulation of stochastic, transcription-blocking lesions, which affect long genes more than short ones. This phenomenon was also discovered in normal aging of post-mitotic tissues. DR largely prevented transcription stress, indicating that DR prolongs genome function. We will present phenotypes of conditional DNA repair models targeting aging to selected organs, striking parallels with Alzheimer’s disease and the first remarkable results translating these concepts from mice to progeroid children. Our findings identify DNA damage as main cause of aging, establish repair-deficient mice as powerful models for interventions to promote healthy aging, reveal untapped potential for reducing endogenous damage and transcription stress in neurodegeneration, explain the molecular anti-aging mechanism of DR and the aging component of proteinopathies based on transcription stress and promote a counterintuitive DR-like therapy for human progeroid genome instability syndromes and DR-like interventions for preventing neurodegenerative diseases and ischemia reperfusion damage.