Significance: Chronic kidney disease (CKD) can be regarded as a burden of lifestyle disease that shares common underpinning features and risk factors with the ageing process; a complex constituted by several adverse components, including chronic inflammation, oxidative stress, early vascular ageing and cellular senescence.Recent Advances: A systemic approach to tackle CKD, based on mitigating the associated inflammatory, cell stress and damage processes, has the potential to attenuate the effects of CKD, but also pre-empts the development and progression of associated morbidities. In effect, this will enhance health span and compress the period of morbidity. Pharmacological, nutritional and potentially lifestyle-based interventions are promising therapeutic avenues to achieve such a goal. Critical Issues: In the present review, currents concepts of inflammation and oxidative damage as key pathomechanisms in CKD are addressed. In particular, potential beneficial but also adverse effects of different systemic interventions in patients with CKD are discussed.Future Directions: Senotherapeutics, the NRF2-KEAP1 signaling pathway, the endocrine klotho axis, inhibitors of the sodium-glucose cotransporter 2 (SGLT2), and live biotherapeutics have the potential to reduce the burden of CKD and improve quality of life, as well as morbidity and mortality, in this fragile high-risk patient group.
A more comprehensive understanding of the human ageing process is required to help mitigate the increasing burden of age-related morbidities in a rapidly growing global demographic of elderly individuals. One exciting novel strategy that has emerged to intervene involves the use of extracellular vesicles to engender tissue regeneration. Specifically, this employs their molecular payloads to confer changes in the epigenetic landscape of ageing cells and ameliorate the loss of functional capacity. Understanding the biology of extracellular vesicles and the specific roles they play during normative ageing will allow for the development of novel cell-free therapeutic interventions. Hence, the purpose of this review is to summarise the current understanding of the mechanisms that drive ageing, critically explore how extracellular vesicles affect ageing processes and discuss their therapeutic potential to mitigate the effects of age-associated morbidities and improve the human health span.
Telomere biology, a key component of the hallmarks of ageing, offers insight into dysregulation of normative ageing processes that accompany age-related diseases such as cancer. Telomere homeostasis is tightly linked to cellular metabolism, and in particular with mitochondrial physiology, which is also diminished during cellular senescence and normative physiological ageing. Inherent in the biochemistry of these processes is the role of magnesium, one of the main cellular ions and an essential cofactor in all reactions that use ATP. Magnesium plays an important role in many of the processes involved in regulating telomere structure, integrity and function. This review explores the mechanisms that maintain telomere structure and function, their influence on circadian rhythms and their impact on health and age-related disease. The pervasive role of magnesium in telomere homeostasis is also highlighted.
Background and Aims Chronic kidney disease (CKD) shares important features of a dysregulated ageing process with other common “burden of lifestyle” diseases, which aggregates into the diseasome of ageing. Typically, this is hallmarked by an acceleration of epigenetic (DNA methylation-based) clocks. It remains to be determined if current therapeutic interventions, such as renal transplantation or dialysis, can slow this clock, and thus the rate of biological ageing, in CKD. We therefore assessed the rate of biological ageing in CKD patients and whether these therapies impact on it, by measuring epigenetic age before and 1 year after treatment. Methods Whole blood samples were taken from CKD 5 patients at baseline and 1 year after renal transplantation (n=12) or dialysis (n=11; peritoneal dialysis n=7, haemodialysis n=4) as well as from age and sex-matched population-based controls (n=24). DNA methylation was measured using the Illumina Infinium Human Methylation 450K BeadChip and epigenetic age was calculated using three independent DNA methylation clocks: the Horvath, Hannum, and PhenoAge clocks. Additionally, a novel composite clock incorporating these three clocks was evaluated. We then calculated the age acceleration (difference between epigenetic and chronological age) for each clock and compared average age acceleration between groups and across time points. Results Incident dialysis patients displayed accelerated ageing versus chronologically age-matched controls (p<0.001). We observed a PhenoAge age acceleration difference in both the transplant (8.5 years, p=0.001) and dialysis (9.7 years, p<0.001) groups at baseline compared to control. After 1 year, we also observed a decrease of the age acceleration in the transplant group (mean reduced by 4.4 years, p=0.016), but not in the dialysis group (mean reduced by 0.7 years, p=0.668). Conclusion CKD 5 patients display an increased biological (i.e. epigenetic) age. This age acceleration is mitigated one year after renal transplantation, but not in patients undergoing dialysis. Neither therapy reverses high biological age.
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