Organ specificity and commonality of epigenetic aging in low- and high-running capacity rats

  1. Takuji Kawamura
  2. Csaba Kerepesi
  3. Ferenc Torma
  4. Zoltan Bori
  5. Lei Zhou
  6. Peter Bakonyi
  7. Attila Kolonics
  8. Laszlo Balogh
  9. Mitsuru Higuchi
  10. Lauren Gerard Koch
  11. Steven Loyal Britton
  12. Erika Koltai
  13. Zsolt Radak
0 evaluations Published on
Read the full article Related papers
This article on Sciety

Abstract

Background

Epigenetic drift, which are gradual age-related changes in DNA methylation patterns, plays a significant role in aging and age-related diseases. However, the relationship between exercise, epigenetics, and aging and the molecular mechanisms underlying their interactions are poorly understood. The aim of this study was to investigate the relationship between cardiorespiratory fitness (CRF), epigenetic aging, and promoter methylation of individual genes across multiple organs in selectively bred low- and high-capacity runner (LCR and HCR) aged rats.

Methods

In this study, we performed reduced representation bisulfite sequencing (RRBS) on LCR and HCR aged rats, focusing on the hippocampus, heart, soleus muscle, and large intestine samples. We calculated various epigenetic indicators, including rat epigenetic clocks, global mean DNA methylation (GMM), mean methylation entropy (MME), and gene-specific promoter methylation.

Results

Epigenetic clocks, trained on available rat blood-derived RRBS data did not reflect differences in CRF between LCR and HCR rats across all four organs. However, we observed organ specific differences in GMM and MME between LCR and HCR rats. The direction of these differences was the opposite compared to the age-related changes in the rat blood suggesting that a high CRF may mitigate age-related epigenetic changes in an organ-specific manner. Notably the soleus muscle, exhibited the most pronounced differences in promoter methylation due to CRF. We also identified seven genes whose promoter methylation was consistently influenced by CRF in all four organs. Moreover, we found that age acceleration of the soleus muscle was significantly higher compared to the heart and the hippocampus, and significantly lower compared to the large intestine. Finally, we found that the age acceleration was not consistent across organs.

Conclusions

Our data suggest that CRF associates with epigenetic aging in an organ-specific manner and regulates the promoter methylation of individual genes in an organ-specific and organ-common manner. Our findings provide important insights into the biology of aging and emphasize the need to validate rejuvenation strategies in the context of the organ-specific nature of epigenetic aging.

Related articles

Related articles are currently not available for this article.