Trending With Impact: Epigenetic Shifts, Aging, and Disease

Researchers from Harvard University and the Broad Institute wrote a theory article, published by Aging in 2021, and entitled, “Shifting epigenetic contexts influence regulatory variation and disease risk.”

Figure 1. Cross-tissue accessibility.
Figure 1. Cross-tissue accessibility.

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From birth to advanced age, chemical changes occur which affect the genetic material in human cells comprising chromosomes—known as chromatin. These nongenetic changes, otherwise referred to as epigenetic aging, accumulate with age and impact transcriptional programs. From growth and development to adulthood, these changes can denote shifting epigenetic contexts. 

“Shifting epigenetic contexts influence regulatory variation and disease risk”

There is a considerable amount of evidence that suggests a causal relationship between changes in epigenetic state and cell aging. Curiously, researchers have repeatedly observed similar epigenetic changes occurring across different cell and tissue types, throughout different stages of life. These potentially synchronized changes may implicate mechanisms of the aging process.

“Together, these findings suggest that a central trajectory for epigenetic state that reflects innate aging processes may exist [20], upon which extrinsic and cell-type effects are layered.”

In 2021, researchers from Harvard University and the Broad Institute wrote a theory article that was published in Aging’s Volume 13, Issue 12, and entitled, “Shifting epigenetic contexts influence regulatory variation and disease risk.” The authors described common epigenetic trends throughout human growth, development, and aging. They also aimed to show how changing epigenetic contexts may influence the behavior of evolutionary forces and risk of genetic disease. 

FETAL TO ADULT EPIGENETIC SHIFTS

The researchers point out that in order to better understand the contribution of epigenetic changes to disease and aging, it is important to understand the developmental changes that occur between fetal and adult tissues, and their interaction with epigenetic aging.

“Furthermore, these fetal to adult epigenetic shifts can be compounded by additional modifications through aging-associated epigenetic changes.”

Characterizing these epigenetic trends and examining their potential interaction with later-in-life epigenetic aging were main goals of this study. In order to do this, the researchers defined genomic regions where, over the course of development and aging, chromatin accessibility consistently shifts. Chromatin can be broadly classified in either of two epigenetic states: activating or repressing modifications. These states refer to chromatin accessibility and the increased or decreased ability of DNA to access gene-regulatory machinery, such as transcription factors. The authors note that they used an accessibility-based definition of epigenetic context, and that there are other marks of epigenetic changes (e.g. methylation, and etc.) that are not captured by this definition.

“Epigenetic marks established during development can persist into adulthood [9], but they do so in the context of shifts in epigenetic states (see below) as tissues transition into their adult forms and functions.”

CONCLUSION

The researchers utilized genome-wide association study (GWAS) datasets to find that gene variants in adult tissues gaining nearby accessibility have stronger associations across a number of aging-related diseases, including neoplasms, arthritis, and atherosclerosis.

“In other words, it is the change in epigenetic context that modifies the regulatory potential of these variants, and this has direct impacts on individual associations with multiple diseases.”

Among their many findings, the researchers explain that the regulatory sequences which are most active during development are subject to strong negative selection later in life. 

“We utilize our findings to propose a model for how evolutionary forces may have acted at these loci in humans, and how these forces in turn influence the distribution of mutations conferring heritable disease risk across a number of age-associated pathologies.”

Click here to read the full theory article, published by Aging.

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Aging is an open-access journal that publishes research papers monthly in all fields of aging research and other topics. These papers are available to read at no cost to readers on Aging-us.com. Open-access journals offer information that has the potential to benefit our societies from the inside out and may be shared with friends, neighbors, colleagues, and other researchers, far and wide.

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