How to Slow Aging (and even reverse it)

Veritasium

14 Dec 201921:10

Summary

TLDRThis video explores groundbreaking research on aging and longevity, focusing on how we might slow or even reverse the aging process. From scientific insights into the epigenome and longevity genes to practical steps like caloric restriction, exercise, and fasting, the video outlines both the current state of aging research and its potential future. It also delves into fascinating discoveries such as the regenerative capabilities of moon jellyfish and Professor David Sinclair's work on resetting the epigenome. The content offers actionable advice and a hopeful outlook on the science of aging.

Takeaways

😀 Aging research aims to extend the 'health span' (the period of life spent in good health) rather than just the lifespan, addressing age-related diseases like Alzheimer's, diabetes, and cancer.
😀 Some species, like moon jellyfish, appear to have 'immortal' qualities due to their ability to regenerate and reset their life cycle, potentially offering clues for extending human lifespan.
😀 Professor David Sinclair proposes that aging may be caused by a loss of epigenetic information, not by damage to DNA itself, with implications for how we approach aging research.
😀 The epigenome, which controls how DNA is packaged and read in cells, is critical to maintaining cellular function and identity. Aging may occur when the epigenome becomes 'disordered'.
😀 The concept of 'senescent cells', which are damaged or dysfunctional cells that accumulate with age, contributes to aging and inflammation in the body.
😀 Unlike DNA, which stores genetic information, the epigenome regulates how this information is expressed. Its deterioration may be a key driver of aging.
😀 Aging can be accelerated by factors such as DNA damage, which occurs from environmental stressors like sun exposure, and the failure of the body to repair this damage properly.
😀 The 'Horvath clock' is a biological aging clock based on DNA methylation patterns, which can predict biological age and even when someone is likely to die.
😀 Scientific experiments on mice show that activating certain genes related to longevity (e.g., sirtuins) and reducing caloric intake can extend lifespan and health span.
😀 Professor Sinclair's lab successfully reversed aging in mice by reprogramming their retinal cells, demonstrating that gene therapy could potentially reverse aging in specific tissues or even whole organisms in the future.

Q & A

What is the main goal of research into extending human lifespan?
-The main goal is to extend the healthy lifespan, or 'health span,' rather than simply increasing the number of years people live. The focus is on slowing aging and preventing age-related diseases like Alzheimer's, diabetes, and cancer.
Why is the concept of health span important in aging research?
-Health span refers to the period of life in which a person remains healthy and free from debilitating diseases. Extending health span is crucial because it focuses on improving quality of life in old age, not just adding years that might be plagued by disease and disability.
What are the concerns people have about extending lifespan?
-Common concerns include the potential for increased inequality, where only the wealthy might benefit, and the environmental impact of a larger population, which could strain resources like food, water, and energy.
How do moon jellyfish contribute to aging research?
-Moon jellyfish are believed to be biologically immortal, as they can revert to an earlier stage of their life cycle and regenerate tissues. Studying their ability to reset their cells might provide insights into reversing aging in humans.
What is the epigenome, and how is it related to aging?
-The epigenome consists of chemical markers and proteins that regulate the expression of genes without altering the DNA itself. As we age, the epigenome deteriorates, leading to cellular dysfunction, which may be a key factor in the aging process.
How does DNA damage contribute to aging?
-DNA damage, such as that caused by UV radiation from the sun, can accumulate over time. The body's repair mechanisms restore most DNA damage, but some errors remain, contributing to aging. This process involves the breakdown of the epigenome and loss of cellular identity.
What are longevity genes, and how do they work?
-Longevity genes are activated in response to stressors such as exercise, hunger, or temperature extremes. These genes help maintain cellular functions, repair DNA, and protect cells from aging. They include proteins like sirtuins, AMP-kinase (AMPK), and mTOR, which regulate energy balance and cell maintenance.
What lifestyle changes can help slow aging?
-To slow aging, it is recommended to: (1) reduce caloric intake, (2) limit protein consumption, (3) engage in high-intensity interval training (HIIT), (4) expose yourself to mild cold or heat, and (5) avoid DNA damage through sun protection and avoiding harmful radiation.
What role does caloric restriction play in aging?
-Caloric restriction has been shown to slow aging in animals by activating longevity genes and enhancing the body's repair mechanisms. It reduces the intake of energy, which triggers the body to focus on maintenance and protection rather than growth and reproduction.
What is the significance of Professor Sinclair's research on reversing aging?
-Professor Sinclair’s research aims to reverse aging by resetting the epigenome, a process demonstrated in mice. By reprogramming cells, Sinclair’s team successfully restored youthful function to eye cells, suggesting that it may be possible to reverse aging in other tissues in the future.