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Category: life extension

Gets advanced, but some might like.

A research team from Cologne has discovered that a change in the DNA structure—more precisely in the chromatin—plays a decisive role in the recovery phase after DNA damage. The key is a double occupation by two methyl groups on the DNA packaging protein histone H3 (H3K4me2). The discovery was made by scientists under the direction of Prof. Björn Schumacher of the Cluster of Excellence for Aging Research CECAD, the Center for Molecular Medicine Cologne (CMMC), and the Institute for Genome Stability in Aging and Disease at the University of Cologne. The specific change enables genes to be reactivated and proteins to be produced after damage: The cells regain their balance and the organism recovers. The protective role of H3K4me2 was identified in experiments with the nematode Caenorhabditis elegans. The study has now been published in the journal Nature Structural & Molecular Biology.

The genome in every human cell is damaged on a daily basis, for example in the skin by UV radiation from the sun. Damage to the DNA causes diseases such as cancer, influences development, and accelerates aging. Congenital malfunctions in DNA repair can lead to extremely accelerated aging in rare hereditary diseases. Therefore, preservation and reconstruction processes are particularly important to ensure development and to maintain tissue function. DNA, which is rolled up on packaging proteins—the histones—like on cable drums, is regulated by methyl groups. Various proteins are responsible for placing methyl groups on histones or removing them. The number of groups on the packaging proteins affects the activity of genes and thus the production of the cell.

In experiments with the nematode, the research team showed that after repairing damaged DNA, two methyl groups were increasingly found on the DNA packages. Furthermore, they found that errors in placing these two methyl groups on the histones (H3K4me2) accelerated the damage-induced aging process, while increased position of this histone alteration prolongs the lifespan after DNA damage. By controlling the proteins that either set or remove these methyl groups, the resistance to DNA damage—and thus the aging process of the animals—could be influenced.

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Curious about science’s latest effort to reverse aging? This podcast describes attainable treatments and the science behind theses gene therapy processes: Elizabeth Parrish discusses BioViva’s anti-aging gene therapy products and research. Even better, she brings a different perspective—she has had viral vector gene therapy herself.

Listen and learn.

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I will be 49 tomorrow. I always like to find some sort of life extension vid for my birthday. And boy did I hit it. Here comes Bill Faloon to drown you in info. Fruit flies 48% increase at 4:30, George Church at 9:00, C. Elegans 5X increase 15:30, 114 year old blood cells reprogrammed ti pluripotent at 18:40, epigenetics at 22:30, Senile plasma at 24:30, Dr Mike West 4 paragraphs to summarize at 21:00, 44:00 minutes is Vitality in Aging Interventions Trail which anyone can join. Enjoy.

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Alexey Turchin and Maxim Chernyakov, researchers belonging to the transhumanism movement, wrote a paper outlining the main ways technology might someday make resurrection possible.

From cryonics to time travel, here are some of the (highly speculative) methods that might someday be used to bring people back to life.

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Perhaps in the future, gene editing may allow retinal regeneration in humans to reverse age-related vision deterioration.

Damage to the retina is the leading cause of blindness in humans, affecting millions of people around the world. Unfortunately, the retina is one of the few tissues we humans can’t grow back.

Unlike us, other animals such as zebrafish are able to regenerate this tissue that’s so crucial to our power of sight. We share 70 percent of our genes with these tiny little zebrafish, and scientists have just discovered some of the shared genes include the ones that grant zebrafish the ability to grow back their retinas.

“Regeneration seems to be the default status, and the loss of that ability happened at multiple points on the evolutionary tree,” said Johns Hopkins University neuroscientist Seth Blackshaw.

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Although it’s clearly NOT the approach taken for ultracold vitrification of patients undergoing life extension cryonization. (ULTRA🥶COLD being the exact opposite of ULTRA-BLOODY-H🥵T, obviously!)

Still, given the vast number of scientific and engineering discoveries and creations born on the backs of unexpected results, accidental discoveries, and outright screw up, it might have very useful data that has practical applications that would never otherwise have even been considered.

Italian scientists found intact brain cells in a man who was killed during the eruption of Mount Vesuvius in 79 AD.

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Watch Liz Parrish’s talk given on Sunday October 4, 2020, during the celebration of the annual event “Revolution Against Aging and Death Festival” (RAADfest 2020).

During her presentation Liz describes for the first time what BioViva Sciences and its exclusive partner Integrated Health Systems (IHS), are doing on the fronts of 1) Patient Access: 2) Research & Development and 3) Data Science.

Due to the pandemic situation caused by SARS-CoV-2 this year the Event was celebrated using online media technologies.

To watch all the presentations given during RAADfest 2020 visit the following website and follow the instructions:

https://www.raadfest.com/

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A newly identified genetic factor allows adult skin to repair itself like the skin of a newborn babe. The discovery by Washington State University researchers has implications for better skin wound treatment as well as preventing some of the aging process in skin.

In a study, published in the journal eLife on September 29, 2020, the researchers identified a factor that acts like a molecular switch in the skin of baby mice that controls the formation of hair follicles as they develop during the first week of life. The switch is mostly turned off after skin forms and remains off in adult tissue. When it was activated in specialized cells in adult mice, their skin was able to heal wounds without scarring. The reformed skin even included fur and could make goosebumps, an ability that is lost in adult human scars.

“We were able to take the innate ability of young, neonatal skin to regenerate and transfer that ability to old skin,” said Ryan Driskell, an assistant professor in WSU’s School of Molecular Biosciences. “We have shown in principle that this kind of regeneration is possible.”

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For many, getting older can unfortunately mean an increased risk of illness from cardiovascular disease to cancer. University of Michigan scientists are actively researching the biological underpinnings of aging with the aim of developing interventions that could potentially help people live longer, healthier lives.

A new paper in the journal Science Advances describes the discovery of several promising small molecules that appear to reduce in mouse skin and could lengthen life.

“Cellular resistance appears to be a common feature of long-lived organisms, such as invertebrates and mice,” says the paper’s lead author David Lombard, M.D., Ph.D., associate professor of pathology. Lombard is part of a multidisciplinary group at U-M’s Paul F. Glenn Center for Aging. Recent research from colleague and fellow study author Richard Miller, M.D., Ph.D., found several promising drugs, including rapamycin, a cancer drug, and acarbose, a diabetes drug, that extended life in mice.

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