Lifeboat Foundation

When an undiagnosed rare genetic disease caused his young son’s kidneys to fail, Professor Chris Toumazou vowed to find a way of uncovering hidden health risks.

The professor of biomedical engineering realised that, although his son’s condition could not have been prevented, the family could have managed his lifestyle very differently had they known about his condition.

Continue reading “This wristband tells you what food to buy based on your DNA” »

Summary: Transplanting gut microbiota from older mice to younger germ-free mice increased hippocampal neurogenesis and intestinal growth. Source: Nanyang Technological UniversityAn internationa.

Researchers from the Max Planck Institute for Evolutionary Anthropology in Leipzig, Germany, Institute of Molecular and Clinical Ophthalmology Basel, and ETH Zurich, Switzerland, have presented new insights into the development of the human brain and differences in this process compared to other great apes. The study reveals features of brain development that are unique to humans, and outlines how these processes have diverged from those in other primates.

Since humans diverged from a common ancestor shared with chimpanzees and the other great apes, the human brain has changed dramatically. However, the genetic and developmental processes responsible for this divergence are not understood. Cerebral organoids (brain-like tissues), grown from stem cells in a dish, offer the possibility to study the evolution of early brain development in the laboratory.

Sabina Kanton, Michael James Boyle and Zhisong He, co-first authors of the study, together with Gray Camp, Barbara Treutlein and colleagues analyzed human cerebral organoids through their development from stem cells to explore the dynamics of gene expression and regulation using methods called single-cell RNA-seq and ATAC-seq. The authors also examined chimpanzee and macaque cerebral organoids to understand how organoid development differs in humans.

Scientists who are trying to save species at the brink of extinction are finding help in an unexpected place.

Heather Farrington, curator of zoology for the Cincinnati Museum Center, is using DNA from specimens collected more than 100 years ago to help understand the evolution and stresses faced by today’s animals.

Farrington runs the museum’s new state-of-the-art genetics laboratory, which helps researchers study populations of animals over time.

Doctors have reported on the first attempts in the United States to use gene editing to help patients fight cancer.

The doctors say one form of gene editing appeared to be safe when tested in three patients. But it is not yet known what long-term effects the method will have on cancer treatment or patient survival rates.

A gene editing tool called CRISPR/Cas9 was used in the tests, which were recently reported in a medical study. The method was discovered in recent years as a way to change the genetic material that make up a person’s DNA.

Scientists at the University of Birmingham have unravelled the genetic mechanisms behind tiny waterfleas’ ability to adapt to increased levels of phosphorus pollution in lakes.

By mapping networks of genes to the physiological responses of ancient and modern waterfleas (Daphnia), the researchers, based in the University’s School of Biosciences, were able to show that a cluster of over 800 genes, many of them involved in metabolic processes, evolved to become “plastic”, or flexible.

This allows the modern Daphnia to adjust its gene expression according to the amount of phosphorus present in the environment. This is particularly fascinating as their 700-year-old ancestors were incapable of such a plastic response.

TABLE OF CONTENTS —————
0:00–17:57 : Introduction (Meaning of Life)
17:58–37:45 CHAPTER 1: Longevism and Life Extension
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WHY DOES AGING HAPPEN?
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37:46–54:39 CHAPTER 2 : Gerontonology and Aging a. Free Radical Theory of Aging b. Waste Accumulation Theory of Aging c. Stem Cell Theory of Aging d. DNA Damage Theory of Aging.
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HOW DO WE CURE AGING?
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54:39–1:08:39 : CHAPTER 3 :The Biochemical Solution (#1)
a. mitoSENS
b. oncoSENS
c. lysoSENS
d. amyloSENS
e. apoptoSENS
f. repliSENS
g. glycoSENS
1:08:40–2:13:12 CHAPTER 4 : The Physiological Solution (#2)
a. Parabiosis and Biovampirism b. Regeneration and Stem Cells c. Lab Grown Organs and Bioprinting d. Head Transplants and Doppleganger Bodies.
2:13:12–2:33:19 CHAPTER 5 : The Genetic Solution (#3)
a. TALEN genetic engineering b. Zinc-Finger gene tailoring c. CRISPR-Cas9 gene editing.
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WILL WE CURE AGING GENETICALLY?
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2:33:20–2:49:58 : CHAPTER 6 : Genomics and DNA
2:49:59–3:05:48 : CHAPTER 7 : Transcriptomics and RNA
3:05:49–3:22:08 : CHAPTER 8 : Proteomics and TNA
3:22:09–3:39:38 : CHAPTER 9 : Xenobiology and XNA
a. alien proteins b. alien base pairs c. alien DNA
3:39:39–3:54:58 : CHAPTER 10 : Vectors and Gene Therapy (Gene Editing #1)
3:54:59–4:14:57 : CHAPTER 11 : Synthetic Biology (Gene Editing #2)
4:14:58–4:32:14 : CHAPTER 12 : Chimeras, Rianths, and Splices (Gene Editing #3)
4:32:15–4:48:35 : CHAPTER 13 : Ouroborology and Immortal Chimeras (Gene Editing #4)
4:48:36-:5:03:52 : CHAPTER 14 : Kleptoplasty and Photosynthesis (Gene Editing #5)
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HOW TO SURVIVE UNTIL AGING IS CURED
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5:03:53–5:14:27 : CHAPTER 15 : Survive to the Singularity a. the breakeven point b. longevity escape velocity c. the longevity dividend.
5:14:28–5:30:16 : CHAPTER 16 : Centennarians and Blue Zones (Survival Method #0)
a. loma linda b. ikaria c. sardinia d. okinawa.
5:30:17–5:42:26 : CHAPTER 17 : Risk Aversion and Micromorts (Survival Method #1)
a. micromorts
b.microlives
5:42:27–5:58:18 : CHAPTER 18 : Nutraceuticals and Geroprotectors (Survival Method #2)
a. rapamycin b. metformin c. selegilene d. nicotinamide riboside e. resverratrol.
5:58:19–6:12:51 : CHAPTER 19 : Caloric Restriction (Survival Method #3)
a. endocrine b. epigenetic c. genetic
6:12:52–6:51:57 : CHAPTER 20 : Cryonics & Cryogenics (Survival Method #4)
a. the efficacy question b. the cost question c. the resurrection question d. the identity question e. the legal question f. the catastrophe question g. the culture question.
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CAN WE BE IMMORTAL WITHOUT CURING AGING?
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6:51:58–7:04:08 : CHAPTER 21 : Genetic Immortality — Test Tube Babies
7:04:09–7:24:02 : CHAPTER 22 : Genetic Immortality — Designer Babies
7:24:03–7:41:55 : CHAPTER 23 : Genetic Immortality — Clone Babies
7:41:56–7:53:08 : CHAPTER 24 : Genetic Immortality — Artificial Wombs
7:53:08–7:53:09 CHAPTER 25 : Immortalism and Ethics a. the crime argument b. the natural argument c. the boredom argument d. the inequality argument e. the overpopulation argument f. the gerontocracy argument g. the economic argument h. EPILOGUE

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Continue reading “Can we Live Forever? (Full Documentary)” »

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“Fahy’s fascination with the thymus goes back to 1986, when he read a study in which scientists transplanted growth-hormone-secreting cells into rats, apparently rejuvenating their immune systems,” Nature reported. “He was surprised that no one seemed to have followed up on the result with a clinical trial. A decade later, at age 46, he treated himself for a month with growth hormone and DHEA, and found some regeneration of his own thymus.”

The thymus is located in the chest between the lungs and the breastbone and is crucial for efficient immune function. “White blood cells are produced in bone marrow and then mature inside the thymus, where they become specialized T-cells that help the body to fight infections and cancers,” Nature reported. “But the gland starts to shrink after puberty and increasingly becomes clogged with fat. Evidence from animal and some human studies shows that growth hormone stimulates regeneration of the thymus. But this hormone can also promote diabetes, so the trial included two widely used anti-diabetic drugs, dehydroepiandrosterone (DHEA) and metformin, in the treatment cocktail.”

Continue reading “Cocktail Of Drugs Gives First Hope That ‘Biological Age’ Can Be Reversed” »

Through early adulthood, exposure to new experiences—like learning to drive a car or memorizing information for an exam—triggers change in the human brain, re-wiring neural pathways to imprint memories and modify behavior. Similar to humans, the behavior of Florida carpenter ants is not set in stone—their roles, whether it is protecting the colony or foraging for food, are determined by signals from the physical and social environment early in their life. But questions remain about how long they are vulnerable to epigenetic changes and what pathways govern social behavior in ants.

Now, a team led by researchers in the Perelman School of Medicine at the University of Pennsylvania discovered that a protein called CoRest, a neural repressor that is also found in humans, plays a central role in determining the social behavior of ants. The results, published today in Molecular Cell, also revealed that worker ants called Majors, known as “brawny” soldiers that protect colonies, can be reprogrammed to perform the foraging role—generally reserved for their sisters, the Minor ants—up to five days after they emerge as an adult ant. However, the reprogramming is ineffective at the 10-day mark, revealing how narrow the window of epigenetic plasticity is in ants.

“How behavior becomes established in humans is deeply fascinating—we know it’s quite plastic especially during childhood and early adolescence—however, of course, we cannot study or manipulate this experimentally,” said the study’s senior author Shelley Berger, Ph.D., the Daniel S. Och University Professor in the departments of Cell and Developmental Biology and Biology, and director of the Penn Epigenetics Institute. “Ants, with their complex societies and behavior, and similar plasticity, provide a wonderful laboratory model to understand the underlying mechanisms and pathways.