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How Engineered Stem Cells May Enable Youthful Immortality

February 2013

By Michael D. West, PhD

(Intro by Life Extension)

Stem Cells

What you are about to read is a blueprint by which newly developing technologies may be used to induce biological immortality in human beings.

This research goes far beyond what is normally published in Life Extension magazine.

When perfected, the research findings you are about to learn may enable doctors to inject progenitor cells that will regenerate every tissue in your body, thus restoring you to youthful health and vigor.

Some readers will find this article challenging to comprehend, but I encourage everyone to review it several times to understand how close we may be to achieving meaningful reversal of aging processes.

This article also contains new findings about how easy it is to increase your telomere length, which has been shown to confer longevity and protect against age-related disease.

Targeting the Clockwork of Cell   Immortality: A Progress Report

There appears to be a consensus among gerontologists that a significant extension of the healthy human lifespan will require targeting of the clockwork mechanisms that cause aging. We will therefore attempt to explain what this means and what the implications may be for reversing biological aging.

Modern gerontology research can be divided into two camps. In the first camp, researchers are on a quest to understand and control the central mechanisms of the aging “clockwork”. This molecular machinery should be thought of as upstream central regulators (like telomeres) that subsequently trigger mechanisms further downstream. It is these downstream pathological mechanisms, such as chronic inflammation, that inflict age-related changes in specific tissues. 1-3

The second camp of researchers is focused on targeting molecules involved in these downstream mechanisms, as these factors (such as pro-inflammatory cytokines) are the “hatchet men” that directly trigger disease processes. 4,5

If we were to think of the individual mortal human as a ticking time bomb, the upstream mechanisms would be the clocking mechanism of the bomb, perhaps a ticking alarm clock or a burning fuse, and the downstream mechanisms would be the dynamite that is the most direct cause of the damage that follows. The first camp’s approach would therefore be to prevent the explosion itself by stopping the clock, whereas the second camp’s solution would be to let it explode but blunt the force of the explosion by covering it with a dump truck full of sand.

In humans, an example of an upstream clockwork mechanism would be the telomere clock of cellular aging, which counts off how many times a cell has divided and hence determines how old a cell really is. An example of a downstream mechanism would be an inflammatory process that leads to activation of damaging molecules in the coronary arteries as seen in atherosclerosis. 6-8

Many of the downstream processes are those typically addressed in Life Extension articles. This emphasis on the downstream may in part reflect the fact that our current understanding of many of the downstream mechanisms predates our understanding of the “upstream” clocking mechanisms. In addition, interventions into in these downstream events have favorably impacted the severity of age-related diseases.

However, most gerontologists agree that targeting the downstream mechanisms will not sufficiently extend human life expectancy to meet the objectives of those who seek aggressive solutions to pathological aging. By targeting upstream-biology—never before attempted in the practice of medicine—we could potentially create the most powerful impact on the aging process.

But first we should consider the basis for assuming that such a central clockwork exists, or that it would even be feasible to intervene in the inexorable progress of this ticking clock.

In this short progress report, we will attempt to describe the shortest path to a proof-of-principle by referring to a natural type of cellular immortality recently captured in the laboratory dish. This line of reasoning is now taking off in the scientific community.

We will then describe research funded in part by the Life Extension Foundation® that has potential clinical application to combat the deadliest manifestation of cell mortality in the United States, namely, coronary artery disease...the leading cause of heart attack.

What You Need to Know
Stem cell research

Scientists Discover Novel Way to Reset Cellular Aging Clock

  • Pluripotent cells have the power to become a variety of cell types.
  • Most somatic cells lack sufficient telomerase, and so every time somatic cells replicate, they progressively shorten their telomeres.
  • Germ-line cells retain telomere length appropriate for the beginning of life, due to an abundance of telomerase activity.
  • Telomerase, is an enzyme that synthesizes telomeres, a repeated sequence of DNA over and over again at the end of DNA strands needed to maintain cellular viability.
  • Although telomeres typically shorten with aging, shortening is not inevitable and telomeres can also lengthen.
  • Recent scientific studies have shown that reduced plasma levels of omega-6 fats coupled with increased omega- 3s resulted in an increase in telomere lengths.
  • It is possible to utilize these advances to not only revert a cell in the body (somatic cell) back to the all-powerful pluripotent stem cell state, but also to activate telomerase and reset the clock of cell aging all the way back to the very beginning of life.

The Facts of Life


Let’s begin with the facts of life and remember how an individual human being comes to exist in the first place. The union of a sperm and egg cell leads to a unified cell commonly called a zygote, which then divides into two cells, then four, and so on, until a small cluster of cells form, each of which has the power to become any of the cell types in the human body.

Cells that have this power are said to be pluripotent, meaning they have power (-potent) to become a variety (plurality or pluri-) of cell types. These cells commit to the cell type they will eventually become, that is, each cell will commit to becoming a reproductive (sperm or egg) cell, or one of the body’s many life-functioning cell types such as muscle, blood, or brain cells. This process of cellular commitment is called differentiation.

If pluripotent cells differentiate into sperm or egg cells, scientists say they are remaining in the germ-line. The germ-line is that lineage of cells that connects the generations and is the biological basis of the immortality of the species. They are the cells whose continuous proliferation ensures there are always zebras in Africa. They are the reason why you can go to a local greenhouse and buy fresh young petunias to plant in your garden every spring, year after year. Germ-line cells have the amazing ability to spin off new individuals forever, without the limitations of aging.

When pluripotent germ-line cells commit to become one of the life-functioning cell types of the body, we say they have differentiated into somatic cells. This differentiation seals their fate. These somatic cells are now mortal, even though, up to this point, they have been proliferating continuously for billions of years as germ-line cells. They will now become part of the body that is programmed to die usually within 100 years. Those cells that went the germ-line route have the potential (though not certainty) that they may continue in future generations indefinitely. Because they are not committed to a mortal fate, scientists say the cells are immortal. The use of this term does not mean that the individual cells are indestructible, nor does it mean anything in a religious sense. Instead, the term simply refers to the lack of commitment to the mortality that occurs when these cells differentiate into somatic (functional) cells that have finite lifespans, sometimes measured in maximum amount of doubling times before they die.

For the past few decades, scientists have focused on deciphering the molecular mechanisms of the immortality of germ-line cells in order to find a means of using those insights to restore health to aging somatic (life-sustaining functional) cells. In other words, we have attempted to find a means to rewind the clock of the “ticking time bomb” in our cells back to the beginning of life.

In the past few years, we have learned that, when cells make the decision to become somatic (that is, cells that enable the body to function as opposed to reproductive germ-line cells) they turn off telomerase, an enzyme that synthesizes a repeated sequence of DNA over and over again at the end of DNA strands needed to maintain cellular viability. This region of the chromosomes is called telomeres, and we refer to it in this article as the “telomere clock of cellular aging”.

Most somatic cells lack sufficient telomerase, and so every time somatic cells proliferate, they progressively shorten their telomeres. This functions as a clock mechanism not unlike the burning of a fuse. However, in contrast to somatic cells, germ-line cells retain telomere length appropriate for the beginning of life, due to an abundance of telomerase activity.

Since there is currently no known way to safely and effectively extend telomere length in the body, our researchers have instead sought means to mimic the natural immortality of germ-line cells in the laboratory dish to make young and healthy cells of all kinds that could potentially be injected into the body. Using this approach, we might be able to repair tissues afflicted with age-related degenerative diseases. The good news is that this technology is now very much operational in the laboratory and is a focus of intensive research around the world.

Reduced Omega-6 + Increased Omega-3 = Extended Telomere Length

Telomeres are the caps at the ends of chromosomes. Shorter telomeres have been linked with age-related disease and early death.13-16

Although telomeres typically shorten with aging, shortening is not inevitable and telomeres can also lengthen. Telomere length is associated with lifestyle behaviors. for instance, women who are obese or smoke cigarettes suffer greater loss of telomere length, with a corresponding reduction in life span.17,18

As this article was being finalized, a new study was published that measured telomere length in humans given EPA/DHA fish oil supplements. The results showed that reduced plasma levels of omega-6 fats coupled with increased omega-3s resulted in an increase in telomere lengths.19

The scientists attributed this telomere length increase to reductions in inflammatory cytokines and oxidative stress brought on by higher levels of omega-3s in relationship to pro-inflammatory omega-6s.

Omega-6 fats to avoid include corn, sunflower, and safflower oils, along with arachidonic acid found in red meat and egg yolks. olive oil, rich in monounsaturated fats, should be substituted for omega-6 oils whenever possible. Dietary sources of omega-3s include cold-water fish, walnuts, and flax seed.

In this human study where telomeres were lengthened, scientists used between 1,250 and 2,500 mg of EPA/DHA fish oil daily to boost omega-3 plasma levels in relation to omega-6s.19

Life Extension members typically consume 2,400 mg of EPA/DHA daily in their fish oil supplement.

Embryonic Stem Cells

The first step in understanding how germ-line cell immortality could be used to regenerate aging tissues in the human body was to capture the cells in the laboratory dish. In the mid 1990s, in collaboration with Drs. James Thomson, Roger Pedersen, and John Gearhart, some of us at Geron Corporation launched a project to isolate these cells and grow them as stable cell lines. These cells, called human embryonic stem cells, were the first naturally immortal human cells ever isolated due to their abundant natural expression of telomerase. They had the wonderful property of being able to generate each and every cell type of the human body. For the first time in history, medicine had in its hands a pluripotent stem cell to make every cellular component of the human body. (Pluripotent stem cells are capable of differentiation into any other functional (somatic) cell the body needs.)

These cells generated considerable excitement since they were a means of mass-producing replacement cells for the treatment of a host of degenerative diseases involving the loss or dysfunction of cells, including those in osteoarthritis, macular degeneration, diabetes, heart failure, Parkinson’s disease, and numerous other disorders. The first report of the isolation of these cells marked the birth of the new field called regenerative medicine. When perfected, this technology offered the theoretical potential of rejuvenating an entire human body back to a youthful state.