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Human Somatic-Cell Engineering

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Kurzweil, Ray - Singularity Is Near, The (hardback ed) [v1.3]

Human Somatic-Cell Engineering.
This even more promising approach, which bypasses the controversy of using
fetal stem cells entirely, is called transdifferentiation; it creates new tissues with a patient's own DNA by converting
one type of cell (such as a skin cell) into another (such as a pancreatic islet cell or a heart cell).
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Scientists from the
United States and Norway have recently been successful in reprogramming liver cells into becoming pancreas cells. In
another series of experiments, human skin cells were transformed to take on many of the characteristics of immune-
system cells and nerve cells.
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Consider the question, What is the difference between a skin cell and any other type of cell in the body? After all,
they all have the same DNA. As noted above, the differences are found in protein signaling factors, which include
short RNA fragments and peptides, which we are now beginning to understand.
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By manipulating these proteins, we
can influence gene expression and trick one type of cell into becoming another.
Perfecting this technology would not only defuse a sensitive ethical and political issue but also offer an ideal
solution from a scientific perspective. If you need pancreatic islet cells or kidney tissues—or even a whole new
heart—to avoid autoimmune reactions, you would strongly prefer to obtain these with your own DNA rather than the
DNA from someone else's germ-line cells. In addition, this approach uses plentiful skin cells (of the patient) rather
than rare and precious stem cells.
Transdifferentiation will directly grow an organ with your genetic makeup. Perhaps most important, the new
organ can have its telomeres fully extended to their original youthful length, so that the new organ is effectively young
again.
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We can also correct accumulated DNA errors by selecting the appropriate skin cells (that is, ones without
DNA errors) prior to transdifferentiation into other types of cells. Using this method an eighty-year-old man could
have his heart replaced with the same heart he had when he was, say, twenty-five.
Current treatments for type 1 diabetes require strong antirejection drugs that can have dangerous side effects.
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With somatic-cell engineering, type 1 diabetics will be able to make pancreatic islet cells from their own cells, either
from skin cells (transdifferentiation) or from adult stem cells. They would be using their own DNA, and drawing upon
a relatively inexhaustible supply of cells, so no antirejection drugs would be required. (But to fully cure type 1
diabetes, we would also have to overcome the patient's autoimmune disorder, which causes his body to destroy islet
cells.)
Even more exciting is the prospect of replacing one's organs and tissues with their "young" replacements without
surgery. Introducing cloned, telomere-extended, DNA-corrected cells into an organ will allow them to integrate
themselves with the older cells. By repeated treatments of this kind over a period of time, the organ will end up being
dominated by the younger cells. We normally replace our own cells on a regular basis anyway, so why not do so with
youthful rejuvenated cells rather than telomere-shortened error-filled ones? There's no reason why we couldn't repeat
this process for every organ and tissue in our body, enabling us to grow progressively younger.

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