Energy-dependent RNA methylation (9)

By: James V. Kohl | Published on: June 9, 2016

Epigenetics and How Our Decisions Affect Our DNA

Excerpt (with my emphasis):
With the Genetics and Genomics 2016 virtual conference now on demand, we are extending the genetics conversation into this month with a new infographic. Epigenetics has been in the news quite a bit lately as researchers have been able to learn more about its process and influences. It turns out that epigenetics is an ever-changing process within our cells, causing more rapid modification within a generation. Unlike standard evolution, where small mutations can span generations before any actual variation takes place, an epigenetic change can affect a person within their lifetime.
Here are a few interesting facts about epigenetics and one cool infographic:
Epigenetics decides which genes are expressed and how much of that gene is expressed. Since every cell in a person has the same DNA, epigenetics control what cells become and how they behave. It is these non-direct changes in DNA sequence that influence a person’s physical traits and propensity for certain diseases.

The first human disease to be linked to epigenetics was cancer…

My comment: “RNA-mediated physics, chemistry, and molecular epigenetics” is available in the “Genome Technology Innovations” of the poster hall, and also available with a narrative from the Labroots Youtube page.

Published on 3 May 2016

Olfaction and the innate immune system link energy as information from the epigenetic landscape to the physical landscape of supercoiled DNA. The sun’s biological energy is the source of the information that links angstroms to ecosystems via physics, chemistry, and molecular epigenetics.
RNA-mediated protein folding chemistry and amino acid substitutions link the anti-entropic quantized energy of sunlight from the virucidal effects of ultraviolet (UV) light to healthy longevity via biophysically-constrained energy-dependent hydrogen-atom transfer in DNA base pairs in solution and cell type differentiation.
Biomarkers link energy-dependent differences in base pairs and amino acid substitutions to biosignatures across the healthy life span. RNA-mediated amino acid substitutions also reveal the increasing complexity of interactions among cell types as pathology progresses. For comparison, successful reproduction links energy from supercoiled DNA to protection of all organized genomes from virus-driven energy theft and pathology.
This model links the sun’s biological energy from top-down causation in microbes to the most recent model of bottom-up gene activation and cell type differentiation in vertebrates. Citations to extant literature provide examples of what is currently known about how ecological variation leads to biophysically constrained cell type differentiation in the context of nutritional epigenetics and Precision Medicine, which clearly link metabolic networks and genetic networks to pharmacogenomics.
See also: Epigenetics and Genetics of Viral Latency

“…viral latency is responsible for life-long pathogenesis and mortality risk…”

As more researchers learn that The first human disease to be linked to epigenetics was cancer… and that “…viral latency is responsible for life-long pathogenesis and mortality risk…” they will be forced to accept the facts about nutritional epigenetics and healthy longevity in the context of the alternative, which is virus-driven energy theft and all pathology.


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