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I. Preface
Readers can determine the accuracy of a DNA or RNA sequence by the degree of variation from the DNA or RNA genetic constant.
This introduction to the concept was detailed in the second post of this series:
"The exercise involved in exposing this "Genetic Constant" is very, very simple at its core:
'The number of atoms in a given nucleotide ('A', 'C', 'G', 'T', and 'U') are:
'A' = "C5H5N5" (5 Carbon, 5 Hydrogen, 5 Nitrogen)
'C' = "C4H5N3O1" (4 Carbon, 5 Hydrogen, 3 Nitrogen, 1 Oxygen)
'T' = "C5H6N2O2" (5 Carbon, 6 Hydrogen, 2 Nitrogen, 2 Oxygen)
'G' = "C5H5N5O1" (5 Carbon, 5 Hydrogen, 5 Nitrogen, 1 Oxygen)
'U' = "C4H4N2O2" (4 Carbon, 4 Hydrogen, 2 Nitrogen, 2 Oxygen)
(Quantum Biology - 18). As you can see the analysis of the atom content of any given genome in the appendix (Link) is a function of simple arithmetic (it is not "rocket science").
The percentages are derived by dividing the count of each atom type by the total atom count.'
(On The Origin of The Containment Entity - 16). How that constant is calculated depends on whether the genetic sequence is DNA or RNA (a DNA 'T' count is not the same as an RNA 'U' count; note that this current exercise only involves DNA)."
(On The Origin Of A Genetic Constant - 2, cf. this). The 'art' of genome sequencing is not yet the 'science' those who do it want it to be, but it is improving quickly.
II. Appendices
Today's appendices (One, Two, Three) detail the variation in a sequence from the valid atom counts in various genomes.
The previous post in this series is here.
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