Abstract
BackgroundPreviously, we suggested prototypal models that describe some clinical states based on group postulates. Here, we demonstrate a group/category theory-like model for molecular/genetic biology as an alternative application of our previous model. Specifically, we focus on deoxyribonucleic acid (DNA) base sequences.ResultsWe construct a wallpaper pattern based on a five-letter cruciform motif with letters C, A, T, G, and E. Whereas the first four letters represent the standard DNA bases, the fifth is introduced for ease in formulating group operations that reproduce insertions and deletions of DNA base sequences. A basic group Z5 = {r, u, d, l, n} of operations is defined for the wallpaper pattern, with which a sequence of points can be generated corresponding to changes of a base in a DNA sequence by following the orbit of a point of the pattern under operations in group Z5. Other manipulations of DNA sequence can be treated using a vector-like notation ‘Dj’ corresponding to a DNA sequence but based on the five-letter base set; also, ‘Dj’s are expressed graphically. Insertions and deletions of a series of letters ‘E’ are admitted to assist in describing DNA recombination. Likewise, a vector-like notation Rj can be constructed for sequences of ribonucleic acid (RNA). The wallpaper group B = {Z5×∞, ●} (an ∞-fold Cartesian product of Z5) acts on Dj (or Rj) yielding changes to Dj (or Rj) denoted by ‘Dj◦B(j→k) = Dk’ (or ‘Rj◦B(j→k) = Rk’). Based on the operations of this group, two types of groups—a modulo 5 linear group and a rotational group over the Gaussian plane, acting on the five bases—are linked as parts of the wallpaper group for broader applications. As a result, changes, insertions/deletions and DNA (RNA) recombination (partial/total conversion) are described. As an exploratory study, a notation for the canonical “central dogma” via a category theory-like way is presented for future developments.ConclusionsDespite the large incompleteness of our methodology, there is fertile ground to consider a symmetry model for genetic coding based on our specific wallpaper group. A more integrated formulation containing “central dogma” for future molecular/genetic biology remains to be explored.
Highlights
We suggested prototypal models that describe some clinical states based on group postulates
We added an imaginary base ‘E’ to the set of actual deoxyribonucleic acid (DNA) bases, and composed group Z5 of basic translational operations on grid-points of a cruciform wallpaper pattern constructed of the five base letters
Category theory-like language is introduced to describe the canonical “central dogma” that is expected to integrate DNA-based processes, the overall profile and range of applicability is unclear at this stage
Summary
We suggested prototypal models that describe some clinical states based on group postulates. We focus on deoxyribonucleic acid (DNA) base sequences. When group theory is used in various fields of natural sciences, it plays an important role in describing geometrical or dynamical symmetries of phenomena under consideration; examples include mathematics [3,4], physics [5,6,7,8], chemistry [9], molecular/genetic biology [10,11,12,13,14,15,16,17,18,19,20,21,22], and anthropology [23]. Deoxyribonucleic acid (DNA) is a nucleic acid containing genetic instructions coded in ordered sequences of four bases located in genes that determine specific genetic characteristics of an organism. The sequence of DNA consisting of bases ‘A, C, T and G’ is transcribed into RNA, composed of bases ‘A, C, U and G’; the sets differ in that ‘U (uracil)’ replaces ‘T (thymine)’
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