The canonical Central Dogma declared the relationship between
a gene (DNA locus), the RNA transcript and the protein
product: Gene → mRNA → Protein. This Central Dogma
approach was casually adopted to explain genetic disease
and, as well, genetic traits in general: Mutant Gene (Allele) →
Aberrant mRNA → Abnormal Protein, the latter accounting for
the overall phenotype. A popular truncated version of Central
Dogma representation used to explain genetic disease oversimplified
both the physical dynamics and the underlying logic:
Mutant Allele(s) → Mutant Phenotype (γ → φ). Knowledge
of a mutant gene (allele) foretold the disease phenotype. As
simple as that! For many reasons, not the least of which is our
recent understanding and characterization of epigenetics and
related disciplines, there is much more to pathogenic schemata
than change in the nucleotide base sequence in a genetic
locus. It is not just the mutant gene, but how that
mutant gene is physically and chemically manifest, that is, put
into practice. The word designating this notion of putting a
gene into practice is Praxitype. The Praxitype consideration
is implicit in various relevant phrases, such as “Metabolome”
and “Interactome” and so on.
The notion or the various phenomena of “putting a gene into
practice” is designated by the term, Praxitype (π),etymologically
consistent with the terms Genotype (γ) and Phenotype
(φ). Thus, the over-simplified formulaic expression γ →
φ necessarily becomes γ → π → φ. In turn, the major efforts
in characterizing how a gene (wildtype or mutant) manifests
as a trait (normal, variant or pathological) must now focus on
the Praxitype. Just what are the conditions and factors that account
for HOW the gene is realized as a phenotypic trait (element)? For example, what are the general and specific
roles of epigenetic silencing, microRNAs, post-translational
modification (e.g., phosphorylation), protein sequestration
or turnover, etc.? Specifically, the progression, γ →
π → φ, is not just a matter of the passage of time, it is a matter
of the details of various mechanisms employed over time.
On the other hand, a disorder’s progression over time is often
overlooked, for example, that an NF1 neurofibroma is the
“same” at all time periods: no, it changes and for at least some
changes, the praxitype must be considered.
(element)? For example, what are the general and specific
roles of epigenetic silencing, microRNAs, post-translational
modification (e.g., phosphorylation), protein sequestration
or turnover, etc.? [4, 5, 8] Specifically, the progression, γ →
π → φ, is not just a matter of the passage of time, it is a matter
of the details of various mechanisms employed over time.
On the other hand, a disorder’s progression over time is often
overlooked, for example, that an NF1 neurofibroma is the
“same” at all time periods: no, it changes and for at least some
changes, the praxitype must be considered.
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