My first two links are indeed about transcription! Rereading my comment in context now I'm realizing it was a bit unclear. I was responding to "the genetic code is rarely discussed as a potential source of error".
However, I believe my third link is about environmental stress triggering intentional mistranslation (mRNA to protein). From that paper's figure 3:
> Proteins arising from “statistical proteomes” have various folding and binding properties, resulting in phenotypic diversity in the host organism.
I haven't bothered to pull up the related references (5 obvious ones) to assess their strength though.
The papers you linked seem to be claiming that codon encoding preferences (which vary by gene category) are in fact due to (or merely correlated with?) GC content in mammalian genomes (as opposed to a number of other previously proposed mechanisms). This is surprising because individual tRNA abundance varies by cell state and type, so that would have been the obvious (but apparently wrong) explanation. It's doubly surprising because a number of single celled organisms utilize the mismatch between codon preference and tRNA availability in order to regulate protein translation, but these papers are claiming that's not a significant factor in mammals.
> This is surprising because individual tRNA abundance varies by cell state and type, so that would have been the obvious (but apparently wrong) explanation.
tRNA gene expression varies by cell state, but isoacceptor abundance is in fact very stable (at least in mammals). Meaning, if you have a set of tRNA genes which all code for, say, Ala_AGC, the sum of the gene expression of all these genes is relatively stable, even if their individual expression varies (http://dx.doi.org/10.1101/gr.176784.114l; full disclosure: I’m an author on this and one of the previously linked papers).
Why individual tRNA gene expression varies, and how the cell regulates the overall stability, is unclear (my personal pet theory is that secondary tRNA function as regulatory RNA, in the form of tRNA-derived fragments, causes the need to regulate tRNA genes, see e.g. http://dx.doi.org/10.1016/j.cell.2017.06.013).
> It's doubly surprising because a number of single celled organisms utilize the mismatch between codon preference and tRNA availability in order to regulate protein translation
It’s not that surprising: gene regulation happens fundamentally differently in eukaryotes and prokaryotes, and even differently in different classes of eukaryotes. The effective population size (= evolvability) and genome complexity seems to play a role here. Simply put, higher animals have much more powerful and precise ways of controlling gene expression (enhancers and histone control). Regulation at the translation level is comparatively slow and wasteful (it’s several steps further down the line of the gene->protein production process).
However, I believe my third link is about environmental stress triggering intentional mistranslation (mRNA to protein). From that paper's figure 3:
> Proteins arising from “statistical proteomes” have various folding and binding properties, resulting in phenotypic diversity in the host organism.
I haven't bothered to pull up the related references (5 obvious ones) to assess their strength though.
The papers you linked seem to be claiming that codon encoding preferences (which vary by gene category) are in fact due to (or merely correlated with?) GC content in mammalian genomes (as opposed to a number of other previously proposed mechanisms). This is surprising because individual tRNA abundance varies by cell state and type, so that would have been the obvious (but apparently wrong) explanation. It's doubly surprising because a number of single celled organisms utilize the mismatch between codon preference and tRNA availability in order to regulate protein translation, but these papers are claiming that's not a significant factor in mammals.