Abstract
The emergence of a primitive genetic code should be considered the most essential event during the origin of life. Almost a complete set of codons (as we know them) should have been established relatively early during the evolution of the last universal common ancestor (LUCA) from which all known organisms descended. Many hypotheses have been proposed to explain the driving forces and chronology of the evolution of the genetic code; however, none is commonly accepted. In the current paper, we explore the features of the genetic code that, in our view, reflect the mechanism and the chronological order of the origin of the genetic code. Our hypothesis postulates that the primordial RNA was mostly GC-rich, and this bias was reflected in the order of amino acid codon assignment. If we arrange the codons and their corresponding amino acids from GC-rich to AU-rich, we find that: 1. The amino acids encoded by GC-rich codons (Ala, Gly, Arg, and Pro) are those that contribute the most to the interactions with RNA (if incorporated into short peptides). 2. This order correlates with the addition of novel functions necessary for the evolution from simple to longer folded peptides. 3. The overlay of aminoacyl-tRNA synthetases (aaRS) to the amino acid order produces a distinctive zonal distribution for class I and class II suggesting an interdependent origin. These correlations could be explained by the active role of the bridge peptide (BP), which we proposed earlier in the evolution of the genetic code.
Highlights
Several theories have sought to explain the establishment of the genetic code and the forces behind it [1]
The stereochemical theory postulates that the physicochemical properties of a given amino acid facilitate its codon recognition, and this relation is the basis for establishing the correspondence between an amino acid and its future tRNA
We describe many correlations evident in the universal genetic code: The most
Summary
Several theories have sought to explain the establishment of the genetic code and the forces behind it [1]. While most hypotheses regarding the establishment of the genetic code assume implicitly that prebiotic conditions were “set” to favor the stability of the early living entities (i.e., the amino acid abundance or various forms of chemical fit between nucleic and amino acids favoring the establishment of the genetic code and, stability), we postulate that from the very beginning, the formation of a genetic code was driven by Darwinian selection [16]. This started with the establishment of a primitive translation by BP-driven RNA–amino acids interactions. Before going into details on the GC/AU content of codons, we need to illustrate our expectations for the amino acid abundance and the nucleotide composition in the prebiotic environment
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