Origin of Most Primitive mRNAs and Genetic Codes via Interactions between Primitive tRNA Ribozymes

Origin of Most Primitive mRNAs and Genetic Codes via Interactions between Primitive tRNA Ribozymes

The origin and early evolution of genetic codon system and early mRNAs were analyzed from a viewpoint of primordial gene theory and the poly-tRNA theory. A hypothetical 25-amino acid (aa)-primordial peptide was deduced from internal aa-sequence homology of adenylate kinases. Theoretical models were...

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Bibliographic Details
Published in:Genome Informatics Vol. 13; pp. 71 - 81
Main Authors: Ohnishil, Koji, Ohshima, Madoka, Hokari, Shouken, Furuichi, Naotaka, Shutou, Hiroshi, Goda, Masaki
Format: Journal Article
Language:English
Published: Japan Japanese Society for Bioinformatics 2002
Subjects:
3-phosphoglycerate transporter protein B
adenylate kinase
Adenylate Kinase - genetics
arbitrary correspondence
Bacillus subtilis - genetics
early peptide-synthesis
Evolution, Molecular
Genetic Code - genetics
Genetic Code - physiology
glyceraldehydes-3-phosphate dehydrogenase
poly-tRNA theory
primordial gene
Protein Biosynthesis - physiology
RNA, Catalytic - genetics
RNA, Catalytic - metabolism
RNA, Messenger - genetics
RNA, Messenger - metabolism
RNA, Transfer - genetics
RNA, Transfer - metabolism
rrnB-peptide
semeiotic culture
trrnD-peptide
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Summary:The origin and early evolution of genetic codon system and early mRNAs were analyzed from a viewpoint of primordial gene theory and the poly-tRNA theory. A hypothetical 25-amino acid (aa)-primordial peptide was deduced from internal aa-sequence homology of adenylate kinases. Theoretical models were made which can reasonably explain how primitive tRNA (s) could have had converted to be earliest mRNAs via interactions between presumptive anticodons and (poly-) tRNA ribozyme. Transfer-RNA gene clusters in the trrnD- and rrnB-operons of Bacillus subtilis seemed to be relics of early peptide-synthesizing RNA machine. Detailed analyses revealed that the poly-tRNA regions in these operons are true relics of RNA-machine for making a 16-aa trrnD-peptide and a 21-aa rrnB-peptide, whose aa sequences are in the order of aa specificities of tRNAs in the tRNA gene clusters of the trrnD-operon and rrnB-operon, respectively. The primordial gene-encoded peptide deduced from adenylate kinases were found to be a genuine homologue of the rrnB-peptide. Various protein superfamilies were found to have evolved from either of these two types of primitive peptides. Earlist mRNAs were concluded to have evolved from tRNAGlY (trrnD-mRNA) or tRNAHis (rrnB-mRNA), where trrnD-and rrnB-mRNAs are hypothetical primitive mRNAs complementary to the tandem arrangement of 16 or 21 anticodons of tRNAs in the trrnD-operon and rrnB-operon, respectively. The poly-tRNA model is considered to be an excellent theory, because it can reasonably explain origins of both genetic codes and earliest mRNAs, and because the hypothesis can be statistically evaluated by base-identity levels in proper alignments. The genetic codon system is a typical mature semeiotic system within a cell, and the genesis of the geneic codon system was discussed from an aspect of de Saussure's semeiology. Arbitrary correspondence between (anti) codon and aa would be most plausibly a result of semeiotic culture system of intracellular tRNA-riboorganismic society.
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ISSN:0919-9454
2185-842X
DOI:10.11234/gi1990.13.71