A fully automated phosphopeptide purification system for large-scale phosphoproteome analysis.

For large-scale phosphoproteome analysis based on mass spectrometry, a fully automated phosphopeptide purification system is essential to obtain reproducible results. An automated system involving pre-cleaning of a sample with a polymer-based reversed-phase column, phosphopeptide purification with a titania column and analysis of the phosphopeptide fraction with a reversed-phase column was developed, and then the analytical conditions for a complex peptide mixture were optimized. A lower flow rate for application of samples to the titania column was essential to obtain high recoveries of phosphopeptides from complex protein digests.

Evolution from possible primitive tRNA-viroids to early poly-tRNA-derived mRNAs: a new approach from the poly-tRNA theory.

Poly-tRNA theory have revealed that the tRNA gene-clusters in the Bacillus subtilis trrnD- and rrnB-operons are relics of early peptide-synthesizing RNA apparatus. The trrnD-type and rrnB-type poly-tRNA models were re-analyzed by using recent databases. The results elucidated that the 16 amino acid (aa)-trrnD- and the 21 aa-rrnB-peptides (whose aa sequences are in the order of aa specificities of tRNAs in the respective tRNA cluster) are really relics of earliest peptides encoded by most primitive mRNAs, trrnD-mRNA and rrnB-mRNA, which are homologous to tRNA(Gly) and tRNA(His), respectively.

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 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.