Possible evolution of splice-junction signals in eukaryotic genes from stop codons

Abstract

Splice-junction sequence signals are strongly conserved structural components of eukaryotic genes. These sequences border exon/intron junctions and aid in the process of removing introns by the RNA splicing machinery. Although substantial research has been undertaken to understand the mechanism of splicing, little is known about the origin and evolution of these splice signal sequences. Based on the previously published theory that the primitive genes evolved in pieces from primordial genetic sequences to avoid the interfering stop codons, a "stop-codon walk" mechanism is proposed in this paper to have assisted in the evolution of coding genes. This mechanism predicts the presence of stop codons in splice-junction signals inside the introns. Evidence of the consistent presence of stop codons in the splice-junction signals, in a position where they are expected, is shown by the analysis of codon statistics in these signal sequences in the GenBank databank. The results suggest that the splice-junction signals may have evolved from stop codons as a consequence of a selective pressure to avoid stop codons during the original evolution of coding genes. They also suggest that other splice signals within the introns, such as the branch-point sequence, may have evolved from stop codons for similar reasons.