Table 2.
Overview of computational studies on the evolutionary impact of exonic splice regulatory information
| References | Motif density | d S/d 4 decrease in motifs | Over-all d S/d 4 decrease | Motifs | Control |
|---|---|---|---|---|---|
| Parmley et al. (2006) | ~30.42% | ~8.19% (including CpG sites)/11.03% (excluding CpG sites) (alignment to mouse) | ~2.49% (including CpG sites)/3.36% (excluding CpG sites) | 238 RESCUE-ESE ESE hexamers (Fairbrother et al. 2002) | Non-ESE sites |
| Cáceres and Hurst (2013) | 13.1–32.7% (exon ends only) | 8.5–17.1% (exon ends only, alignment to mouse) | 1.2–4% (extrapolated from exon ends to the full sequence) | Various sets of putative ESEs, formed by taking intersections of pre-existing sets | Either all non-ESE sites near exon ends or sites overlapping with nucleotide-matched control motifs |
| Savisaar and Hurst (2017) | ~57.3% | ~4.1% (alignment to macaque) | ~2.4% | 1483 motifs experimentally determined to be recognized by human RBPs | Sites that overlap dinucleotide-matched control motifs |
For Cáceres and Hurst (2013), the figures are presented as a range, as they depend on the set of motifs and the method of control used. Note that some studies considered d S (rate of evolution at synonymous sites) while others considered d 4 (rate of evolution at fourfold degenerate sites). Parmley et al. (2006) also provided a second estimate for the over-all decrease in d S (~8%), however, only the lower estimate is reproduced here because of concerns that the reasoning used to derive the higher value may have been circular
ESE exonic splice enhancer, RBP RNA-binding protein