posted on 2018-02-21, 12:21authored byAndrew M. Jobbins, Linus F. Reichenbach, Christian M. Lucas, Andrew J. Hudson, Glenn A. Burley, Ian C. Eperon
Exonic splicing enhancer (ESE) sequences are bound by serine & arginine-rich (SR) proteins, which in turn enhance the recruitment of splicing factors. It was inferred from measurements of splicing around twenty years ago that Drosophila doublesex ESEs are bound stably by SR proteins, and that the bound proteins interact directly but with low probability with their targets. However, it has not been possible with conventional methods to demonstrate whether mammalian ESEs behave likewise. Using single molecule multi-colour colocalization methods to study SRSF1-dependent ESEs, we have found that that the proportion of RNA molecules bound by SRSF1 increases with the number of ESE repeats, but only a single molecule of SRSF1 is bound. We conclude that initial interactions between SRSF1 and an ESE are weak and transient, and that these limit the activity of a mammalian ESE. We tested whether the activation step involves the propagation of proteins along the RNA or direct interactions with 3' splice site components by inserting hexaethylene glycol or abasic RNA between the ESE and the target 3' splice site. These insertions did not block activation, and we conclude that the activation step involves direct interactions. These results support a model in which regulatory proteins bind transiently and in dynamic competition, with the result that each ESE in an exon contributes independently to the probability that an activator protein is bound and in close proximity to a splice site.
Funding
Leverhulme Trust [RPG-2014-001 to G.A.B. and I.C.E.]. Funding for open access charge: Universities of Leicester and Strathclyde.
History
Citation
Nucleic Acids Research, 2018, gky056
Author affiliation
/Organisation/COLLEGE OF LIFE SCIENCES/Biological Sciences/Molecular & Cell Biology