PLoS Genetics (May 2016)

The Splicing Efficiency of Activating HRAS Mutations Can Determine Costello Syndrome Phenotype and Frequency in Cancer.

  • Anne-Mette Hartung,
  • Jeff Swensen,
  • Inaki E Uriz,
  • Morten Lapin,
  • Karen Kristjansdottir,
  • Ulrika S S Petersen,
  • Jeanne Mari V Bang,
  • Barbara Guerra,
  • Henriette Skovgaard Andersen,
  • Steven F Dobrowolski,
  • John C Carey,
  • Ping Yu,
  • Cecily Vaughn,
  • Amy Calhoun,
  • Martin R Larsen,
  • Lars Dyrskjøt,
  • David A Stevenson,
  • Brage S Andresen

DOI
https://doi.org/10.1371/journal.pgen.1006039
Journal volume & issue
Vol. 12, no. 5
p. e1006039

Abstract

Read online

Costello syndrome (CS) may be caused by activating mutations in codon 12/13 of the HRAS proto-oncogene. HRAS p.Gly12Val mutations have the highest transforming activity, are very frequent in cancers, but very rare in CS, where they are reported to cause a severe, early lethal, phenotype. We identified an unusual, new germline p.Gly12Val mutation, c.35_36GC>TG, in a 12-year-old boy with attenuated CS. Analysis of his HRAS cDNA showed high levels of exon 2 skipping. Using wild type and mutant HRAS minigenes, we confirmed that c.35_36GC>TG results in exon 2 skipping by simultaneously disrupting the function of a critical Exonic Splicing Enhancer (ESE) and creation of an Exonic Splicing Silencer (ESS). We show that this vulnerability of HRAS exon 2 is caused by a weak 3' splice site, which makes exon 2 inclusion dependent on binding of splicing stimulatory proteins, like SRSF2, to the critical ESE. Because the majority of cancer- and CS- causing mutations are located here, they affect splicing differently. Therefore, our results also demonstrate that the phenotype in CS and somatic cancers is not only determined by the different transforming potentials of mutant HRAS proteins, but also by the efficiency of exon 2 inclusion resulting from the different HRAS mutations. Finally, we show that a splice switching oligonucleotide (SSO) that blocks access to the critical ESE causes exon 2 skipping and halts proliferation of cancer cells. This unravels a potential for development of new anti-cancer therapies based on SSO-mediated HRAS exon 2 skipping.