Analysis of splicing parameters in the dystrophin gene: relevance for physiological and pathogenetic splicing mechanisms.

The molecular mechanisms that direct splice-site selection and assure orderly exon juxtaposition have not been fully clarified. The extraordinary nature of the dystrophin gene points to several hurdles in the processing of transcripts. In this study, dystrophin statistical and thermodynamic splicing parameters have been evaluated providing the first comprehensive description for a single human gene. We show that concomitant use of consensus values (CV) and DeltaDG degrees 37 values for U1snRNA annealing better discriminates between real donor sites and donor-like sequences. Evidence is also provided that, on average, out-of-frame dystrophin exons have significantly stronger CVs and more favorable DeltaDG degrees 37 values; this feature has never been reported and might reflect evolutionary-driven minimization of out-of-frame exon misplicing. Dystrophin splicing mutations have been reported to determine either Duchenne or Becker Muscular Dystrophy, but no comprehensive genotypic/phenotypic correlation has ever been investigated. We have analyzed splicing affecting single base-pair substitutions in the dystrophin gene with respect to their effect on splicing parameters; functional and clinical consequences are also reported. We have found 5'-splice-site mutation occurrence to be statistically related to mutability quotients and propose the use of DeltaDG degrees 37 values as a more effective tool than CV alone to describe donor site mutation consequences. Our analysis also indicates a nearly 100% correlation between clinical phenotype and the reading-frame rule determined at the RNA level. We consider that elucidation of the relative importance of splicing determinants might help to clarify the molecular mechanisms that direct correct splicing in complex genes and might be useful in the validation of predictive models.