Branch site haplotypes that control alternative splicing

doi:10.1093/hmg/ddh334

Human Molecular Genetics Advance Access originally published online on October 20, 2004
Human Molecular Genetics 2004 13(24):3189-3202; doi:10.1093/hmg/ddh334

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Branch site haplotypes that control alternative splicing

Jana Královi $c$ ová¹, Sophie Houngninou-Molango², Angela Krämer² and Igor Vo $r$ echovsk $y$ ¹^,*

¹University of Southampton School of Medicine, Division of Human Genetics, Southampton SO16 6YD, UK and ²University of Geneva, Department of Cell Biology, CH-1211 Geneva 4, Switzerland

Received August 25, 2004; Revised October 6, 2004; Accepted October 12, 2004

We show that the allele-dependent expression of transcriptsencoding soluble HLA-DQß chains is determined by branchpointsequence (BPS) haplotypes in DQB1 intron 3. BPS RNAs associatedwith low inclusion of the transmembrane exon in mature transcriptsshowed impaired binding to splicing factor 1 (SF1), indicatingthat alternative splicing of DQB1 is controlled by differentialBPS recognition early during spliceosome assembly. We also demonstratethat naturally occurring human BPS point mutations that altersplicing and lead to recognizable phenotypes cluster in BP andin position –2 relative to BP, implicating impaired SF1–BPSinteractions in disease-associated BPS substitutions. CodingDNA variants produced smaller fluctuations of exon inclusionlevels than random exonic substitutions, consistent with a selectionagainst coding mutations that alter their own exonization. Finally,proximal splicing in this multi-allelic reporter system waspromoted by at least seven SR proteins and repressed by hnRNPsF, H and I, supporting an extensive antagonism of factors balancingthe splice site selection. These results provide the molecularbasis for the haplotype-specific expression of soluble DQß,improve prediction of intronic point mutations and indicatehow extraordinary, selection-driven DNA variability in HLA affectspre-mRNA splicing.

^* To whom correspondence should be addressed at: University of Southampton School of Medicine, Division of Human Genetics, Duthie Building, MP808, Southampton SO16 6YD, UK. Tel: +44 2380796425; Fax: +44 2380794264; Email: igvo{at}soton.ac.uk

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