BACKGROUND: Hirschsprung disease (HSCR) is a complex disorder with traditional germline mutations in RET in up to 30% of familial cases and in 3% of sporadic cases in a population-based series. We have previously demonstrated that an ancestral haplotype at the 5' end of RET (haplotype 0) was strongly associated with a large subset of isolated HSCR cases and that a putative low penetrance susceptibility locus was encompassed within this ancestral haplotype, anchored by exon 2 SNP A45A. OBJECTIVE: To determine the 5' extent of the HSCR-associated ancestral haplotype by defining the linkage disequilibrium breakpoint in search for the low penetrance susceptibility locus. METHODS: Systematic screening of the region upstream of the anchoring A45A SNP, comprising RET intron 1, exon 1, and promoter in 117 population-based HSCR cases and 100 controls. Dual luciferase assay to determine differential activities between SNP combinations near a transcription start site. RESULTS: New SNP's were found which formed upstream haplotypes, anchored by A45A, in linkage disequilibrium with HSCR (2 = 76.96, p<0.00000001). Linkage disequilibrium appeared to break at the -1249C/T SNP. Further, the HSCR-associated genotype (00) was found in >60% of HSCR but only 2% of controls. Because only 2 variants, -200A>G and -196C>A, lie within the promoter region and are in proximity to the transcriptional start site (at -195), we modelled these combinations into constructs for luciferase reporter assay. The HSCR-associated SNP combination showed the lowest activity and the control-associated combination, the highest. CONCLUSIONS: Our observations seem to discard the existence of a HSCR-causing mutation as it is conceived in the traditional sense, but strengthen the idea of a specific combination of variants conferring susceptibility to the disease in a low penetrance fashion. The data derived from our functional "in vitro" studies would suggest that the HSCR-associated haplotype 0 may result in a lower level of expression of the RET gene [corrected]
BACKGROUND:Hirschsprung disease (HSCR) is a complex disorder with traditional germline mutations in RET in up to 30% of familial cases and in 3% of sporadic cases in a population-based series. We have previously demonstrated that an ancestral haplotype at the 5' end of RET (haplotype 0) was strongly associated with a large subset of isolated HSCR cases and that a putative low penetrance susceptibility locus was encompassed within this ancestral haplotype, anchored by exon 2 SNP A45A. OBJECTIVE: To determine the 5' extent of the HSCR-associated ancestral haplotype by defining the linkage disequilibrium breakpoint in search for the low penetrance susceptibility locus. METHODS: Systematic screening of the region upstream of the anchoring A45A SNP, comprising RET intron 1, exon 1, and promoter in 117 population-based HSCR cases and 100 controls. Dual luciferase assay to determine differential activities between SNP combinations near a transcription start site. RESULTS: New SNP's were found which formed upstream haplotypes, anchored by A45A, in linkage disequilibrium with HSCR (2 = 76.96, p<0.00000001). Linkage disequilibrium appeared to break at the -1249C/T SNP. Further, the HSCR-associated genotype (00) was found in >60% of HSCR but only 2% of controls. Because only 2 variants, -200A>G and -196C>A, lie within the promoter region and are in proximity to the transcriptional start site (at -195), we modelled these combinations into constructs for luciferase reporter assay. The HSCR-associated SNP combination showed the lowest activity and the control-associated combination, the highest. CONCLUSIONS: Our observations seem to discard the existence of a HSCR-causing mutation as it is conceived in the traditional sense, but strengthen the idea of a specific combination of variants conferring susceptibility to the disease in a low penetrance fashion. The data derived from our functional "in vitro" studies would suggest that the HSCR-associated haplotype 0 may result in a lower level of expression of the RET gene [corrected]
Authors: A S Brooks; P A Leegwater; G M Burzynski; P J Willems; B de Graaf; I van Langen; P Heutink; B A Oostra; R M W Hofstra; A M Bertoli-Avella Journal: J Med Genet Date: 2006-07 Impact factor: 6.318
Authors: C S Tang; Y Sribudiani; X P Miao; A R de Vries; G Burzynski; M T So; Y Y Leon; B H Yip; J Osinga; K J W S Hui; J B G M Verheij; S S Cherny; P K H Tam; P C Sham; R M W Hofstra; M M Garcia-Barceló Journal: Hum Genet Date: 2010-04-02 Impact factor: 4.132
Authors: Rocio Núñez-Torres; Raquel M Fernández; Manuel Jesus Acosta; Maria Del Valle Enguix-Riego; Martina Marbá; Juan Carlos de Agustín; Luis Castaño; Guillermo Antiñolo; Salud Borrego Journal: BMC Med Genet Date: 2011-10-13 Impact factor: 2.103
Authors: Berta Luzón-Toro; Raquel M Fernández; Ana Torroglosa; Juan Carlos de Agustín; Cristina Méndez-Vidal; Dolores Isabel Segura; Guillermo Antiñolo; Salud Borrego Journal: PLoS One Date: 2013-01-23 Impact factor: 3.240