par Willems, Glenda 
;Dräger, Dörthe B;Courbot, Mikaël ;Godé, Cécile;Verbruggen, Nathalie ;Saumitou-Laprade, Pierre
Référence Genetics, 176, 1, page (659-674)
Publication Publié, 2007
;Dräger, Dörthe B;Courbot, Mikaël ;Godé, Cécile;Verbruggen, Nathalie ;Saumitou-Laprade, PierreRéférence Genetics, 176, 1, page (659-674)
Publication Publié, 2007
Article révisé par les pairs
| Résumé : | The species Arabidopsis halleri, an emerging model for the study of heavy metal tolerance and accumulation in plants, has evolved a high level of constitutive zinc tolerance. Mapping of quantitative trait loci (QTL) was used to investigate the genetic architecture of zinc tolerance in this species. A first-generation backcross progeny of A. halleri ssp. halleri from a highly contaminated industrial site and its nontolerant relative A. lyrata ssp. petraea was produced and used for QTL mapping of zinc tolerance. A genetic map covering most of the A. halleri genome was constructed using 85 markers. Among these markers, 65 were anchored in A. thaliana and revealed high synteny with other Arabidopsis genomes. Three QTL of comparable magnitude on three different linkage groups were identified. At all QTL positions zinc tolerance was enhanced by A. halleri alleles, indicating directional selection for higher zinc tolerance in this species. The two-LOD support intervals associated with these QTL cover 24, 4, and 13 cM. The importance of each of these three regions is emphasized by their colocalization with HMA4, MTP1-A, and MTP1-B, respectively, three genes well known to be involved in metal homeostasis and tolerance in plants. |
