Genomic analyses reveal the stepwise domestication and genetic mechanism of curd biogenesis in cauliflower.
Rui ChenKe ChenXingwei YaoXiaoli ZhangYingxia YangXiao SuMingjie LyuQian WangGuan ZhangMengmeng WangYanhao LiLijin DuanTianyu XieHaichao LiYuyao YangHong ZhangYutong GuoGuiying JiaXianhong GePanagiotis F SarrisTao LinDeling SunPublished in: Nature genetics (2024)
Cauliflower (Brassica oleracea L. var. botrytis) is a distinctive vegetable that supplies a nutrient-rich edible inflorescence meristem for the human diet. However, the genomic bases of its selective breeding have not been studied extensively. Herein, we present a high-quality reference genome assembly C-8 (V2) and a comprehensive genomic variation map consisting of 971 diverse accessions of cauliflower and its relatives. Genomic selection analysis and deep-mined divergences were used to explore a stepwise domestication process for cauliflower that initially evolved from broccoli (Curd-emergence and Curd-improvement), revealing that three MADS-box genes, CAULIFLOWER1 (CAL1), CAL2 and FRUITFULL (FUL2), could have essential roles during curd formation. Genome-wide association studies identified nine loci significantly associated with morphological and biological characters and demonstrated that a zinc-finger protein (BOB06G135460) positively regulates stem height in cauliflower. This study offers valuable genomic resources for better understanding the genetic bases of curd biogenesis and florescent development in crops.