Identification of favorable SNP alleles and candidate genes responsible for inflorescence-related traits via GWAS in chrysanthemum

Key message

81 SNPs were identified for three inflorescence-related traits, in which 15 were highly favorable. Two dCAPS markers were developed for future MAS breeding, and six candidate genes were predicted.

Abstract

Chrysanthemum is a leading ornamental species worldwide and demonstrates a wealth of morphological variation. Knowledge about the genetic basis of its phenotypic variation for key horticultural traits can contribute to its effective management and genetic improvement. In this study, we conducted a genome-wide association study (GWAS) based on two years of phenotype data and a set of 92,617 single nucleotide polymorphisms (SNPs) using a panel of 107 diverse cut chrysanthemums to dissect the genetic control of three inflorescence-related traits. A total of 81 SNPs were significantly associated with the three inflorescence-related traits (capitulum diameter, number of ray florets and flowering time) in at least one environment, with an individual allele explaining 22.72–38.67% of the phenotypic variation. Fifteen highly favorable alleles were identified for the three target traits by computing the phenotypic effect values for the stable associations detected in 2 year-long trials at each locus. Dosage pyramiding effects of the highly favorable SNP alleles and significant linear correlations between highly favorable allele numbers and corresponding phenotypic performance were observed. Two highly favorable SNP alleles correlating to flowering time and capitulum diameter were converted to derived cleaved amplified polymorphic sequence (dCAPS) markers to facilitate future breeding. Finally, six putative candidate genes were identified that contribute to flowering time and capitulum diameter. These results serve as a foundation for analyzing the genetic mechanisms underlying important horticultural traits and provide valuable insights into molecular marker-assisted selection (MAS) in chrysanthemum breeding programs.

     

Genetic dissection of floral traits in anemone-type chrysanthemum by QTL mapping

Brassica oleracea comprises several important subspecies, including cabbage, broccoli, cauliflower, Chinese kale, and kohlrabi. The petal color of Chinese kale is mostly white and sometimes yellow. To explore the genetic basis of petal color variation in Chinese kale, F₂ and BC₁ (backcross) populations were constructed from the cross of two inbred lines, 2114 (yellow petal) and 2116 (white petal). Genetic analysis of the F₂ and BC₁ populations demonstrated that yellow petal color was controlled by a single recessive nuclear gene, termed cpc-2. Insertion-deletion (InDel) markers, designed based on the parental resequencing data, were used to map cpc-2. The fine mapping results indicated that the cpc-2 gene was located in a 569-kb interval on chromosome C03 flanked by InDel markers ZB636 and ZB692, with genetic distances of 0.3 cM and 0.6 cM, respectively. By analyzing the nucleotide variations and annotations of the genes in this interval, a CCD4 family gene was predicted to be a candidate for cpc-2 and renamed BoCCD4.2. In addition, insertion of the CACTA-like transposable element (TE3) interrupted the function of the BoCCD4 gene, which may have resulted in the loss of function of BoCCD4 and the petal color transition from white to yellow. The TE3 insertion in the BoCCD4 gene was also present in 63 cabbage inbred lines among 159 accessions, which revealed that the TE3-type null allele of BoCCD4 formed before the divergence of the two subspecies cabbage and Chinese kale and that Chinese kale evolved much earlier than cabbage. This study lays the foundation for cloning BoCCD4.2 and revealing the molecular mechanism underlying petal color formation in Chinese kale.