TY - JOUR
T1 - Identification of quantitative trait loci controlling developmental characteristcs of Brassica oleracea L
AU - Sebastian, Rachel
AU - Kearsey, Michael
AU - King, Graham
PY - 2002/3/1
Y1 - 2002/3/1
N2 - A segregating population of F-1-derived doubled haploid (DH) lines of Brassica oleracea was used to detect and locate QTLs controlling 27 morphological and developmental traits, including leaf, flowering, axillary bud and stem characters. The population resulted from a cross between two very different B. olerczcea crop types, an annual cauliflower and a biennial Brussels sprout. A principal component analysis (PCA), based on line means, allowed all the traits to be grouped into distinct categories according to the first five Principal Components. These were: leaf traits (PC 1), flowering traits (PC2), axillary bud traits (PC3 and 5) and stem traits (PC4). Between zero and four putative QTL were located per trait, which individually explained between 6% and 43% of the additive genetic variation, using the multiple-marker regression approach to QTL mapping. For lamina width, bare petiole length and stem length two QTL with opposite effects were detected on tine same linkage groups. Intra- and inter-specific comparative mapping using RFLP markers identified a QTL on linkage group O8 accounting for variation in vernalisation, which is probably synonymous with a QTL detected on linkage group N19 of Brassica napus. In addition, a QTL for petiole length detected on O3 of this study appeared to be homologous to a QTL detected on another B. oleracea genetic map (Camargo et al. 1995).
AB - A segregating population of F-1-derived doubled haploid (DH) lines of Brassica oleracea was used to detect and locate QTLs controlling 27 morphological and developmental traits, including leaf, flowering, axillary bud and stem characters. The population resulted from a cross between two very different B. olerczcea crop types, an annual cauliflower and a biennial Brussels sprout. A principal component analysis (PCA), based on line means, allowed all the traits to be grouped into distinct categories according to the first five Principal Components. These were: leaf traits (PC 1), flowering traits (PC2), axillary bud traits (PC3 and 5) and stem traits (PC4). Between zero and four putative QTL were located per trait, which individually explained between 6% and 43% of the additive genetic variation, using the multiple-marker regression approach to QTL mapping. For lamina width, bare petiole length and stem length two QTL with opposite effects were detected on tine same linkage groups. Intra- and inter-specific comparative mapping using RFLP markers identified a QTL on linkage group O8 accounting for variation in vernalisation, which is probably synonymous with a QTL detected on linkage group N19 of Brassica napus. In addition, a QTL for petiole length detected on O3 of this study appeared to be homologous to a QTL detected on another B. oleracea genetic map (Camargo et al. 1995).
KW - genetic analysis
KW - QTL
KW - developmental traits
KW - linkage mapping
KW - Brassica vegetables
UR - http://www.scopus.com/inward/record.url?scp=0036945705&partnerID=8YFLogxK
U2 - 10.1007/s001220100743
DO - 10.1007/s001220100743
M3 - Article
SN - 1432-2242
SN - 1432-2242
SN - 1432-2242
SN - 1432-2242
SN - 1432-2242
VL - 104
SP - 601
EP - 609
JO - Theoretical and Applied Genetics
JF - Theoretical and Applied Genetics
IS - 4
ER -