Genetic Analysis of Salt Tolerance in Safflower (Carthamus tinctorius L.)

Abstract: Aim:The mode of agronomic traits inheritance was investigated in safflower (Carthamus tinctorius L.) in salt stress as a new report in this study.

“…According to the obtained results, the large proportion of δ 2 A to δ 2 D and dominance ratio (less than unity) indicated the predominance role of additive gene effects, rather than the dominance ones, in the genetic control of seeds per capitulum and seed mass in safflower. Our findings were consistent with previous reports (Mandal and Banerjee 1997;Shahbazi and Saeidi 2007;Nakhaei et al 2014).The comparison of the magnitude of δ 2 GCA (12.61) and δ 2 SCA (0.0017) and dominance ratio (1.01) for seed yield per plant indicated the additive -dominance genetic control of this trait ( Table 2). The previous studies observed the predominant role of dominance gene action for seed yield per plant (Singh et al 2008;Deedawat et al 2015) and additive gene action in salinity stress (Nakhaei et al 2014).…”

“…Our findings were consistent with previous reports (Mandal and Banerjee 1997;Shahbazi and Saeidi 2007;Nakhaei et al 2014).The comparison of the magnitude of δ 2 GCA (12.61) and δ 2 SCA (0.0017) and dominance ratio (1.01) for seed yield per plant indicated the additive -dominance genetic control of this trait ( Table 2). The previous studies observed the predominant role of dominance gene action for seed yield per plant (Singh et al 2008;Deedawat et al 2015) and additive gene action in salinity stress (Nakhaei et al 2014). So, this new type of genetic control for the seed yield of safflower per plant could be utilized by both breeding methods based on selection and hybridization.…”

Combining ability × environment interaction and genetic analysis for agronomic traits in safflower (Carthamus tinctorius L.): biplot as a tool for diallel data

“…According to the obtained results, the large proportion of δ 2 A to δ 2 D and dominance ratio (less than unity) indicated the predominance role of additive gene effects, rather than the dominance ones, in the genetic control of seeds per capitulum and seed mass in safflower. Our findings were consistent with previous reports (Mandal and Banerjee 1997;Shahbazi and Saeidi 2007;Nakhaei et al 2014).The comparison of the magnitude of δ 2 GCA (12.61) and δ 2 SCA (0.0017) and dominance ratio (1.01) for seed yield per plant indicated the additive -dominance genetic control of this trait ( Table 2). The previous studies observed the predominant role of dominance gene action for seed yield per plant (Singh et al 2008;Deedawat et al 2015) and additive gene action in salinity stress (Nakhaei et al 2014).…”

“…Our findings were consistent with previous reports (Mandal and Banerjee 1997;Shahbazi and Saeidi 2007;Nakhaei et al 2014).The comparison of the magnitude of δ 2 GCA (12.61) and δ 2 SCA (0.0017) and dominance ratio (1.01) for seed yield per plant indicated the additive -dominance genetic control of this trait ( Table 2). The previous studies observed the predominant role of dominance gene action for seed yield per plant (Singh et al 2008;Deedawat et al 2015) and additive gene action in salinity stress (Nakhaei et al 2014). So, this new type of genetic control for the seed yield of safflower per plant could be utilized by both breeding methods based on selection and hybridization.…”

Combining ability × environment interaction and genetic analysis for agronomic traits in safflower (Carthamus tinctorius L.): biplot as a tool for diallel data

Safflower (Carthamus tinctorius L.) Breeding

Inheritance of carthamin and carthamidin in safflower (Carthamus tinctorius L.)