Correlation, multiple regression and path analysis for some yield-related traits in safflower

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Research Paper 01/02/2014
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Correlation, multiple regression and path analysis for some yield-related traits in safflower

Moslem Bahmankar, Daryoosh Ahmadi Nabati, Massoud Dehdari
J. Bio. Env. Sci.4( 2), 111-118, February 2014.
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Abstract

Safflower (Carthamus tinctorius L.) is an important oilseed crop which is cultivated predominantly in semiarid and temperate regions of the world. The aim of this study was to use statistical methods of phenotypic correlation, multiple stepwise regressions and path analysis to evaluate the relationship between yield and components yield using 20 different safflower genotypes. Plant characters such as day to initiate flowering, day to 50% flowering, day to maturity, plant height, main head diameter, heads per plants, seeds per head, 1000-seed weight and seed yield per plants were main selected measurements for the data analysis. Phenotypic correlation indicated that seed yield per plants had highly positive correlation with 1000-seed weight (r=0.79**), main head diameter (r=0.77**) and heads per plants (r=0.49*). Stepwise multiple linear regression interpretation also indicated that 90% of variation in seed yield attributed to variation which arose from 1000-seed weight, heads per plants, main head diameter and plant height characters. The results of path analysis strongly suggested that 1000-seed weight; heads per plants and main head diameter contain positive direct effect on seed yield. Therefore, it could be concluded that number of head per plant, 1000-seed weight, main head diameter and plant height are putative morphological markers which can be considered as the desirable tools for screening elite safflower genotype under the field conditions.

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Acharya S, Dhaduk LK, Maliwal GL. 1994. Path analysis in safflower (Carthamus tinctorius L) under conserved moisture conditions. University Research Journal 20,154- 157.

Ahmadzade AR, Majidie E, Alizade B, Omidi AH. 2010. Study the Yield, Yield Components and Morphological Traits in the Spring Safflower (Carthamus tinctorius L.) Using Journal of new Agriculture Science. Journal of new Agriculture Science 6, 1-8.

Abd El-Latteif EA .2012. Evaluation of 25 safflower genotypes for seed and oil yields under Arid Environment in Upper Egypt. Asian Journal of Crop Science 1-8.

Bhatt GM. 1973. Significance of path coefficient analysis in determining the nature of character association. Euphytica 22, 338–343.

Chaudhary SK. 1990. Path analysis for seed yield in safflower (Carthamus tinctorius L.) in acid soil under mid altitude conditions. International Journal Tropical Agricultural 8, 129–132.

Dwivedi SL, Upadhyaya HD, Hegde DM. 2005. Development of core collection using geographic information and morphological descriptors in safflower (Carthamus tinctorius L.) germplasm. Directorate of Oilseed Research, Rajandra Nagar, Heyderabad 500 030, India. Genetic Resources and Crop Evolution 52, 821-830.

Golkar P, Arzani A, Rezaei AM. 2011. Determining relationships among seed yield, yield components and Morpho-phenological traits using multivariate analyses in safflower (Carthamus tinctorious L.). Annals of Biological Research 2, 162-169.

Knowles PF. 1969. Centers of plant diversity and conservation of crop germplasm Safflower. Economic Botany 23, 324-329.

Mokhtassi A, Akbar GA, Mirhadi MJ, Zand E, Soufizade S. 2006. Relationships among characters using correlation, principal components and path analysis in safflower (Carthamus tinctorious L.) Euphytica 148, 261-268.

Mozzafari K, Asadi AA. 2006. Relationships among characters using correlation, principal components and path analysis in safflower mutants sown in irrigated and drought stress condition. Asian Journal of Plant Sciences 5, 977-983.

Nie Z, Chen FT, Shi XC. 1993. Path analysis of character related to seed yield in safflower. Oil Crop of China 3, 26-29.

Nie Z, Shi XC, Chen FT, Chang C. 1987. A study on the heritability, genetic advance and genetic correlations of the main agronomic characters in safflower Oil Crops of China 2, 18–22.

Omidi Tabrizi AH. 2000. Correlation between characters and path analysis for grain and oil yield in spring safflower. Sesame and Safflower Newsletter 15, 78–83.

Pascual-Villalobos MJ, Albuquerque N. 1996. Genetic variation of a safflower germplasm collection grown as a winter crop in southern Spain. Euphytica 92, 327–332.

Prasad S, Agrawal RK. 1994. Correlation and path coefficients studies in safflower hybrids. Sesame and Safflower Newsletter 9, 69–75.

Prasad S, Chaudhary BR, Agrawal RK. 1993. Correlation and path analysis of yield and its components in safflower hybrids (Carthamus tinctorius L.). Sesame and Safflower Newsletter 8, 74–78.

Rafeaie F, Saeidi G. 2006. Genotypic and phenotypic relationships among agronomic characters and yield components in safflower (Carthamus tinctorious L.). Agriculture scientific journal 28,137-149.

Samonte SO, Wilson LT, McClung AM. 1998. Path analyses of yield and yield-related characters of fifteen diverse rice genotypes. Crop Science 38, 1130–1136.

Shabana R, Abd El Mohsen AA, Gouda HAH, Hafez HS. 2013. Impact of temperature fluctuation on yield and quality traits of different safflower genotypes. Scientific Research and Review Journal 1, 74-87.

Toker C, Cagirgan MI. 2004. The use of phenotypic correlations and factor analysis in determining characters for grain yield selection in chickpea (Cicer arietinum L.). Hereditas 140, 226-228.

Tuncturk M, Ciftici V. 2004. Relationships among traits using correlation and path coefficient analysis in safflower (Carthamus tinctorious L.) sowed different fertilization levels and row spacing. Asian Journal Plant Science 3, 683-686.

Walton PD. 1980. The production characteristics of Bromus inermis Leyss. And their inheritance. Advances in Agronomy 32, 341–369.