بررسی تنوع ژنتیکی و روابط بین صفات زراعی در لاین‌های عدس

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه شهرکرد

2 شهرکرد

چکیده

آگاهی‌داشتن از میزان تنوع ژنتیکی و ارتباط بین صفات، از اهمیت ویژه‌ای در پیشبرد تحقیقات به‌نژادی و انتخاب ژنوتیپ‌های مطلوب، برخوردار است. از این‌رو، به‌منظور بررسی تنوع ژنتیکی و شناسایی روابط بین عملکرد دانه و برخی صفات زراعی در لاین‌های عدس، آزمایشی در قالب طرح لاتیس ساده 10×10 با دو تکرار در مزرعه تحقیقاتی دانشکده کشاورزی دانشگاه شهرکرد در سال زراعی 92-1391 اجرا گردید. به دلیل عدم معنی‌دارشدن اثر بلوک‌های ناقص درون هر تکرار برای کلیه صفات، داده‌ها به‌صورت طرح بلوک‌های کامل تصادفی مورد تجزیه و تحلیل قرار گرفتند. تجزیه واریانس حاکی از وجود تنوع بالا در بین لاین‌های مورد مطالعه از لحاظ کلیه صفات بود. نتایج حاصل از مقایسه میانگین صفات نشان داد لاین‌های ILL590، ILL947، ILL3963، ILL2795، ILL461، ILL459، ILL353 و ILL5888 از لحاظ عملکرد دانه و سایر صفات، برتر از سایرین بودند. بیشترین مقدار ضریب تنوع ژنتیکی، وراثت‌پذیری عمومی و پیشرفت ژنتیکی برای صفات تعداد غلاف در بوته، وزن غلاف در بوته، عرض برگ و عملکرد زیستی به‌دست آمد. نتایج حاصل از بررسی همبستگی‌های ساده نشان داد که تعداد و وزن غلاف در بوته، تعداد روز از کاشت تا گلدهی و رسیدگی، ازجمله صفات مهم و مؤثر بر روی عملکرد دانه بودند. تجزیه به عامل‌ها با استفاده از 13صفت زراعی، نشان از انتخاب چهار عامل داشت که در مجموع 97/77درصد از تنوع کل را توجیه کردند. تجزیه خوشه‌ای به‌روش Ward، لاین‌های مورد بررسی را در هشت خوشه قرار داد و لاین‌های برتر در خوشۀ هشتم قرار گرفتند.

کلیدواژه‌ها

عنوان مقاله [English]

Study of genetic diversity and relationships between agronomic traits in lentil

نویسندگان [English]

  • Mohammad Hassan Rahimi 1
  • Saadolah Houshmand 1
  • Mahmoud Khadambashi 2
  • Narges Ghasemi Siani 2
1 University of Shahrekord
2 University of Shahrekord
چکیده [English]

Introduction
Food legumes with high amounts of protein are known as the second largest source of human food. Lentil (Lens culinaris Medik.) have large amounts of protein (28%), micronutrients and vitamins in its seeds and is one of the beans in the world that is highly consumed in human diets. Also, its straw contains 2% minerals and 59% carbohydrates and considered valuable in animal feeding. Study of the genetic diversity is one of the most important steps in plant breeding program, so that the genetic diversity is considered as the basis of selection. By studying the diversity, the relationships between traits can be understood, too, and the best assays for high yielding are selected. In this regard, the morphological markers are the selection criteria. As reviewed above, the present research was carried out for studying the genetic diversity of 100 lines of lentil in terms of agro-morphological, determining the relationship between seed yield and other traits and selecting the superior pure lines using multivariate statistics methods.
 
Materials & Methods
To evaluate the 100 lines of lentil that were imported from ICARDA, an experimental field was conducted in research station of Shahrekord University in based on simple lattice 10×10 with two replications at 2012-13 cropping season. Because of the incomplete blocks within each repeat for all characteristics were non-significant, the data were analyzed as the randomized complete block design. The studied pure lines were cultivated in late winter in 3-5cm depth and 10cm intervals on the plots which consisted of 2 rows of 1m length, and 30cm between rows. During the growth season, the weeding was done manually in several times. During the study, days to flowering and days to maturity were recorded. After the physiological maturity, 10 plants of each plot were harvested and some traits such as 100 seed weight (g), plant height (cm), number of pods per plant, weight of pods per plant (g), leaf length (cm), leaf width (cm), seed diameter (mm), stem diameter (mm), biological yield per plant (g), RWC (%) and seed yield (kg/ha) were measured. Analysis of variance, comparison of means, correlation analysis, cluster analysis, factor analysis, and estimate of Phenotypic coefficient of variability (PCV), Genotypic coefficient of variability (GCV), broad sense heritability (h2) and genetic advance (GA) were achieved to evaluate the yield performances, genetic diversity and the relationship between traits in pure lines of lentil in the present study. For above analysis, SAS software version 9.1 and SPSS software version 20 were used.
 
 
Results & Discussion
The results of analysis of variance showed that high genetic variation among studied lines as the differences between 100 pure lines were significant at 1% probability level. According to the means comparison, it was not observed a desirable line in terms of all studied traits but the superior pure lines (ILL590, ILL947, ILL3963, ILL2795, ILL461, ILL459, ILL353 and ILL5888) in terms of phonological characters, stem diameter, number of pods per plant, plant height and seed yield were identified. Number of pods per plant, weight of pods per plant, leaf width and biological yield had the highest values of GCV, h2 and GA. The correlation analysis indicated that seed yield had positive and significant correlation with number of pods per plant and weight of pods per plant at 1% probability level; while its relationship with days to flowering and days to maturity was negative and significant at 1% probability level. Thirteen agronomic traits have been classified into four groups which expressed 77/97% diversity of the total variation according to the factor analysis Each of the first, second, third and fourth components were able to allocate 26.16%, 25.37%, 17.30% and 9.13% respectively. Cluster analysis using Euclidean distance with Ward's method placed the studied lines into eight groups and desirable lines in Shahrekord climate were grouped on the cluster 8.
 
Conclusion
Identification of relationship between agronomic traits and genetic diversity can help the breeders to select the best traits and varieties. The results of this study showed significant genetic variation for agronomic traits in lines of lentil and lines ILL590, ILL947, ILL3963, ILL2795, ILL461, ILL459, ILL353 and ILL5888 had high genetic potential for increasing the seed yield. Also, the number and weight of pods per plant, days to flowering and maturity can be used to improve the seed yield in breeding programs.

کلیدواژه‌ها [English]

  • Cluster analysis
  • Correlation
  • Factor analysis
  • Genetic diversity
  • pure lines of lentil

مراجع

1. Ahamed, K.U., Akhter, B., Islam, M.R., Humaun, M.R., and Alam, M.J. 2014. Morphological characterization and genetic diversity in lentil (Lens culinaris Medikus ssp. Culinaris) germplasm. International Journal of Agricultural Research, Innovation and Technology 4(1): 70-76.
2. Ahmed, A. 2009. Genetic Diversity of Lentil (Lens culinaris). MSc. Thesis. Patuakhali Science and Technology University. Bangladesh.
3. Alam, A.K.M.M., Podder, R., and Sarker, A. 2011. Estimation of genetic diversity in lentil germplasm. Agrivita 33(2): 103-110.
4. Anjam, M.S., Ali, A., Iqbal, SH.M., and Haqqani, A.M. 2005. Evaluation and correlation of economically important traits in exotic germplasm of lentil. International Journal of Agriculture and Biology 7(6): 959-961.
5. Azizi Chakherchaman, Sh., Mostafaei, H., Hassanpanah, D., Kazemi Arbat, H., and Yarnia, M. 2009. Path analysis of seed yield and its components of lentil in rainfed condition. Journal Of New Agricultural Science 17: 45-56.
6. Bayoumi, T.Y. 2008. Genetic diversity among lentil genotypes for drought tolerance. Journal of Agricultural Investment 3: 25-35.
7. Chakraborty, M., and Haque, M.F. 2000. Genetic variability and component analysis in lentil (Lens culinaris Medik). Journal of Research, Birsa Agricultural University 12(2): 199-204.
8. FAOSTAT, F., 2014. Agriculture Organization of the United Nations. http://faostat.fao.org/site/567/default
9. Fehr, W.R. 1987. Principals of Cultivar Development: Theory and Technique. McMillan, New York.
10. Gautam, N.K., Singh, N., Iquebal, M.A., Singh, M., Akhtar, J., Khan, Z., and Ram, B. 2014. Genetic diversity analysis for quantitative traits in lentil (Lens culinaris Medik.) germplasm. Legume Research-An International Journal 37(2): 139-144.
11. Hoover, R., Hughes, T., Chung, H.J., and Liu, Q. 2010. Composition, molecular structure, properties, and modification of pulse starches: A review. Food Research International 43(2): 399-413.
12. Iqbal, A., Khalil, I.A., Ateeq, N., and Khan, M.S. 2006. Nutritional quality of important food legumes. Food Chemistry 97(2): 331-335.
13. John, P.W.M., and John, P.W. 1971. Statistical Design and Analysis of Experiments (No. 04; QA279, J6.). New York: Macmillan.
14. Kumar J., Basu, P.S., Srivastava, E., Chaturvedi, S.K., and Nadarajan, N. 2012. Phenotyping of traits imparting drought tolerance in lentil. Crop Pasture Science 63: 547-554.
15. Manly, B.F., 1994. Multivariate Statistical Methods: A Primer. CRC Press.
16. Mostafaei, H., Hssanpanah, D., and Shahriari, R. 2006. Adaptation of local and domesticated lentil genotypes in dry farming of Ardabil region. (Abstract). The First International Conference on the Theory and Practices in Biological Water Saving (ICTPB). 21-25 May, Beijing-China. http://www.conferene.ac.cn/ictpb.htm.
17. Muehlbauer, F.J., Cho, S., Sarker, A., McPhee, K.E., Coyne, C.J., Rajesh, P.N., and Ford, R. 2006. Application of biotechnology in breeding lentil for resistance to biotic and abiotic stress. Euphytica 147(1-2): 149-165.
18. Muhammed, A. 2012. Genetic Diversity in Plants (Vol. 8). Springer Science & Business Media.
19. Naroui Rad, M.R., Aghaei, M., Fanaei, H.R., and Ghasemi, M. 2009. The study of genetic variation of some morphologic and phenologic characters in lentil germplasms of warm and dry regions. Journal of Research and Development 78: 173-181. (In Persian with English Summary).
20. Nuri, M., Dashti, H., Maddah Hoseini, Sh., and Dehghan, E. 2014. Genetic diversity in the gene pool lentil using morphological traits in Bardsir. Iranian Journal of Field Crop Science 45(4): 541-551. (In Persian with English Summary).
21. Rahimi, M.H., Houshmand, S., and Khodambashi, M. 2016. Determination of the most important agronomic traits affecting seed yield in lentil (Lens culinaris Medik) recombinant inbred lines. Iranian Journal of Crop Sciences 18(2): 161-177. (In Persian with English Summary).
22. Rasmusson, D.C., and Phillips, R.L. 1997. Plant breeding progress and genetic diversity from de novo variation and elevated epistasis. Crop Science 37(2): 303-310.
23. Ritchie, S.W., Nguyen, H.T., and Holaday, A.S. 1990. Leaf water content and gas-exchange parameters of two wheat genotypes differing in drought resistance. Crop Science 30(1): 105-111.
24. Roy, S., Islam, M.A., Sarker, A., Malek, M.A., Rafii, M.Y., and Ismail, M.R. 2013. Determination of genetic diversity in lentil germplasm based on quantitative traits. Australian Journal of Crop Science 7(1): 14-21.
25. Ruisi, P., Longo, M., Martinelli, F., Di Miceli, G., Frenda, A.S., Saia, S., Carimi, F., Giambalvo, D., and Amato, G. 2015. Morpho-agronomic and genetic diversity among twelve Sicilian agro-ecotypes of lentil (Lens culinaris). Journal of Animal and Plant Sciences 25(3): 716-728.
26. Salehi, M., Haghnazari, A., Shekari, F., and Faramarzi, A. 2008. The study of seed yield and seed yield components of lentil (Lens culinaris Medik) under normal and drought stress conditions. Pakistan Journal of Biological Sciences 11(5): 758-762.
27. Singh, S.P., Gutierrez, J.A., Molina, A., Urrea, C., and Gepts, P. 1991. Genetic diversity in cultivated common bean: II. Marker-based analysis of morphological and agronomic traits. Crop Science 31(1): 23-29.
28. Singh, T., and Gupta, K.K., 2004. Genetic diversity for yield and related traits in lentil (Lens culinaris Medik.). Plant Archives 4(1): 39-43.
29. Sirohi, S.P.S., Yadav, R., and Singh, R. 2007. Genetic variability, correlations and path analysis of yield and its component characters in lentil (Lens culinaris Medik.). Plant Archives 7(1): 295-299.
30. Tadesse, T., Leggesse, T., Mulugeta, B., and Sefera, G. 2014. Correlation and path coefficient analysis of yield and yield components in lentil (Lens culinaris Medik.) germplasm in the highlands of Bale, Ethiopia. International Journal of Biodiversity and Conservation 6(1): 115-120.
31. Toklu, F., Biçer, B., and Karaköy, T. 2009. Agro-morphological characterization of the Turkish lentil landraces. African Journal of Biotechnology 8(17): 4121-4127.
32. Tyagi, S.D., and Khan, M.H. 2011. Correlation, path-coefficient and genetic diversity in lentil (Lens culinaris Medik) under rainfed conditions. International Research Journal of Plant Science 2(7): 191-200.
33. Upadhyaya, H.D., Bramel, P.J., and Singh, S. 2001. Development of a chickpea core subset using geographical distribution and quantitative traits. Crop Science 41: 206-210.
34. Whitt, S.R., Wilson, L.M., Tenaillon, M.I., Gaut, B.S., and Buckler, E.S. 2002. Genetic diversity and selection in the maize starch pathway. Proceedings of the National Academy of Sciences 99(20): 12959-12962.
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