Study of Genetical Correlation and Diversity of Morphological Traits Induced in Rice (Oryza sativa L.) Mutant Population of Hashemi Cultivar

Khazaie, Leila; Shirzadian Khoramabad, Reza; Ebadi, Ali-Akbar; Moumeni, Ali

doi:10.52547/pgr.7.1.4

[Home ] [Archive]

[ فارسی ]

Main Menu

Home

Journal Information

Articles archive

For Authors

For Reviewers

Registration

Contact us

Site Facilities

Search in website

Receive site information

Volume 7, Issue 1 (2020)

pgr 2020, 7(1): 47-62

Back to browse issues page

Study of Genetical Correlation and Diversity of Morphological Traits Induced in Rice (Oryza sativa L.) Mutant Population of Hashemi Cultivar

Leila Khazaie

, Reza Shirzadian Khoramabad ^*

, Ali-Akbar Ebadi

, Ali Moumeni

Department of Agricultural Biotechnology, Faculty of Agricultural Sciences, University of Guilan, Rasht, Iran , r.shirzadian@guilan.ac.ir

Abstract: (7046 Views)

Mutagenesis has been one of the important sources of genetic diversity and Plant mutants can be important bio-resources for crop breeding and functional genomics studies. Breeding conventional methods for generating of genetic variability are of low efficiency. We showed that treatment of seeds of rice(Hashemi cultivar) with 0.8% EMS for 8 h caused visible phenotypic variations on M2 rice mutant genotypes including flowering date, plant height, number of fertile tiller, panicle length, number of filled and unfilled grains per panicle, grain width and length, 100 grain weight and grain yield. The phenotypic variation coefficients of most traits found to be more than the genetic variation coefficients. The number of filled grains per panicle and seed length had the highest and lowest general heritability, respectivly. The seed yield had also high heritability. Analysis of correlation between different characteristics in the mutant genotypes showed that the number of fertile tillers and the number of unfilled grains per panicle had positive correlation with yield. Also, grain yield exhibited positive and significant correlation with panicle length, number of tillers and number of filled grains at genotypic level. In multiple regression analysis by stepwise method, number of tillers, number of filled grains per panicle, 100-grain weight, and grain width entered into the model, respectively, that explained 96 percent of grain yield variations. Results of grain yield and its components path coefficient analysis showed that the number of tiller had the highest direct effect (0.77) through than other traits on grain yield and, therefore it can be considered as major trait in grain yield improvement in rice. Also, based on results of this research and by using optimal selection index, mutant genotypes EM 18-17-5 and EM 15-14-1 were selected as superior mutant genotypes. This mutant population is expected to be serves as a genetical resource for understanding rice biology as well as for use in genetic improvement of quantitative traits.

Keywords: Rice, Genetics variability, Mutation, Index, Concentration, EMS

Full-Text [PDF 674 kb] (1099 Downloads)

Type of Study: Research | Subject: Population genetics
Accepted: 2020/02/27

References

1. Ahmadikhah, A., Shojaeian, H., Pahlevani, M.H. and Nayyeipasand, L. (2014). Study on ethyl methane sulfonate (EMS)-induced variability in morphological traits of rice and identification of mutant lines with high yield potential. Plant Products Research Journal, 21(2): 47-65 (In Persian).

2. Ahmadpour, S., Darvishzadeh, R. and Sofalian, O. (2017). Selection indices for yield improvement of sunflower under normal and salt stress conditions. Journal of Crop Breeding, 10(25): 91-100 (In Persian).

3. Akbarpour, O. (2017). Application of variance components estimators in plant breeding. Plant Genetic Researches, 4: 1-24 (In Persian).

4. Allah Gholipour, M. (1998). Correlation between agronomic traits in rice yield through path analysis. M.Sc. Thesis, Faculty of Agriculture, Tehran University, Karaj, Iran (In Persian).

5. Allah Gholipour, M. and Mohammad Salehi, M. (2003). Factor and path analysis in different rice genotypes. Seed and Plant Improvement Journal, 19(1): 76-86 (In Persian).

6. Azizi, H., Aalami, A., Esfahani, M. and Ebadi, A.A. (2015). The study of correlation and path analysis of grain yield and its related traits in rice (Oryza sativa L.) varieties and lines. Journal of Crop Breeding, 9(21): 36-43 (In Persian).

7. Baker, R.J. (1986). Selection Indices in Plant Breeding. CRC Press, Inc., Boca Raton, Florida, USA.

8. Chen, Y.L., Liang, H.L., Ma, X.L., Lou, S.L., Xie, Y.Y., Lu, Z.L., Chen, L.T. and Liu, Y.G. (2013). An efficient rice mutagenesis system based on suspension-cultured cells. Journal of Integrative Plant Biology, 55(2): 122-130.

9. Danesh Gilevaei, M., Samizadeh Lahiji, H. and Rabiei, B. (2015). Relationship between grain yield and its components and grouping of rice (Oryza sativa L.) recombinant inbred lines. Journal of Crop Breeding, 9(21): 257-272 (In Persian).

10. Dewey, K.D. and Lu, K.H. (1959). A correlation and path cofficioent analysis of components of crested wheatgrass seed production. Journal of Agronomy, 51: 515-520.

11. Domingo, C., Andres, F. and Talon, M. (2007). Rice cv. Bahia mutagenized population: a new resource for rice breeding in the Mediterranean basin. Spanish Journal of Agriculture Research, 5(3): 341-347.

12. Dorusti, H. (2000). Genetic diversity based on agronomic traits of rice promising lines. M.Sc. Thesis, Faculty of Agriculture, Islamic Azad University of Karaj, Karaj, Iran (In Persian).

13. Dorusty, H., Motahar, Y. and Ghanadha, M.R. (2004). Genetic diversity based on agronomic traits of advanced lines and rice varieties. Seed and Plant Production Journal, 20(2):137-147 (In Persian).

14. Farshadfar, A. (1997). Application of Quantitative Genetics in Plant Breeding, Volume II. Bostan Publications, Kermanshah, IR (In Persian).

15. Fazlalipour, M., Rabiei, B. Samizadeh Lahijih, H.A. and Rahim Souroush, H. (2007a). Use of coefficient path analysis for base and optimum selection indices in rice. Journal of Agricultural Science, 17(4): 97-112 (In Persian).

16. Fazlalipour, M., Rabiei, B. Samizadeh Lahijih, H.A. and Rahim Souroush, H. (2007b). Index selection in an F3 rice population. Iranian Journal of Agricultural Sciences. Journal of Agriculture, 38-1(2): 385-397 (In Persian).

17. Golparvar, A.R., Ghannadha, M.R., Zali, A.A. and Ahmadi, A. (2002). Evaluation of some morphologic traits as selection criteria for improvement of bread wheat. Journal of Crop Science, 4: 202-207 (In Persian).

18. Jahani, M., Nematzadeh, G.H. and Mohammadi Nejad, G.H. (2015). Evaluation of agronomic traits associated with grain yield in rice (Oryza sativa) using regression and path analysis. Journal of Crop Breeding, 7(16): 115-122 (In Persian).

19. Jankowicz-Cieslak, J. and Till, B.J. (2016). Chemical mutagenesis of seed and vegetatively propagated plants using EMS. Current Protocols in Plant Biology, 1: 617-635.

20. Jiang, Y., Cai, Z., Xie, W., Long, T., Yu, H. and Zhang, Q. (2012). Rice functional genomics research: Progress and implications for crop genetic improvement. Biotechnology Advances, 30: 1059-1070.

21. Kanra, O.P. and Brunner, H. (1970). Chemical mutagens. mode of action. in: manual in mutation breeding. FAO/IAEA. Technical Report Series, 119: 62-64.

22. Khademian, R. and Babaeian Jelodar, N.A. (2006). Mutagenic effects of gamma rays and ethyl methan solfonate (EMS) on agronomic characteristics of some Iranian rice cultivars. Proceeding of 9th National Iranian Crop Science Congress, 27-29 Aguust. Seed and Plant Improvement Campus, Karaj, Iran (In Persian).

23. Kundu, S. and Kundagrami, S. (2015). Estimation of path coefficient analysis to identify the yield contributing traits in rice (Oryza sativa L.) under saline and non-saline coastal regions of West Bengal. Journal Advances in Biology, 8(1): 1433-1438.

24. Luz, V.K., Silveira Silveira, S.F., Fonseca, G.M., Goli, E.L., Figueiredo, R.G., Baretta, D., Marini Kopp, M., Magalhes Junior, A.M., Maya, L.C. and Oliveira, A.C. (2015). Identification of variability for gronomically important traits in rice mutant families. Plant Breeding, 75 (1): 41-50.

25. Micke, A. (1999). Mutation and In vitro Mutation Breeding. Kalani Publishers, Ludhiana, IND.

26. Mohapatra, T., Robin, S., Sarla, N., Shehashayee, M., Singh, A.K., Singh, K., Singh, N.K., Amitha Mithra, S.V. and Sharma, R.P. (2014). EMS induced mutants of upland rice variety nagina22: generation and characterization. Proceedings of the Indian National Science Academy, 80: 163-172.

27. MVD. (2016). FAO/IAEA mutant variety database. Available online at: http://www-naweb.iaea.org/nafa/pbg/ index.html/

28. Majidi, Z., Babaeian-Jelodar, N.A., Ranjbar, G.A. and Bagheri, N.A. (2013). Study of induced variation by ethyl methane sulphonate and sodium azide on tarrom mahali rice cultivar. Journal of Crop Breeding, 5(12): 49-62 (In Persian).

29. Mohadesi, A., Bakhshipour, S., Yekta, M. and Poshtiban, M. (2017). Promising rice lines clustering based on morphological and agronomic traits. Agroecology Journal, 13(2): 73-83 (In Persian).

30. Momeni, A. (1996). Correlation and path analysis of some agronomic traits related to yield rice varieties and hybrids. M.Sc. Thesis, Faculty of Agriculture, Tehran University, Tehran, Iran (In Persian).

31. Nandan, R., Sweta, D. and Singh, S.K. (2010). Character association and path analysis in rice (Oryza sativa L.) genotypes. World Journal of Agricultural Sciences, 6(2): 201-206.

32. Ndou, N., Shimelis, H., Odindo, A. and Modi, A. (2015). Agro-morphological variation among two selected wheat varieties after ethyl methane-sulfonate mutagenesis. Research on Crops, 16(1): 27-36.

33. Rabiei, B., Valizadeh, M., Gharayazie, B. and Moghaddam, M. (2004). Evaluation of selection indices for improving rice grain shape. Field Crops Research, 89(2): 359-367 (In Persian).

34. Rahimi, M. and Rabiei, B. (2011). The application of selection indices on improvement of grain yield in rice (Oryza sativa L.). Agronomy Journal (Pajouhesh & Sazandegi), 90: 39-46 (In Persian).

35. Rahimsoroush, C., Mesbah, M., Hosseinzadeh, A. and Bozorgipour, R. (2004). Genetic variation and phenotypic cluster analysis for quantitative and qualitative traits in rice. Seed and Plant Production Journal, 20(2): 167-182 (In Persian).

36. Ravindra, V., Shreya, K., Singh Dangi, K., Usharani, G. and Siva Shankar, A. (2012). Correlation and path analysis studies in popular rice hybrids of India. International Journal of Scientific Research, 2(3): 1-5.

37. Sabouri, H. (2002). Path analysis of rice grain filling in different planting patterns. M.Sc. Thesis, Isfahan University of Technology, Isfahan, Iran (In Persian).

38. Sabesan, T., Suresh, R. and Saravanan, K. (2009). Genetic variability and correlation for yield and grain quality characters of rice grown in coastal saline low land of Tamilnadu. Electronic Journal of Plant Breeding, 1: 56-59.

39. Serrat, X., Esteban, R., Guibourt, N., Moysset, L., Nogués, S. and Lalanne, E. (2014). EMS mutagenesis in mature seed-derived rice calli as a new method for rapidly obtaining TILLING mutant populations. Plant Methods, 10: 5-18.

40. Shoshi Dezfoli, A.A. (1999). The estimated effect of genes correlated qualitative and quantitative traits in rice. M.Sc. Thesis, Faculty of Agriculture, University of Guilan, Rasht, Iran (In Persian).

41. Smith, H.F. (1936). A discriminant function for plant selection. Annals of Human Genetics, 7: 240-250.

42. Tanveer, U.H., Javaid, A., Shafaqat, N. and Ahmad, A. (2009). Morpho-Physiological response of rice (Oryza sativa L.) varieties to salinity stress. Journal of Botany, 41(6): 2943-2956.

43. Watto, K., Aslam, S., Shab, G. and Shabir, M. (2012). Ethyl methane sulphonate (EMS) induced mutagenic attempts to create genetic variability in Basmati rice. Journal of Plant Breeding and Crop Science, 4(7): 101-105

44. Zhao, X., Zhou, L. Ponce, K. and Ye, G. (2015). The usefulness of known genes/QTLs for grain quality traits in an Indica population of diverse breeding lines tested using association analysis. Rice, 8: 29-39.

Send email to the article author

Add your comments about this article

‎ 10.52547/pgr.7.1.4

‎ 20.1001.1.23831367.1399.7.1.3.0

Mendeley

Zotero

RefWorks

Khazaie L, Shirzadian Khoramabad R, Ebadi A, Moumeni A. Study of Genetical Correlation and Diversity of Morphological Traits Induced in Rice (Oryza sativa L.) Mutant Population of Hashemi Cultivar. pgr 2020; 7 (1) :47-62
URL: http://pgr.lu.ac.ir/article-1-139-en.html

Rights and permissions
	This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

Volume 7, Issue 1 (2020)

Back to browse issues page

Persian site map - English site map - Created in 0.06 seconds with 39 queries by YEKTAWEB 4642