Evaluation of Physiological and Biochemical Characteristics of Four Canola (Brassica napus L.) Cultivars in drought condition

Document Type : Research Article

Authors

1 University of Shahed

2 Agricultural Biotechnology Research Institute of Iran

Abstract

Introduction
Rapeseed (Brassica napus L.) is one of the major crops cultivated mainly for oil, human consumption and renewable fuel all over the world. Drought stress is one of the most important abiotic factors which adversely affect growth, metabolism and yield of crops in semiarid and arid area. Drought stress during any particular growth stage of crops causes yield reduction. In order to evaluate the effect of drought stress on yield, physiological, morphological and biochemical characteristics of rapeseed in flowering stage, this field experiment was carried out in Yazd agricultural research institute during 2011-2012.
Materials and Methods
The experiment was conducted in split-plot design based on randomized complete blocks with three replications imposed. Irrigation was considered as the main plot at two levels including control (irrigation after 80 mm evaporation from class A pan) and stress in the anthesis stage (irrigation after 160 mm evaporation from class A pan) and cultivars (Oise, Triangle, Karun and SLM046) were considered as sub plots. Sampling was carried out 7, 12 and 26 days after drought stress imposed. In each plot, 7, 12 and 26 days after stop irrigation from flowering stage (drought stress treatment), 4-5 expanded leaves from above of canopy were harvested. Relative water content of leaves and stomatal conductance were recorded. Soluble carbohydrate and proline content were measured. The lipid peroxidation level of the leaves was determined by measuring the content of malondealdehyde. Yield and yield components (number of grains per pod, number of pod per plant and weight of 1000 grains) were recorded at maturity.
Results and Discussion
The results showed that drought and cultivar interaction on SPAD value was not significant after stress. The interaction of the drought on leaf relative water content was significant at 26 days after the stress. The results revealed that, drought stress led to a significant decrease in relative water content of leaves and stomata conductance in all cultivars. However, soluble carbohydrates and proline were increased after stress application. The interaction of drought on soluble carbohydrate was significant at 26 days after the stress.
Interaction of treatments on leaf proline content in each sampling period was significant. The highest content of proline was observed in SLM046 (11.76 mM g-1 fresh weight) and the lowest proline content was observed in Oise cultivar (6.01 mM g-1 fresh weight). MDA content was increased in stress conditions. The highest MDA content was observed in Oise cultivar (1.15 µM g-1 fresh weight) 26 days after the stress and the lowest MDA observed in SLM046 cultivar (0.695 µM g-1 fresh weight) 7days after the stress. Analysis of variance for yield and yield components under irrigation regimes showed that, interaction of treatments on grain yield and weight of 1000 grains was significant. Triangle and SLM046 cultivars had higher grain yield in compare to the other cultivars. SLM046 exhibited the highest stress tolerance and also contained the highest yield, grain weight, number of pod per plant, relative water content and stomata conductance among all the cultivars. In addition, the highest and the lowest yield were observed in cultivars SLM046 and Karun (2553and 2178 kg ha-1, respectively), following stress application. Water deficit stress on canola decreased the number of pods per plant and the number of grains per pod.

Conclusions
Occurrence of drought stress during flowering reduced the number of grains per pod and canola yield. The results showed that, there was significant difference between cultivars for crop yield, weight of thousands grains, relative water content, stomata conductance, proline and carbohydrate content. Increased carbohydrate and proline content as osmolites caused lower cell water potential. The cultivars had different response to drought stress and the the highest yield and RWC were observed in SLM046 cultivar. Sugar and proline in the cell, the cell water potential decreased. The drought tolerance of SLM046 was better than other cultivars and had the highest yield and Relative water content.

Keywords

References

1. Alyari, H., and Shekari, F. 2000. Oil seeds. Agriculture and Physiology. Amidi Publisher. Tabriz.
2. Bates, C. J., Waldern, R. P., and Teare, I. D. 1973. Rapid determination of free proline for water stress studies. Plant and Soil 39: 205-207.
3. Cechin, I., Rossi, S., Oliveira, V., and Fumis, T. 2006. Photosynthetic responses and proline content of mature and young leaves of sunflower plants under water deficit. Photosynthetica 44: 143-146.
4. Champolivier, I., and Merrien, A. 1996. Effects of water stress applied at different growth stages of Brassica napus L. var. oleifera on yield, yield components and seed quality. European Journal of Agronomy 5: 153-160.
5. Chaves, M. M., Flexas, J., and Pinheiro, C. 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany 103: 551-560.
6. Dehshiri, A. 1999. Canola Agriculture. Ministry of Jihad-e-Agriculture, Agricultural Research and Education Organization.
7. FAO. 2010. Food Outlook Global Market Analysis. http://www.Fao.org.
8. Farooq, M., Basra, S. M. A., Wahid, A., Ahmad, N., and Saleem, B. A. 2009. Improving the drought tolerance in rice Oryza sativa L. by exogenous application of salicylic acid. Agronomy and Crop Science 195: 237-246.
9. Ghamarnia, H., and Gowing, J. W. 2005. Effect of water stress on three wheat cultivars. ICID 21st European Regional Conference, 15-19 May, 2005 Frankfurt (Oder) and Slubica, Germany and Poland.
10. Heath, R. L., and Packer, L. 1968. Photoperoxidation in isolated chloroplast, kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics 125: 189-198.
11. Hosseini, P. 2007. Study the physiological effects of cold stress at seedling stage in rice genotypes. Ph.D thesis. Crop Physiology. Faculty of Agriculture. University of Shahid Chamran, Ahvaz. (in Persian with English abstract).
12. Jensen, C. R., Mogensen, V. O., Mortensen, G., Fieldsend, J. K., Milford, G. F. J., Andersen, M. N., and Thage, J. H. 1996. Seed glucosinolate, oil and protein contents of field grown rape Brassica napus L. affected by soil drying evaporation demand. Field Crop Researches 47: 93-105.
13. Kishor, P. B. K., Sangama, S., Amrutha, R. N., Laxmi, P. S., Naidu, K. R., Rao, K. R. S. S., Rao, S., Reddy, K. J., Theriappan, P., and Sreenivasulu, N. 2005. Regulation of proline biosynthesis, degradation, uptake and transport in higher plants: Its implications in plant growth and abiotic stress tolerance. Current sciences 88: 424-438.
14. Kumar, A., and Singh, D. P. 1998. Use of physiological indices as a screening technique for drought tolerance in oilseed Brassica species. Annual of Botany 81: 413-420.
15. Liang, C. H., and Feng, R. 2010. Identification and expression analysis of genes in response to high-salinity and drought stresses in Brassica napus L., Acta Biochimica et Biophysica Sinica 42: 154-164.
16. Liang, Y., Chen, Q., Liu, Q., Zhang, W., and Ding, R. 2003. Exogenous silicon (Si) increases antioxidant enzyme activity and reduces lipid peroxidation in roots of salt-stressed barley (Hordeumvulgare L.). Plant Physiology 160: 1157-1164.
17. Liu, F., and Stützel1, H. 2002. Leaf Expansion, Stomatal Conductance, and Transpiration of Vegetable Amaranth (Amaranthus sp.) in Response to Soil Drying. Journal of American Society of Horticultural Science 127 (5): 878-883.
18. Mahajan, M. A., and Samuels, H. H. 2005. Nuclear hormone receptor coregulator role in hormone action, metabolism, growth, and development. Endocrine reviews 26: 583-597.
19. MarjanovicJeromela, A., Marinkovic, R., Mijic, A., Zdunic, Z., Ivanovska, S., and Jankulovska, M. 2008. Correlation and path analysis of quantitative traits in winter rapeseed Brassica napus L. Agriculturae Conspectus Scientificus (ACS) 73: 13-18.
20. Mendham, N., Salisbury, P., Kimber, D., and McGregor, D. 1995. Physiology crop development, Growth and yield, in Brassica Oilseed: Prodution and Utilization, CAB International, Wallingford, Oxon. PP: 11-67.
21. Mujdeci, M., Senol, H., Cakmakci, T., and Celikok, P. 2011. The effects of different soil water matric suctions on stomatal resistance. Food Agriculture and Environment 9: 1027-1029.
22. Naseri, F. 1991. Oil Seeds. AstaneGhods Publisher. (in Persian).
23. Nasri, M., Khalatbari, M., Zahedi, H., Paknejad, F., and TohidiMoghadam, H. R. 2008. Evaluation of micro and macro elements in drought stress condition in cultivars of rapeseed Brassica napus L. American journal of Agricultural and Biological Science 3: 579-583.
24. Nielsen, D. C. 1997. Water use and yield of canola under dry land condition in the Central Great Plains. Production Agriculture 10: 303-313.
25. Omae H., Kumar A., Kashiviba, K., and Shono, M. 2007. Assessing drought tolerance of Snap bean Phaseolus vulgaris L. from genotypic differences in leaf water relations, shoot growth and photosynthetic parameters. Plant Production Science 10: 28-35.
26. Paseban-Islam, B., Shakiba, M. R., Neyshabouri, M. R., Moghaddam, M., and Ahmadi, M. R. 2000. Evaluation of physiological indices as screening technique for drought resistance in oilseed rape. Proceeding Pakistan Academic of Science 37: 143-152.
27. Patakas, A., Nikolaou, N., Zioziou, E., Radoglou, K., and Noitsakis, B. 2002. The role of organic solute and ion accumulation in osmotic adjustment in drought-stressed grapevines. Plant Science 163: 361-367.
28. Rao, I. M., Sharp, R. E., and Boyer, J. S. 1987. Leaf magnesium alters photosynthetic response to low water potentials in sunflower. Plant Physiology 84: 1214-1219.
29. Rao, M. S. S., and Mendham, N. J. 1991. Soil plant water relations of oilseed rape Brassica napus L. and B. campestris L. Agriculture Sciences117: 197-205.
30. Rashidi, S. H., Shirani Rad, A. M., Ayene Band, A., Javidfar, F., and Lak, S. H. 2012. Study of relationship between drought stress tolerances with some physiological parameters in canola genotypes Brassica napus L. Annals of Biological Research 3: 564-569.
31. Rezaei, V. 2004. Ministry of Jihad-e-Agriculture. Plant Protection Organization. Pest of Canola.
32. Robertson, M. J., and Holland, J. F. 2004. Production risk of canola in the semi-arid subtropics of Australia. Australian Journal of Agricultural Research 55: 525-538.
33. Sana, M., Ali, A., Malik, M. A., Saleem, M. F., and Rafiq, M. 2003. Comparative yield potential and pil content of different canola cultivars Brassica napus L. Proceeding. Pakistan Journal of Agronomy 2: 1-7.
34. Schlegel, H. G. 1956. Die VerwertungorganischerSäurendurch Chlorella imLicht. Planta. 47: 510-526.
35. Setter, T. L., Brain, A., Flannigan, B. A., and Melkonian, J. 2001. Loss of kernel set due to water deficit and shade in maize Carbohydrate supplies abscise acid and cytokinins. Crop Science 41: 1530-1540.
36. Shahrabi, B., Farahmandfar, E., Hassanloo, T., Shirani Rad, A. H., and Tabatabaee, S. A. 2013. Evaluation of drought tolerance in rapeseed (Brassica napus L.) varieties based on physiologic and agronomic characters. Electronic Journal of Crop Production 6 (4): 77-92.
37. Shokuhfar, A., Abufitilehnejad, S. 2013. The effect of drought stress on the physiological characteristics and agricultural biomass of the different varieties of Vignaradiata in Dezful. Crop Physiology Journal 17: 49- 59. (in Persian with English abstract).
38. Takeda, S., and Matsuoka, M. 2008. Genetic approaches to crop improvement responding to environmental and population change. Nature Reviews Genetics 9: 444-457.
39. Taylor, A. J., and Smith, C. J. 1992. Effect of sowing date and seeding rate on yield and yield Components of irrigated Canola Brassica napus L. grown on a red–brown earth in south eastern Australia. Crop and Pasture Science 43: 1629-1641.
40. Yadav, R. S., and Bhushan, C. H. 2001. Effect of moisture stress on growth and yield in rice genotypes. Indian journal of Agricultural Research 35: 104-107.
41. Yang, Y., Liu, Q., Wang, G. X., Wang, X. D., and Guo, J. Y. 2010. Germination osmotic adjustment and antioxidant enzyme activities of gibberellin pretreated Piceaasperata L. seeds under water stress. New Forest 39: 231-243.
42. Zhang, X., Fan, X., Li, C. H., and Nan, Z. H. 2010. Effects of cadmium stress onseed germination seedling growth and antioxidative enzymes in Achnatheruminebrians plants infected with a Neotyphodiumendophyte. Plant Growth Regulation 60: 91-97.
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Iranian Journal of Field Crops Research
Volume 13, Issue 3 - Serial Number 39
October 2015
Pages 583-597

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