Evaluation of the Effect of Different Irrigation Regimes on the Accumulation of Some Compatible Osmolytes and the Activity of Antioxidant Enzymes in Quinoa

Document Type : Research Article

Authors

1 Department of Plant Production and genetics, Faculty of Agriculture, University of Kurdistan

2 Crop and Horticultural Research Department, Kurdistan Agricultural and Natural resources Research and Education Center, AREEO, Sanandaj, Iran

Abstract

Introduction
The high nutritional value of quinoa and its ability to grow under adverse environmental conditions have led to an increase in the area under cultivation globally. Quinoa has attracted particular attention in recent years due to its ability to grow under adverse environmental conditions and its high nutritional value.  Water scarcity stress is one of the non-bioenvironmental stresses that has destructive effects on crops' development and yield. Morphological, physiological, and biochemical reactions of plants to water deficiency depend on several factors, including stress intensity, duration of stress, and plant growth stage. Increased proline content, glycine betaine, total carbohydrates, and decreased yield under water stress conditions have been reported in various quinoa studies. The low cost of growing quinoa and its relatively high price, on the one hand, and the need for low water and adaptation to difficult climatic conditions, on the other hand, have made quinoa cultivation very economical. Due to the lack of water resources in different parts of the country and the fact that few studies have been done on quinoa cultivation in our country, the present study was conducted to investigate the effect of different irrigation regimes on some biochemical parameters and quinoa yield.
Materials and Methods
An experiment was conducted to investigate the effect of irrigation intervals and amounts on the quinoa's physiological traits and yield at the University of Kurdistan research farm, located in Dehgolan plain. The experiment was arranged in a split-plot scheme based on randomized complete blocks design with three replications. Four irrigation intervals (4, 8, 12, and 16 days) were considered the main factor, and four irrigation levels (100%, 75%, 50%, and 25% of plant water requirement) were considered secondary factors. Giza1 cultivar, which was obtained from the Seed and Plant Improvement Institute, was used for cultivation. Traits such as the content of proline, glycine betaine, soluble carbohydrates, insoluble carbohydrates, catalase activity, peroxidase activity, and grain yield were studied. Data analysis of variance was performed using SAS 9.1 statistical software, and means were compared using the Duncan test at 5% probability level. Excel software was also used to draw the graphs.
Results and Discussion
The effect of irrigation intervals and levels were significant on all studied traits. The study results showed that by reducing the plant's available water and increasing the irrigation intervals, the amount of proline, glycine betaine, soluble carbohydrates, insoluble carbohydrates, peroxidase activity, and catalase activity were increased, but the grain yield was decreased. Increasing the irrigation intervals from 4 to 8 days did not significantly affect grain yield, but increasing the interval to 12 and 16 days reduced grain yield by 24.4 and 44.8%, respectively. The highest grain yield was observed at full irrigation treatment (1866.5 kg.ha-1) but there was no significant difference with the treatment of 75% of the plant water requirement. The rate of yield reduction in the treatment of 25% of plant water requirement compared to the control was about 56.5%.
Conclusions
The results showed that quinoa produced acceptable levels of yield even under severe drought stress, i.e., when the irrigation interval increases or the water availability decreases. Based on our results, one reason for this is stress reduction mechanisms by the quinoa plant, such as increasing the content of compatible osmolites and increasing antioxidant enzymes' activity.

Keywords

Main Subjects


  1. Aranjuelo, I., Molero, G., Erice, G., Christophe Avice, J., and Nogues, S. 2011. Plant physiology and proteomics reveals the leaf response to drought in alfalfa (Medicago sativa ). The Journal of Experimental Botany 62: 111-123.
  2. Ardalani, Sh., Saeidi, M., Jalali-Honarmand, S., Ghobadi, M. E., and Abdoli, M. 2014. The physiological responses and antioxidant enzyme activity in bread wheat genotypes under post anthesis drought tension. Crop Physiology Journal 6 (4): 45-59. (in Persian with English abstract).
  3. Ashraf, M. F. M. R., and Foolad, M. R. 2007. Roles of glycine betaine and proline in improving plant abiotic stress resistance. Environmental and Experimental Botany 59 (2): 206-216.
  4. Aziz, A., Akram, N. A., and Ashraf, M. 2018. Influence of natural and synthetic vitamin C (ascorbic acid) on primary and secondary metabolites and associated metabolism in quinoa (Chenopodium quinoa) plants under water deficit regimes. Plant Physiology and Biochemistry 123: 192-203.
  5. Bascunan-Godoy, L., Reguera, M., Abdel-Tawab, Y. M., and Blumwald, E. 2016. Water deficit stress-induced changes in carbon and nitrogen partitioning in Chenopodium quinoa Planta 243 (3): 591-603.
  6. Bates, L. S., Waldren, R. P., and Tear, I. B. 1973. Rapid determination of free proline for water-stress studies. Plant and Soil 39: 205-207.
  7. Bergmeyer, N. 1970, “Method of enzymatic analyse”, Academia Verlag Berlin 1: 636-647.
  8. Carvalho, L. G. D., Evangelista, A. W. P., Oliveira, K. M. G., Silva, B. M., Alves, M. D. C., Júnior, S., Miranda, W. L. 2013. FAO Penman-Monteith equation for reference evapotranspiration from missing data.
  9. Daryanto, S., Wang, L., and Jacinthe, P. A. 2017. Global synthesis of drought effects on cereal, legume, tuber and root crops production: A review. Agricultural Water Management 179: 18-33.
  10. Elewa, T. A., Sadak, M. S., and Dawood, M. G. 2017. Improving drought tolerance of quinoa plant by foliar treatment of trehalose. Agricultural Engineering International: CIGR Journal 19 (Special Issue): 245-254.
  11. Farooq, M., Wahid, A., Kobayashi, N., Fujita, D. B. S. M. A., and Basra, S. M. A. 2009. Plant drought stress: effects, mechanisms and management. In Sustainable agriculture (pp. 153-188). Springer, Dordrecht.
  12. Fghire, R., Ali, O. I., Anaya, F., Benlhabib, O., Jacobsen, S. E., and Wahbi, S. 2013. Protective antioxidant enzyme activities are affected by drought in Quinoa (Chenopodium quinoa Willd). Journal of Biology, Agriculture and Healthcare 3 (4): 62-68.
  13. Ford, K. L., Cassin, A., and Bacic, A. F. 2011. Quantitative proteomic analysis of wheat cultivars with differing drought stress tolerance. Frontiers in Plant Science 2: 1-11.
  14. Gamez, A. L., Soba, D., Zamarreño, Á. M., García-Mina, J. M., Aranjuelo, I., and Morales, F. 2019. Effect of water stress during grain filling on yield, quality and physiological traits of Illpa and Rainbow quinoa (Chenopodium quinoa) cultivars. Plants 8 (6): 1-15.
  15. Geerts, S., Raes, D., Garcia, M., Vacher, J., Mamani, R., Mendoza, J., and Taboada, C. 2008. Introducing deficit irrigation to stabilize yields of quinoa (Chenopodium quinoa). European Journal of Agronomy 28 (3): 427-436.
  16. Gendy, A. S. H., Said, Ali. Ahl, H. A. H., and Mahmoud, A. A. 2012. Growth, productivity and chemical constituents of roselle (Hibiscus sabdariffa) plants as influenced by cattle manure and biofertilizers treatments. Australian Journal of Basic and Applied Sciences 6 (5): 1-12.
  17. Gonzalez, J. A., Gallardo, M., Hilal, M., Rosa, M., and Prado, F. E. 2009. Physiological responses of quinoa (Chenopodium quinoa) to drought and waterlogging stresses: dry matter partitioning. Botanical Studies 50 (1): 35-42.
  18. Grieve, C. M., and S. R. Grattan. 1983. Rapid assay for determination of water soluble quaternary ammonium compounds. Plant Soil 70: 303-307.
  19. Habibi, G. 2013. Effect of drought stress and selenium spraying on photosynthesis and antioxidant activity of spring barley. Acta Agriculturae Slovenica 101 (1): 31-39.
  20. Hemeda, H. M., and Kelin, B. P. 1990. Effects of naturally occurring antioxidants on peroxidase activity of vegetables extracts. Journal of Food Science 55: 184-185.
  21. Jongrungklang, N., Toomsan, B., Vorasoot, N., Jogloy, S., Boote, K. J., Hoogenboom, G., and Patanothai, A. 2013. Drought tolerance mechanisms for yield responses to pre-flowering drought stress of peanut genotypes with different drought tolerant levels. Field Crops Research 144: 34-42.
  22. Kleijn, D., Treier, U. A., and Müller-Schärer, H. 2005. The importance of nitrogen and carbohydrate accumulation for plant growth of the alpine herb Veratrum album. New Phytologist 166: 565-575.
  23. Kooyers, N. J. 2015. The evolution of drought escape and avoidance in natural herbaceous populations. Plant Science 234: 155-162.‏
  24. Lehmann, S., Funck, D., Szabados, L., and Rentsch, D. 2010. Proline metabolism and transport in plant development. Amino Acids 39: 949-962.
  25. Miller, G. A. D., Suzuki, N., Ciftci‐Yilmaz, S. U. L. T. A. N., and Mittler, R. O. N. 2010. Reactive oxygen species homeostasis and signalling during drought and salinity stresses. Plant, Cell and Environment 33 (4): 453-467.
  26. Miranda-Apodaca, J., Yoldi-Achalandabaso, A., Aguirresarobe, A., Del-Canto, A., and Pérez-López, U. 2018. Similarities and differences between the responses to osmotic and ionic stress in quinoa from a water use perspective. Agricultural Water Management 203: 344-352.
  27. Nakabayashi, R., Yonekura‐Sakakibara, K., Urano, K., Suzuki, M., Yamada, Y., Nishizawa, T., and Michael, A. J. 2014. Enhancement of oxidative and drought tolerance in Arabidopsis by overaccumulation of antioxidant flavonoids. The Plant Journal 77 (3): 367-379.
  28. Nakano, Y., and Asada. K. 1981. Hydrogen proxide is scavenged by ascorbate-spesific proxidase in spinach chloroplasts. Plant Cell Physiology 22: 867-880.
  29. Naz, H., Akram, N. A., and Kong, H. 2020. Assessment of secondary metabolism involvement in water stress tolerance of quinoa (Chenopodium Quinoa) subjected to varying water regimes. Pakistan Journal of Botany 52 (5): 1553-1559.
  30. Parida, A. K., Dagaonkar, V. S., Phalak, M. S., and Aurangabadkar, L. P. 2008. Differential responses of the enzymes involved in proline biosynthesis and degradation in drought tolerant and sensitive cotton genotypes during drought stress and recovery. Acta Physiologiae Plantarum 30 (5): 619-627.
  31. Repo-Carrasco, R., Espinoza, C., and Jacobsen, S. E. 2003. Nutritional value and use of the Andean crops quinoa (Chenopodium quinoa) and kañiwa (Chenopodium pallidicaule). Food Reviews International 19 (1-2): 179-189.
  32. Sadiq, M., Akram, N. A., Ashraf, M., and Ali, S. 2017. Tocopherol confers water stress tolerance: sugar and osmoprotectant metabolism in mung bean [Vigna radiata (L.) Wilczek]. Agrochimica 61 (1): 28-42.
  33. Saeedipour, S., and Moradi, F. 2011. Effect of drought at the post-anthesis stage on remobilization of carbon reserves and some physiological changes in the fla leaf of two wheat cultivars differing in drought resistance. Journal of Agricultural Science 33: 81-92.
  34. Sami, F., Yousuf, M., Faizan, M., Faraz, A., and Hayat, S. 2016. Role of sugars under abiotic stress. Plant Physiology and Biochemistry 109: 57-61.
  35. Sarker, U., and Oba, S. 2018. Catalase, superoxide dismutase and ascorbate-glutathione cycle enzymes confer drought tolerance of Amaranthus tricolor. Scientific Reports 8 (1): 1-12.
  36. Sinha, S., and Saxena, R. 2006. Effect of iron on lipid peroxidation, and enzymatic and non-enzymatic antioxidants and bacoside-A content in medicinal plant Bacopa monnieriChemosphere 62 (8): 1340-1350.
  37. Song, Q., Liu, C., Bachir, D. G., Chen, L., and Hu, Y. G. 2017. Drought resistance of new synthetic hexaploid wheat accessions evaluated by multiple traits and antioxidant enzyme activity. Field Crops Research 210: 91-103.
  38. Talebnejad, R., and Sepaskhah, A. R. 2015. Effect of different saline groundwater depths and irrigation water salinities on yield and water use of quinoa in lysimeter. Agricultural Water Management 148: 177-188.
  39. Wang, G. P., Zhang, X. Y., Li, F., Luo, Y., and Wang, W. 2010a. Over accumulation of glycine betaine enhances tolerance to drought and heat stress in wheat leaves in the protection of photosynthesis. Photosynthetica 48 (1): 117-126.
  40. Wang, L. J., Fan, L., Loescher, W., Duan, W., Liu, G. J., Cheng, J. S., and Li, S. H. 2010b. Salicylic acid alleviates decreases in photosynthesis under heat stress and accelerates recovery in grapevine leaves Mbmc. Plant Biology 10 (1): 34.
  41. Yemen, E. W., and Willis, A. J. 1954. Estimation of carbohydrates in plant extracts by anthrone. Journal of Biochemistry 57: 508-514.
CAPTCHA Image
Volume 19, Issue 3 - Serial Number 63
October 2021
Pages 275-285
  • Receive Date: 20 January 2021
  • Revise Date: 26 June 2021
  • Accept Date: 05 July 2021
  • First Publish Date: 05 July 2021