Environmental Stresses in Crop Sciences

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Evaluation of quinoa (Chenopodium quinoa Wild.) cultivars in saline conditions using germination indices in controlled environment

Document Type : Original Article

Authors

1 PhD Student of Crop Physiology, Shahid Chamran Univercity of Ahvaz, Iran

2 Professor, Department of Production Engineering and Plant Genetics, Shahid Chamran Univercity of Ahvaz, Iran

3 Associate Professor, Department of Production Engineering and Plant Genetics, Shahid Chamran Univercity of Ahvaz, Iran

4 Faculty Member of Seed and Plant Improvement Institute, Iran

Abstract

Introduction
About 6.8 million hectares of agricultural lands in the country have different degrees of salinity, of which 4.3 million hectares have only salinity limits. The response of plants to salt stress is complex and depends on various factors such as concentration and type of solutes, plant species, plant growth stage and environmental factors. The use of salinity tolerant cultivars is currently one of the most effective ways to exploit and increase yield in saline and low saline soils. Chenopodium quinoa Willd. is a native plant of the Andean region of South America that was cultivated there from 5,000 to 7,000 years ago. The Food and Agriculture Organization (FAO 2002) designated Quinoa as one of the most important crops for food security of the world's population in the last century. Most Quinoa cultivars are capable of growing in salinity at concentrations of 40 (dSm-1) and even higher. This salinity is too high for most crops. Increasing the concentration of NaCl in the nutrient solution, followed by increasing the osmotic potential, adsorption of Na+ and Cl- ions during seed germination causes cell damage and ultimately inhibits or reduces germination. Therefore, the purpose of this study was to evaluate the effect of salinity caused by the use of poor quality water on yield and yield components of Quinoa as well as germination components of different Quinoa cultivars.
 
Materials and methods
This study was carried out in cultivation in controlled environment (germination apparatus) at the Faculty of Agriculture, Shahid Chamran University, Ahvaz, Iran, in order to evaluate the reaction of cultivars and genotypes to salt stress conditions. In the experiment conducted under controlled conditions, the experimental treatments included salinity (NaCl) at six levels (0, 10, 20, 30, 40 and 50 dSm-1) and three genotypes and genotypes of Quinoa (Giz, Titicaca, Q26) was performed as factorial experiment in a completely randomized design with three replications. To find plant respanses and chose the best one using seed number and germination rate, percentage and germination rate, seed Vigor index, mean germination time, time to 10% germination, time to 50% germination and time to 90% germination were calculated according to the equations.
 

Results
The results of analysis of variance showed that salinity stress had a significant effect on germination percentage and rate, and other measured germination indices (p < 0.01). Interaction of cultivar and salinity stress on root length, stem length, root dry weight and shoot dry weight, seed vigor index, germination uniformity, D10, D50 at 1% and germination percentage at 5% were significant. With increasing salinity levels from the control treatment to the highest salinity level (50 dSm-1), the decreasing trend of root and shoot length as well as root and shoot dry weight was observed. Titicaca showed the highest germination percentage and the highest seed vigor index in control treatment. In the salinity-free treatment, Titicaca showed the best and worst yield in Q26 at 50 (dSm-1) for 10% germination. Among other cultivars, Titicaca showed the highest root and shoot length and the lowest root and shoot length at 50 (dSm-1) under non-salinity stress conditions. Titicaca cultivar had the highest and Giz cultivar had the lowest germination and root dry weight. Titicaca cultivar in control treatment showed the highest root and shoot length with an average of 5.53 and 5.57 cm, respectively, while in salinity treatment of 50 dS/m-1 with an average of 0.4 and 0.3 cm minimum root and shoot length. Also, the best uniformity in germination with 20.2 hours was observed in Titicaca cultivar in control treatment.
 
Conclusions
At low salinity levels, acceptable yield was observed but in sever salinity condition most of the crops could not grow during the phenological stages. According to the results of this study and the study of quinoa behavior and high tolerance of the plant in the germination stage in the face of salinity stress, to improve salinity resistance in crops through breeding programs, and further study of salinity defense mechanisms in susceptible cultivars It is recommended. It seems that despite the significant effectiveness of all three cultivars and significant reduction in germination indices at high salinity levels Titicaca cultivar had a higher tolerance threshold than the other two cultivars, indicating the diversity of cultivars in response to physiological processes to salinity stress. It is also possible to use this cultivar with further research into breeding and breeding programs of other sensitive quinoa cultivars.

Keywords

Main Subjects

References
Ashraf, M., Ali, Q., 2008. Relative membrane permeability and activities of some. Antioxidant enzymes as the key determinants of salt tolerance in canola (Brassica napus L.). Environmental and Experimental Botany. 63, 266–273.
Baisakh, N., Subudhi, P.K., Bhardwaj, P., 2008. Primary responses to salt stress in a halophyte, smooth cordgrass (Spartina alterniflora Loisel). Functional and Integrative Genomics. 8, 287-300.
Barrett‐Lennard, E.G., Norman, H. C., Dixon, K., 2016. Improving salt land revegetation through understanding the “recruitment niche”: potential lessons for ecological restoration in extreme environments. Restoration Ecology. 24, 91-97.
Bartels, D., Sunkar, R., 2005. Drought and salt tolerance in plants. Critical Reviews in Plant Science. 24, 23-58.
Boero, F.E., Gallardo, C., Gonzalez, J.A., 2000. Effect of NaCl on germination, growth, and soluble sugar content in (Chenopodium quinoa Willd.) seeds. Botanical Bulletin of Academia Sinica. 41, 27–34.
Chaves, M.M., Flexas, J. Pinheiro, C., 2009. Photosynthesis under drought and salt stress: regulation mechanisms from whole plant to cell. Annals of Botany. 103, 551-560
Cha-Um, S., Kirdmanee, CH., 2009. Effect of salt stress on proline accumulation, photosynthetic ability and growth characters in two maize cultivars. Pakistan Journal of Botany. 41, 87-98.
Ekiz, H., Yilmaz, A., 2003. Determination of the salt tolerance of some barley genotypes and the characteristics affecting tolerance. Turkish Journal of Agriculture and Forestry. 27, 253-260.
Ellis, R.H., Roberts, E.H., 1980. Improved equations for prediction of seed longevity. Annals of Botany. 45, 13-30.
Eisavand, H.R., Madah Arefi, H., Tavakol Afshari, R., 2007. Effects of various treatments on breaking seed dormancy of Astragalus siliquosus. Seed Science and Technology. 34, 747-752. [In Persain with English summary].
FAO, 2002. Crops and Drops, Making the Best Use of Water for Agriculture. FAO, Rome.
Farhoudi, R., Sharifzadeh, F., Poustini, K., Makkizadeh, M.T., Kochak pour, M., 2007. The effects of NaCl priming on salt tolerance in canola (Brassica napus) seedlings grown under saline conditions. Seed Science and Technology. 35, 754-759. [In Persain with English summary].
Ghanbari, E., Nejati, V., Khazaei, M., 2016. Antioxidant and protective effects of Royal jelly on histopathological changes in testis of diabetic rats. International Journal of Reproductive BioMedicine. 14, 519-526.
Gonzalez, J.A., Prado, F.E., 1992. Germination in relation to salinity and temperature in (Chenopodium quinoa Willd.). Agrochimica (Italy) 36, 101–107.
Hu, Y., Schmidhalter, U., 2005. Drought and salinity: a comparison of their effects on mineral nutrition of plants. Journal of Plant Nutriention and Soil Science. 168, 541–549.
Jacobsen, S., 1999. Evaluación de Accesiones de Quinua para la Tolerancia a Salinidad. Primer Taller Internacional Sobre Quinua: RECURSOS ENERGÉTICOS Y SISTEMAS DE PRODUCCIÓN. Lima, Peru, 10 – 14 de mayo, 1999. In: CD, Cultivos Andinos, FAO 2001.
Jacobsen, S.-E., Quispe, H., Mujica, A., 2001. Quinoa: an alternative crop for saline soil in the Andes. In: Scientist and Farmer-Partners in Research for the 21st Century. Program Report 1999–2000, pp. 403–408. CIP: Lima Peru.
Jamali, s., Sharifan, H., Hezarjaribi, A., Sepahvand, N.A., 2016. The effect of different levels of salinity on germination and growth indices of two cultivars of Quinoa. Journal of Water and Soil Conservation. 6(1), 87-98. [In Persain with English summary].
Khalesro, Sh., M. Aghaalikhani., 2007. Effect of salinity and water deficit stress on seed germination of forage sorghum and pearl millet. Pajouhesh and Sazandegi. 77, 153-163 [In Persain with English summary].
Koyro, H.W., Eisa, S.S., 2008. Effect of salinity on composition, viability and germination of seeds of Chenopodium quinoa Willd. Plant and Soil. 302, 79–90.
Malcolm, C., Lindley, V., O'leary, J., Runciman, H., Barrett-Lennard, E., 2003. Halophyte and glycophyte salt tolerance at germination and the establishment of halophyte shrubs in saline environments. Plant and Soil. 253, 171-185.
Maleki, P., Bahrami, H.A., Saadat, S., Sharifi, F., Dehghany, F., 2016. Germination of Quinoa (Chenopodium quinoa Willd.) under Salinity Stress. Quinoa for Future Food and Nutrition Security in Marginal Environments. ICBA, Dubai.
Mamedi A., Tavakkol Afshari R., Sepahvand, N.A., 2015. Quantifying seed germination response of quinoa (Chenopodium quinoa Willd.) under temperature and drought stress regimes. Iranian Journal of Field Crop Science. 48(3), 615-623. [In Persain with English summary].
Masoumi, A., Darvish, F., Daneshian, J., 2011. Chemical and biochemical responses of soybean (Glycine max L.) cultivars to water deficit stress. Australian Journal of Crop Science. 5, 214-221.
Momeni, A., 2010. Geoghephical distrbiotion and salinity level of Iranian soils. Irannian Journal of Siol Reseach. 24, 1-5. [In Persain with English summary].
Mostafavi, K., Sadeghi Geive, H., Dadresan, M. Zarabi, M., 2011. Effects of drought stress on germination indices of corn hybrids (Zea mays L.). International Journal of Agricultur Science. 1, 10-18.
Okcu, G., Kaya, M.D., Atak, M., 2005. Effects of salt and drought stresses on germination and seedling growth of pea (Pisum sativum L.). Turkish Journal of Agriculture and Forestry. 29, 237-242.
Panuccio, M.R., Jacobsen, S.E., Akhtar, S.S., Muscolo, A., 2014. Effect of saline water on seed germination and early seedling growth of the halophyte quinoa. Annals of Botany Plants 6: plu047; doi:10.1093/aobpla/plu047
Postini, K., Bieker, A., 1994. The photosynthesis reaction of two wheat varieties related to salt stress. Journal of Agricultral Science of Iran. 26. [In Persain with English summary].
Repo-Carrasco, R., Espinoza, C., Jacobsen, S. E., 2003. Nutritional value and use of the Andean crops quinoa (Chenopodium quinoa) and kaٌiwa (Chenopodium pallidicaule). Food Reviews International, 19, 179-189.
Sreenivasulu, N., Butarado, V. M., Gopal, M., Cuevas, R., Anacleto, R., Kavi Kishor, P., 2014. Designing climate-resilient rice with ideal grain quality suited for high-temperature stress. Journal of Experimental Botany. 66(7), 1737–1748
Soltani, A., Zeinali. E., Galeshi, S., Latifi, N., 2001. Genetic variation for and interrelationships among seed vigor traits in wheat from the Caspian Sea coast of Iran. Seed Science and Technology. 29, 653-662.
Taiz L. Zieger E., 2002. Plant Physiology. 3 rd Ed., Sunderland, Sinauer Associates, Inc.
Turhan A., Ozmen N., Serbeci M.S., Seniz V., 2011. Effects of grafting on different rootstocks on tomato fruit yield and quality. Horticultural Science. (Prague), 38, 142–149.
Xianzhao, L., Chunzhi, W., Qing, S., 2013. Screening for Salt Tolerance in Eight Halophyte Species from Yellow River Delta at the Two Initial Growth Stages. Hindawi Publishing Corporation. 2013. Pp 8.
Zeinali, E., Soltani, A., Galeshi, S., 2002. Response of germination components to salinity stress in Oilseed rape (Brasica napus L.). Iranian Journal Agriculture Science. 33, 137-145. [In Persian with English summary].
Environmental Stresses in Crop Sciences
Volume 14, Issue 2
Open Access Policy
June 2021
Pages 475-485
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History
  • Receive Date: 05 November 2019
  • Revise Date: 13 October 2020
  • Accept Date: 19 October 2020
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