Evaluation of reaction of some rice (Oryza sativa L.) genotypes to salinity stress at seedling stage

Majidi-Mehr, Ahmad; Amiri-Fahliani, Reza

doi:10.22077/escs.2020.2468.1649

Document Type : Original Article

Authors

¹ Ph. D. Student, Dept. of Plant Breeding and Biotechnology, Faculty of Crop Production, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran

² Assistant Professor, Department of Agronomy & Plant Breeding, Faculty of Agriculture, Yasouj University, Yasouj, Iran

https://doi.org/10.22077/escs.2020.2468.1649

Abstract

Introduction
Rice (Oryza sativa L.) is the main staple food for more than half the world's population, and its world consumption has reached about 505.80 million tons in 2017 (IRRI, 2018). Rice cultivation has a special importance in Iran and its harvest area is estimated about 859100 hectares (Agricultural Statistics, 2017). Salinity is one of the environmental stressors that threaten not only the growth of plants, but also the extent of the distribution and diversity of plants in different ecosystems (Ismail and Horie, 2017). Currently, half of the arable lands of Iran (9.59 million hectares) are affected by salinity, which has a major impact on culturing area, and amount of the crop production, (Nabiollahi et al., 2017). Thus, the aim of this study was to evaluate the genetic variation, Heritability and Genetic Advance of among rice genotypes in terms of physiological characteristics and selection of the best parents for use in rice hybridization programs.

Material and Method
In order to study of diversity among 11 rice genotypes under salt stress condition plotted in an experiment as a split-plot based on randomized complete block design with three replications in summer 2012, at the farm of college of Agriculture, Yasouj University. The main plots were considered for 4 levels of salinity (0, 44, 88 and 132 m‌M), and the subplots for 11 rice genotypes including Gharib, Local Yasouj, Champa and Shahri Loudab, 304, Lenjan- Askari, Kamfirooze, Domsiah mamasani, Mossa-Tarom, Hassan-Serayi. The physiological parameters (F0, Fm, Fv, Fv‌/‌Fm, chlorophyll, soluble carbohydrates, protein and proline leaves) were evaluated one month after salinity stress application. Characteristics of chlorophyll fluorescence (F0, Fm, Fv, Fv‌/‌Fm) and chlorophyll leaves were recorded using a Flow cytometry Model (OS1-FL). Irigoyen et al (Irigoyen et al., 1992) method used for measurement of leaf soluble carbohydrates, Paquine and Lechasseur, (Paquine and Lechasseur, 1979) method for leaf proline, and Liu and Zhang (2000) method for leaf protein. At maturity stage, 2 plants of each pot were selected, and then plant grain yield was measured as the number of grains per spike.

Results and Discussion
Study of the genetic and phenotypic variation coefficients in salinity stress conditions showed that the maximum and minimum of these coefficients were belonged to grain yield and fluorescence characteristics, respectively. Grain yield under stress conditions showed a positive and significant correlation with Fv, chlorophyll and Fv / Fm, indicating that with increasing leaf chlorophyll content and Fv / Fm leaves, more photosynthesis is carried out,and thus the grain yield increases., leaf protein content had the highest, and F0 the lowest broad sense heritability, under stress conditions. Based on the results of cluster analysis, using the minimum variance method based on the 12 Euclidean distance, the genotypes under both stress and stress conditions were classified into 4 separate groups. In salinity stress conditions, a cross between the genotypes of the first and the fourth groups, which have the highest genetic distance in terms of the studied physiological traits, can be used for hybridization programs, transgressive segregation, and other breeding programs for finding tolerant genotypes to salinity.

Conclusion
In general, due to the results of cluster analysis in salinity stress conditions, in order to create dwarf, early and high yielding genotypes, the genotypes in the first and the fourth clusters can be considered as suitable and parents in the necessary and targeted crosses between them for improvement the important Physiological characteristics, and to access to the superior salinity tolerant and high product genotypes.

Keywords

References

Agricultural Statistics, 2017. Annual Report. Ministry of Agriculture Press. https://www.maj.ir/Index.aspx. [In Persian]

Azizpour, K., Shakiba, M. R., Khosh Kholgh Sima, N. A., Alyari, H., Moghaddam, M., Esfandiari, E., Pessarakli, M., 2010. Physiological response of spring durum wheat genotypes to salinity. Journal of plant nutrition. 33, 859-873.

Dubey, R. D., Rani. M., 1989. Influence of NaCl salinity on growth and metabolic status of protein and amino acids in rice seedling. Agronomy Journal. 162, 67-72.

Fallah, A., Farahmanfar, E., Moradi, F., 2015. Effect of salt stress on some morphological characters of two rice cultivars during different growth stages at greenhouse. Applied Field Crops Research. 28, 175-182.

Hoagland, D.R., Arnon, D.I., 1950. The water-culture for growing plants without soil. California Agriculture Experimental Statistics Circular, 3-32.

Hosseineyan-Khoshrou, H., Bihamta, M.R., Soltani, A., Aghaei, M.J. 2011. Study and comparison of some biochemical characteristics of different genotypes of Aegilops tauschii Iran. Iranian Journal of Field Crop Science. 42, 661-649. [In Persian with English Summary].

Hosseini, S.J., Tahmasebi, Z., Pirdashti, H., 2012. Screening of rice (Oryza sativa L.) genotypes for NaCl tolerance at early seedling stage. International Journal of Agronomy and Plant Production. 8, 274-283.

Irigoyen, J.J., Emerich, D.W., Sanchez-Diaz, M., 1992. Water stress induced changes in concentration of proline and total soluble sugars in modulated alfalfa (Medicago sativa L.) plants. Physiology of Plants. 84, 55-60.

IRRI. 2017. Stress and disease tolerance: Breeding for salt tolerance in rice. http://www.knowledgebank.irri.org/ricebreedingcourse/Breeding_for_salt_tolerance.htm.

IRRI. 2018. World rice statistics online query facilities. http://ricestat.irri.org:8080/wrsv3/entrypoint.htm.

Ismail, A.M., Horie, T., 2017. Genomics, Physiology, and Molecular Breeding Approaches for Improving Salt Tolerance. Annual Review of Plant Biology. 68, 405-434.

Javadipour, Z., 2012. Effect of salinity on germination and physiological characteristics of spring safflower (Charthamus tinctorius L.) MSc dissertation, Faculty of Agriculture, University Yasouj, 132p. [In Persian with English Summary]

Juan, M.R., Esteban, S., Pablo C.G., Luis, R. L., Rosa, M.R., Luis, R., 2002. Proline metabolism and NAD kinase activity in green bean plants subjected to cold-shock. Phytochemistry. 59, 473–478.

Kanawapee, N., Sanitchon, J., Lontom, W., Threerakulpisut. P., 2012. Evaluation of salt tolerance at the seedling stage in rice genotypes by growth performance, ion accumulation, proline and chlorophyll content. Plant and Soil. 358, 235-249.

Kao, W.Y., Tsai, T., Tsai, H., Shih, C.N., 2006. Response of three glycine species to salt stress. Environmental and Experimental Botany. 56, 120–125.

Krishnamurthy, S.L., Gautam, R.K., Sharma, P.C., Sharma, D.K., 2016. Effect of different salt stresses on agro-morphological traits and utilisation of salt stress indices for reproductive stage salt tolerance in rice. Field Crops Research. 190, 26-33.

Liu, C., Zhang, J., 2000. Heat stress injury in relation to membrane lipid per oxidation in creeping. Crop Science. 151, 135-143.

Majidi. M., Karimzadeh, G., Mahfoozi, S., 2008. Effects of low temperature and exogenous calcium on the quantum efficiency of photosystem II (Fv/Fm) and relative content of chlorophyll in cold susceptible and tolerant wheat cultivars. Pajouhesh & Sazandegi. 77, 175-181. [In Persian with English Summary].

Majidi-Mehr, A., Amiri-Fahliani, R., and Masoumi-Asl, A., 2014. Study of biochemical and chemical traits of different rice genotypes under salinity stress. Cereal Research. 4(1), 45-58. [In Persian with English Summary]

Majidi-Mehr, A., Khoshchereh, H., 2016. Study of different genotypes of rice using multivariate analysis. Journal of Plant Eco physiology. 30, 118-128. [In Persian with English Summary].

Mardani-Nezhad, S.H., Vazirpour, M., 2007. The study of seed viability, amount of proline and chlorophyll of local genotypes of rice under salt stress. Agroecology Journal. 3, 69-80. [In Persian with English Summary].

Mighani, F., Ebrahimzadeh, H., 2003. Effect salinity stress on carbohydrates wheat. Journal of Sciences University of Tehran. 2, 257-265. [In Persian].

Musavizadeh, Z.S., Najafi-Zarini, H., Hashemi-Petroudi, S. H.R., Kazemitabar, S.K., 2018. Assessment of proline, chlorophyll and malondialdehyde in sensitive and tolerant rice (Oryza sativa L.) cultivars under salt stress conditions. Journal of Crop Breeding, 10, 28-35.

Nabiollahi, K., Taghizadeh-Mehrjardi, R., Kerry, R., Moradian, S., 2017. Assessment of soil quality indices for salt-affected agricultural land in Kurdistan Province, Iran. Ecological Indicators. 83, 482-494.

Nemati, I., Moradi, F., Esmaeili, M.A., Gholizadeh, S., 2009. Ions and total soluble carbohydrates compartmentation in different leaves of rice genotypes in response to salt stress. Journal of Plant Production. 16, 143-158. [In Persian with English Summary].

Paquine, F., Lechasseur, P., 1979. Observations sure one method dosage 1a Libra-dens les de plants. Canadian Journal of Botany. 57, 1851-1854.

Rachoski, M., Gazquez, A., Calzadilla, P., Bezus, R., Rodriguez, A., Ruiz, O., Maiale, S., 2015. Chlorophyll fluorescence and lipid peroxidation changes in rice somaclonal lines subjected to salt stress. Acta Physiologiae Plantarum. 37, 117-128.

Rahman, M.A., Thomson, M.J., Shah-E-Alam, M., Ocampo, M., Egdane, J., Ismail, A.M., 2016. Exploring novel genetic sources of salinity tolerance in rice through molecular and pH ysiological characterization. Annals of Botany. 117, 1083-1097. [In Persian].

Saeidipour, S. 2015. Salinity effects on osmotic potential, soluble proteins and carbohydrates concentration in rice (Oryza sativa) genotypes at seedling stage. Agronomy Journal (Pajouhesh & Sazandegi). 108, 1-8. [In Persian with English Summary].

Sairam, R. K., Tyagi, A., 2004. Physiology and molecular biology of salinity stress tolerance in plants. Current Science. 86, 407-421.

Santos, C.V., 2004. Regulation of chlorophyll biosynthesis and degradation by salt stress in sunflower leaves. Scientia Horticulture. 103, 93–99.

SAS Institute. 2002. SAS user’s guide: Statistics. Ver 9.1. SAS Institute Cary, NC.

Singh, D.P., Sarkar, R.K., 2014. Distinction and characterization of salinity tolerant and sensitive rice cultivars as probed by the chlorophyll fluorescence characteristics and growth parameters. Functional Plant Biology. 41, 727-736.

StatGraphics. 2019. Statistical analysis and data visualization system (revised version). Stat Point Technologies, Incorporation.

Vendruscolo, E.C.G., Schuster, I., Pilegg, M., Scapim, C.A., Molinari, H.B.C., Marur, C.J., Vieira, L.G.E., 2007. Stress-induced synthesis of proline confers tolerance to water deficit in transgenic wheat. Journal of Plant Physiology. 164(10), 1367-1376.

Zhang, Z.H., Liu, Q., Song, H.X., Rong, X.M., Abdelbagi, M.I., 2010. Responses of different rice (Oryza sativa L.) genotypes to salt stress and relation to carbohydrate metabolism and chlorophyll content. African Journal of Agricultural Research. 7, 19-27.

Zhao, G.Q., Ma, B.L., Ren, C.Z., 2007. Growth, gas exchange, chlorophyll fluorescence, and ion content of naked oat in response to salinity. Crop Science. 41, 123-13.

Environmental Stresses in Crop Sciences

Evaluation of reaction of some rice (Oryza sativa L.) genotypes to salinity stress at seedling stage

References

References

Volume 13, Issue 4
Open Access Policy
January 2021
Pages 1293-1306

Evaluation of reaction of some rice (Oryza sativa L.) genotypes to salinity stress at seedling stage

References

References

Volume 13, Issue 4 Open Access PolicyJanuary 2021Pages 1293-1306

Volume 13, Issue 4
Open Access Policy
January 2021
Pages 1293-1306