Investigation of new sugar beet hybrids by tolerance indices in salt condition

Document Type : Research Paper

Abstract

In order to evaluate of new sugar beet hybrids for salt tolerance, 20 single cross hybrids produced by crosses between 5 diploid pollinators as male and 4 cytoplasmic male sterile as females ( caused by factorial design) along with parents were investigated in Rudasht salinity research station in 2012 and 2013. In each year, genotypes were studied in two experiments under saline (EC for water and soil about 12 and 8 dS/m respectively) and non-saline field conditions (EC for water and soil about 4 dS/m) using a randomized complete block design with two and three replications in first and second year, respectively. Four salt tolerance indices including salt tolerance index (STI), field emergency potential (FEP), beet tolerance index (BTI) and drought tolerance index (DTI) were calculated based on sugar yield in stress and non-stress condition. Regression analysis of sugar yield in two conditions with these indices showed that STI and BTI had significantly positive relationship coefficient with sugar yield under both stress and non-stress conditions suggesting that these indices are more efficient for determining salt tolerant genotypes. In based on the results of cluster analysis, hybrids 2×3, 3×1, 5×3 and 5×4 were recognized as salt tolerant hybrids with high yield and hybrids 1×1, 2×4, 4×3, 3×2 and 5×2 were introduced as susceptible hybrids with low yield for salinity condition.

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References
 
[1] Ebrahimian, H. R. (2010). Breeding for development of sugar beet salt tolerant Diploid pollinators. Sugar Beet Seed Institute, Final Report, 31 pages, (in Farsi).
[2]. Ebrahimian, H. R., Ranji, Z., Rezaei. M. & Abbasi, Z. (2008). Screening of sugar beet genotypes under salt condition in greenhouse and field. Sugar beet research, 24, 1-21.
[3]. Ahmadi, M. (2012). Study on characteristics related to drought tolerance in improved sugar beet population. PhD Thesis, College of Agriculture, Islamic Azad University of Science and Research of Tehran, (in Farsi).
[4]. Fotuhi, K., Mesbah, M., Sadeghian, S.Y., Ranji, Z., & Orazizadeh, M. (2007). Evaluation of salinity tolerance in sugar beet genotypes. Sugar Beet Research, 22, 1-18, (in Farsi).
[5]. Abbasi, Z. & Rezaei. M. (2014). Development of sugar beet salt tolerant triploid hybrids. Sugar Technology, DOI: 10. 1007/s 12355–014–0309-2.
[6]. Ahmadi, M., Majidi Heravan, E., Sadeghian, S.Y., Mesbah, M. & Darvish, F. (2011). Drought tolerance variability in S1 pollinator lines developed from a sugar beet open population. Euphytica, 178, 339-349.
[7]. Annicchiarico, P. (2002). Genotype × environment interactions. Challenges and opportunities for plant breeding and cultivar recommendations, In: Kang MS (Ed.), Quantitative genetics, genomics and plant breeding, CABI Publishing, Wallingford.
[8]. Betran, F.J., Beck, D., Banziger, M. & Edmeades, G.O. (2003). Genetic analysis of inbred and hybrid grain yield under stress and non stress environments in tropical maize. Crop Science, 43, 807-817.
[9]. Beyene, Y., Mugo, S., Semagn, K., Asea, G., Trevisan, W., Tarekegne, A. & Chavangi., A. (2013). Genetic distance among doubled haploid maize lines and their testcross performance under drought stress and non-stress conditions. Euphytica, 192, 379-392.
[10]. Blum, A., Sinmena, B., & Ziv, O. (1980). An evaluation of seed and seedling drought tolerance screening tests in wheat. Euphytica, 29(3), 727-736.
[11]. Dadkhah, A. (2011). Effect of salinity on growth and leaf photosynthesis of two sugar beet (Beta vulgaris L.) cultivars. Journal of Agricultural Science and Technology, 13, 1001-1012.
[12]. Genc, Y., McDonald, G. K. & Tester, M. (2007). Reassessment of tissue Na+ concentration as a criterion for salinity tolerance in bread wheat. Plant, Cell & Environment, 30, 1486-1498.
[13]. Ghoulam, C., Foursy, A.& Fares. K. (2002). Effects of salt stress on growth, inorganic ions and proline accumulation in relation to osmotic adjustment in five sugar beet cultivars. Environmental and Experimental Botany, 47, 39-50.
[14]. Hasthanasombut, S., Ntui, V., Supaibulwatana, K., Mii, M. & Nakamura, I. (2010) Expression of Indica rice OsBADH1 gene under salinity stress in transgenic tobacco. Plant Biotechnology Reports, 4, 75-83.
[15]. Hu, T., Zhang, X. Z., Sun, J. M., Li, H. Y., & Fu, J. M. (2014). Leaf functional trait variation associated with salt tolerance in perennial ryegrass. Plant Biology, 16(1), 107-116.
 [16]. Juste, A., Lievens, B., Frans, I., Marsh, T.L., Klingeberg, M., Michiels, C.W. & Willems, K.A. (2008) Genetic and physiological diversity of Tetragenococcus halophilus strains isolated from sugar- and salt-rich environments. Microbiology, 154, 2600-2610.
[17]. Kopittke, P. M., Blamey, F. P. C., Kinraide, T. B., Wang, P., Reichman, S. M., & Menzies. N. W. (2011). Separating multiple, short-term, deleterious effects of saline solutions on the growth of cowpea seedlings. New Phytologist, 189, 1110-1121.
[18]. Läuchli, A. & Epstein, E. (1990). Plant responses to saline and sodic conditions, In: Tanji KK (Ed.), Agricultural salinity assessment and management, ASCE manuals and reports on engineering practice, ASCE New York, pp. 113-137.
[19]. McGrath, J. M., Elawady, A., El-Khishin, D., Naegele, R. P., Carr, K.M., & Reyes,.B., (2008). Sugar beet germination: Phenotypic selection and molecular profiling to identify genes involved in abiotic stress response. Proc. IVth IS on seed. Transplant and Stand Establishment of Hort. Crops. Ed. D.I.Leskovar. Acta Hort.782 .ISHS 2008
[20]. Mohammadi, R., Amri, A. & Nachit, M. (2011b) Evaluation and Characterization of International Durum Wheat Nurseries under Rainfed Conditions in Iran. International Journal of Plant Breeding, 5, 94-100.
[21]. Mohammadi, R., Armion, M., Kahrizi, D. & Amri, A. (2010). Efficiency of screening techniques for evaluating durum wheat genotypes under mild drought conditions. International Journal of Plant Production, 4(1), 11-24.
[22]. Najafian, G. (2009) Drought tolerance indices, their relationships and manner of application to wheat breeding programs. In: Mohammadi R, Haghparast R (Eds) Plant Science in Iran. Middle Eastern and Russian Journal of Plant Science and Biotechnology, 3, 25-34.
[23]. Nouri, A., Etminan, A., Teixeira, da Silva, J. A., & Mohammadi, R. (2011) Assessment of yield, yield-related traits and drought tolerance of durum wheat genotypes (Triticum  turjidum var. durum Desf.). Australian Journal of Crop Science, 5 (1), 8-16.
[24]. Ober, E. S., Clark, C. J. A., Bloa, M. L., Royal, A., Jaggard, K. W., and Pidgeon, J. D. (2004). Assessing the genetic resources to improve drought tolerance in sugar beet: agronomic traits of diverse genotypes under droughted and irrigated conditions. Field Crop Research, 90, 213-234.
[25]. Ober, E.S. & Rajabi, A. (2010). Abiotic Stress in Sugar Beet. Sugar Technology, 12, 294-298. [26]. Rajabi, A., Griffiths, H., E. S., Ober, W., Kromdijk, and J. D. Pidgeon, 2008. Genetic characteristics of water-use related traits in sugar beet. Euphytica, 160, 175-187.
[27]. Saccomani, M., Stevanato, P., Trebbi, D., McGrath, J.M. & Biancardi, E. (2009) Molecular and morpho-physiological characterization of sea, ruderal and cultivated beets. Euphytica, 169,19-29.
[28]. Sadeghian, S.Y., Fazli, T., Mohamadian, R.& Taleghani, D. (2000) Genetic variation for drought stress in sugarbeet. Journal of Sugar Beet Research, 37, 55-77, (in Farsi).
[29]. Schneider, K., Schäfer-Pregl, R., Borchardt, D. C., and Salamini, F. (2002). Mapping QTLs for sucrose content, yield and quality in a sugar beet population fingerprinted by EST-related markers. Theoretical and Applied Genetics, 104,1107-1113.
[30]. Shiri, M., Aliyev, R. T., and Choukan, R., (2010). Water stress effects on combining ability and gene action of yield and genetic properties of drought tolerance indices in Maize. Research Journal of Environmental Sciences,(4), 75-84.
[31]. Tavakoli, E., Fatehi, F., Rengasamy, P., & Glenn, K. M., (2012). A comparision of hydroponic and soil-based screening methods to identify salt tolerance in the field in barley. Journal of Experimental Botany, 63, 3853-3868.
[32]. Wu, G.-Q., Liang, N., Feng, R.-J. & Zhang, J.-J. (2013). Evaluation of salinity tolerance in seedlings of sugar beet (Beta vulgaris L.) cultivars using proline, soluble sugars and cation accumulation criteria. Acta Physiology Plant, 35, 2665-2674.