Yıl 2023,
Cilt: 33 Sayı: 3, 354 - 362, 30.09.2023
Seval Eliş
,
Behiye Bicer
,
Mehmet Yıldırım
Kaynakça
- Alo, F., Furman, B. J., Akhunov, E., Dvorak, J., & Gepts, P. (2011). Leveraging genomic resources of model species for the assessment of diversity and phylogeny in wild and domesticated lentil. Journal of Heredity, 102(3), 315-329.
- Biçer, B.T., Akinci, C., Kizilgeçi, F., Albayrak, Ö., & Yildirim, M. (2018). Stability parameters in lentil genotypes. El-Cezeri, 5(2), 287-291.
- Bowonder, B., Ramana, K. V., Ravi, C., & Srinivas, C. (1987). Land use, waterlogging and irrigation management. Land Use Policy, 4(3), 331–341. https://doi.org/10.1016/0264-8377(87)90032-9
- radial oxygen loss from roots. Plant, Cell & Environment, 26(1), 17-36.
- FAO, (2022). Food and agriculture data. https://www.fao.org/faostat/en/#data. Access date: 29.09.2022.
- Lake, L., Izzat, N., Kong, T., & Sadras, V. O. (2021). High-throughput phenotyping of plant growth rate to screen for waterlogging tolerance in lentil. Journal of Agronomy and Crop Science, 207(6), 995–1005. https://doi.org/10.1111/JAC.12522
- Malik, A. I., Ailewe, T. I., & Erskine, W. (2015). Tolerance of three grain legume species to transient waterlogging. AoB PLANTS, 7. https://doi.org/10.1093/AOBPLA/PLV040
- Materne, M., & Siddique, K.H.M. (2009). Agroecology and crop adaptation. In the lentil: botany, production and uses (pp. 47-63). Wallingford UK: CABI, doi: 10.1079/9781845934873.0047.
- Mustroph, A., Boamfa, E.I., Laarhoven, L. J., Harren, F. J., Albrecht, G., & Grimm, B. (2006). Organ-specific analysis of the anaerobic primary metabolism in rice and wheat seedlings. I: Dark ethanol production is dominated by the shoots. Planta, 225, 103-114.
- Mustroph, A., Stock, J., Hess, N., Aldous, S., Dreilich, A., & Grimm, B. (2013). Characterization of the phosphofructokinase gene family in rice and its expression under oxygen deficiency stress. Frontiers in Plant Science, 4, 125.
- Osman, K.A., Tang, B., Wang, Y., Chen, J., Yu, F., Li, L., Han, X., Zhang, Z., Yan, J., Zheng, Y., Yue, B., & Qiu, F. (2013). Dynamic QTL analysis and candidate gene mapping for waterlogging tolerance at maize seedling stage. Plos One. 14;8(11):e79305. doi: 10.1371/journal.pone.0079305.
- Ozseven, İ., & Gençtan, T. (2018). The effect of long-term waterlogging on flag leaf chlorophyll content in some bread wheat (Triticum aestivum L.) genotypes. Journal of Aegean Agricultural Research Institute, 28(2), 1-16. https://dergipark.org.tr/en/pub/anadolu/issue/41816/504322.
- Pan, J., Sharif, R., Xu, X., & Chen, X. (2021). Mechanisms of waterlogging tolerance in plants: Research progress and prospects. Frontiers in Plant Science, 11, 627331.
- Paudel, G. P., Devkota, M., Keil, A., & McDonald, A. J. (2020). Climate and landscape mediate patterns of low lentil productivity in Nepal. Plos One, 15(4), e0231377.
- Prasanna, Y.L., & Rao, G.R. (2014). Effect of waterlogging on growth and seed yield in greengram genotypes. International Journal of Food, Agriculture and Veterinary Sciences, 4, 124-128.
- Setter, T.L., & Waters, I. (2003). Review of prospects for germplasm improvement for waterlogging tolerance in wheat, barley and oats. Plant and Soil, 253, 1-34.
- Solaiman, Z., Colmer, T.D., Loss, S.P., Thomson, B.D., & Siddique, K.H.M. (2007). Growth responses of cool-season grain legumes to transient waterlogging. Australian Journal of Agricultural Research, 58(5), 406-412.
- Wiraguna, E., Malik, A.I., & Erskine, W. (2017). Waterlogging tolerance in lentil (Lens culinaris Medik. subsp. culinaris) germplasm associated with geographic origin. Genetic Resources and Crop Evolution, 64, 579-586.
- Yavas, I., Unay, A., & Aydin, M. (2012). The waterlogging tolerance of wheat varieties in western of Turkey. The Scientific World Journal, vol: 2012, pages: 7, doi:10.1100/2012/529128.
- Zeroual, A., Baidani, A., & Idrissi, O. (2022). Drought Stress in Lentil (Lens culinaris, Medik) and Approaches for Its Management.. Horticulturae, 9(1), 1.
Waterlogging Response of Lentil Cultivars Grown in Greenhouse Throughout The Early Vegetative and Recovery Period
Yıl 2023,
Cilt: 33 Sayı: 3, 354 - 362, 30.09.2023
Seval Eliş
,
Behiye Bicer
,
Mehmet Yıldırım
Öz
Under conditions of global climate change, the frequency of climate anomalies is predicted to increase. One of these issues is the problem of waterlogging in agricultural areas as a direct result of the unexpected and severe rainfall that has occurred over the last decades. In this study, the morphological responses to waterlogging stress and the recovery capacity of the lentil cultivars were investigated. A waterlogging stress study was conducted in small water pools with four different lentil varieties (Çağıl, Fırat 87, Kafkas and Kayı). Lentil cultivars were exposed to waterlogging stress for 7 and 14 days in the same greenhouse conditions. Measurements were taken at the end of 7 and 14 days of waterlogging (W-7 and W-14) and during the recovery period after flowering (R-7 and R-14). Lentil cultivars and plant traits were negatively affected by waterlogging stress applications (W-7 and W-14). According to the study, 14-day waterlogging had a greater impact on lentil cultivars than 7-day waterlogging. Total biomass measured after flowering at R-7 and R-14 waterlogging decreased by about 31.5% and 49.3%, respectively. Çağıl cultivar had a tolerance to waterlogging stress, but Kafkas cultivar was sensitive to waterlogging stress.
Kaynakça
- Alo, F., Furman, B. J., Akhunov, E., Dvorak, J., & Gepts, P. (2011). Leveraging genomic resources of model species for the assessment of diversity and phylogeny in wild and domesticated lentil. Journal of Heredity, 102(3), 315-329.
- Biçer, B.T., Akinci, C., Kizilgeçi, F., Albayrak, Ö., & Yildirim, M. (2018). Stability parameters in lentil genotypes. El-Cezeri, 5(2), 287-291.
- Bowonder, B., Ramana, K. V., Ravi, C., & Srinivas, C. (1987). Land use, waterlogging and irrigation management. Land Use Policy, 4(3), 331–341. https://doi.org/10.1016/0264-8377(87)90032-9
- radial oxygen loss from roots. Plant, Cell & Environment, 26(1), 17-36.
- FAO, (2022). Food and agriculture data. https://www.fao.org/faostat/en/#data. Access date: 29.09.2022.
- Lake, L., Izzat, N., Kong, T., & Sadras, V. O. (2021). High-throughput phenotyping of plant growth rate to screen for waterlogging tolerance in lentil. Journal of Agronomy and Crop Science, 207(6), 995–1005. https://doi.org/10.1111/JAC.12522
- Malik, A. I., Ailewe, T. I., & Erskine, W. (2015). Tolerance of three grain legume species to transient waterlogging. AoB PLANTS, 7. https://doi.org/10.1093/AOBPLA/PLV040
- Materne, M., & Siddique, K.H.M. (2009). Agroecology and crop adaptation. In the lentil: botany, production and uses (pp. 47-63). Wallingford UK: CABI, doi: 10.1079/9781845934873.0047.
- Mustroph, A., Boamfa, E.I., Laarhoven, L. J., Harren, F. J., Albrecht, G., & Grimm, B. (2006). Organ-specific analysis of the anaerobic primary metabolism in rice and wheat seedlings. I: Dark ethanol production is dominated by the shoots. Planta, 225, 103-114.
- Mustroph, A., Stock, J., Hess, N., Aldous, S., Dreilich, A., & Grimm, B. (2013). Characterization of the phosphofructokinase gene family in rice and its expression under oxygen deficiency stress. Frontiers in Plant Science, 4, 125.
- Osman, K.A., Tang, B., Wang, Y., Chen, J., Yu, F., Li, L., Han, X., Zhang, Z., Yan, J., Zheng, Y., Yue, B., & Qiu, F. (2013). Dynamic QTL analysis and candidate gene mapping for waterlogging tolerance at maize seedling stage. Plos One. 14;8(11):e79305. doi: 10.1371/journal.pone.0079305.
- Ozseven, İ., & Gençtan, T. (2018). The effect of long-term waterlogging on flag leaf chlorophyll content in some bread wheat (Triticum aestivum L.) genotypes. Journal of Aegean Agricultural Research Institute, 28(2), 1-16. https://dergipark.org.tr/en/pub/anadolu/issue/41816/504322.
- Pan, J., Sharif, R., Xu, X., & Chen, X. (2021). Mechanisms of waterlogging tolerance in plants: Research progress and prospects. Frontiers in Plant Science, 11, 627331.
- Paudel, G. P., Devkota, M., Keil, A., & McDonald, A. J. (2020). Climate and landscape mediate patterns of low lentil productivity in Nepal. Plos One, 15(4), e0231377.
- Prasanna, Y.L., & Rao, G.R. (2014). Effect of waterlogging on growth and seed yield in greengram genotypes. International Journal of Food, Agriculture and Veterinary Sciences, 4, 124-128.
- Setter, T.L., & Waters, I. (2003). Review of prospects for germplasm improvement for waterlogging tolerance in wheat, barley and oats. Plant and Soil, 253, 1-34.
- Solaiman, Z., Colmer, T.D., Loss, S.P., Thomson, B.D., & Siddique, K.H.M. (2007). Growth responses of cool-season grain legumes to transient waterlogging. Australian Journal of Agricultural Research, 58(5), 406-412.
- Wiraguna, E., Malik, A.I., & Erskine, W. (2017). Waterlogging tolerance in lentil (Lens culinaris Medik. subsp. culinaris) germplasm associated with geographic origin. Genetic Resources and Crop Evolution, 64, 579-586.
- Yavas, I., Unay, A., & Aydin, M. (2012). The waterlogging tolerance of wheat varieties in western of Turkey. The Scientific World Journal, vol: 2012, pages: 7, doi:10.1100/2012/529128.
- Zeroual, A., Baidani, A., & Idrissi, O. (2022). Drought Stress in Lentil (Lens culinaris, Medik) and Approaches for Its Management.. Horticulturae, 9(1), 1.