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1860797977327566848
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| building |
INTELEK Repository
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| collection |
Online Access
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| collectionurl |
https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072
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| date |
2024-08-30 11:18:31
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| format |
Restricted Document
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| id |
15230
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| institution |
UniSZA
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| internalnotes |
Akbar, M. and F.N. Ponnamperuma, 1982. Saline soils of South and South East Asia as potential rice lands. Rice research strategies for the future. IRRI. Manila. Philippines., pp: 265-281. Akbar, M. and Y. Yabuno, 1974. Breeding for saline-resistant varieties of rice. II. Comparative performance of some rice varieties to salinity during early developing stages. Japanese Journal of Breeding, 25: 176-181. Asch, F. and M.S.C. Wopereis, 2001. Responses of field-grown irrigated rice cultivars to varying levels of floodwater salinity in a semi-arid environment. Field Crops Research, 70: 127-137. Asch, F., M. Dingkuhn, M.S.C. Wopereis, K. Dörffling, K.M. Miezan, and 1997. A conceptual model for sodium uptake and distribution in irrigated rice. In: Applications of Systems Approaches at the Field Level (Eds. MJ Kropff et al., Kluver Academic Publishers, Dordrecht, pp: 201-217. Ashraf, M., H.R. Athar, P.J.C. Harris and T.R. Kwon, 2008. Some prospective strategies for improving crop salt tolerance. Adv Agron 97: 45-110. Azhar, F.M., A.A. Khan and N. Saleem, 2007. Genetic mechanism controlling salt tolerance in Gossypium hirsutum L. seedlings. Pakistan Journal of Botany, 39: 115-121. Binzel, M.L. and M. Reuveni, 1994. Cellular mechanisms of salt tolerance in plant cells. Hort. Rev., 16: 33-69 Chelah, M.K.B., M.N B. Nordin, M.I. Musliania, Y.M. Khanif and M.S. Jahan, 2011. Composting increases BRIS soil health and sustains rice production on BRIS soil. Scienceasia, 37: 291- 295. FAO, 2012. FAO says rice production outpacing consumption. http://www.fao.org/news/story/en/item/164713/icode /. Accessed on 17 Nov. 2014. Flowers, T.J., A. Garcia, M. Koyama and A.R. Yeo, 1997. Breeding for salt tolerance in crop plants: the role of molecular. biology. Acta Physiogia Plantarum, 19: 427-433. Flowers, T.J., Koyama, M.L., Flowers, S.A., Sudhakar, C., Singh, K.P. and Yeo, A.R. 2000. QTL: their place in engineering tolerance of rice to salinity. Journal of Experimental Botany, 51: 99-106. Galvani, A. 2007. The challenge of the food sufficiency through salt tolerant crops. Rev. Environ. Sci. Biotechnol., 6: 3-16. Horneck, D.A., J.W. Ellsworth, B.G. Hopkins, D.M. Sullivan and R.G. Stevens, 2007. Managing saltaffected soils for crop production (PNW 601-E). Pullman, WA: Pacific Northwest Extension. International Rice Research Institute. 2008. Annual Report for 2007. Los Baños, Philippines. Jahan, M.S., I. Muslianie and M.M. Khandaker, 2014b. Effects of Soil Amendments on BRIS Soil Health, Crop Physiology and Production. International Journal of Research and Innovations in Earth Science,1: 1-4. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, 2013a. Effects of low water input on rice yield: Fe and Mn bioavailability in soil. Pertanika Journal of Tropical Agriculture Sciences, 36: 27-34. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, M.B.N. Nozulaidi, M.B.C.L. Khairi, 2012. Bioavailability of soil nitrogen in low water-input rice production. Journal of Sustainable Science and Management, 7: 207-212. Jahan, M.S., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The Effect of Different Water Regimes on Yield and Bioavailability of Phosphorus in Rice Production in Malaysia. Malaysian Journal of Soil Science, 8:53-62. Jahan, M.S., Y. Nakamura and Y. Murata, 2011. Histochemical quantification of GSH contents in guard cells of Arabidopsis thaliana. Scienceasia, 37: 281-284. Jahan, M.S., M.B.N. Nozulaidi, M.B.C.L. Khairi and Y.M. Khanif, 2013b. Effects of water stress on rice production: bioavailability of potassium in soil. Journal of Stress Physiology & Biochemistry, 9: 97-107. Jahan, M.S., M.B.N. Nozulaidi, M.K. Moneruzzaman, A. Ainun and N. Husna, 2014a. Control of plant growth and water loss by a lack of light-harvesting complexes in photosystem-II in Arabidopsis thaliana ch1-1 mutant. Acta Physiologiae Plantarum, 36: 1627-1635. Kant, S., P. Kant, H. Lips and S. Barak, 2007. Partial substitution of NO3- by NH4+ fertilization increases ammonium assimilating enzyme activities and reduces the deleterious effects of salinity on the growth of barley. Journal of Plant Physiology, 164: 303-311. Khairi, M., M. Nozulaidi, A. Afifah and M.S. Jahan, 2015a. Effect of various water regimes on rice production in lowland irrigation. Australian Journal of Crop Science, 9(2): 153-59. Khairi, M., M. Nozulaidi and M.S. Jahan, 2015b. Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety. Australian Journal of Basic and Applied Sciences, 9: 339-345. Khan, A.A., S.A. Rao and T. McNeilly, 2003. Assessment of salinity tolerance based upon seedling root growth response functions in maize (Zea mays L.). Euphytica, 131: 81-89. Khatun, S. and T.J. Flowers, 1995. Effect of salinity on seed set in rice. Plant Cell and Environment, 18: 61-87. Khatun, S., C.A. Rizzo and T.J. Flowers, 1995. Genotypic variation in the effect of salinity on fertility on rice. Plant Soil, 173: 239-50. Manneh, B., 2004. Genetic, physiological and modeling approaches towards tolerance to salinity and low nitrogen supply in rice (Oryza sativa L.). Ph.D. Thesis. Wageningen University. Mori, I.K. and T. Kinoshita, 1987. Salt tolerance of rice callus clones. Rice Genet. Newsletter, 4: 112- 113. Munirah, N., M. Khairi, M. Nozulaidi, M.M Khandaker, N. Mat and M.S. Jahan, 2015. The Effects of Zinc Application on Physiology and Production of Corn Plants. Australian Journal of Basic and Applied Sciences, 9: 339-345. Munns, R., 2009. Strategies for crop improvement in saline soils. In Salinity and Water Stress: Improving Crop Efficiency. Tasks for Vegetation Sciences 44. Eds M. Ashraf, M. Ozturk, H.R. Athar. Springer. pp: 99-110. Nozulaidi, N., M.S. Jahan, M. Khairi, M.M. Khandaker, M. Nashriyah and Y.M. Khanif, 2015. N-acetylcysteine increased rice yield. Turkish Journal of Agriculture and Forestry, DOI: 10.3906/tar-1402-48. Roychoudhury, A., S. Basu, S.N. Sarkar and D.N. Sengupta, 2008. Comparative physiological and molecular responses of a common aromatic indica rice cultivar to high salinity with non-aromatic indica rice cultivars. Plant Cell Reports, 27: 1395-1410. Sani, K., 1991. The management of saline soils for paddy cultivation (in Malay). Teknologi Kejuruteraan Pertanian., 20: 33-36. Sarwar, M.J. and Y.M. Khanif, 2005. Techniques of water saving in rice production in Malaysia. Asian Journal of Plant Science, 4: 83-84. Sarwar, M.J. and Y.M. Khanif, 2005b. Low water rice production and its effect on redox potential and soil pH. Journal of Agronomy, 4: 142- 146. Sarwar, M.J., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The effect of different water regimes on yield and bioavailability of Phosphorus in rice production in Malaysia. Malaysian Journal of Soil Science, 8: 53-62. Sarwar, M.J. and Y.M. Khanif, 2005c. The Effect of Different Water Levels on Rice Yield and Cu and Zn Concentration. Journal of Agronomy, 4: 116-121. Sarwar, M.J. and Khanif Y.M. 2005d. Effect of Water Saving Irrigation on Yield and Concentration of Ca and Mg in Malaysian Rice Cultivation. Pakistan Journal of Biological Sciences, 8: 65-67. Sarwar, M.J., 2004. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Shereen, A., S. Mumtaz, S. Raza, M.A. Khan and S. Solangi, 2005. Salinity effects on seedling growth and yield components of different inbred rice lines. Pakistan Journal of Botany, 37(1): 131-139. Syuhada, N., M.S. Jahan, M.M. Khandaker, M. Nashriyah, M. Khairi, M. Nozulaidi and M.H.B. Razali, 2014. Application of Copper Increased Corn Yield Through Enhancing Physiological Functions. Australian Journal of Basic and Applied Science, 8: 282-286. Zeng, L., M.C. Shannon and C.M. Grieve, 2002. Evaluation of salt tolerance in rice genotypes by multiple agronomic parameters. Euphytica, 127: 235-245. Zeng, L. and M.C. Shannon, 2000. Salinity effects on seedling growth and yield components of rice. Crop Science, 40: 996-1003.
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| originalfilename |
6020-01-FH02-FBIM-15-03274.pdf
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| person |
Dr.Moharam
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| recordtype |
oai_dc
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| resourceurl |
https://intelek.unisza.edu.my/intelek/pages/view.php?ref=15230
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| spelling |
15230 https://intelek.unisza.edu.my/intelek/pages/view.php?ref=15230 https://intelek.unisza.edu.my/intelek/pages/search.php?search=!collection407072 Restricted Document Article Journal application/pdf Adobe Acrobat Pro DC 20 Paper Capture Plug-in with ClearScan 8 1.6 Dr.Moharam 2024-08-30 11:18:31 6020-01-FH02-FBIM-15-03274.pdf UniSZA Private Access Effects of different salinity levels on rice production Australian Journal of Basic and Applied Sciences Background: Salinity is one of major problems for rice production. Objective: We tested if different salinity conditions affect production of local rice variety. Rice variety of MR219 was cultivated under different saline conditions and yield and plant parameters were evaluated. Results: Root and shoot length decreased gradually with increasing saline concentration in soil solution. Chlorophyll (Chl) content decreased under salinity condition than control but soil pH was unchanged except 6 ds salinity which significantly reduced soil pH. Relative water content (RWC) decreased with increasing salinity condition in soil solution. Plant height and tiller numbers also decreased with increasing salinity in soil. Other parameters, panicle length, panicle per pot, grain per plant and weight of grains showed similar to the plant height. Conclusion: These results suggest that local variety, MR219, is saline susceptible and need to pay attention in agronomic practices for sustainable crop production. 9 5 524-530 Akbar, M. and F.N. Ponnamperuma, 1982. Saline soils of South and South East Asia as potential rice lands. Rice research strategies for the future. IRRI. Manila. Philippines., pp: 265-281. Akbar, M. and Y. Yabuno, 1974. Breeding for saline-resistant varieties of rice. II. Comparative performance of some rice varieties to salinity during early developing stages. Japanese Journal of Breeding, 25: 176-181. Asch, F. and M.S.C. Wopereis, 2001. Responses of field-grown irrigated rice cultivars to varying levels of floodwater salinity in a semi-arid environment. Field Crops Research, 70: 127-137. Asch, F., M. Dingkuhn, M.S.C. Wopereis, K. Dörffling, K.M. Miezan, and 1997. A conceptual model for sodium uptake and distribution in irrigated rice. In: Applications of Systems Approaches at the Field Level (Eds. MJ Kropff et al., Kluver Academic Publishers, Dordrecht, pp: 201-217. Ashraf, M., H.R. Athar, P.J.C. Harris and T.R. Kwon, 2008. Some prospective strategies for improving crop salt tolerance. Adv Agron 97: 45-110. Azhar, F.M., A.A. Khan and N. Saleem, 2007. Genetic mechanism controlling salt tolerance in Gossypium hirsutum L. seedlings. Pakistan Journal of Botany, 39: 115-121. Binzel, M.L. and M. Reuveni, 1994. Cellular mechanisms of salt tolerance in plant cells. Hort. Rev., 16: 33-69 Chelah, M.K.B., M.N B. Nordin, M.I. Musliania, Y.M. Khanif and M.S. Jahan, 2011. Composting increases BRIS soil health and sustains rice production on BRIS soil. Scienceasia, 37: 291- 295. FAO, 2012. FAO says rice production outpacing consumption. http://www.fao.org/news/story/en/item/164713/icode /. Accessed on 17 Nov. 2014. Flowers, T.J., A. Garcia, M. Koyama and A.R. Yeo, 1997. Breeding for salt tolerance in crop plants: the role of molecular. biology. Acta Physiogia Plantarum, 19: 427-433. Flowers, T.J., Koyama, M.L., Flowers, S.A., Sudhakar, C., Singh, K.P. and Yeo, A.R. 2000. QTL: their place in engineering tolerance of rice to salinity. Journal of Experimental Botany, 51: 99-106. Galvani, A. 2007. The challenge of the food sufficiency through salt tolerant crops. Rev. Environ. Sci. Biotechnol., 6: 3-16. Horneck, D.A., J.W. Ellsworth, B.G. Hopkins, D.M. Sullivan and R.G. Stevens, 2007. Managing saltaffected soils for crop production (PNW 601-E). Pullman, WA: Pacific Northwest Extension. International Rice Research Institute. 2008. Annual Report for 2007. Los Baños, Philippines. Jahan, M.S., I. Muslianie and M.M. Khandaker, 2014b. Effects of Soil Amendments on BRIS Soil Health, Crop Physiology and Production. International Journal of Research and Innovations in Earth Science,1: 1-4. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, 2013a. Effects of low water input on rice yield: Fe and Mn bioavailability in soil. Pertanika Journal of Tropical Agriculture Sciences, 36: 27-34. Jahan, M.S., Y.M. Khanif, U.R. Sinniah, M.B.N. Nozulaidi, M.B.C.L. Khairi, 2012. Bioavailability of soil nitrogen in low water-input rice production. Journal of Sustainable Science and Management, 7: 207-212. Jahan, M.S., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The Effect of Different Water Regimes on Yield and Bioavailability of Phosphorus in Rice Production in Malaysia. Malaysian Journal of Soil Science, 8:53-62. Jahan, M.S., Y. Nakamura and Y. Murata, 2011. Histochemical quantification of GSH contents in guard cells of Arabidopsis thaliana. Scienceasia, 37: 281-284. Jahan, M.S., M.B.N. Nozulaidi, M.B.C.L. Khairi and Y.M. Khanif, 2013b. Effects of water stress on rice production: bioavailability of potassium in soil. Journal of Stress Physiology & Biochemistry, 9: 97-107. Jahan, M.S., M.B.N. Nozulaidi, M.K. Moneruzzaman, A. Ainun and N. Husna, 2014a. Control of plant growth and water loss by a lack of light-harvesting complexes in photosystem-II in Arabidopsis thaliana ch1-1 mutant. Acta Physiologiae Plantarum, 36: 1627-1635. Kant, S., P. Kant, H. Lips and S. Barak, 2007. Partial substitution of NO3- by NH4+ fertilization increases ammonium assimilating enzyme activities and reduces the deleterious effects of salinity on the growth of barley. Journal of Plant Physiology, 164: 303-311. Khairi, M., M. Nozulaidi, A. Afifah and M.S. Jahan, 2015a. Effect of various water regimes on rice production in lowland irrigation. Australian Journal of Crop Science, 9(2): 153-59. Khairi, M., M. Nozulaidi and M.S. Jahan, 2015b. Effects of Different Water Levels on Physiology and Yield of Salinity Rice Variety. Australian Journal of Basic and Applied Sciences, 9: 339-345. Khan, A.A., S.A. Rao and T. McNeilly, 2003. Assessment of salinity tolerance based upon seedling root growth response functions in maize (Zea mays L.). Euphytica, 131: 81-89. Khatun, S. and T.J. Flowers, 1995. Effect of salinity on seed set in rice. Plant Cell and Environment, 18: 61-87. Khatun, S., C.A. Rizzo and T.J. Flowers, 1995. Genotypic variation in the effect of salinity on fertility on rice. Plant Soil, 173: 239-50. Manneh, B., 2004. Genetic, physiological and modeling approaches towards tolerance to salinity and low nitrogen supply in rice (Oryza sativa L.). Ph.D. Thesis. Wageningen University. Mori, I.K. and T. Kinoshita, 1987. Salt tolerance of rice callus clones. Rice Genet. Newsletter, 4: 112- 113. Munirah, N., M. Khairi, M. Nozulaidi, M.M Khandaker, N. Mat and M.S. Jahan, 2015. The Effects of Zinc Application on Physiology and Production of Corn Plants. Australian Journal of Basic and Applied Sciences, 9: 339-345. Munns, R., 2009. Strategies for crop improvement in saline soils. In Salinity and Water Stress: Improving Crop Efficiency. Tasks for Vegetation Sciences 44. Eds M. Ashraf, M. Ozturk, H.R. Athar. Springer. pp: 99-110. Nozulaidi, N., M.S. Jahan, M. Khairi, M.M. Khandaker, M. Nashriyah and Y.M. Khanif, 2015. N-acetylcysteine increased rice yield. Turkish Journal of Agriculture and Forestry, DOI: 10.3906/tar-1402-48. Roychoudhury, A., S. Basu, S.N. Sarkar and D.N. Sengupta, 2008. Comparative physiological and molecular responses of a common aromatic indica rice cultivar to high salinity with non-aromatic indica rice cultivars. Plant Cell Reports, 27: 1395-1410. Sani, K., 1991. The management of saline soils for paddy cultivation (in Malay). Teknologi Kejuruteraan Pertanian., 20: 33-36. Sarwar, M.J. and Y.M. Khanif, 2005. Techniques of water saving in rice production in Malaysia. Asian Journal of Plant Science, 4: 83-84. Sarwar, M.J. and Y.M. Khanif, 2005b. Low water rice production and its effect on redox potential and soil pH. Journal of Agronomy, 4: 142- 146. Sarwar, M.J., Y.M. Khanif, S.R. Syed Omar and U.R. Sinniah, 2004. The effect of different water regimes on yield and bioavailability of Phosphorus in rice production in Malaysia. Malaysian Journal of Soil Science, 8: 53-62. Sarwar, M.J. and Y.M. Khanif, 2005c. The Effect of Different Water Levels on Rice Yield and Cu and Zn Concentration. Journal of Agronomy, 4: 116-121. Sarwar, M.J. and Khanif Y.M. 2005d. Effect of Water Saving Irrigation on Yield and Concentration of Ca and Mg in Malaysian Rice Cultivation. Pakistan Journal of Biological Sciences, 8: 65-67. Sarwar, M.J., 2004. PhD Thesis. Department of Land Management, Faculty of Agriculture, Universiti Putra Malaysia. Shereen, A., S. Mumtaz, S. Raza, M.A. Khan and S. Solangi, 2005. Salinity effects on seedling growth and yield components of different inbred rice lines. Pakistan Journal of Botany, 37(1): 131-139. Syuhada, N., M.S. Jahan, M.M. Khandaker, M. Nashriyah, M. Khairi, M. Nozulaidi and M.H.B. Razali, 2014. Application of Copper Increased Corn Yield Through Enhancing Physiological Functions. Australian Journal of Basic and Applied Science, 8: 282-286. Zeng, L., M.C. Shannon and C.M. Grieve, 2002. Evaluation of salt tolerance in rice genotypes by multiple agronomic parameters. Euphytica, 127: 235-245. Zeng, L. and M.C. Shannon, 2000. Salinity effects on seedling growth and yield components of rice. Crop Science, 40: 996-1003.
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| spellingShingle |
Effects of different salinity levels on rice production
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| summary |
Background: Salinity is one of major problems for rice production. Objective: We tested if different salinity conditions affect production of local rice variety. Rice variety of MR219 was cultivated under different saline conditions and yield and plant parameters were evaluated. Results: Root and shoot length decreased gradually with increasing saline concentration in soil solution. Chlorophyll (Chl) content decreased under salinity condition than control but soil pH was unchanged except 6 ds salinity which significantly reduced soil pH. Relative water content (RWC) decreased with increasing salinity condition in soil solution. Plant height and tiller numbers also decreased with increasing salinity in soil. Other parameters, panicle length, panicle per pot, grain per plant and weight of grains showed similar to the plant height. Conclusion: These results suggest that local variety, MR219, is saline susceptible and need to pay attention in agronomic practices for sustainable crop production.
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| title |
Effects of different salinity levels on rice production
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| title_full |
Effects of different salinity levels on rice production
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| title_fullStr |
Effects of different salinity levels on rice production
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| title_full_unstemmed |
Effects of different salinity levels on rice production
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| title_short |
Effects of different salinity levels on rice production
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| title_sort |
effects of different salinity levels on rice production
|