اثر پلیمر سوپرجاذب و بافت خاک بر واکنش های فیزیولوژیک ذرت (Zea mays L) تحت تنش کمآبی
محورهای موضوعی : اکوفیزیولوژی گیاهان زراعیعلیرضا معینی 1 , علی نشاط 2 , نجمه یزدانپناه 3 , امین پسندی پور 4
1 - دانشکده فنی – مهندسی، گروه علوم و مهندسی آب، واحد کرمان، دانشگاه آزاد اسلامی، کرمان، ایران
2 - دانشکده فنی – مهندسی، گروه علوم و مهندسی آب، واحد کرمان، دانشگاه آزاد اسلامی، کرمان، ایران
3 - دانشکده فنی – مهندسی، گروه علوم و مهندسی آب، واحد کرمان، دانشگاه آزاد اسلامی، کرمان، ایران
4 - دانشکده کشاورزی، گروه مهندسی تولید و ژنتیک گیاهی، دانشگاه شهید باهنر کرمان، کرمان، ایران
کلید واژه: محتوای رطوبت نسبی, پرولین, ماده خشک, فعالیت آنتی اکسیدانی, سرعت فتوسنتز خالص,
چکیده مقاله :
نقش پلیمر سوپرجاذب در کاهش اثر تنش کم آبی در خاک های شنی و لومی رسی، اثر پنج سطح پلیمر سوپر جاذب (صفر، 0.1، 0.2، 0.4 و 0.8 گرم در کیلوگرم خاک)، سه تیمار آبیاری (محتوای رطوبت نسبی خاک شامل 80، 60 و 40 درصد ظرفیت زراعی خاک) و دو نوع بافت خاک (شنی و لومی رسی) بر روی تولید زیست توده، رنگدانه های فتوسنتزی، میزان تبادل گاز برگ، محتوای نسبی آب برگ، نشت الکترولیت، مقدار پرولین، فعالیت کاتالاز، فعالیت سوپراکسید دیسموتاز و آسکوربات پراکسیداز به صورت فاکتوریل در قالب طرح کاملاً تصادفی در سه تکرار در مرکز تحقیقات و آموزش کشاورزی و منابع طبیعی کرمان مورد بررسی قرار گرفت. نتایج نشان داد که تنش کم آبی باعث کاهش قابل توجه میزان فتوسنتز خالص، هدایت روزنه ای برگ، کلروفیلa+b ، محتوای نسبی آب برگ، ارتفاع بوته و تولید ماده خشک ذرت شد. فعالیت آنزیم های کاتالاز، سوپراکسید دیسموتاز و آسکوربات پراکسیداز، نشت الکترولیت و مقدار پرولین با افزایش سطح تنش کم آبی به طور قابل توجهی افزایش یافت. استفاده از پلیمر سوپرجاذب تحت تنش کم آبی 40 درصد موجب افزایش فتوسنتز خالص (32.3 درصد)، هدایت روزنه ای (38 درصد)، کلروفیلa+b (23.9 درصد)، محتوای نسبی آب برگ (11.9 درصد) و تولید ماده خشک (24 درصد) و کاهش نشت الکترولیت (10.8 درصد)، مقدار پرولین (66.9 درصد)، فعالیت کاتالاز (42.7 درصد)، فعالیت سوپراکسید دیسموتاز (33.2 درصد) و آسکوربات پراکسیداز (34.3 درصد) در مقایسه با عدم کاربرد آن گردید. در مجموع می توان گفت که کاربرد پلیمر سوپر جاذب به میزان 0.8 گرم در کیلوگرم خاک از طریق افزایش ظرفیت نگهداری آب در خاک باعث بهبود رشد و نمو گیاه ذرت در شرایط تنش کم آبی می شود.
In order to evaluate the role of super absorbent polymer (SAP) for mitigating the water deficit stress at sandy and clay-loam soils, the effect of five values of SAP (0, 0.1, 0.2, 0.4 and 0.8 g.kg-1 soil), three water treatment (the relative soil water content of 80, 60, and 40%) and two soil textures (sandy and clay-loam) on biomass production, photosynthetic pigments, leaf gas exchange parameters, leaf relative water content (RWC), electrolyte leakage (REC), proline content, catalase, super oxide dismutase, and ascorbate peroxidase activity. The experiment was carried out with a factorial arrangement based on complete randomized design in triplicates at the Agricultural and Natural Resources Research and Education Center, Kerman, Iran. The results revealed that water deficit stress caused a significant decrease in net photosynthesis rate, leaf stomatal conductance, chlorophyll a+b content, RWC, plant height, and dry matter production of maize. CAT, SOD, APX activity, REC, and proline were elevated with increasing water deficit stress levels. Application of SAP under water deficit stress increased the net photosynthesis (32.3%), stomatal conductance (38%), chlorophyll a+b (23.9%), RWC (11.9%), and dry matter production (24%), while it decreased REC (10.8%), proline content (66.9%), CAT (42.7%), SOD (33.2%), and APX activity (34.3%) as compared to control. It can be concluded that application of SAP (0.8 g.kg-1 soil) improved plant growth of maize under water deficit stress through increasing the water holding capacity in soil.
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Li, Y., H. Song, L. Zhou, Z. Xu, and G. Zhou. 2019b. Tracking chlorophyll fluorescence as an indicator of drought and rewatering across the entire leaf lifespan in a maize field. Agricultural Water Management. 211: 190–201.
Liang, J., W. Shi, Z. He, L. Pang, and Y. Zhang. 2019. Effects of poly-γ-glutamic acid on water use efficiency, cotton yield, and fiber quality in the sandy soil of southern Xinjiang, China. Agricultural Water Management. 218: 48-59.
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_||_Abobatta, W. 2018. Impact of hydrogel polymer in agricultural sector. Advances in Agriculture and Environmental Science. 1: 59-64.
Ahmad, P., S. Jamsheed, A. Hameed, S. Rasool, I. Sharma, M. Azooz, and M. Hasanuzzaman. 2014. Chapter 11 - drought stress induced oxidative damage and antioxidants in plants. Oxidative Damage Plants.154: 345–367.
Bates, L.S., S.P. Waldern, and I.D. Teare. 1973. Rapid determination of free proline for water-stress studies. Plant and Soil. 39: 205-207.
Bhusal, N., S.G. Han, and T.M. Yoon. 2019. Impact of drought stress on photosynthetic response, leaf water potential, and stem sap flow in two cultivars of bi-leader apple trees (Malus × domestica Borkh.). Scientia Horticulturae. 246: 535–543.
Buckley, T.N., and K.A. Mott. 2013. Modelling stomatal conductance in response to environmental factors. Plant, Cell and Environment. 36: 1691–1699.
Buezo, J., A. Sanz-Saez, J.F. Moran, D. Soba, I. Aranjuelo, and R. Esteban. 2019. Drought tolerance response of high-yielding soybean varieties to mild drought: physiological and photochemical adjustments. Physiolgia Plantarum. 166: 88–104.
Cai, F., Y. Zhang, N. Mi, H. Ming, S. Zhang, H. Zhang, and X. Zhao. 2020. Maize (Zea mays ) physiological responses to drought and rewatering, and the associations with water stress degree. Agricultural Water Management. 241: 106379.
Cai, Y., J. Wang, S. Li, L. Zhang, L. Peng, W. Xie, and F. Liu. 2015. Photosynthetic response of an alpine plant, rhododendron delavayi franch, to water stress and recovery: the role of mesophyll conductance. Front Plant Science. 6: 1089.
Cairns, J.E., J. Hellin, K. Sonder, J. Araus, J. MacRobert, C. Thierfelder, and B. Prasanna. 2013. Adapting maize production to climate change in sub-Saharan Africa. Food Security. 5(3): 1-16.
Chen, S., P. Hawighorst, J. Sun, and A. Polle. 2014. Salt tolerance in populus: significance of stress signaling networks, mycorrhization, and soil amendments for cellular and whole-plant nutrition. Environmental and Experimental Botany. 107: 113-124.
Daryanto, S., L. Wang, and P.A. Jacinthe. 2016. Global synthesis of drought effects on maize and wheat production. Plos One. 11: 1-15.
Dhindsa, R.S., P. Plump-Dhindsa, and T.A. Thrope. 1981. Leaf senescence: correlated with increased levels of membrane permeability and lipid peroxidation, and decreased levels of superoxide dismutase and catalase. Journal of Experimental Botany. 32: 93-101.
Djaman, K., S. Irmak, W.R. Rathje, D.L. Martin, and D.E. Eisenhauer. 2013. Maize evapotranspiration, yield production functions, biomass, grain yield, harvest index, and yield response factors under full and limited irrigation. Biological Systems Engineering: Papers and Publications. 56: 373–393.
Dong, S., Y. Jiang, Y. Dong, L. Wang, W. Wang, Z. Ma, C. Yan, C. Ma, and L. Liu. 2019. A study on soybean responses to drought stress and rehydration. Saudi Journal of Biological Sciences. 26: 2006–2017.
Dorraji, S.S., A. Golchin, and S. Ahmadi. 2010. The effects of hydrophilic polymer and soil salinity on corn growth in sandy and loamy soils. Clean Soil Air Water. 38(7): 584-591.
Dutta, T., N.R.R. Neelapu, S.H. Wani, and C. Surekha. 2019. Chapter 30- Role and regulation of osmolytes as signaling molecules to abiotic stress tolerance. Plant Signaling Molecules. 459-477.
El-Hendawy, S., N. Al-Suhaibani, S. Elsayed, W. Hassan, Y. Dewir, Y. Refay, and K. Abdella. 2019. Potential of the existing and novel spectral reflectance indices for estimating the leaf water status and grain yield of spring wheat exposed to different irrigation rates. Agricultural Water Management. 217: 356–373.
Eneji, A.E., R. Islam, P. An, and U.C. Amalua. 2013. Nitrate retention and physiological adjustment of maize to soil amendment with super absorbent polymers. Journal of Cleaner Production. 52: 474-480.
Esteban, R., O. Barrutia, U. Artetxe, B. Fernandez-Marin, A. Hernandez, and J.I. Garcia- Plazaola. 2015. Internal and external factors affecting photosynthetic pigment composition in plants: a meta-analytical approach. New Phytologist. 206: 268–280.
Farahbakhsh, H., A. Pasandi Pour, and N. Reiahi. 2017. Physiological response of henna (Lawsonia inermise) to salicylic acid and salinity. Plant Production Science. 20: 237-247.
Farooq, M.A., A.K. Niazi, J. Akhtar, Saifullah, M. Farooq, Z. Souri, N. Karimi, and Z. Rengel. 2019. Acquiring control: the evolution of ROS-induced oxidative stress and redox signaling pathways in plant stress responses. Plant Physiology and Biochemistry. 141: 353–369.
Fazeli Rostampour, M., M. Yarnia, R. Farokhzadeh Khoee, M.J. Seghatoleslami, and G.R. Moosavi. 2013. Physiological response of forage sorghum to polymer under water deficit conditions. Agronomy Journal. 105(4): 951-959.
Feng, D., B. Bai, C. Ding, H. Wang, and Y. Suo. 2014. Synthesis and swelling behaviors of yeast-g-poly (acrylic acid) superabsorbent co-polymer. Industrial and Engineering Chemistry Research. 53(32): 12760–12769.
Galeş, D.C., L.C. Trincă, A. Cazacu, C.A. Peptu, and G. Jităreanu. 2016. Effects of a hydrogel on the cambic chernozem soil's hydrophysic indicators and plant morphophysiological parameters. 267: 102–111.
Giannopolitis, C.N., and S.K. Ries. 1977. Superoxide dismutase. I: Occurrence in higher plant. Plant Physiology. 59: 309-314.
Gill, S.S., N.A. Khan, N.A. Anjum, and N. Tuteja. 2011. Amelioration of cadmium stress in crop plants by nutrients management: morphological, physiological and biochemical aspects. Plant Stress. 5: 1-23.
Hong-Bo, S., C. Li-Ye, A.j. Cheruth, and Z. Chang-Xing. 2008. Water deficit stress induced anatomical changes in higher plants. Comptes Rendus Biologies. 331: 215-225.
Iqbal, H., C. Yaning, M. Waqas, M. Shareef, and S.T. Raza. 2018. Differential response of quinoa genotypes to drought and foliage-applied H2O2 in relation to oxidative damage, osmotic adjustment and antioxidant capacity. Ecotoxicology and Environmental Safety. 164: 344-354.
Ismail, H., M. Irani, and Z. Ahmad. 2013. Starch-based hydrogels: present status and applications. International Journal of Polymeric Materials and Polymeric Biomaterials. 62(7): 411–420.
Junttila, S., J. Sugano, M. Vastaranta, R. Linnakoski, H. Kaartinen, A. Kukko, M. Holopainen, H. Hyyppa, and J. Hyyppa. 2018. Can leaf water content be estimated using multispectral terrestrial laser scanning? a case study with Norway spruce seedlings. Frontiers in Plant Science. 9: 299.
Kapoor, D., S. Singh, V. Kumar, R. Romero, R. Prasad, and J. Singh. 2019. Antioxidant enzymes regulation in plants in reference to reactive oxygen species (ROS) and reactive nitrogen species (RNS). Plant Gene. 19: 100182.
Khadem, S.A., M. Galavi, M. Ramordi, S.R. Mousavi, M.J. Rousta, and P. Rezvani- Moghadam. 2010. Effect of animal manure and superabsorbent polymer on corn leaf relative water content, cell membrane stability and leaf chlorophyll content under dry condition. Australian Journal of Crop Science. 4(8): 642-647.
Li, Y., H. Song, L. Zhou, Z. Xu, and G. Zhou. 2019 a. Vertical distributions of chlorophyll and nitrogen and their associations with photosynthesis under drought and rewatering regimes in a maize field. Agricultural and Forest Meteorology. 272–273: 40–54.
Li, Y., H. Song, L. Zhou, Z. Xu, and G. Zhou. 2019b. Tracking chlorophyll fluorescence as an indicator of drought and rewatering across the entire leaf lifespan in a maize field. Agricultural Water Management. 211: 190–201.
Liang, J., W. Shi, Z. He, L. Pang, and Y. Zhang. 2019. Effects of poly-γ-glutamic acid on water use efficiency, cotton yield, and fiber quality in the sandy soil of southern Xinjiang, China. Agricultural Water Management. 218: 48-59.
Lichtenthaler, H.K. 1987. Chlorophlls and carotenoids: Pigments of photosynthetic bio membranes. Methods in Enzymology. 148: 350–382.
Liu, S., Y. Peng, W. Du, Y. Le, and L. Li. 2015. Remote estimation of leaf and canopy water content in winter wheat with different vertical distribution of water-related properties. Remote Sensing. 7(4): 4626–4650.
Mao, S., M.R. Islam, Y. Hu, X. Qian, F. Chen, and X. Xue. 2011. Antioxidant enzyme activities and lipid peroxidation in maize (Zea mays) following soil application of superabsorbent polymer at different fertilizer regimes. African Journal of Biotechnology. 10: 1000-1008.
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