炭化秸秆对苹果根系一氧化氮生成及根区土壤硝酸盐代谢的影响

doi:10.3864/j.issn.0578-1752.2014.19.013

Abstract

Abstract: 【Objective】The soil nitrate is not only fruit tree’s nitrogen nutrition but also the latent environmental pollution factor. The carbonization straw, a product of incomplete combustion of crop straw, is applied into the soil to improve soil physical and chemical properties. This study focused on the changes of nitric oxide (NO) and nitrate metabolism related enzymes in the roots and the root zone soil of apple tree applied with carbonized corn straw. The purpose was to reveal the regulating effects of carbonized straw on the nitrate metabolism of apple roots and it’s root-zone soil, so as to provide a theoretical basis for the control of soil nitrate transformation and the improvement of orchard soil management.【Method】In the spring, the carbonized corn straw and soil was mixed according to the mass ratio of 0.5%-8.0% (w/w) and loaded to the clay pots, and then the 3-year-old ‘Fuji’ apple trees (rootstock for Malus hupehensis Rehd) in similar growth were transplanted to the pots. After 120-190 d of transplantation, the change of NO formation and the activity of nitrate reductase (NR) in roots and root zone soil was investigated, the activity of nitric oxide synthase (NOS) in roots and activity of hydroxylamine reductase (HyR) and the nitrification intensity in root zone soil were measured regularly.【Result】It was significantly different that the responses of nitric oxide formatiom and nitrate metabolic in roots and root zone soil to the applicationrate of carbonized corn straw to the soil. The rate of NO formation, the activity of NR and NOS in root increased significantly when carbonized straw applied into the soil at 1%-2% (w/w), and they all decreased significantly while the application rate reached 8%. The NR activity in root increased significantly when carbonized straw applied into the soil at 0.5%-2.0% (w/w) and dropped significantly while the application rate at 4.0%-8.0%. It was more significant after 120-170 d of treatment that the effects of carbonized straw on the nitric oxide formation and nitrate reduction in root. The rate of NO formation, the activity of NR and NiR in the soil of root zone all increased significantly when carbonized straw applied into the soil at 1%-2% (w/w). But the rate of NO formation decreased significantly when the carbonized straw applied over 1%; the activity of NR and NiR in root zone soil dropped significantly when the application rate over 2.0%. It was 120-155 d after treatment that the effects of carbonized straw on the nitric oxide formation and nitrate reduction in root were most significant. The application of carbonized straw promoted the nitrification in the soil of root zone. The nitrification strength of root zone soil reached maximum when the dose of carbonized straw applied at 2%, and soil HyR activity increased gradually with the application rate of carbonized straw increased from 0.5% to 8.0%. It was more significant after 120-170 d of treatment that the effects of carbonized straw on the nitrification of root zone soil.【Conclusion】The application of carbonized straw into soil influenced the NO formation in apple roots and the nitrate metabolism in root zone soil significantly. The reduction of nitrate to NO in apple roots and root zone soil is promoted by carbonization straw in the lower application rate of 0.5%-1.0%. The nitrification in the soil of root zone was promoted by carbonization straw in the higher application rate of 2.0%-4.0%. It is most significant that the nitrate reduction promoted by carbonization straw in the soil of root zone when the application rate was 0.5%. The rate of NO formation in roots was the highest when the application rate of carbonization straw was 1.0%. The nitrification strength of root zone soil was the highest when the application rate of carbonization straw was 1.0%.

Key words: carbonized straw, root, root-zone soil, nitric oxide, nitrate metabolism

YAN Li-juan, YANG Hong-qiang, SU Qian, MEN Xiu-jin, ZHANG Wei-wei. Effects of Carbonized Straw on the Nitric Oxide Formation and Nitrate Metabolism in Apple Roots and Its Root Zone Soil[J].Scientia Agricultura Sinica, 2014, 47(19): 3850-3856.

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References

[1] 朱兆良. 中国土壤氮素研究. 土壤学报, 2008, 45(5): 778-783.

Zhu Z L. Chinese soil nitrogen research. Journal of Soil, 2008, 45(5): 778-783. (in Chinese)

[2] Howden N J, Burt T P, Worrall F, Mathias S A, Whelan M J. Farming for water quality: balancing food security and nitrate pollution in UK river basins. Annals of the Association of American Geographers, 2013, 103(2): 397-407.

[3] 杜连凤, 赵同科, 张成军, 安志装, 吴琼, 刘宝存, 李鹏, 马茂亭. 京郊地区3种典型农田系统硝酸盐污染现状调查. 中国农业科学, 2009, 42(8): 2837-2843

Du L F, Zhao T K, Zhang C J, An Z Z, Wu Q , Liu B C, Li P, Ma M T. Investigation on nitrate pollution in soils, ground water and vegetables of three typical farmlands in Beijing region. Scientia Agricultura Sinica, 2009, 42(8): 2837-2843.(in Chinese)

[4] Lehmann J, Gaunt J, Rondon M. Biochar sequestration in terresterial ecosystems - a review. Mitig Adapt Strat Global Change, 2006, 11: 403-427.

[5] Demirbas A. Effects of temperature and particle size on biochar yield from pyrolysis of agricultural residues. Journal of Analytical and Applied Pyrolysis, 2004, 72: 243-248.

[6] Schmidt M W I, Noack A G. Black carbon in soils and sediments: analysis, distribution, implications, and current challenges. Global Biogeochemical Cycles, 2000, 14(3): 777-793.

[7] Glaser B, Lehmann J, Zech W. Ameliorating physical and chemical properties of highly weathered soils in the tropics with charcoal-a review. Biology Fertility of Soils, 2002, 35: 219-230.

[8] Steiner C, Glaser B, Teixeira W G, Lehmann J, Blum W E H, Zech W. Nitrogen retention and plant uptake on a highly weathered central Amazonian Ferralsol amended with compost and charcoal. Soil Seience and Plant Nutrition, 2008, 171: 275-290.

[9] Warnock D D, Lehmann J, Kuyper T W, Rillig M C. Mycorrhizal responses to biochar in soil-concepts and mechanisms. Plant and Soil, 2007, 300: 9-20.

[10] Liang B, Lehmann J, Solomon D. Black carbon increase cation exchange capacity in soils. Soil Science Society of America Journal, 2006, 70(5): 1719-1730.

[11] Glaser B, Haumaier L, Guggenberger G, Zech W. The ‘Terra Preta’ phenomenon: a model for sustainable agriculture in the humid tropics. Naturwissenschaften, 2001, 88: 37-41.

[12] Saito M, Marumoto T. Inoculation with arbuscular mycorrhizal fungi: The status quo in Japan and the future prospects. Plant and Soil, 2002, 244: 273-279.

[13] Wang J, Zhang M, Zheng Q, Liu P, Pan G. Effects of biochar addition on N₂O and CO₂ emissions from two paddy soils. Biology and Fertility of Soils, 2011, 47: 887-896

[14] Kammann C, Ratering S, Eckhard C. Biochar and hydrochar effects on greenhouse gas (carbon dioxide, nitrous oxide, and methane) fluxes from soils. Journal of Environmental Quality,2012, 41(4): 1052-1066.

[15] Felber R, Hüppi R, Leifeld J, Neftel A. Nitrous oxide emission reduction in temperate biochar-amended soils. Biogeosciences Discuss, 2012, 9: 151-189.

[16] Wang Z, Zheng H, Luo Y, Deng X, Herbert S, Xing B. Characterization and influence of biochars on nitrous oxide emission from agricultural soil. Environmental Pollution, 2013, 174: 289-296.

[17] Giles M, Morley N, Baggs E M, Daniell T J. Soil nitrate reducing processes - drivers, mechanisms for spatial variation, and significance for nitrous oxide production. Front Microbiology, 2012, 3(407): 1-16.

[18] Atkinson C J, Fitzgerald J D, Hipps N A. Potential mechanisms for achieving agricultural benefits from biochar application to temperate soils: a review. Plant and Soil, 2010, 37: 1-18.

[19] Warnock D D, Lehmann J, Kuyper T W, Rillig M C. Mycorrhizal responses to biochar in soil-concepts and mechanisms . Plant and Soil, 2007, 300: 9-20.

[20] 高华君, 杨洪强, 杜方岭. 平邑甜茶幼苗生长过程中精氨酸和一氧化氮水平的变化.植物营养与肥料学报, 2008, 14(4): 774-778.

Gao H J, Yang H Q, Du F L. Changes in arginine and nitric oxide levels in Malus hupehensis Rehd. seedlings during plant development. Plant Nutrition and Fertilizer Science, 2008, 14(4): 774-778. (in Chinese)

[21] Hageman R H, Hucklesby D P. Nitrate reductase from higher plants. Methods in Enzymology, 1971, 23: 491-503.

[22] 关荫松. 土壤酶及其研究法. 北京: 农业出版社, 1986: 320-338.

Guan Y S. Soil Enzyme and Its Methodology. Beijing: Agriculture Press, 1986: 320-338. (in Chinese)

[23] 唐光木, 葛春辉, 徐万里, 王西和, 郑金伟, 李恋卿, 潘根兴. 施用生物黑炭对新疆灰漠土肥力与玉米生长的影响. 农业环境科学学报, 2011, 30(9): 1797-1802.

Tang G M, Ge C H Xu W L, Wang X H, Zheng J W, Li L Q, Pan G X. Effect of applying biochar on the quality of grey desert soil and maize cropping in Xinjiang, China. Journal of Agro-Environment Science, 2011, 30(9): 1797-1802. (in Chinese)

[24] Laird D A, Fleming P, Davis D D, Horton R, Wang B, Karlen D L. Impact of biochar amendment on the quality of a typical Midwestern agricultural soil. Geoderma, 2010, 158: 443-449.

[25] Nacry P, Bouguyon E, Gojon A. Nitrogen acquisition by roots: physiological and developmental mechanisms ensuring plant adaptation to a fluctuating resource. Plant and Soil, 2013, 370(1/2): 1-29.

[26] Neill S, Hancock J, Desikan R. Preface to nitric oxide signalling: plant growth and development. Journal of Experimental Botany, 2006, 57(3): 462.

[27] Gouvea C M C P, Souza J F, Magalhaes A C N, Martins I S. NO₂ releasing substances that induce growth elongation in maize root segments. Plant Growth Regulation, 1997, 21(3): 183-187.

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