运用微根管技术研究草地植物细根的进展

doi:10.11686/cyxb2017041

摘要/Abstract

摘要： 微根管(minirhizotron, MR)技术自出现以来,因其方便、简洁、省时省力和能够原位观察的特点而在植物细根(直径<2 mm)研究中发挥重要作用。草地植物细根在土壤养分循环和草地可持续发展中起到关键作用。本研究综述了国内外学者运用微根管技术研究草地植物细根的进展,主要集中在草地植物根系产量、寿命及周转速率对气候变化、草地管理与利用以及土壤生物的响应等方面。多数研究认为CO₂浓度升高和气候变暖会增加植物细根根长、根数量或生物量,降低根系寿命;春季发生的细根寿命相对秋季发生的细根较短。刈割和人工施加氮肥对天然草地植物根系没有显著影响,但会成倍增加草地地上生物量,减少物种丰富度。植物细根寿命与直径呈正相关关系,周转速率与直径呈负相关关系。微根管技术在今后研究的重点可围绕4个方面:1)放牧、草地利用与管理以及土壤生物与草地植物细根的相互关系;2)根系寿命或周转速率对土壤碳库或养分库的影响;3)气候变化或人类活动引起草地植物根系发生变化的机制。通过综述,以期更好地利用微根管技术服务于草地根系研究,促进草地农业生态系统根系研究的发展。

Abstract: Minirhizotron (MR) devices are playing an important role in fine root study due to their convenience, low time-input requirement, also because they can be used in situ. The fine roots of grassland plants are important in the soil nutrient cycle and in the sustainable development of grassland. Therefore, this review summarized the progress of research into fine root dynamics of plants in grassland. Aspects covered include the effect of global climate change, land use, land management and soil organisms on root longevity and root turnover rate. Most studies indicated that high CO₂ concentration, and also global warming, increased root length, root number or biomass, but decreased root longevity. Fine roots developed in spring tend to have greater longevity than those developed in autumn. Additionally, grazing and nitrogen fertilizer have no effect on plant root growth, but increase shoot biomass, and decrease the species diversity in natural grassland. Plant fine root longevity is positively correlated with root diameter, whereas root turnover rate is negatively correlated with root diameter. The future research directions for MR research include study of: 1) the relationship between grazing, land-use change, soil organism populations and plant root dynamics in grassland; 2) the effect of root longevity and root turnover rate on the soil carbon and soil nutrient pool; 3) the mechanisms where by interaction between climate change and human activity affect plant root systems; and 4) how external factors influence the relationship between plant roots and soil organisms. We expect to raise awareness of the application of MR technology in the grassland agro-ecosystem research, and to advance the development of fine root research in grasslands.

牛学礼, 南志标. 运用微根管技术研究草地植物细根的进展[J]. 草业学报, 2017, 26(11): 205-215.

NIU Xue-Li, NAN Zhi-Biao. Review of minirhizotron applications for study of fine roots in grassland[J]. Acta Prataculturae Sinica, 2017, 26(11): 205-215.

参考文献

[1] Scurlock J, Hall D. The global carbon sink: a grassland perspective. Global Change Biology, 1998, 4(2): 229-233.
[2] Nan Z B. The grassland farming system and sustainable agricultural development in China. Grassland Science, 2005, 51(1): 15-19.
[3] Parton W J, Stewart J W B, Cole C V. Dynamics of C, N, P and S in grassland soils: a model. Biogeochemistry, 1988, 5(1): 109-131.
[4] McGill W, Hunt H, Woodmansee R, et al . Phoenix, a model of the dynamics of carbon and nitrogen in grassland soils. Ecological Bulletins, 1981, 33: 105-113.
[5] Plantureux S, Peeters A, McCracken D. Biodiversity in intensive grasslands: Effect of management, improvement and challenges. Agronomy Research, 2005, 3(2): 153-164.
[6] Conant R T, Paustian K, Elliott E T. Grassland management and conversion into grassland: effects on soil carbon. Ecological Applications, 2001, 11(2): 343-355.
[7] Brodie E, Edwards S, Clipson N. Soil fungal community structure in a temperate upland grassland soil. FEMS Microbiology Ecology, 2003, 45(2): 105-114.
[8] Osterkamp W, Hupp C, Stoffel M. The interactions between vegetation and erosion: new directions for research at the interface of ecology and geomorphology. Earth Surface Processes and Landforms, 2012, 37(1): 23-36.
[9] Fattet M, Fu Y, Ghestem M, et al . Effects of vegetation type on soil resistance to erosion: Relationship between aggregate stability and shear strength. Catena, 2011, 87(1): 60-69.
[10] Burylo M, Hudek C, Rey F. Soil reinforcement by the roots of six dominant species on eroded mountainous marly slopes (Southern Alps, France). Catena, 2011, 84(1/2): 70-78.
[11] Du Q, Zhong Q C, Wang K Y. Root effect of three vegetation types on shoreline stabilization of Chongming Island, Shanghai. Pedosphere, 2010, 20(6): 692-701.
[12] Goebel M, Hobbie S E, Bulaj B, et al . Decomposition of the finest root branching orders: linking belowground dynamics to fine-root function and structure. Ecological Monographs, 2011, 81(1): 89-102.
[13] Wan L Q, Hou X Y, Ren J Z. The application system coupling in grassland agro-system in China. Chinese Journal of Eco-agriculture, 2004, 12(1): 162-164.
万里强, 侯向阳, 任继周. 系统耦合理论在我国草地农业系统应用的研究. 中国生态农业学报, 2004, 12(1): 162-164.
[14] Ren J Z, Nan Z B, Hao D Y. The three major interfaces within pratacultural system. Acta Prataculturae Sinica, 2000, 9(1): 1-8.
任继周, 南志标, 郝敦元. 草业系统中的界面论. 草业学报, 2000, 9(1): 1-8.
[15] Zhou B Z, Zhang S G, Fu M Y. Minirhizotron, a new technique for plant root system research: its invention, development and application. Chinese Journal of Ecology, 2007, 26(2): 253-260.
周本智, 张守攻, 傅懋毅. 植物根系研究新技术Minirhizotron的起源、发展和应用. 生态学杂志, 2007, 26(2): 253-260.
[16] Nadelhoffer K J. The potential effects of nitrogen deposition on fine-root production in forest ecosystems. New Phytologist, 2000, 147(1): 131-139.
[17] Gill R A, Jackson R B. Global patterns of root turnover for terrestrial ecosystems. New Phytologist, 2010, 147(1): 13-31.
[18] Wu Y B, Che R X, Ma S, et al . Estimation of root production and turnover in an alpine meadow: comparison of three measurement methods. Acta Ecologica Sinica, 2014, 34(13): 3529-3537.
吴伊波, 车荣晓, 马双, 等. 高寒草甸植被细根生产和周转的比较研究. 生态学报, 2014, 34(13): 3529-3537.
[19] Guo D, Li H, Mitchell R J, et al . Fine root heterogeneity by branch order: exploring the discrepancy in root turnover estimates between minirhizotron and carbon isotopic methods. New Phytologist, 2008, 177(2): 443-456.
[20] Liao X Q. Review on research methods of plant roots. World Agriculture, 1995, 7: 23-24.
廖兴其. 根系研究方法评述. 世界农业, 1995, 7: 23-24.
[21] Huang R D. Development of methods of studying root systems. Journal of Shengyang Agiricultral University, 1991, 22(2): 164-168.
黄瑞冬. 植物根系研究方法的发展. 沈阳农业大学学报, 1991, 22(2): 164-168.
[22] Hendrick R L, Pregitzer K S. Patterns of fine root mortality in two sugar maple forests. Nature, 1993, 361: 59-61.
[23] Joslin J D, Wolfe M H. Disturbances during minirhizotron installation can affect root observation data. Soil Science Society of America Journal, 1999, 63(1): 218-221.
[24] Johnson M G, Tingey D T, Phillips D L, et al . Advancing fine root research with minirhizotrons. Environmental and Experimental Botany, 2001, 45(3): 263-289.
[25] Waddington J. Observation of plant roots in situ. Canadian Journal of Botany, 1971, 49(10): 1850-1852.
[26] Tierney G L, Fahey T J. Fine root turnover in a northern hardwood forest: a direct comparison of the radiocarbon and minirhizotron methods. Canadian Journal of Forest Research, 2002, 32(9): 1692-1697.
[27] Pritchard S G, Strand A E, Mccormack M L, et al . Fine root dynamics in a loblolly pine forest are influenced by free-air-CO 2 -enrichment: a six-year-minirhizotron study. Global Change Biology, 2008, 14(3): 588-602.
[28] Day F P, Weber E P, Hinkle C, et al . Effects of elevated atmospheric CO 2 on fine root length and distribution in an oak-palmetto scrub ecosystem in central Florida. Global Change Biology, 1996, 2(2): 143-148.
[29] Machado R M A, do Rosario M, Oliveira G, et al . Tomato root distribution, yield and fruit quality under subsurface drip irrigation. Plant and Soil, 2003, 255(1): 333-341.
[30] Merrill S D. Pressurized-wall minirhizotron for field observation of root growth dynamics. Agronomy Journal, 1992, 84: 755-758.
[31] Martin D, Chambers J. Restoration of riparian meadows degraded by livestock grazing: above- and belowground responses. Plant Ecology, 2002, 163(1): 77-91.
[32] Kobiela B, Biondini M, Sedivec K. Comparing root and shoot responses to nutrient additions and mowing in a restored semi-arid grassland. Plant Ecology, 2016, 217(3): 303-314.
[33] Iversen C, Murphy M, Allen M, et al . Advancing the use of minirhizotrons in wetlands. Plant and Soil, 2012, 352(1/2): 23-39.
[34] Vamerali T, Bandiera M, Mosca G. Minirhizotrons in modern root studies[M]//Measuring Roots. Berlin Heidelberg: Springer, 2012: 341-361.
[35] Majdi H. Root sampling methods-applications and limitations of minirhizotron technique. Plant and Soil, 1996, 185: 255-258.
[36] Hendrick R L, Pregitzer K S. Applications of minirhizotrons to understand root function in forests and other natural ecosystems. Plant and Soil, 1996, 185: 293-304.
[37] Shi J W, Yu S Q, Yu L Z, et al . Application of minirhizotron in fine root studies. Chinese Journal of Applied Ecology, 2006, 17(4): 715-719.
史建伟, 于水强, 于立忠, 等. 微根管在细根研究中的应用. 应用生态学报, 2006, 17(4): 715-719.
[38] Bai W M, Cheng W X, Li L H. Applications of minirhizotron techniques to root ecology research. Acta Ecologica Sinica, 2005, 25(11): 3076-3081.
白文明, 程维信, 李凌浩. 微根窗技术及其在植物根系研究中的应用. 生态学报, 2005, 25(11): 3076-3081.
[39] Guo L B, Wang M, Gifford R M. The change of soil carbon stocks and fine root dynamics after land use change from a native pasture to a pine plantation. Plant & Soil, 2007, 299(1/2): 251-262.
[40] Pilon R, Picon-Cochard C, Bloor J M G, et al . Grassland root demography responses to multiple climate change drivers depend on root morphology. Plant & Soil, 2012, 364(1/2): 395-408.
[41] Guo D L. Plant root system: architecture, function and the status in material cycle of ecosystem[M]//Lectures in Modern Ecology (ш) Advances and Key Topics. Beijing: Higher Education Press, 2007: 92-109.
郭大立. 植物根系: 结构、功能及在生态系统物质循环中的地位[M]//现代生态学讲座(Ⅲ)学科进展与热点论题. 北京: 高等教育出版社, 2007: 92-109.
[42] Vogt K A, Grier C C, Gower S T, et al . Overestimation of net root production: A real or imaginary problem. Ecology, 1985, 67(2): 577-579.
[43] Schoettle A W, Shoettle A W. Foliage and fine root longevity of pines. Ecological Bulletins, 1994, 43(43): 136-153.
[44] Quan X K, Yu S Q, Shi J W, et al . Minirhizotron and radiocarbon methods-their application and comparison in estimating fine root longevity. Chinese Journal of Ecology, 2007, 26(3): 428-434.
全先奎, 于水强, 史建伟, 等. 微根管法和同位素法在细根寿命研究中的应用及比较. 生态学杂志, 2007, 26(3): 428-434.
[45] Burton A J, Pregitzer K S, Hendrick R L. Relationships between fine root dynamics and nitrogen availability in Michigan northern hardwood forests. Oecologia, 2000, 125(3): 389-399.
[46] Pregitzer K S, Zak D R, Curtis P S, et al . Atmospheric CO 2 , soil nitrogen and turnover of fine roots. New Phytologist, 1995, 129(4): 579-585.
[47] Eissenstat D M, Yanai R D. The ecology of root lifespan. Advances in Ecological Research, 1997, 27: 1-60.
[48] Hendricks J J, Nadelhoffer K J, Aber J D. Assessing the role of fine roots in carbon and nutrient cycling. Trends in Ecology & Evolution, 1993, 8(5): 174-178.
[49] Gill R A, Burke I C, Lauenroth W K, et al . Longevity and turnover of roots in the shortgrass steppe: influence of diameter and depth. Plant Ecology, 2002, 159(2): 241-251.
[50] Wells C E, Glenn D M, Eissenstat D M. Changes in the risk of fine-root mortality with age: a case study in peach, Prunus persica (Rosaceae). American Journal of Botany, 2002, 89(1): 79-87.
[51] Mei L, Wang Z Q, Cheng Y H, et al . A review: factors influencing fine root longevity in forest ecosystems. Acta Phytoecologica Sinica, 2004, 28(4): 704-710.
梅莉, 王政权, 程云环, 等. 林木细根寿命及其影响因子研究进展. 植物生态学报, 2004, 28(4): 704-710.
[52] Wang Z, Ding L, Wang J, et al . Effects of root diameter, branch order, root depth, season and warming on root longevity in an alpine meadow. Ecological Research, 2016, 31(5): 739-747.
[53] van der Krift T A J, Berendse F. Root life spans of four grass species from habitats differing in nutrient availability. Functional Ecology, 2002, 16(2): 198-203.
[54] Wu Y, Deng Y, Zhang J, et al . Root size and soil environments determine root lifespan: evidence from an alpine meadow on the Tibetan Plateau. Ecological Research, 2013, 28(3): 493-501.
[55] van Vliet A J, Schwartz M D. Phenology and climate: the timing of life cycle events as indicators of climatic variability and change. International Journal of Climatology, 2002, 22(14): 1713-1714.
[56] Milchunas D G, Morgan J A, Rosier A R, et al . Root dynamics and demography in shortgrass steppe under elevated CO 2 , and comments on minirhizotron methodology. Global Change Biology, 2005, 11(10): 1837-1855.
[57] Sindhøj E, Hansson A C, Andrén O, et al . Root dynamics in a semi-natural grassland in relation to atmospheric carbon dioxide enrichment, soil water and shoot biomass. Plant & Soil, 2000, 223(1/2): 255-265.
[58] Leadley P W, Niklaus P A, Stocker R, et al . A field study of the effects of elevated CO 2 on plant biomass and community structure in a calcareous grassland. Oecologia, 1999, 118(1): 39-49.
[59] Volder A, Gifford R M, Evans J R. Effects of elevated atmospheric CO 2 , cutting frequency, and differential day/night atmospheric warming on root growth and turnover of Phalaris swards. Global Change Biology, 2007, 13(5): 1040-1052.
[60] Arnone J A, Zaller J G, Spehn E M, et al . Dynamics of root systems in native grasslands: effects of elevated atmospheric CO 2 . New Phytologist, 2000, 147(1): 73-85.
[61] Anderson L J, Derner J D, Polley H W, et al . Root responses along a subambient to elevated CO 2 gradient in a C 3 -C 4 grassland. Global Change Biology, 2010, 16(1): 454-468.
[62] Phillips D L, Johnson M G, Tingey D T, et al . Effects of elevated CO 2 on fine root dynamics in a Mojave Desert community: a FACE study. Global Change Biology, 2006, 12(1): 61-73.
[63] Wu Y, Jing Z, Deng Y, et al . Effects of warming on root diameter, distribution, and longevity in an alpine meadow. Plant Ecology, 2014, 215(9): 1057-1066.
[64] Kreyling J, Beierkuhnlein C, Pritsch K, et al . Recurrent soil freeze-thaw cycles enhance grassland productivity. New Phytologist, 2008, 177(4): 938-945.
[65] Edwards E J, Benham D G, Marland L A, et al . Root production is determined by radiation flux in a temperate grassland community. Global Change Biology, 2004, 10(2): 209-227.
[66] Ditomaso J M, Kyser G B, Pirosko C B. Effect of light and density on yellow starthistle ( Centaurea solstitialis ) root growth and soil moisture use. Weed Science, 2003, 51(3): 334-341.
[67] Stewart A M, Frank D A. Short sampling intervals reveal very rapid root turnover in a temperate grassland. Oecologia, 2008, 157(3): 453-458.
[68] Ren A T, Narkesi W, Lu W H, et al . Effect of the arbuscular mycorrhizal fungi on the dynamic characteristics of fine root growth and biomass of alfalfa. Acta Botanical Boreal-Occidentalia Sinica, 2014, 34(12): 2535-2543.
任爱天, 娜丽克斯·外里, 鲁为华, 等. AM真菌对紫花苜蓿细根生长及其生物量动态特征的影响. 西北植物学报, 2014, 34(12): 2535-2543.
[69] Ren A T, Lu W H, Yang J J, et al . Seasonal change patterns in the production and mortality of fine roots in cotton and alfalfa. Acta Prataculturae Sinica, 2015, 24(6): 213-219.
任爱天, 鲁为华, 杨洁晶, 等. 棉花、苜蓿细根生长和死亡的季节变化. 草业学报, 2015, 24(6): 213-219.
[70] Xun J J, Li J Y, Chen J W, et al . Relationships of fine root standing length of Caragana korshinskii seedlings with environmental factors. Chinese Journal of Plant Ecology, 2009, 33(4): 764-771.
荀俊杰, 李俊英, 陈建文, 等. 幼龄柠条细根现存量与环境因子的关系. 植物生态学报, 2009, 33(4): 764-771.
[71] Huang G, Zhao X Y, Su Y G. Root dynamics of three grasses in Horqin sandy land of China. Journal of Plant Ecology, 2007, 31(6): 1161-1167.
黄刚, 赵学勇, 苏延桂. 科尔沁沙地3种草本植物根系生长动态. 植物生态学报, 2007, 31(6): 1161-1167.
[72] Huang G, Zhao X Y, Huang Y X, et al . The root longevity of Artemisia halodendron inhabiting two sandy land habitats. Chinese Journal of Plant Ecology, 2009, 33(4): 755-763.
黄刚, 赵学勇, 黄迎新, 等. 两种生境条件下差不嘎蒿细根寿命. 植物生态学报, 2009, 33(4): 755-763.
[73] Balogianni V G, Wilson S D, Vaness B M, et al . Different root and shoot responses to mowing and fertility in native and invaded grassland. Rangeland Ecology & Management, 2014, 67(1): 39-45.
[74] Guo L B, Halliday M J, Siakimotu S J M, et al . Fine root production and litter input: Its effects on soil carbon. Plant & Soil, 2005, 272: 1-10.
[75] Frank D A, Kuns M M, Guido D R. Consumer control of grassland plant production. Ecology, 2002, 83(3): 602-606.
[76] Bonin C, Flores J, Lal R, et al . Root characteristics of perennial warm-season grasslands managed for grazing and biomass production. Agronomy, 2013, 3(3): 508-523.
[77] Rytter R M, Rytter L. Quantitative estimates of root densities at minirhizotrons differ from those in the bulk soil. Plant & Soil, 2012, 350(1/2): 205-220.
[78] Pärtel M, Wilson S D. Root and leaf production, mortality and longevity in response to soil heterogeneity. Functional Ecology, 2002, 15(6): 748-753.
[79] Kristensen H L, Thorup-kristensen K. Root growth and nitrate uptake of three different catch crops in deep soil layers. Soil Science Society of America Journal, 2004, 68(2): 529-537.
[80] Ziter C, MacDougall A S. Nutrients and defoliation increase soil carbon inputs in grassland. Ecology, 2013, 94(1): 106-116.
[81] Padilla F M, de Dios Miranda J, Armas C, et al . Effects of changes in rainfall amount and pattern on root dynamics in an arid shrubland. Journal of Arid Environments, 2015, 114: 49-53.
[82] Mann J J, Barney J N, Kyser G B, et al . Root system dynamics of Miscanthus×giganteus and Panicum virgatum in response to rainfed and irrigated conditions in California. Bioenergy Research, 2012, 6(2): 678-687.
[83] Fu J M, Dernoeden P H. Creeping bentgrass putting green turf responses to two summer irrigation practices: rooting and soil temperature. Crop Science, 2009, 49(3): 1063-1070.
[84] Majdi H, Damm E, Nylund J E. Longevity of mycorrhizal roots depends on branching order and nutrient availability. New Phytologist, 2001, 150(1): 195-202.
[85] Zhao A F. Morphology, distribution and dynamics of root systems of Artemisia halodendron and Caragana microphylla . Grassland of China, 1994, 3: 15-19.
赵爱芬. 差巴嘎蒿和小叶锦鸡儿根系分布及生长动态的初步研究. 中国草地学报, 1994, 3: 15-19.
[86] Zhang Z S, Li X R, Zhang J G, et al . Root growth dynamics of Caragana korshinskii using minirhizotrons. Journal of Plant Ecology, 2006, 30(3): 457-464.
张志山, 李新荣, 张景光, 等. 用Minirhizotrons观测柠条根系生长动态. 植物生态学报, 2006, 30(3): 457-464.
[87] Steinaker D F, Wilson S D. Belowground litter contributions to nitrogen cycling at a northern grassland-forest boundary. Ecology, 2005, 86(10): 2825-2833.
[88] Solly E F, Schöning I, Boch S, et al . Factors controlling decomposition rates of fine root litter in temperate forests and grasslands. Plant & Soil, 2014, 382(1/2): 203-218.
[89] Arnone III J A, Zaller J G. Earthworm effects on native grassland root system dynamics under natural and increased rainfall. Frontiers in Plant Science, 2014, 5(2): 152-159.
[90] Steinaker D F, Wilson S D. Scale and density dependent relationships among roots, mycorrhizal fungi and collembola in grassland and forest. Oikos, 2008, 117(5): 703-710.
[91] Aryal S K, Crow W T, Mcsorley R, et al . Effects of infection by Belonolaimus longicaudatus on rooting dynamics among St. Augustine grass and Bermudagrass genotypes. Journal of Nematology, 2015, 47(4): 332-331.
[92] Ren A T. Effect of Arbuscular Mycorrhizal Fungi on Phosphorus Utilization and Turnover of Fine Root of Alfalfa[D]. Shihezi: Shihezi University, 2015.
任爱天. 丛枝菌根真菌(AMF)对苜蓿磷素利用效率和细根周转的影响[D]. 石河子: 石河子大学, 2015.
[93] Treseder K K, Schimel J P, Garcia M O, et al . Slow turnover and production of fungal hyphae during a Californian dry season. Soil Biology and Biochemistry, 2010, 42(9): 1657-1660.
[94] Vogt K A, Vogt D J, Bloomfield J. Analysis of some direct and indirect methods for estimating root biomass and production of forests at an ecosystem level. Plant & Soil, 1998, 200(1): 71-89.