[1] 王琴, 郭良栋. 油松外生菌根的形态解剖特征. 林业科学, 2013, 49(2): 100-111 [Wang Q, Guo L-D. Morphological characteristics of ectomycorrhizae associa-ted with Pinus tabulaeformis. Scientia Silvae Sinicae, 2013, 49(2): 100-111] [2] Wang Q, Gao C, Guo LD. Ectomycorrhizae associated with Castanopsis fargesii (Fagaceae) in a subtropical forest, China. Mycological Progress, 2011, 10: 323-332 [3] Van der Heijden MG, Bardgett RD, Van Straalen NM. The unseen majority: Soil microbes as drivers of plant diversity and productivity in terrestrial ecosystems. Eco-logy Letters, 2008, 11: 296-310 [4] Read DJ, Perez-Moreno J. Mycorrhizas and nutrient cycling in ecosystems: A journey towards relevance? New Phytologist, 2003, 157: 475-492 [5] Abd-Alla MH, EI-Enany AW, Nafady NA, et al. Synergistic interaction of Rhizobium leguminosarum bv. viciae and arbuscular mycorrhizal fungi as a plant growth promoting biofertilizers for faba bean (Vicia faba L.) in alkaline soil. Microbiological Research, 2014, 169: 49-58 [6] Fernandez CW, Nguyen NH, Stefanski A, et al. Ectomycorrhizal fungal response to warming is linked to poor host performance at the boreal-temperate ecotone. Global Change Biology, 2016, 23: 1598-1609 [7] Agerer R. Exploration types of ectomycorrhizae: A proposal to classify ectomycorrhizal mycelial system according to their patterns of differentiation and putative ecological importance. Mycorrhiza, 2001, 11: 107-114 [8] Lilleskov EA, Hobbie EA, Horton TR. Conservation of ectomycorrhizal fungi: Exploring the linkages between functional and taxonomic responses to anthropogenic N deposition. Fungal Ecology, 2011, 4: 174-183 [9] Morgado LN, Semenova TA, Welker JM, et al. Summer temperature increase has distinct effects on the ectomycorrhizal fungal communities of moist tussock and dry tundra in Arctic Alaska. Global Change Biology, 2015, 21: 959-972 [10] Comas LH, Eissenstat DM. Patterns in root trait variation among 25 co-existing North American forest species. New Phytologist, 2009, 182: 919-928 [11] Ostonen I, Helmisaari HS, Borken W, et al. Fine root foraging strategies in Norway spruce forests across a European climate gradient. Global Change Biology, 2011, 17: 3620-3632 [12] Ostonen I, Truu M, Helmisaari HS, et al. Adaptive root foraging strategies along a boreal-temperate forest gra-dient. New Phytologist, 2017, 215: 977-991 [13] 刘庆. 亚高山针叶林生态学研究. 成都: 四川大学出版社, 2002 [Liu Q. Ecological Research on Subalpine Coniferous Forests in China. Chengdu: Sichuan University Press, 2002] [14] 李文建. 冷杉、红桦内外生菌根对温度、CO2浓度和栽培密度响应的研究. 硕士论文. 成都: 四川农业大学, 2006 [Li W-J. Studies on Endomycorrhiza and Ectomycorrhizal of Abies faxoniana and Betula albo-sinensis Response to Temperature and CO2 Concentration and Cultivated Density. Chengdu: Sichuan Agricultural University, 2006] [15] 何飞, 冯秋红, 潘红丽, 等. 四川卧龙岷江冷杉林分布规律及种群特征. 四川林业科技, 2015, 36(2): 10-14 [He F, Feng Q-H, Pan H-L, et al. Distribution Law and Population Characteristics of Abies faxoniana Forest in Wolong Natural Reserve, Sichuan Province. Journal of Sichuan Forestry Science and Technology, 2015, 36(2): 10-14] [16] Mitchell K. Quantitative Analysis by the Point-centered Quarter Method. PhD Thesis. New York: Hobart and William Smith Colleges, 2007 [17] Köhle J, Yang N, Pena R, et al. Ectomycorrhizal fungal diversity increases phosphorus uptake efficiency of European beech. New Phytologist, 2018, 220: 1200-1210 [18] Agerer R. Colour Atlas of Ectomycorrhizae. Schwäbisch Gmünd: Einhorn-Verlag, 2006 [19] Matsuda Y, Hijii N. Ectomycorrhizal fungal communities in an Abies firma forest, with special reference to ectomycorrhizal associations between seedlings and mature trees. Canadian Journal of Botany, 2004, 82: 822-829 [20] Nelson DW, Sommers LE. Total carbon, organic carbon, and organic matter// Page AL, Miller RH, Keeney DR, eds. Methods of Soil Analysis. Madison: American Sociert of Afronomy and Soil Science Society of American, 1982: 101-129 [21] Gallaher RN, Weldon CO, Boswell FC. A semi-automated procedure for total nitrogen in plant and soil samples. Soil Science Society of America Journal, 1976, 40: 887-889 [22] Ladd JN, Butler JHA. Short-term assays of soil proteolytic enzyme activities using proteins and dipeptide derivatives as substrates. Soil Biology and Biochemistry, 1972, 4: 19-30 [23] Schinner F, Ohlinger R, Kandeler E, et al. Methods in Soil Biology. Berlin: Springer-Verlag, 1995: 162-232 [24] 关松荫. 土壤酶及其研究方法. 北京: 中国农业出版社, 1986: 214-344 [Guan S-Y. Soil Enzyme and Research Method. Beijing: China Agriculture Press, 1986: 214-344] [25] Ostonen I, Lõhmus K, Helmisaari HS, et al. Fine root morphological adaptations in Scots pine, Norway spruce and silver birch along a latitudinal gradient in boreal forests. Tree Physiology, 2007, 27: 1627-1634 [26] Rosinger C, Sandén H, Matthews B, et al. Patterns in ectomycorrhizal diversity, community composition, and exploration types in European Beech, Pine, and Spruce forests. Forests, 2018, 9: 445, doi: 10.3390/f9080445 [27] Ma Z, Guo D, Xu X, et al. Evolutionary history resolves global organization of root functional traits. Nature, 2018, 555: 94-97 [28] Koide RT, Fernandez C, Malcolm G. Determining place and process: Functional traits of ectomycorrhizal fungi that affect both community structure and ecosystem function. New Phytologist, 2014, 201: 433-439 [29] Tedersoo L, Naadel T, Bahram M, et al. Enzymatic activities and stable isotope patterns of ectomycorrhizal fungi in relation to phylogeny and exploration types in an afrotropical rain forest. New Phytologist, 2012, 195: 832-843 [30] Pritsch K, Garbaye J. Enzyme secretion by ECM fungi and exploitation of mineral nutrients from soil organic matter. Annals of Forest Science, 2011, 68: 25-32 [31] Koide R, Suomi L, Stevens C, et al. Interactions between needles of Pinus resinosa and ectomycorrhizal fungi. New Phytologist, 1998, 140: 539-547 [32] Clemmensen KE, Michelsen A, Jonasson S, et al. Increased ectomycorrhizal fungal abundance after long-term fertilization and warming of two arctic tundra ecosystems. New Phytologist, 2006, 171: 391-404 [33] Alberton O, Kuyper TW. Ectomycorrhizal fungi associated with Pinus sylvestris seedlings respond differently to increased carbon and nitrogen availability: Implications for ecosystem responses to global change. Global Change Biology, 2009, 15: 166-175 [34] 张薇, 黄建国, 袁玲, 等. 外生菌根真菌对Al3+胁迫和低钾土壤的响应. 环境科学, 2014, 35(10): 3862-3868 [Zhang W, Huang J-G, Yuan L, et al. Response of ectomycorrhizal fungi to aluminum stress and low potassium soil. Environmental Science, 2014, 35(10): 3862-3868] [35] 王琚钢, 峥嵘, 白淑兰, 等. 外生菌根对干旱胁迫的响应. 生态学杂志, 2012, 31(6): 1571-1576 [Wang J-G, Zheng R, Bai S-L, et al. Responses of ectomycorrhizal to drought stress: A review. Chinese Journal of Ecology, 2012, 31(6): 1571-1576] [36] Põlme S, Bahram M, Yamanaka T, et al. Biogeography of ectomycorrhizal fungi associated with alders (Alnus spp.) in relation to biotic and abiotic variables at the global scale. New Phytologist, 2013, 198: 1239-1249 [37] 朱教君, 许美玲, 康宏樟, 等. 温度、pH及干旱胁迫对沙地樟子松外生菌根菌生长影响. 生态学杂志, 2005, 24(12): 1375-1379 [Zhu J-J, Xu M-L, Kang H-Z, et al. Effects of temperature, pH and drought stresses on ectomycorrhizal fungi growth in a Pinus sylvestris var. mongolica plantation on sandy land. Chinese Journal of Ecology, 2005, 24(12): 1375-1379] |