Nutrient uptake strategy selection by first-order roots of Juglans mandshurica under shading and phosphorus limitation

doi:10.13287/j.1001-9332.202312.008

Abstract

Abstract: We investigated root growth of 1-year-old Juglans mandshurica seedlings under different light environments and varying doses of phosphorus fertilizer, to understand the relationship between root resource acquisition strategies and the variations of light and phosphorus availability. There were four shading intensities (full light, 65% full light, 35% full light, and 20% full light) along with three doses of phosphate fertilizer (0 (CK), 200% soil background available phosphorus, and 500% soil background available phosphorus). We measured in root morphology characteristics, architectural characteristics, and mycorrhizal colonization rates of first-order roots. The results showed that average diameter, average root length, and mycorrhizal colonization rates of first-order roots gradually decreased, and the specific root length, specific surface area, branching ratio and branching intensity showed a trend of first increasing and then decreasing with the increases of shading degree. As the phosphorus content decreased, the first-order root diameter gradually became thinner, and the mycorrhizal infection rate gradually increased. Root morphology and architecture of J. mandshurica would undergo adaptive changes under shade, adapting to the shading environment by expanding specific root length, specific surface area, branching ratio and branching intensity. Under phosphorus limitation, root system of J. mandshurica would increase phosphorus absorption through symbiosis with mycorrhizal fungi. When J. mandshurica was artificially regenerate in forest land with a light transmittance of 35%, root morphology and architecture would adapt to the shading environment. The symbiosis between J. mandshurica and mycorrhizal fungi would be enhanced under phosphorus limitation, which could improve phosphorus absorption of roots.

Key words: Juglans mandshurica, shading, phosphorus limitation, first-order root

CAI Zhi, WANG Qingcheng, ZHANG Yong, XU Liqing , LI Qiuyu. Nutrient uptake strategy selection by first-order roots of Juglans mandshurica under shading and phosphorus limitation[J]. Chinese Journal of Applied Ecology, 2023, 34(12): 3239-3244.

References

[1] 庄作峰. 中国天然林资源保护工程——世纪之交的重大生态工程. 世界林业研究, 2001, 14(3): 47-54
[2] 于均屹, 徐立清, 张勇, 等. 光照和地下竞争对林冠下人工更新紫椴苗木形态和生物量分配的影响. 森林工程, 2023, 39(4): 38-47
[3] 平晓燕, 周广胜, 孙敬松, 等. 基于功能平衡假说的玉米光合产物分配动态模拟. 应用生态学报, 2010, 21(1): 129-135
[4] Devine WD, Harrington TB. Belowground competition from overstory trees influences Douglas-fir sapling morphology in thinned stands. New Forests, 2009, 37: 137-153
[5] Barber SA, Bouldin DR, Karal DM, et al. Roots, nutrient and water influx, and plant growth// Barber SA. Plant Root Morphology and Nutrient Uptake. New York: Wiley-Interscience, 1984: 65-87
[6] 平晓燕, 周广胜, 孙敬松, 等. 植物光合产物分配及其影响因子研究进展. 植物生态学报, 2010, 34(1): 100-111
[7] 韩文娟, 何景峰, 张文辉, 等. 黄龙山林区油松人工林林窗对幼苗根系生长及土壤理化性质的影响. 林业科学, 2013, 49(11): 16-23
[8] 张东来, 葛文志, 张玲, 等. 遮阴处理对胡桃楸幼苗形态特征及生理特性的影响. 林业科技, 2017, 42(6): 1-4
[9] 张书娜, 王庆成, 郝龙飞, 等. 光照和施肥对白桦林冠下水曲柳、胡桃楸苗木生长的影响. 森林工程, 2015, 31(2): 51-56
[10] 王清君, 王若森, 刘立波, 等. 次生林内胡桃楸人工更新技术. 林业科技开发, 2010, 24(4): 128-130
[11] 王庆成, 程云环. 土壤养分空间异质性与植物根系的觅食反应. 应用生态学报, 2004, 15(6): 1063-1068
[12] 赵艳云, 陆兆华, 夏江宝, 等. 黄河三角洲贝壳堤岛3种优势灌木的根系构型. 生态学报, 2015, 35(6): 1688-1695
[13] 郭小城. 不同光环境下入侵植物瘤突苍耳对大豆菌根真菌和根瘤菌的影响. 硕士论文. 沈阳: 沈阳农业大学, 2020
[14] 祁鲁玉, 吴峰, 吴瑞雪, 等. 遮阴和不同形态氮素施肥对红松幼苗生长的影响. 森林工程, 2019, 35(4): 1-5
[15] Fitter AH. Morphometric analysis of root systems: Application of the technique and influence of soil fertility on root system development in two herbaceous species. Plant, Cell & Environment, 2010, 5: 313-322
[16] Rewald B, Raveh E, Gendler T, et al. Phenotypic plasticity and water flux rates of citrus root orders under salinity. Journal of Experimental Botany, 2012, 63: 2717-2727
[17] Caldwell BM. The effects of shading and N status on root proliferation in nutrient patches by the perennial grass Agropyron desertorum in the field. Oecologia, 1995, 103: 10-16
[18] Wen Z, Li H, Shen Q, et al. Tradeoffs among root morphology, exudation and mycorrhizal symbioses for phosphorus-acquisition strategies of 16 crop species. New Phytologist, 2019, 223: 882-895
[19] Phillips JM. Improved procedures for clearing roots and staining parasitic and vesicular-arbuscular mycorrhizal fungi for rapid assessment of infection. Transactions of the British Mycological Society, 1970, 55: 158-161
[20] Leuschner C, Hertel D, Schmid I, et al. Stand fine root biomass and fine root morphology in old-growth beech forests as a function of precipitation and soil fertility. Plant and Soil, 2004, 258: 43-56
[21] Hodge A. The plastic plant: root responses to heterogeneous supplies of nutrients. New Phytologist, 2010, 162: 9-24
[22] Bauhus J, Khanna P, Menden N, et al. Aboveground and belowground interactions in mixed plantations of Eucalyptus globulus and Acacia mearnsii. Canadian Journal of Forest Research, 2000, 30: 1886-1894
[23] 师伟, 王政权, 刘金梁, 等. 帽儿山天然次生林20个阔叶树种细根形态. 植物生态学报, 2008, 32(6): 1217-1226
[24] 徐立清, 崔东海, 王庆成, 等. 张广才岭西坡次生林不同生境胡桃楸幼树根系构型及细根特征. 应用生态学报, 2020, 31(2): 373-380
[25] Ward D. Shade affects fine-root morphology in range-encroaching eastern redcedars (Juniperus virginiana) more than competition, soil fertility and pH. Pedobiologia, 2021, 84: 150708
[26] 尹慧, 安莹, 陈雅君, 等. 不同遮阴强度下白三叶形态特征和生长动态. 中国草地学报, 2015, 37(5): 86-91
[27] Fitter AH. Functional significance of root morphology and root system architecture// Fitter AH. Ecological Interactions in Soil. London, UK: British Ecological Society, 1985: 87-106
[28] 王港, 白晋华, 刘碧桃, 等. 华北山地6个外生菌根树种的根属性及其与菌根侵染率的关系. 西北植物学报, 2020, 40(5): 852-861
[29] 郑朝元. 遮光和磷供应对菌根共生体碳-磷互作的影响及不同演替草原植物的菌根响应. 硕士论文. 北京: 中国农业大学, 2014
[30] Kong D, Ma C, Zhang Q, et al. Leading dimensions in absorptive root trait variation across 96 subtropical forest species. New Phytologist, 2014, 203: 863-872
[31] 苗原, 吴会芳, 马承恩, 等. 菌根真菌与吸收根功能性状的关系:研究进展与评述. 植物生态学报, 2013, 37(11): 1035-1042
[32] Jackson RB, Manwaring JH, Caldwell MM, et al. Rapid physiological adjustment of roots to localized soil enrichment. Nature, 1990, 344: 58-60
[33] Fang NY, Shan CR, Lei JG, et al. Responses of root architecture development to low phosphorus availability: A review. Annals of Botany, 2013, 112: 391-408
[34] 赵华, 徐芳森, 石磊, 等. 植物根系形态对低磷胁迫应答的研究进展. 植物学通报, 2006, 23(4): 409-417
[35] Eissenstat DM, Kucharski JM, Zadworny M, et al. Linking root traits to nutrient foraging in arbuscular mycorrhizal trees in a temperate forest. New Phytologist, 2015, 208: 114-124
[36] Holdaway RJ, Richardson SJ, Dickie IA, et al. Species- and community-level patterns in fine root traits along a 120000-year soil chronosequence in temperate rain forest. Journal of Ecology, 2011, 99: 954-963
[37] Zhang Y, Ma X, Zhou Z, et al. The influence of light conditions and interspecific competition on the root foraging traits and seedling growth of two tree species. Plant Biosystems, 2011, 146: 1-8