亚热带岩溶区森林不同土壤氮水平下固氮植物对根际土壤磷含量的影响

doi:10.13287/j.1001-9332.202507.040

应用生态学报 ›› 2025, Vol. 36 ›› Issue (7): 2019-2027.doi: 10.13287/j.1001-9332.202507.040

亚热带岩溶区森林不同土壤氮水平下固氮植物对根际土壤磷含量的影响

朱雨^1,2, 李杰^1,2, 刘丽君³, 韦柳红^1,2, 陈淑婷^1,2, 邓璐嫔^1,2, 朱同彬³, 段敏^1,2,4*

¹广西师范大学珍稀濒危动植物生态与环境保护教育部重点实验室, 广西桂林 541006;
²广西漓江流域景观资源保育与可持续利用重点实验室, 广西桂林 541006;
³中国地质科学院岩溶地质研究所自然资源部/广西岩溶动力学重点实验室, 广西桂林 541004;
⁴广西漓江源森林生态系统国家定位观测研究站, 广西桂林 541316

收稿日期:2024-11-13 接受日期:2025-03-05 出版日期:2025-07-18 发布日期:2026-01-18
通讯作者: *E-mail: duanmin0517@163.com
作者简介:朱雨, 男, 2000年生, 硕士研究生。主要从事岩溶区森林土壤磷循环研究。E-mail: 2460643966@qq.com
基金资助:
国家自然科学基金项目(42467047,42067023)、广西科技基地和人才专项(桂科AD20159055)、广西师范大学珍稀濒危动植物生态与环境保护教育部重点实验室主任基金项目(ERESEP2020Z01)和自治区级大学生创新创业训练计划项目(S202410602006,S202410602007)

Effects of nitrogen-fixing plants on rhizosphere soil phosphorus contents at different soil nitrogen levels in subtropical karst forests

ZHU Yu^1,2, LI Jie^1,2, LIU Lijun³, WEI Liuhong^1,2, CHEN Shuting^1,2, DENG Lupin^1,2, ZHU Tongbin³, DUAN Min^1,2,4*

¹Ministry of Education Key Laboratory of Ecology of Rare and Endangered Species and Environmental Protection, Guangxi Normal University, Guilin 541006, Guangxi, China;
²Guangxi Key Laboratory of Landscape Resources Conservation and Sustainable Utilization in Lijiang River Basin, Guilin 541006, Guangxi, China;
³Key Laboratory of Karst Dynamics of Ministry of Natural and Resources & Guangxi, Institute of Karst Geology, Chinese Academy of Geological Sciences, Guilin 541004, Guangxi, China;
⁴Guangxi Lijiangyuan Forest Ecosystem Research Station, Guilin 541316, Guangxi, China

Received:2024-11-13 Accepted:2025-03-05 Online:2025-07-18 Published:2026-01-18

摘要/Abstract

摘要： 探究亚热带岩溶区森林固氮植物和非固氮植物根际土壤磷含量对不同土壤氮水平的响应差异,有助于深入认识固氮植物对土壤养分循环的影响,为该区域植被恢复过程中固氮植物的广泛种植提供科学参考。本研究以云南省建水县具有不同土壤氮水平的岩溶区森林为对象,采集基本处于同一年龄的3种优势固氮植物和非固氮植物根际土壤,测定全磷(TP)、有机磷(OP)、无机磷(IP)和有效磷(AP)含量及其他土壤理化性质,结合土壤微生物生物量和酶活性指标,分析不同土壤氮水平下固氮植物对根际土壤磷含量的影响及其主要影响因素。结果表明: 1)与非固氮植物相比,在土壤低氮(有效氮含量15.62 mg·kg^-1)水平下固氮植物根际土壤TP、OP和AP含量分别显著增加了16.0%、66.5%和139.5%,在高氮水平(有效氮含量37.15 mg·kg^-1)下分别显著增加了13.5%、25.7%和15.7%,但在两种土壤氮水平下IP含量在两种植物之间均没有显著差异;与低氮水平相比,在土壤高氮水平下固氮植物根际土壤TP和IP含量分别显著降低了21.3%和31.7%,非固氮植物分别显著降低了19.6%和39.1%,固氮和非固氮植物根际土壤AP含量分别显著提高了32.8%和174.8%,但OP含量没有显著影响。2)与非固氮植物相比,在低氮水平下,固氮植物显著提高了根际土壤微生物生物量碳(MBC)、氮(MBN)、磷(MBP)及碱性磷酸酶(ALP)活性;在高氮水平下,固氮植物显著提高了MBP和ALP活性,但对MBC和MBN均没有显著影响;随着土壤氮水平的增加,固氮植物根际土壤MBC、MBN和MBP以及氮循环相关酶活性均显著降低,而ALP活性显著提高,非固氮植物根际土壤MBN和ALP活性显著提高,氮循环相关酶活性显著降低。Mantel分析发现,在低氮水平下根际土壤磷含量受土壤理化性质、微生物生物量和酶活性的共同调控,而在高氮水平下根际土壤磷含量主要受土壤理化性质调控。综上,与非固氮植物相比,亚热带岩溶区森林固氮植物能够显著提高土壤TP、OP和AP含量,但这种作用受到土壤氮水平的调控。因此,在亚热带岩溶区植被恢复初期土壤氮水平较低的情况下引种固氮植物可以在一定程度上缓解土壤磷限制,改善土壤养分状况,有利于岩溶区植被恢复。

关键词: 岩溶区森林, 固氮植物, 根际土壤, 有机磷, 无机磷, 酶活性

Abstract: Exploring the differential responses of rhizosphere soil phosphorus contents associated with nitrogen-fixing and non-nitrogen-fixing plants to different soil nitrogen levels in subtropical karst forests can provide valuable insights into the effects of nitrogen-fixing plants on soil nutrient cycling. Such knowledge will serve as a scientific reference for the extensive planting of nitrogen-fixing plants in vegetation restoration efforts in karst regions. Taking karst forests with varying soil nitrogen levels in Jianshui County, Yunnan Province as test objects, we collected soil samples from the rhizosphere of three types of dominant nitrogen-fixing and non-nitrogen-fixing plants with the same age and analyzed the total phosphorus (TP), organic phosphorus (OP), inorganic phosphorus (IP), available phosphorus (AP), and other soil physicochemical properties. Soil microbial biomass and enzyme activities were measured to assess the influence of nitrogen-fixing plants on rhizosphere soil phosphorus contents under different soil nitrogen levels, as well as the main driving factors. Results showed that the contents of TP, OP and AP in the rhizosphere soil of nitrogen-fixing plants significantly increased by 16.0%, 66.5% and 139.5% under a low soil nitrogen level with the available nitrogen of 15.62 mg·kg^-1, and significantly increased by 13.5%, 25.7% and 15.7% under higher soil nitrogen level with the available nitrogen of 37.15 mg·kg^-1, respectively. There was no significant difference in IP content between nitrogen-fixing and non-nitrogen-fixing plants under the two soil nitrogen levels. Compared with low soil nitrogen level, the contents of TP and IP in the rhizosphere soil of nitrogen-fixing plants under high soil nitrogen level significantly decreased by 21.3% and 31.7%, and those of non-nitrogen-fixing plants significantly decreased by 19.6% and 39.1%. The AP content in the rhizosphere soil of nitrogen-fixing and non-nitrogen-fixing plants significantly increased by 32.8% and 174.8%, respectively, with no notable change in OP content. Under low nitrogen conditions, nitrogen-fixing plants significantly increased microbial biomass carbon (MBC), microbial biomass nitrogen (MBN), microbial biomass phosphorus (MBP), and alkaline phosphatase (ALP) activity in the rhizosphere soil. Under high nitrogen condition, nitrogen-fixing plants significantly increased MBP and ALP activity, but had no significant effect on MBC and MBN. As soil nitrogen level increased, soil MBC, MBN, MBP, and nitrogen cycle-related enzyme activities in the rhizosphere soil of nitrogen-fixing plants decreased significantly, while ALP activity increased. In contrast, in the rhizosphere soil of non-nitrogen-fixing plants, MBN and ALP activity significantly increased, while nitrogen cycle-related enzyme activities significantly decreased. Mantel analysis indicated that under low nitrogen level, rhizosphere soil phosphorus contents were primarily regulated by a combination of soil physicochemical properties, microbial biomass, and enzyme activity, while they were mainly regulated by soil physicochemical properties under high nitrogen level. In conclusion, compared to non-nitrogen-fixing plants, nitrogen-fixing plants in subtropical karst forests can significantly increased soil TP, OP, and AP contents and this effect is largely regulated by soil nitrogen level. Therefore, introducing nitrogen-fixing plants into low-nitrogen subtropical karst areas at the beginning of vegetation restoration may alleviate phosphorus limitation, improve soil nutrient status, and facilitate vegetation restoration in these regions.

Key words: karst forest, nitrogen-fixing plant, rhizosphere soil, organic phosphorus, inorganic phosphorus, enzyme activity

朱雨, 李杰, 刘丽君, 韦柳红, 陈淑婷, 邓璐嫔, 朱同彬, 段敏. 亚热带岩溶区森林不同土壤氮水平下固氮植物对根际土壤磷含量的影响[J]. 应用生态学报, 2025, 36(7): 2019-2027.

ZHU Yu, LI Jie, LIU Lijun, WEI Liuhong, CHEN Shuting, DENG Lupin, ZHU Tongbin, DUAN Min. Effects of nitrogen-fixing plants on rhizosphere soil phosphorus contents at different soil nitrogen levels in subtropical karst forests[J]. Chinese Journal of Applied Ecology, 2025, 36(7): 2019-2027.

参考文献

[1] Rui YC, Wang YF, Chen CR, et al. Warming and gra-zing increase mineralization of organic P in an alpine meadow ecosystem of Qinghai-Tibet Plateau, China. Plant and Soil, 2012, 357: 73-87
[2] 陈美领, 陈浩, 毛庆功, 等. 氮沉降对森林土壤磷循环的影响. 生态学报, 2016, 36(16): 4965-4976
[3] Lang F, Bauhus J, Frossard E, et al. Phosphorus in forest ecosystems: New insights from an ecosystem nutrition perspective. Journal of Plant Nutrition and Soil Science, 2016, 179: 129-135
[4] Vitousek PM, Porder S, Houlton BZ, et al. Terrestrial phosphorus limitation: Mechanisms, implications, and nitrogen-phosphorus interactions. Ecological Applications, 2010, 20: 5-15
[5] Lie ZY, Zhou GY, Huang WJ, et al. Warming drives sustained plant phosphorus demand in a humid tropical forest. Global Change Biology, 2022, 28: 4085-4096
[6] 刘洢杋, 杨峻晖, 刘家齐, 等. 喀斯特和非喀斯特森林植物磷含量及土壤无机磷分级特征比较. 南方农业学报, 2023, 54(1): 110-118
[7] 宋同清, 王克林, 曾馥平. 西南喀斯特植物与环境. 北京: 科学出版社, 2015
[8] Fan YX, Lu SX, He M, et al. Long-term throughfall exclusion decreases soil organic phosphorus associated with reduced plant roots and soil microbial biomass in a subtropical forest. Geoderma, 2021, 404: 115309
[9] Pan FJ, Yang Q, Liang YM, et al. Lithology and eleva-ted temperature impact phoD-harboring bacteria on soil available P enhancing in subtropical forests. Science of the Total Environment, 2024, 948: 174815
[10] Li M, You YM, Tan XM, et al. Mixture of N₂-fixing tree species promotes organic phosphorus accumulation and transformation in topsoil aggregates in a degraded karst region of subtropical China. Geoderma, 2022, 413: 115752
[11] Chen WF, Wang ET, Ji ZJ, et al. Recent development and new insight of diversification and symbiosis specifi-city of legume rhizobia: Mechanism and application. Journal of Applied Microbiology, 2020, 131: 553-563
[12] 潘复静, 章润阳, 秦国鑫, 等. 岩溶区固氮植物适应土壤氮素变化的潜在策略. 桂林理工大学学报, 2021, 41(4): 869-876
[13] Reed SC, Cleveland CC, Townsend AR. Relationships among phosphorus, molybdenum and free-living nitrogen fixation in tropical rain forests: Results from observational and experimental analyses. Biogeochemistry, 2013, 114: 135-147
[14] Pankievicz VSC, do Amaral FP, Santos KFDN, et al. Robust biological nitrogen fixation in a model grass-bacterial association. Plant Journal, 2015, 81: 907-919
[15] 赵玉洁, 张宇清. 固氮类植物的生态功能及其在生态修复中的应用. 干旱区资源与环境, 2012, 26(1): 179-183
[16] Augusto L, Delerue F, Gallet-Budynek A, et al. Global assessment of limitation to symbiotic nitrogen fixation by phosphorus availability in terrestrial ecosystems using a meta-analysis approach. Global Biogeochemical Cycles, 2013, 27: 804-815
[17] Yao YZ, Han BB, Dong XZ, et al. Disentangling the variability of symbiotic nitrogen fixation rate and the controlling factors. Global Change Biology, 2024, 30: e17206
[18] 曹建华, 袁道先, 杨慧, 等. 岩溶生态系统中的植物. 中国岩溶, 2022, 41(3): 365-377
[19] 梁燕, 刘家齐, 肖凡, 等. 氮沉降形态对西南岩溶区森林土壤有效磷来源的影响. 生态环境学报, 2024, 33(2): 192-201
[20] 梁月明, 苏以荣, 何寻阳, 等. 岩溶区典型灌丛植物根系丛枝菌根真菌群落结构解析. 环境科学, 2018, 39(12): 5657-5664
[21] Camenzind T, Hättenschwiler S, Treseder KK, et al. Nutrient limitation of soil microbial processes in tropical forests. Ecological Monographs, 2018, 88: 4-21
[22] Toro L, Pereira-Arias D, Perez-Aviles D, et al. Phosphorus limitation of early growth differs between nitrogen-fixing and nonfixing dry tropical forest tree species. New Phytologist, 2023, 237: 766-779
[23] Tian DS, Niu SL. A global analysis of soil acidification caused by nitrogen addition. Environmental Research Letters, 2015, 10: 024019
[24] 丁娜, 林华, 张学洪, 等. 植物根系分泌物与根际微生物交互作用机制研究进展. 土壤通报, 2022, 53(5): 1212-1219
[25] 黄梓敬, 徐侠, 张惠光, 等. 根系输入对森林土壤碳库及碳循环的影响研究进展. 南京林业大学学报: 自然科学版, 2022, 46(1): 25-32
[26] Liu J, Shen YX, Zhu XA, et al. Spatial distribution patterns of rock fragments and their underlying mechanism of migration on steep hillslopes in a karst region of Yunnan Province, China. Environmental Science and Pollution Research, 2019, 26: 24840-24849
[27] Xie B, Jones P, Dwivedi R, et al. Evaluation, comparison, and unique features of ecological security in southwest China: A case study of Yunnan Province. Ecological Indicators, 2023, 153: 110453
[28] Tang CQ, Li YH, Zhang ZY, et al. Effects of management on vegetation dynamics and associated nutrient cycling in a karst area, Yunnan, SW China. Landscape and Ecological Engineering, 2015, 11: 177-188
[29] Wen DN, Yang L, Ni K, et al. Topography-driven differences in soil N transformation constrain N availabi-lity in karst ecosystems. Science of the Total Environment, 2024, 908: 168363
[30] Liu L, He XY, Wang KL, et al. The Bradyrhizobium-legume symbiosis is dominant in the shrubby ecosystem of the Karst region, Southwest China. European Journal of Soil Biology, 2015, 68: 1-8
[31] Li DD, Zhang XY, Dungait JAJ, et al. Changes in the biological N₂-fixation rates and diazotrophic community as vegetation recovers on abandoned farmland in a karst region of China. Applied Soil Ecology, 2021, 158: 103808
[32] 刘家齐, 梁燕, 肖凡, 等. 西南喀斯特区域不同植被恢复阶段土壤磷主要来源及其季节变化. 应用生态学报, 2023, 34(12): 3313-3321
[33] 罗原骏, 黄来明, 袁大刚. 基于³¹P NMR的自然成土过程中有机磷组分演变特征及影响因素研究进展. 土壤学报, 2023, 60(1): 23-38
[34] Chen H, Chen ML, Li DJ, et al. Responses of soil phosphorus availability to nitrogen addition in a legume and a non-legume plantation. Geoderma, 2018, 322: 12-18
[35] Shi SW, Peng CH, Wang M, et al. A global meta-ana-lysis of changes in soil carbon, nitrogen, phosphorus and sulfur, and stoichiometric shifts after forestation. Plant and Soil, 2016, 407: 323-340
[36] Li L, Li SM, Sun JH, et al. Diversity enhances agricultural productivity via rhizosphere phosphorus facilitation on phosphorus-deficient soils. Proceedings of the National Academy of Sciences of the United States of America, 2007, 104: 11192-11196
[37] 张晓晴, 曾泉鑫, 元晓春, 等. 氮添加诱导的磷限制改变了亚热带黄山松林土壤微生物群落结构. 应用生态学报, 2023, 34(1): 203-212
[38] Romanyà J, Blanco-Moreno JM, Sans FX. Phosphorus mobilization in low-P arable soils may involve soil orga-nic C depletion. Soil Biology and Biochemistry, 2017, 113: 250-259
[39] Pan FJ, Zhang W, Liu SJ, et al. Leaf N:P stoichiome-try across plant functional groups in the karst region of southwestern China. Trees, 2015, 29: 883-892
[40] 车荣晓, 邓永翠, 吴伊波, 等. 生物固氮与有效氮的关系: 从分子到群落. 生态学杂志, 2017, 36(1): 224-232
[41] 严君, 韩晓增. 盆栽条件下土壤无机氮浓度对大豆结瘤、固氮和产量的影响. 中国农业科学, 2014, 47(10): 1929-1938
[42] Ning QS, Hättenschwiler S, Lü XT, et al. Carbon limitation overrides acidification in mediating soil microbial activity to nitrogen enrichment in a temperate grassland. Global Change Biology, 2021, 27: 5976-5988
[43] 李娟, 张立成, 章明清, 等. 长期施用尿素降低赤红壤旱地耕层pH的特征与预测. 植物营养与肥料学报, 2022, 28(12): 2161-2171

亚热带岩溶区森林不同土壤氮水平下固氮植物对根际土壤磷含量的影响

Effects of nitrogen-fixing plants on rhizosphere soil phosphorus contents at different soil nitrogen levels in subtropical karst forests

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	徐玲, 薛丹, 孙嘉悦, 邹庆, 黄贝贝, 刘恋, 吴林. 不同营养类型泥炭地土壤酶活性及其化学计量特征 [J]. 应用生态学报, 2025, 36(6): 1880-1888.
[2]	谢雨霜, 韩冰鑫, 柳荻, 雷怡婷, 王晓春. 干旱对白桦和水曲柳木质部形成过程和生长的影响 [J]. 应用生态学报, 2025, 36(5): 1289-1297.
[3]	殷启杰, 姜建武, 殷汉琴, 杨宗坤, 龚冬琴, 李桂芳, 褚先尧, 刘文波, 张敏. 有机物料投入对新垦耕地土壤养分和微生物代谢的影响 [J]. 应用生态学报, 2025, 36(4): 969-983.
[4]	车佳聪, 杨佳, 吴政鸿, 谷会岩. 林火对小兴安岭阔叶红松林土壤理化性质、酶活性和微生物群落的长期影响 [J]. 应用生态学报, 2025, 36(4): 1071-1080.
[5]	毛娇艳, 杨青, 郭琦玲, 孙嘉雯, 施秀珍, 王建青. 亚热带天然林转换为锥栗林后土壤胞外酶活性及其化学计量特征 [J]. 应用生态学报, 2025, 36(2): 481-488.
[6]	孙榕, 赵颖志, 陈勇, 郑旭理, 周燕, 邵帅, 梁辰飞, 秦华, 陈俊辉. 典型毛竹入侵阔叶林生境凋落物、土壤碳氮组分及酶活性特征 [J]. 应用生态学报, 2025, 36(2): 489-496.
[7]	沈阳, 李晓英, 蔡慧颖, 许涛, 李景涛, 陈魁. 林火干扰后大兴安岭多年冻土区土壤胞外酶活性变化特征及其影响因素 [J]. 应用生态学报, 2025, 36(2): 497-203.
[8]	张仲富, 王禹童, 艾静, 刀静梅, 李傲梅, 邓军, 吴建明, 赵勇. 钾肥对甘蔗根际微生物多样性和群落构建过程的影响 [J]. 应用生态学报, 2025, 36(2): 526-536.
[9]	吴佳芯, 李邵宇, 韩国栋. 不同放牧强度下荒漠草原土壤化学计量失衡与微生物碳利用效率的联系 [J]. 应用生态学报, 2024, 35(8): 2108-2118.
[10]	田圣陶, 罗洋, 隋鹏祥, 王浩, 任英, 周思琪, 刘海峰, 郑金玉. 长期耕作对黑土有机碳储量及其组分的影响 [J]. 应用生态学报, 2024, 35(8): 2167-2175.
[11]	周琦锐, 赵梦停, 杨丽, 栾佳萌, 高源, 黄正来, 马尚宇, 樊永惠, 张文静. 外源6-BA对孕穗期低温胁迫后小麦旗叶生理、产量及品质的影响 [J]. 应用生态学报, 2024, 35(6): 1573-1582.
[12]	张鹏, 田瑞, 胡啸, 赵同亮, 雷俊, 王鹤龄, 吕晓东. 增温和降水变化对陇中黄土高原半干旱麦田土壤有机碳和酶活性的影响 [J]. 应用生态学报, 2024, 35(11): 3031-3042.
[13]	安小兵, 郑粉莉, 王雪松, 杨新月, 梁瑞, 王伦. 冻融作用对东北黑土区坡耕地土壤微生物养分限制的影响 [J]. 应用生态学报, 2024, 35(10): 2744-2754.
[14]	周艳秋, 李法云, 王玮, 周纯亮, 蒋镕鞠. 种子载体固定化微生物对油菜生长和石油烃污染土壤修复的影响 [J]. 应用生态学报, 2024, 35(10): 2897-2906.
[15]	常婕, 居新, 伊李凯, 宁亚楠, 刁华杰, 郝杰, 王常慧, 董宽虎. 不同水平氮添加下华北盐渍化草地根际土壤阴阳离子特征 [J]. 应用生态学报, 2024, 35(1): 212-218.