木麻黄细根形态和化学计量特征对P添加的塑性响应

doi:10.11924/j.issn.1000-6850.casb2023-0069

摘要/Abstract

摘要：

探究不同发育阶段木麻黄防护林细根形态和化学计量特征对磷(P)添加的塑性响应规律，为滨海沙地土壤低磷限制下进行木麻黄不同发育阶段有针对性的施肥抚育提供科学依据。以福建省平潭岛木麻黄幼龄林(5 a)、中龄林(12 a)和成熟林(25 a)为研究对象，以内生长土芯法开展P添加试验，细根在内生长芯生长一年后，采用功能划分法对细根形态性状和化学计量特征进行测定。结果表明：（1）P添加显著提高木麻黄细根根长和根表面积，其中，总根长和总表面积总体提高7.79倍、8.69倍，比根长和比表面积总体提升15.1%、19.5%；（2）不同根系功能类群间，细根形态对P添加的塑性响应具有较显著差异，形态塑性以吸收根为主，且吸收根对P养分资源的响应更为敏感，P添加使吸收根P含量总体提高56.0%，C/P和N/P总体降低18.7%和38.7%，组织密度总体降低31.4%；（3）对于土壤P养分资源的变化，不同林龄木麻黄采取不同的塑性响应策略，P添加后，幼龄林主要通过吸收根化学计量特征变异，改变自身生理性状获取P元素，中龄林细根形态和化学计量特征无显著变异，成熟林主要通过改变吸收根形态，扩大根系吸收面积获取P元素。外源P添加可以协调木麻黄细根形态与化学计量特征的内部关系，而不同林龄木麻黄细根在获取P资源时会选择性投资。故在木麻黄施肥抚育时，应根据不同林龄采取针对性的抚育方案。

关键词: P添加, 林龄, 吸收根, 运输根, 细根形态, 细根化学计量学, 木麻黄

Abstract:

The plasticity response of fine root morphology and stoichiometric characteristics to phosphorus (P) addition in Casuarina equisetifolia forests at different development stages was investigated, providing a scientific basis for targeted fertilization and nurturing of C. equisetifolia at different development stages under the limitation of low phosphorus in coastal sandy soil. The C. equisetifolia plantations at young (5 a), middle-aged (12 a) and mature (25 a) stages were selected as the research objects in Pingtan Island, Fujian Province, and the phosphorus addition experiment was carried out by using the inner growth method. After the fine roots growing in the inner growth cores for a year, the fine root morphological characters and stoichiometric characteristics were measured by the functional division method. The results showed that: 1) adding phosphorus significantqly increased the root length and surface area, the total root length and total surface area increased by 7.79 times and 8.69 times, respectively, the specific root length and specific surface area increased by 15.1% and 19.5%, respectively; 2) among different root functional groups, the plastic response of fine root morphology to P addition was significantly different. The morphological plasticity was dominated by absorbing roots, and the response of absorbing roots to P nutrient resources was more sensitive. P addition increased the P content in absorbing roots by 56.0%, decreased the C/P and N/P by 18.7% and 38.7%, and decreased the tissue density by 31.4%; 3) for the change of soil P nutrient resources, different forest ages of C. equisetifolia adopted different plastic response strategies. After P addition, the young forest mainly obtained P element by changing its own physiological characteristics through the variation of stoichiometric characteristics of absorbing roots. The fine root morphology and stoichiometric characteristics of the middle-aged forest had no significant variation. The mature forest mainly obtained P element by changing the absorbing root morphology and expanding the root absorption area. The present study demonstrates that the addition of exogenous P can coordinate the internal relationship between the fine root morphology and stoichiometric characteristics of C. equisetifolia. Moreover, our results show that the fine roots of C. equisetifolia at different ages selectively invest in acquiring P resources. Thus, to effectively fertilize and nurture C. equisetifolia, targeted tending schemes should be adopted according to the forest's age.

Key words: phosphorus addition, forest age, absorptive fine root, transport fine root, fine root morphology, fine root stoichiometry, Casuarina equisetifolia

聂森. 木麻黄细根形态和化学计量特征对P添加的塑性响应[J]. 中国农学通报, 2024, 40(2): 34-41.

NIE Sen. Plasticity Response of Fine Root Morphology and Stoichiometric Characteristics of Casuarina equisetifolia to Phosphorus Addition[J]. Chinese Agricultural Science Bulletin, 2024, 40(2): 34-41.

图/表 8

参考文献 26

[1]	郑妍, 江瑶, 孙冬晓, 等. 华南沿海地区林地土壤养分空间异质性研究[J]. 林业与环境科学, 2020, 36(6):110-114.
[2]	MIGUEL M A, POSTMA J A, LYNCH J P. Phene synergism between root hair length and basal root growth angle for phosphorus acquisition[J]. Plant physiology, 2015, 167(4):1430-1439. doi: 10.1104/pp.15.00145 pmid: 25699587
[3]	吴文景, 梅辉坚, 许静静, 等. 供磷水平及方式对杉木幼苗根系生长和磷利用效率的影响[J]. 生态学报, 2020, 40(6):2010-2018.
[4]	KOVAR J, ClAASSEN N. Soil-Root Interactions and Phosphorus Nutrition of Plants[J]. Phosphorus: agriculture and the environment, agronomy monograph, 2005, 46:379-414.
[5]	王鹏, 牟溥, 李云斌. 植物根系养分捕获塑性与根竞争[J]. 植物生态学报, 2012, 36(11):1184-1196. doi: 10.3724/SP.J.1258.2012.01184
[6]	MA Z, GUO D, XU X, et al. Evolutionary history resolves global organization of root functional traits[J]. Nature, 2018, 555:94-97. doi: 10.1038/nature25783 URL
[7]	王昕, 李海港, 程凌云, 等. 磷与水分互作的根土界面效应及其高效利用机制研究进展[J]. 植物营养与肥料学报, 2017, 23(4):1054-1064.
[8]	WEN Z, LI H, SHEN J, et al. Maize responds to low shoot P concentration by altering root morphology rather than increasing root exudation[J]. Plant and soil, 2017, 416(1):377-389. doi: 10.1007/s11104-017-3214-0
[9]	AMIT K, MUHAMMAD S, MANISHA K, et al. Root trait plasticity and plant nutrient acquisition in phosphorus limited soil[J]. Journal of plant nutrition and soil science, 2019, 182(6):945-952. doi: 10.1002/jpln.v182.6 URL
[10]	田地, 严正兵, 方精云. 植物生态化学计量特征及其主要假说[J]. 植物生态学报, 2021, 45(7):682-713. doi: 10.17521/cjpe.2020.0331
[11]	张小全, 吴可红, MURACH D. 树木细根生产与周转研究方法评述[J]. 生态学报, 2000, 20(5):875-883.
[12]	赵佳宁, 梁韵, 柳莹, 等. 森林生态系统细根周转规律及影响因素[J]. 植物学报, 2020, 55(3):308-317. doi: 10.11983/CBB19231
[13]	熊静, 虞木奎, 成向荣, 等. 光照和氮磷供应比对木荷生长及化学计量特征的影响[J]. 生态学报, 2021, 41(6):2140-2150.
[14]	MCCORMACK M L, GUO D L, COLLEEN M I, et al. Building a better foundation: improving root-trait measurements to understand and model plant and ecosystem processes[J]. New phytologist, 2017, 215(1): 27-37. doi: 10.1111/nph.14459 pmid: 28295373
[15]	MUCHA J, ZADWORNY M, HELMISAARI H S, et al. Fine root classification matters: nutrient levels in different functional categories, orders and diameters of roots in boreal Pinus sylvestris across a latitudinal gradient[J]. Plant soil, 2020, 447(1):507-520. doi: 10.1007/s11104-019-04395-1
[16]	丁国泉, 于立忠, 王政权, 等. 施肥对日本落叶松细根形态的影响[J]. 东北林业大学学报, 2010, 38(5):16-19.
[17]	于立忠, 丁国泉, 朱教君, 等. 施肥对日本落叶松不同根序细根养分含量的影响[J]. 应用生态学报, 2009, 20(4):747-753.
[18]	谷加存, 王东男, 夏秀雪, 等. 功能划分方法在树木细根生物量研究中的应用:进展与评述[J]. 植物生态学报, 2016, 40(12):1344-1351. doi: 10.17521/cjpe.2016.0167
[19]	叶功富, 张立华, 林益明, 等. 滨海沙地木麻黄人工林细根养分与能量动态[J]. 生态学报, 2007, 27(9):3874-3882.
[20]	叶功富, 张立华, 侯杰, 等. 滨海沙地木麻黄人工林细根生物量及其动态研究[J]. 应用与环境生物学报, 2007, 13(4):481-485.
[21]	李钦禄, 莫其锋, 王法明, 等. 华南热带沿海不同林龄木麻黄人工林养分利用特征[J]. 应用与环境生物学报, 2015, 21(1):139-146.
[22]	林文泉, 高伟, 叶功富, 等. 海岸沙地木麻黄林立地质量评价及类型划分[J]. 中南林业科技大学学报, 2021, 41(1):159-167,187.
[23]	贾林巧, 陈光水, 张礼宏, 等. 常绿阔叶林外生和丛枝菌根树种细根形态和构型性状对氮添加的可塑性响应[J]. 应用生态学报, 2021, 32(2):529-537. doi: 10.13287/j.1001-9332.202102.025
[24]	刘士玲, 陈琳, 杨保国, 等. 氮磷肥对西南桦无性系生物量分配和根系形态的影响[J]. 南京林业大学学报(自然科学版), 2019, 43(5):23-29.
[25]	LI A, GUO D, WANG Z, et al. Nitrogen and phosphorus allocation in leaves, twigs, and fine roots across 49 temperate, subtropical and tropical tree species: a hierarchical pattern[J]. Functional ecology, 2010, 24(1):224-232. doi: 10.1111/fec.2010.24.issue-1 URL
[26]	LYNCH J P. Root phenes for enhanced soil exploration and phosphorus acquisition: tools for future crops[J]. Plant physiology, 2011, 156(3):1041-1049. doi: 10.1104/pp.111.175414 pmid: 21610180

项目	树龄/ a	土壤容重/ (g/cm³)	胸径/ cm	树高/ m	林分密度/ （株/hm²）	土壤碳含量/ (g/kg)	土壤氮含量/ (g/kg)	土壤磷含量/ (g/kg)
幼龄林	5	1.38±0.14a	12.08±1.12c	8.56±0.82c	2310±56a	1.48±0.83a	0.31±0.11a	0.14±0.03a
中龄林	12	1.35±0.08a	18.00±1.49b	10.12±0.64b	2100±75b	0.79±0.38a	0.19±0.06a	0.07±0.02b
成熟林	25	1.13±0.19b	26.29±3.43a	12.45±2.44a	1879±138c	1.00±0.25a	0.22±0.05a	0.05±0.02c

项目	树龄/ a	土壤容重/ (g/cm³)	胸径/ cm	树高/ m	林分密度/ （株/hm²）	土壤碳含量/ (g/kg)	土壤氮含量/ (g/kg)	土壤磷含量/ (g/kg)
幼龄林	5	1.38±0.14a	12.08±1.12c	8.56±0.82c	2310±56a	1.48±0.83a	0.31±0.11a	0.14±0.03a
中龄林	12	1.35±0.08a	18.00±1.49b	10.12±0.64b	2100±75b	0.79±0.38a	0.19±0.06a	0.07±0.02b
成熟林	25	1.13±0.19b	26.29±3.43a	12.45±2.44a	1879±138c	1.00±0.25a	0.22±0.05a	0.05±0.02c

变异来源	TRL	TRA	SRL	SRA	AD	RTD
P	0	0	0.049	0	0.496	0.020
R	0	0	0	0	0	0.002
F	0	0	0.006	0	0.005	0
P×R	0.001	0.001	0.023	0	0.112	0.016
P×F	0	0	0.032	0.335	0.102	0.188
R×F	0	0	0	0	0.009	0.425
P×R×F	0	0	0.520	0.820	0.635	0.698

变异来源	TRL	TRA	SRL	SRA	AD	RTD
P	0	0	0.049	0	0.496	0.020
R	0	0	0	0	0	0.002
F	0	0	0.006	0	0.005	0
P×R	0.001	0.001	0.023	0	0.112	0.016
P×F	0	0	0.032	0.335	0.102	0.188
R×F	0	0	0	0	0.009	0.425
P×R×F	0	0	0.520	0.820	0.635	0.698

变异来源	TC	TN	TP	C/N	C/P	N/P
P	0.035	0.199	0	0.203	0	0
R	0	0.050	0.327	0.008	0.032	0
F	0.006	0.442	0	0.07	0	0.001
P×R	0.391	0.278	0.029	0.247	0.020	0.002
P×F	0.447	0.448	0.010	0.578	0.069	0.239
R×F	0.264	0.334	0	0.257	0	0.002
P×R×F	0.618	0.237	0.580	0.386	0.598	0.584