北京百花山华北落叶松群落主要木本植物的叶性状变异及适应策略

doi:10.11707/j.1001-7488.LYKX20220864

摘要/Abstract

摘要：

目的: 探讨华北落叶松群落叶性状间的权衡及叶化学性状、结构性状与光合性状间的关系，为林业经营管理优化造林树种的选择和配置提供科学支撑。方法: 以北京百花山落叶松群落木本植物包括优势种华北落叶松、3种落叶阔叶乔木（白蜡、黄檗和五角枫）、2种灌木（胡枝子和绣线菊）为研究对象，于2021年7—8月测定分析叶片的8个光合性状：最大净光合速率（P_nmax）、饱和光强（I_sat）、暗呼吸速率（R_d）、饱和胞间CO₂浓度（Ci_sat）、最大羧化速率（V_cmax）、最大电子传递速率（J_max）、水分利用效率（WUE）和光合氮利用效率（PNUE），2个化学性状：碳氮比（C∶N）、氮磷比（N∶P），3个结构性状：叶厚（LT）、比叶面积（SLA）、叶组织密度（LTD）。利用单因素方差分析、斯皮尔曼相关性分析、主成分分析和线性回归等方法，分析叶性状之间的权衡及化学性状和结构性状对光合性状的影响。结果: 1）种间变异最大的性状为PNUE和SLA，其为反映光合速率和获取光能的主要性状，变异系数分别为60.88%和56.8%，说明该群落植物更多的是对光资源的竞争。2）灌木为增加群落垂直结构上的光获取能力，通常具有更大的SLA。同时，灌木叶片的N:P为21.10，高于乔木（14.58），证明位于林分垂直结构下层的灌木为获取更多的光以维持自身生长发育，会将更多的氮分配到叶片中。3）阔叶乔木叶C∶N、N∶P和SLA分别为18.19、16.04和193.77 cm²·g^?1，针叶乔木的对应指标分别为39.6、10.2和82.2 cm²·g^?1，针叶乔木具有较大的C∶N和较低的N∶P、SLA，说明针叶乔木更倾向于构建叶片的防御组织，对胁迫具有更强抵抗能力，但光的截获能力和利用率较低。4）华北落叶松在叶经济谱中倾向于“缓慢投资-收益”型，2种灌木更倾向于“快速投资-收益”型。华北落叶松具有较高的WUE和较低的PNUE，2个叶性状之间存在明显的权衡关系。5）五角枫和绣线菊的P_nmax没有显著差异，但其R_d仅为0.54和0.68 μmol·m^?2s^?1，显著小于同生活型的其他物种。6）该典型群落木本植物的I_sat、R_d、WUE和PNUE与C∶N、LT和SLA呈显著线性相关（P<0.05）。结论: 百花山华北落叶松典型群落6种主要木本植物之间存在叶经济谱，群落的种间竞争主要是对光资源竞争。在一定程度上C∶N、LT和SLA可以作为预测植物光合能力的易于观察的叶化学性状和结构性状，即具有较大C∶N、LT，较小SLA的物种，其对强光的耐受能力更高、水分利用效率越高、对弱光的利用能力强且碳消耗较少，但其光合氮利用能力较弱。

关键词: 叶片, 化学性状, 结构性状, 光合性状, 权衡, 光响应曲线, CO₂响应曲线

Abstract:

Objective: This stusy aims to examine the trade-offs between leaf traits, including chemical-, structural- and photosynthetic traits, and the relationship between leaf chemical- and structural traits and photosynthetic traits. Method: In the community, the dominant main woody species include Larix principis-rupprechtii, three broad-leaved trees, Fraxinus chinensis, Phellodendron amurense and Acer pictumsubsp.mono, and two shrubs, Lespedeza bicolorand Spiraea salicifolia. The 13 leaf traits were measured for the woody species in the L. principis-rupprechtii community in Bahushan, Beijing using portable analyzer during July-August in 2021. Photosynthetic traits included maximum net photosynthetic rate (P_nmax), saturation irradiance (I_sat), dark respiration rate (R_d), saturation intercellular CO₂ concentration (Ci_sat), maximum rate of carboxylation (V_cmax), maximum potential rate of electron transport (J_max), water use efficiency (WUE), and photosynthetic nitrogen-use efficiency (PNUE). The structural traits were leaf thickness (LT), specific leaf area (SLA), and leaf tissue density (LTD). The chemical traits were carbon-nitrogen ratio (C∶N), and nitrogen-phosphorus ratio (N∶P). One-way analysis of variance, Spearman correlation analysis, principal component analysis and linear regression were used to analyze the correlation of leaf traits and the effects of leaf chemical and structural traits on photosynthetic traits in the L. principis-rupprechtii community. Result: 1) The PNUE and SLA showed the largest inter-species variation with variation coefficient of 60.88% and 56.83%, respectively, indicating that the species in the commnuity competed for light resource. 2) Shrubs had higher SLA in order to increase light acquisition ability on vertical structure in the community. Meanwhile, N∶P in tree leaves was 14.58, while that in shrub leaves was 21.10. Compared with trees, shrubs had lower C∶N, but higher N∶P, indicating that the shrub allocated more nitrogen into leaf to obtain light and maintain growth. 3) C∶N, N∶P and SLA were 18.19, 16.04 and 193.77 cm²·g^?1 in broad-leaved trees, respectively, and were 39.6, 10.2 and 82.2 cm²·g^?1 in needle-leaved trees, respectively. Compared with broad-leaved trees, the needle-leaved trees had higher C∶N, but lower N∶P and SLA, indicating that the needle-leaved trees tended to construct the more defensive organization and had higher resistance to stress and lower light interception capability. 4) L. principis-rupprechtii was located at “slow investment-return”, shrubs were at “fast investment-return” in leaf economic spectrum. L. principis-rupprechtii had higher WUE but lower PNUE, suggesting that the trade-off between WUE and PNUE occurred, with WUE increasing at the expense of PNUE. 5) Compared with other broad-leaved trees and shrubs, the P_nmax of A. pictum subsp. mono and S. salicifolia were not obviously higher, but the R_d were significantly lower than other species. 6) The I_sat, R_d WUE and PNUE were significantly correlated with C∶N, LT and SLA (P<0.05). Conclusion: These results suggest that there is obvious leaf economics spectrum existed across the woody species in the community, and the interspecific competition is mainly for light resource. Although A. pictum subsp. mono and S. salicifolia are not the dominant species in the community, their net carbon sequestration capacity in per unit area is stronger than other species. The C∶N, LT and SLA can be used as the indicators predicting the photosynthetic capacity. Species with higher C∶N, LT and lower SLA have higher tolerance to strong light and higher water use efficiency, but have stronger utilization of weak light and less carbon consumption. Meanwhile, photosynthetic nitrogen utilization efficiency is lower. The results can provide theoretical support for subsequent forest management.

Key words: leaf, chemical trait, structural trait, photosynthetic trait, trade-off, light response curve, CO₂ response curve

中图分类号:

S718.43

刘新月,王立平,刘春和,孙艳丽,魏晓帅,徐铭泽,韩聪,田赟,贾昕,查天山. 北京百花山华北落叶松群落主要木本植物的叶性状变异及适应策略[J]. 林业科学, 2023, 59(7): 12-23.

Xinyue Liu,Liping Wang,Chunhe Liu,Yanli Sun,Xiaoshuai Wei,Mingze Xu,Cong Han,Yun Tian,Xin Jia,Tianshan Zha. Variation and Adaptation Strategies in Leaf Traits of Main Woody Plants in the Larix principis-rupprechtii Community in Baihua Mountain, Beijing[J]. Scientia Silvae Sinicae, 2023, 59(7): 12-23.

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物种 Species	郁闭度/盖度 Crown density/ coverage (%)	平均树高 Average height/m	平均胸径 Average diameter at breast height/cm
华北落叶松 Larix principis-rupprechtii	43	19.83	23.01
白蜡 Fraxinus chinensis	43	12.57	31.57
黄檗 Phellodendron amurense	43	7.67	9.33
五角枫 Acer pictum subsp. mono	43	15.06	19.63
胡枝子 Lespedeza bicolor	12.6	1.27	2.00
绣线菊 Spiraea salicifolia	7.2	0.96	3.22

性状 Traits	平均值（±标准差） Mean (±SD)	最大值 Max.	最小值 Min.	变异系数 Coefficient variation（%）
最大净光合速率Maximum net photosynthetic rate（P_nmax）/(μmol·m^?2s^?1)	10.40±0.83	18.42	4.99	32.96
饱和光强Saturation irradiance（I_sat）/(μmol·m^?2s^?1)	1131.63±74.44	1649.31	561.89	27.12
暗呼吸速率Dark respiration rate（R_d）/(μmol·m^?2s^?1)	0.90±0.09	1.42	0.47	39.10
饱和胞间二氧化碳浓度Saturation intercellular CO₂ concentration （Ci_sat）/(μmol·mol^?1)	1176.06±52.78	1843.73	908.90	18.50
最大羧化速率Maximum rate of carboxylation（V_cmax）/(μmol·m^?2s^?1)	44.17±3.86	80.45	24.63	36.00
最大电子传递速率Maximum potential rate of electron transport（J_max）/(μmol·m^?2s^?1)	83.93±6.86	148.82	51.16	33.69
水分利用效率Water use efficiency（WUE）/(μmol·mmol^?1)	5.60±0.42	9.31	2.17	32.08
光合氮利用效率Photosynthetic nitrogen-use efficiency（PNUE）/(μmol·g^?1s^?1)	8.88±1.27	22.88	2.71	60.88
碳氮比Carbon-nitrogen ratio（C∶N）	22.01±2..35	50.30	13.00	48.03
氮磷比Nitrogen-phosphorus ratio （N∶P）	16.76±1.28	27.00	7.49	34.37
叶厚Leaf thickness （LT/mm）	0.33±0.0.4	0.71	0.17	36.98
比叶面积Specific leaf area（SLA）/( cm²·g^?1)	205.58±22.27	405.73	66.30	56.83
叶组织密度Leaf tissue density（LTD）/( g·cm^?3)	0.39±0.01	0.49	0.30	32.61

	氮磷比 Nitrogen-phosphorus ratio(N∶P)	叶厚 Leaf thickness (LT)	比叶面积 Specific leaf area(SLA)	叶组织密度 Leaf tissue density(LTD)
碳氮比 Carbon-nitrogen ratio（C∶N）	?0.40	0.26	?0.04	?0.33
氮磷比 Nitrogen-phosphorus ratio（N∶P）	—	?0.63**	0.63**	?0.24
叶厚 Leaf thickness（LT）	—	—	?0.72**	?0.11
比叶面积 specific leaf area（SLA）	—	—	—	?0.52*

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