毛竹林林下植物叶片功能性状的模拟氮沉降响应

doi:10.11707/j.1001-7488.LYKX20250236

Abstract

Abstract:

Objective: This study targets eight dominant understory species in a subtropical moso bamboo forest, and investigates their leaf functional traits in response to simulated nitrogen deposition, aiming to elucidate the ecological adaptation strategies of understory plants to nitrogen deposition, and provide a scientific basis for nitrogen deposition management in regional moso bamboo forest ecosystems. Method: Two simulated nitrogen deposition modes was set up, one above the canopy and the other below the canopy with organic (a urea-glycine mixture) and inorganic (ammonium nitrate). There were a total of six treatment groups: canopy inorganic nitrogen addition (CIN), canopy organic nitrogen addition (CON), canopy control (CCK), understory inorganic nitrogen addition (UIN), understory organic nitrogen addition (UON), and understory control (UCK). The nitrogen addition amount for each treatment group was uniformly at a rate of 50 kg·hm^?2a^?1, while control plots received an equivalent volume of water. After three years, eight leaf functional traits (specific leaf area, leaf dry matter content, leaf thickness, plant height, and contents of total nitrogen, phosphorus, potassium, and N∶P ratio) were determined for four shrub species (Rubus buergeri, Rubus corchorifolius, Ardisia japonica, Wisteria sinensis) and four herbaceous species (Chelonopsis chekiangensis, Lophatherum gracile, Parathelypteris glanduligera, Carex spp.). Result: 1) Except for leaf dry matter content, leaf functional traits did not significantly respond to the simulated nitrogen deposition (above/below canopy) or nitrogen form (organic/inorganic). However, there were significant interspecific differences, particularly between herbs and shrubs, and between Fabaceae and non-Fabaceae shrubs. 2) Simulated nitrogen deposition significantly increased leaf nitrogen content in both herbs and shrubs. Herbs exhibited increased leaf potassium content and nitrogen-to-phosphorus ratio, but decreased leaf dry matter content. Shrub height significantly increased. Fabaceae shrubs showed increased plant height but decreased specific leaf area, while non-Fabaceae shrubs displayed increased leaf nitrogen content and nitrogen-to-phosphorus ratio. 3) Leaf dry matter content was negatively correlated with nitrogen content across all treatments. Leaf nitrogen content was positively correlated with phosphorus content only under CCK, CIN, and UCK treatments. Nitrogen-to-phosphorus ratio was positively correlated with nitrogen content only in CCK, CON, and UIN treatments. Specific leaf area was negatively correlated with leaf thickness solely under CON treatment, and leaf thickness was positively correlated with plant height under CCK and CIN treatments. Conclusion: This study has revealed differences in adaptation strategies to nitrogen deposition between herbaceous plants and shrubs, and between Fabaceae and non-Fabaceae shrubs in a moso bamboo forest. In response to nitrogen deposition, herbaceous plants not only enhance their resource-acquisition strategy through increasing leaf nitrogen content but also attenuate their resource-conservation strategy by reducing leaf dry matter content. Non-Fabaceae shrubs only increase resource-acquisition functional traits such as leaf nitrogen content, without adjusting resource-conservation traits. In contrast, Fabaceae shrubs adapt to nitrogen-enriched environments by maintaining leaf nitrogen-phosphorus stoichiometric balance.

Key words: nitrogen deposition, subtropical forests, moso bamboo, leaf functional traits, herbaceous plants, shrub plants, Fabaceae

CLC Number:

S154

Lemei Yang,Baogang Zhang,Youchao Chen,Yanjiang Cai. Leaf Functional Traits of Understory Plants in a Moso Bamboo Forests in Response to Simulated Nitrogen Deposition[J]. Scientia Silvae Sinicae, 2025, 61(12): 61-71.

Figures/Tables 5

Table 1

Leaf functional traits of understory plants under different nitrogen deposition treatments (mean±SD)"

植物种类 Plant species	处理 Treatment	比叶面积 Specific leaf area (SLA)/ (m2·kg^?1)	叶片干物质含量Leaf dry matter content (LDMC)/ (g·kg^?1)	叶片厚度 Leaf thickness (LT)/ mm	株高 Plant height (H)/ cm	全氮含量Total nitrogen content (TN)/ (g·kg^?1)	全磷含量Total phosphorus content (TP)/ (g·kg^?1)	全钾含量Total potassium content (TK)/ (g·kg^?1)	叶片氮磷比 Leaf N∶P ratio （N/P）
寒莓 Rubus buergeri	CCK	378.1±40.7bc	287.2±18.4c	0.43±0.03a	90.4±41.2a	19.7±1.0bc	0.80±0.30a	13.2±2.3a	27.5±10.2a
	CIN	441.8±60.8ab	249.9±44.3bc	0.38±0.08a	86.3±42.9a	23.2±1.2a	0.69±0.13a	10.4±2.9ab	34.5±6.2a
	CON	347.5±39.9c	241.9±40.1abc	0.36±0.02a	93.6±28.1a	20.4±3.2abc	0.60±0.18a	9.4±2.2b	35.0±5.7a
	UCK	355.9±12.0bc	290.7±17.3ab	0.39±0.04a	78.7±38.8a	18.2±0.8c	0.67±0.11a	13.8±2.1a	27.7±4.9a
	UIN	508.2±107.9a	268.4±15.5ab	0.39±0.03a	69.8±18.7a	22.6±1.4ab	0.82±0.11a	12.4±1.7ab	28.0±3.9a
	UON	380.2±32.6bc	305.2±7.7a	0.37±0.06a	47.6±25.2a	23.4±2.9a	0.70±0.11a	11.0±2.1ab	33.8±4.3a

山莓 Rubus corchorifolius	CCK	566.4±28.4a	366.2±66.3a	0.29±0.04a	58.8±17.5a	20.6±0.7a	0.68±0.05a	13.7±2.4ab	30.7±2.0a
	CIN	617.3±87.2a	307.9±39.7a	0.27±0.10a	65.1±11.0a	21.9±2.7a	0.75±0.18a	14.5±2.1ab	30.0±6.0a
	CON	475.8±89.6a	347.2±144.0a	0.29±0.05a	79.5±20.0a	24.6±5.0a	0.74±0.13a	14.9±4.1ab	33.1±0.1a
	UCK	574.4±49.9a	299.0±74.8a	0.25±0.05a	60.5±14.5a	22.4±3.5a	0.73±0.06a	17.3±1.7a	30.9±3.7a
	UIN	557.9±224.7a	318.6±34.3a	0.29±0.06a	62.7±6.1a	22.7±1.6a	0.86±0.27a	15.0±0.1ab	28.2±8.0a
	UON	635.7±31.7a	280.9±11.9a	0.29±0.10a	70.3±13.5a	25.2±3.0a	0.74±0.10a	12.0±0.1b	34.3±3.0a

紫金牛 Ardisia japonica	CCK	322.3±22.7a	366.0±17.6a	0.28±0.06a	7.9±1.9a	16.1±1.9c	0.74±0.15a	13.4±3.4a	21.9±2.5a
	CIN	349.4±23.0a	360.0±31.1a	0.22±0.02a	9.9±5.2a	18.5±1.6abc	0.77±0.03a	15.6±1.6a	24.3±1.3a
	CON	327.2±27.2a	375.4±23.0a	0.35±0.09a	10.2±4.3a	18.8±1.2ab	0.87±0.17a	15.0±2.0a	22.3±4.5a
	UCK	305.4±23.7a	333.9±64.3a	0.27±0.07a	9.8±1.7a	18.3±1.9bc	0.78±0.08a	14.4±2.4a	23.3±1.4a
	UIN	339.0±52.3a	362.0±8.3a	0.25±0.02a	9.5±1.5a	19.8±1.1ab	0.81±0.01a	15.3±1.0a	24.7±1.1a
	UON	330.1±63.3a	365.1±32.8a	0.33±0.15a	9.5±3.2a	21.0±1.8a	0.84±0.07a	14.8±0.6a	25.0±0.4a

紫藤 Wisteria sinensis	CCK	604.8±20.6b	296.4±36.7a	0.21±0.01ab	40.8±4.2a	32.9±1.3a	1.10±0.11ab	9.2±6.6a	30.2±1.7a
	CIN	693.3±148.9ab	254.0±129.1a	0.18±0.03b	48.3±23.5a	33.9±1.2a	1.05±0.02bc	8.3±3.1a	19.4±15.6a
	CON	537.7±65.3b	329.8±55.2a	0.28±0.11a	72.4±15.4a	30.9±3.7a	1.05±0.05bc	8.0±2.5a	29.6±4.1a
	UCK	939.6±379.5a	273.4±62.5a	0.20±0.02b	54.4±31.1a	33.5±0.5a	1.24±0.13a	8.6±0.4a	27.2±3.3a
	UIN	616.6±76.5b	310.4±32.3a	0.22±0.01ab	52.5±17.2a	28.3±7.0a	0.92±0.14c	7.4±1.2a	30.5±4.0a
	UON	624.8±26.6b	317.7±30.1a	0.19±0.04b	65.9±10.5a	32.9±2.6a	1.12±0.10ab	7.3±1.4a	29.7±4.5a

绵穗苏 Chelonopsis chekiangensis	CCK	572.5±124.4a	253.9±21.0a	0.37±0.14a	78.6±26.3a	26.8±6.9b	0.80±0.36a	24.1±6.7a	38.3±16.8a
	CIN	558.0±33.8a	239.9±17.8a	0.29±0.10a	68.9±21.2a	31.7±5.6ab	0.84±0.42a	20.4±11.2a	41.9±10.7a
	CON	571.4±73.4a	175.8±55.1b	0.28±0.05a	67.0±9.7a	36.6±5.1a	0.65±0.02a	22.3±5.9a	56.3±7.7a
	UCK	544.8±40.9a	241.5±26.0b	0.29±0.11a	57.4±24.9a	29.5±0.8ab	0.81±0.11a	22.1±3.0a	37.1±4.8a
	UIN	637.5±78.3a	212.5±35.4ab	0.32±0.08a	64.3±16.5a	35.3±5.7ab	0.83±0.18a	25.0±1.9a	44.1±11.3a
	UON	622.1±96.0a	211.5±32.0ab	0.31±0.12a	52.7±20.5a	33.6±6.1ab	0.73±0.31a	24.0±5.4a	52.5±22.3a

淡竹叶 Lophatherum gracile	CCK	942.8±92.3a	224.9±30.0a	0.17±0.04a	27.8±4.5a	27.2±0.9b	0.91±0.12ab	23.4±4.8a	30.2±3.6b
	CIN	1032.6±244.5a	215.7±35.9a	0.18±0.07a	28.8±9.3a	32.0±1.5a	1.03±0.17a	23.8±2.9a	31.7±4.8b
	CON	986.6±292.9a	172.1±75.9a	0.18±0.05a	24.8±7.3a	30.6±3.4ab	0.81±0.08b	22.1±2.7a	38.1±3.1a
	UCK	862.3±155.7a	235.2±33.2a	0.21±0.14a	26.1±2.1a	29.0±2.8ab	1.03±0.21a	26.7±5.5a	28.6±3.5b
	UIN	911.2±82.6a	225.3±15.7a	0.12±0.02a	25.6±4.1a	30.2±2.6ab	0.99±0.10ab	24.0±3.6a	30.6±3.2b
	UON	968.5±54.0a	217.4±20.0a	0.14±0.02a	24.1±6.9a	33.1±3.5a	0.96±0.03ab	23.7±1.6a	34.6±4.6ab

金星蕨 Parathelypteris glanduligera	CCK	1867.0±795.0ab	336.8±53.6a	0.27±0.09a	26.3±1.6ab	19.1±1.2a	0.78±0.09a	9.2±1.9bc	24.6±1.3a
	CIN	1632.4±392.7ab	306.6±52.4a	0.20±0.07a	25.2±6.0ab	22.3±2.6ab	0.82±0.12a	10.5±2.0abc	27.9±7.1a
	CON	2657.6±1269.4a	282.2±68.0a	0.18±0.01a	32.5±6.5a	24.8±7.1a	0.99±0.33a	15.8±5.7a	25.8±6.6a
	UCK	1430.5±317.0ab	320.3±42.8a	0.27±0.08a	29.9±3.1ab	19.0±0.8b	0.74±0.03a	7.7±2.1c	25.7±1.9a
	UIN	1286.7±823.5b	315.8±15.7a	0.25±0.12a	27.2±8.2ab	21.9±1.5ab	0.80±0.07a	14.2±5.3ab	27.5±0.9a
	UON	1511.2±737.3ab	310.2±25.0a	0.20±0.08a	23.0±4.1b	21.2±1.1ab	0.75±0.13a	11.1±2.0abc	28.7±5.1a

苔草Carex spp.	CCK	336.1±56.2b	377.2±31.5ab	0.33±0.03a	58.6±4.6a	16.2±1.3bc	0.86±0.21a	19.7±1.5a	19.4±3.8a
	CIN	340.9±45.7b	360.8±19.1ab	0.34±0.08a	58.4±4.9a	17.4±1.1b	0.82±0.33a	18.2±0.6a	24.2±10.0a
	CON	315.0±79.5b	385.6±51.8a	0.34±0.09a	63.00±24.3a	15.5±1.3c	0.68±0.07a	20.2±0.7a	18.2±11.1a
	UCK	437.4±165.9ab	357.4±42.2ab	0.28±0.05a	64.8±8.6a	16.5±1.3bc	0.72±0.16a	20.3±1.4a	23.6±4.9a
	UIN	522.0±122.1a	323.6±12.1b	0.27±0.10a	59.8±2.3a	17.4±1.2bc	0.98±0.27a	17.9±5.1a	18.8±5.0a
	UON	399.7±82.7ab	336.4±40.5ab	0.30±0.06a	55.7±16.6a	20.5±0.7a	0.95±0.36a	18.9±1.9a	24.2±9.5a

Table 1

Table 2

Fig.1

Fig.2

Fig.3

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叶片功能性状 Leaf functional traits	氮沉降方法 N deposition approach		沉降氮形态 Deposited N form		植物种类 Plant species		草本或灌木 Herbs or shrubs		豆科或非豆科 Fabaceae or non-Fabaceae
叶片功能性状 Leaf functional traits	df	P	df	P	df	P	df	P	df	P
比叶面积Specific leaf area (SLA)	1, 122	0.849	1, 122	0.593	7, 115	0.378	1, 121	0.178	1, 57	0.003

叶片干物质含量Leaf dry matter content (LDMC)	1, 125	0.010	1, 125	0.871	7, 118	0.038	1, 124	0.012	1, 57	0.104

叶片厚度Leaf thickness (LT)	1, 122	0.353	1, 122	0.283	7, 115	0.426	1, 121	0.130	1, 57	0.742

株高Plant height (H)	1, 125	0.785	1, 125	0.843	7, 118	0.017	1, 124	0.026	1, 60	0.009

全氮含量Total nitrogen content (TN)	1, 122	0.511	1, 122	0.278	7, 115	<0.001	1, 124	0.007	1, 60	<0.001

全磷含量Total phosphorus content (TP)	1, 122	0.408	1, 122	0.307	7, 115	0.157	1, 121	0.531	1, 57	0.010

全钾含量Total potassium content (TK)	1, 125	0.628	1, 125	0.813	7, 118	<0.001	1, 124	0.016	1, 60	0.968

叶片氮磷比 Leaf N∶P ratio (N/P)	1, 122	0.496	1, 122	0.094	7, 115	0.026	1, 121	0.157	1, 57	0.096

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Leaf Functional Traits of Understory Plants in a Moso Bamboo Forests in Response to Simulated Nitrogen Deposition

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