Effects of tree diversity on enzyme activity in litter of a subtropical forest ecosystem

doi:10.17520/biods.2021240

Abstract

Abstract:

Aims There is a growing concern regarding biodiversity loss and its effects on ecosystem functioning. Previous studies have primarily focused on the impact of biodiversity loss on plant productivity in forest ecosystems, but research regarding its effects on enzyme-mediated litter decomposition remains elusive. It has been well documented that the rate of litter decomposition is directly controlled by the activities of extracellular enzymes secreted by microbial decomposers, which is an important indicator of nutrient cycling in forest ecosystems. To explore the effect of biodiversity loss on extracellular enzyme activities in litter, and the underpinning mechanism that regulates litter decomposition, a field experiment was conducted in a subtropical forest.
Methods The experiment was conducted in a subtropical forest biodiversity-ecosystem functioning experimental area established in Xingangshan, Jiangxi Province. In this study area, 31 intensively studied plots which form a gradient of tree species diversity (i.e., 16 monocultures, eight 2-species mixtures, four 4-species mixtures, two 8-species mixtures and one 16-species mixture) were chosen. We collected fresh-fallen leaf litter in the plots of varying tree diversity levels and measured the extracellular enzyme activity, chemicals, and fungi in litter. We hypothesized that extracellular enzyme activities in litter, particularly those relevant to carbon (C), nitrogen (N), and phosphorus (P) cycling would significantly change with tree species diversity loss. We also expected to find that fungal decomposers could modulate the responses of enzyme activities to tree species diversity loss.
Result Our results showed that tree species diversity loss significantly affected the activities of extracellular enzymes, and extracellular enzyme activity showed a positive correlation with increasing tree species richness, except for single species. The activities of α-glucosidase (AG), β-glucosidase (BG), and cellubiosidase (CB), which are involved in C turnover, were the highest in the litter from the plot with the highest tree species diversity. Xylosidase (XS), N-acetyl-β-glucosaminidase (NAG), acid phosphatase (AP), and polyphenol oxidase (PPO), which are respectively involved in the turnover of N and P and the degradation of polyphenol, had higher rates of activity when the tree species diversity was lower. Moreover, we found that the extracellular enzyme activities showed a ‘single peak’ trend that correlated to changes of neighboring tree species diversity. This trend indicates that most of the extracellular enzyme activities relevant to the turnover of C, N and P were highest when the species richness of the six neighboring tree species was high as well. These findings indicate that both plot-level tree diversity and neighboring tree species can significantly alter extracellular enzyme activities in litter of target tree species. Fungal decomposers may play an important role in affecting the response of extracellular enzyme activities to tree species diversity loss.
Conclusions Our findings demonstrate that the loss of tree species diversity may indirectly affect extracellular enzyme activity by influencing the community structure and abundance of fungal decomposers. This study promotes our understanding of how tree diversity loss influences litter degradation and nutrient release through the modulation of extracellular enzyme activities in subtropical forests.

Key words: enzymatic degradation, litter decomposition, tree species diversity, neighboring tree species diversity, saprotrophic fungi, subtropical forest

Yumei Pan, Naili Zhang. Effects of tree diversity on enzyme activity in litter of a subtropical forest ecosystem[J]. Biodiv Sci, 2021, 29(11): 1447-1460.

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URL: https://www.biodiversity-science.net/EN/10.17520/biods.2021240

https://www.biodiversity-science.net/EN/Y2021/V29/I11/1447

Figures/Tables 6

Table 1 The corresponding substrate of extracellular enzyme activity of litter leaves

胞外酶名称 Extracellular enzyme	胞外酶活性对应底物 Extracellular enzyme activity substrate
α-葡萄糖苷酶 α-glucosidase (AG)	4-羟甲基-7-香豆素(MUB)-α-D-葡萄糖苷 4-MUB-α-D-glucopyranoside
β-葡萄糖苷酶 β-glucosidase (BG)	4-羟甲基-7-香豆素(MUB)-β-D-葡萄糖苷 4-MUB-β-D-glucopyranoside
纤维二糖水解酶 Cellubiosidase (CB)	4-羟甲基-7-香豆素(MUB)-β-D-纤维二糖糖苷 4-MUB-β-D-cellobioside
木糖苷酶 Xylosidase (XS)	4-羟甲基-7-香豆素(MUB)-β-D-木吡喃糖苷 4-MUB-β-D-xylopyranoside
N-乙酰-β-氨基葡萄糖苷酶 N-acetyl-β-glucosaminidase (NAG)	4-羟甲基-7-香豆素(MUB)-N-乙酰-β-氨基葡萄糖苷 4-MUB-N-acetyl-β-D-glucosaminide
酸性磷酸酶 Acid phosphatase (AP)	4-羟甲基-7-香豆素(MUB)磷酸盐 4-MUB phosphate
多酚氧化酶 Polyphenol oxidase (PPO)	L-二羟苯丙氨酸(DOPA) L-dihydroxyphenyllalanine

Table 2 The effects of tree richness at the plot level, neighbor tree richness and litter chemicals on the activities of extracellular enzymes (F value). A linear mixed effect model was established with tree species richness, neighbour tree species richness, conspecifics richness (the richness of the same species with neighbor species as target species), litter organic carbon, total nitrogen, phosphorus, calcium, iron, magnesium, elevation, north-south slope orientation and east-west slope orientation as fixed factors, and tree species and species category as random variables. AG, α-glucosidase; BG, β-glucosidase; CB, Cellubiosidase; XS, Xylosidase; NAG, N-acetyl-β-glucosaminidase; AP, Acid phosphatase; PPO, Polyphenol oxidase. *, P < 0.1; **, P < 0.05; ***, P < 0.01.

影响因子 Impact factor	AG	BG	CB	XS	NAG	AP	PPO
树种丰富度 Tree richness	12.469^***	2.245	5.282^**	4.683^**	0.434	1.945	0.404
邻居树种丰富度 Neighbor tree richness	8.351^***	1.474	6.076^**	4.712^**	8.009^***	1.100	1.897
同种树种丰富度 Conspecific species richness	1.058	10.658^***	11.566^***	17.113^***	10.518^***	11.720^***	5.526^**
凋落叶有机碳含量 Litter organic carbon content	0.500	0.290	0.177	0.566	1.982	0.000	1.008
凋落叶全氮含量 Litter total nitrogen content	1.868	1.845	3.140^*	0.000	9.660^***	1.214	1.424
凋落叶磷含量 Litter P content	0.652	2.313	3.109^*	1.374	3.378^*	0.626	0.057
凋落叶钙含量 Litter Ca content	0.452	0.462	0.669	3.195^*	10.781^***	4.451^**	1.122
凋落叶铁含量 Litter Fe content	0.591	2.325	1.532	1.884	0.925	1.066	0.172
凋落叶镁含量 Litter Mg content	0.101	0.234	0.269	0.352	0.068	3.068^*	0.035
海拔 Altitude	0.218	0.169	0.218	0.413	0.238	0.187	1.234
南北坡向 North-south aspect	2.519	5.133^**	6.337^**	13.787^***	6.817^**	5.251^**	0.072
东西坡向 East-west aspect	0.089	0.001	1.414	0.392	0.061	7.307^**	3.663^*
坡度 Slope	1.305	2.709	2.303	1.526	0.237	1.215	0.988

影响因子 Impact factor	AG	BG	CB	XS	NAG	AP	PPO
树种丰富度 Tree richness	12.469^***	2.245	5.282^**	4.683^**	0.434	1.945	0.404
邻居树种丰富度 Neighbor tree richness	8.351^***	1.474	6.076^**	4.712^**	8.009^***	1.100	1.897
同种树种丰富度 Conspecific species richness	1.058	10.658^***	11.566^***	17.113^***	10.518^***	11.720^***	5.526^**
凋落叶有机碳含量 Litter organic carbon content	0.500	0.290	0.177	0.566	1.982	0.000	1.008
凋落叶全氮含量 Litter total nitrogen content	1.868	1.845	3.140^*	0.000	9.660^***	1.214	1.424
凋落叶磷含量 Litter P content	0.652	2.313	3.109^*	1.374	3.378^*	0.626	0.057
凋落叶钙含量 Litter Ca content	0.452	0.462	0.669	3.195^*	10.781^***	4.451^**	1.122
凋落叶铁含量 Litter Fe content	0.591	2.325	1.532	1.884	0.925	1.066	0.172
凋落叶镁含量 Litter Mg content	0.101	0.234	0.269	0.352	0.068	3.068^*	0.035
海拔 Altitude	0.218	0.169	0.218	0.413	0.238	0.187	1.234
南北坡向 North-south aspect	2.519	5.133^**	6.337^**	13.787^***	6.817^**	5.251^**	0.072
东西坡向 East-west aspect	0.089	0.001	1.414	0.392	0.061	7.307^**	3.663^*
坡度 Slope	1.305	2.709	2.303	1.526	0.237	1.215	0.988

Fig. 1 The activities of seven extracellular enzymes in litter of the target tree species under different tree species richness at the plot level (mean ± SE). Different letters indicate significant differences (P < 0.05).

Fig. 2 The activities of seven extracellular enzymes in litter of the target tree species under different neighbour tree species richness (mean ± SE). Different letters indicate significant differences (P < 0.05).

Fig. 3 Correlation between alpha-diversity index of saprotrophic fungal community and extracellular enzyme activities in litter of the target tree species. AG, α-glucosidase; BG, β-glucosidase; CB, Cellubiosidase; XS, Xylosidase; NAG, N-acetyl-β-glucosaminidase; AP, Acid phosphatase; PPO, Polyphenol oxidase. Richness, Saprotrophic fungal richness; Chao 1, Chao 1 index; ACE, Abundance-based coverage estimators index; Shannon, Shannon index; Simpson, Simpson index; Pielou’s, Pielou’s evennesss index; Abundance, Saprotrophic fungal abundance. green, Positive correlation; red, Negative correlation; *, P < 0.1; **, P < 0.05; ***, P < 0.001.

Fig. 4 Mantel test and distance-based redundancy analysis (db-RDA) of saprotrophic fungal community and extracellular enzyme activities. AG, α-glucosidase; BG, β-glucosidase; CB, Cellubiosidase; XS, Xylosidase; NAG, N-acetyl-β-glucosaminidase; AP, Acid phosphatase; PPO, Polyphenol oxidase.

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