川西亚高山暗针叶林及其采伐次生林林下分层谱系结构

doi:10.11707/j.1001-7488.20200701

林业科学 ›› 2020, Vol. 56 ›› Issue (7): 1-11.doi: 10.11707/j.1001-7488.20200701

川西亚高山暗针叶林及其采伐次生林林下分层谱系结构

陈欢欢^1,²,许格希^1,²,马凡强^1,²,刘顺^1,²,张淼淼^1,²,曹向文^1,²,陈健^1,²,赵广东^1,²,杨洪国³,史作民^1,^2,^4,*

1. 中国林业科学研究院森林生态环境与保护研究所国家林业和草原局森林生态环境重点实验室北京 100091
2. 四川米亚罗森林生态系统定位观测研究站阿坝 623100
3. 中国林业科学研究院湿地研究所北京 100091
4. 南京林业大学南方现代林业协同创新中心南京 210037

收稿日期:2019-01-21 出版日期:2020-07-25 发布日期:2020-07-17
通讯作者: 史作民
基金资助:
国家重点研发计划(2016YFC0502104-02);国家重点研发计划(2017YFC0505001);中国林业科学研究院基本科研业务费专项(CAFYBB2018ZA003)

Phylogenetic Structure of Undergrowth Layers across Subalpine Dark Coniferous Forests and Their Post-Harvesting Secondary Forests in Western Sichuan

Huanhuan Chen^1,²,Gexi Xu^1,²,Fanqiang Ma^1,²,Shun Liu^1,²,Miaomiao Zhang^1,²,Xiangwen Cao^1,²,Jian Chen^1,²,Guangdong Zhao^1,²,Hongguo Yang³,Zuomin Shi^1,^2,^4,*

1. Key Laboratory on Forest Ecology and Environmental Sciences of National Forestry and Grassland Administration Institute of Forest Ecology, Environment and Protection, CAF Beijing 100091
2. Miyaluo Research Station of Alpine Forest Ecosystem Aba 623100
3. Institute of Wetland Research, CAF Beijing 100091
4. Co-Innovation Center for Sustainable Forestry in Southern China Nanjing Forestry University Nanjing 210037

Received:2019-01-21 Online:2020-07-25 Published:2020-07-17
Contact: Zuomin Shi

摘要/Abstract

摘要：

目的: 研究川西亚高山不同演替阶段森林群落的林下乔灌草层次谱系结构及对其驱动的生态学过程，为川西林区森林生物多样性保护与生态系统修复提供理论依据。方法: 利用川西亚高山原始暗针叶林(以下简称原始林)及其在1950—1969年和1970—1989年采伐后形成的天然次生林(以下简称次生林)的林下(不包括主林层，因其树种组成相对单一)乔灌草群落生态学调查资料，基于APG Ⅲ谱系框架，构建不同演替阶段森林群落的乔灌草系统发育树，选用广泛使用的谱系多样性指数——净亲缘指数(NRI)和最近类群指数(NTI)，量化和评估不同演替阶段林型的乔灌草分层谱系结构及对其驱动的生态学过程。结果: 原始林亚林层物种组成谱系离散(NRI < 0；NTI < 0)，即共存物种亲缘相疏，而原始林其他层次(草本层、灌木层与小乔木层)物种组成倾向于谱系聚集(NRI > 0；NTI > 0)，即共存物种亲缘相近；2个不同采伐年代形成的次生林的草本层和亚林层的谱系结构呈现出林型间相似但层次间相反的模式(草本层：谱系离散；亚林层：谱系聚集)，灌木层和小乔木层则表现为层间相似但林型间相反的模式(1950—1969年：谱系聚集；1970—1989年代：谱系离散)；不同演替阶段森林群落的林下乔灌草NRI与NTI均极显著正相关(0.698 ≤ R² ≤ 0.769，P < 0.001)；不同演替阶段森林群落的林下乔灌草分层谱系结构(NRI与NTI)与物种多样性(香侬多样性指数H')的关联分析绝大部分未通过显著性检验，但林下乔灌草谱系结构与H'的局部多项式回归分析发现，原始林和1970—1989年采伐后次生林中的H'与NRI、H'与NTI的相关变化趋势表现出相似的波峰-波谷变化模式。结论: 川西亚高山原始暗针叶林及其采伐次生林的林下乔灌草层次谱系结构在层次间和林型间存在差异性。环境过滤是驱动原始林中草本层、灌木层和小乔木层物种谱系组成的主要生态学过程，竞争互斥则塑造亚林层中的物种谱系组成。次生林的林下乔灌草层次谱系结构及对其驱动的生态学过程大致与原始林相反，表现为环境过滤主导亚林层的谱系结构，竞争互斥主导草本层的谱系结构。川西亚高山不同演替阶段森林群落的林下乔灌草层次谱系多样性与物种多样性相互独立。

关键词: 净亲缘指数与最近类群指数, 生态位理论, 乔灌草层次, 谱系结构, 暗针叶林

Abstract:

Objective: To provide a theoretical basis for biodiversity conservation and ecosystem restoration,a study of phylogenetic structure of the undergrowth tree,shrub,and herb layers and their driven ecological processes were conducted across different successional forest communities in the subalpine area of western Sichuan. Method: We used inventory data of tree-shrub-grass species compositions of the undergrowth layers in the subalpine forests,which consists of primary dark coniferous forests(hereafter primary forest) and their secondary forests(hereafter secondary forest) after harvesting in the period 1950 to 1969 and 1970 to 1989. We ignored canopy layer because tree species compositions in this layer were relatively simple. A phylogenetic tree of the understory plant species was rebuilt based on the APG Ⅲ phylogenetic framework for different successional forest communities. Two widely selected phylogenetic diversity indices,net relatedness index(NRI) and nearest taxon index(NTI),were used to quantify and assess the phylogenetic structure of different undergrowth layers and their driven ecological processes during forest succession. Result: For primary forest,a phylogenetic over-dispersion pattern(i.e.,NRI < 0; NTI < 0) was shown in the sub-canopy layer,suggesting that distantly related species coexist in this layer. In contrast,a phylogenetic clustering pattern(i.e.,NRI > 0; NTI > 0) was displayed in the other three layers(i.e.,herb,shrub and small tree),which implies that close related species consist of these layers. The two secondary forests formed in different deforestation phases showed a consistent phylogenetic pattern in the herb layer(i.e.,phylogenetic over-dispersion),which was contrary to that in the sub-canopy layer(i.e.,phylogenetic clustering). However,the shrub and small tree layers showed a similar pattern but inversely expressed on the two secondary forests,which were phylogenetic clustering in 1950—1969 regenerated forest and phylogenetic overdispersion in 1970—1989 regenerated forest. The relationships between NRI and NTI of the undergrowth layers were significantly positive for both primary and secondary forests. Pearson correlation analysis showed that Shannon's diversity index(H') and NRI or NTI were neither significant across undergrowth layers nor across different successional forests. However,the local polynomial regression fitting revealed that the correlations between H' and NRI or NTI displayed identical peak-and-trough changing patterns on primary and 1970—1989 secondary forests. Conclusion: The phylogenetic structure is different across undergrowth layers as well as across primary forests and their secondary forests with different deforestation phases. Environmental filtering is a main ecological process influencing species compositions in the herb,shrub and small tree layers,whereas competitive exclusion has a greater force in constructing phylogenetic assembly of the sub-canopy layer. For secondary forest,the phylogenetic structure of undergrowth layers and their underlying ecological processes are mainly opposite to those in primary forest,that is environmental filtering determines phylogenetic structure of the sub-canopy layer and competitive exclusion determines species compositions of the herb layer. Phylogenetic diversity is independent with species diversity for undergrowth layers across different successional forests in the subalpine of western Sichuan.

Key words: net relatedness index and nearest taxon index, niche theory, tree, shrub, herb layers, phylogenetic structure, dark coniferous forest

中图分类号:

S714.3

陈欢欢,许格希,马凡强,刘顺,张淼淼,曹向文,陈健,赵广东,杨洪国,史作民. 川西亚高山暗针叶林及其采伐次生林林下分层谱系结构[J]. 林业科学, 2020, 56(7): 1-11.

Huanhuan Chen,Gexi Xu,Fanqiang Ma,Shun Liu,Miaomiao Zhang,Xiangwen Cao,Jian Chen,Guangdong Zhao,Hongguo Yang,Zuomin Shi. Phylogenetic Structure of Undergrowth Layers across Subalpine Dark Coniferous Forests and Their Post-Harvesting Secondary Forests in Western Sichuan[J]. Scientia Silvae Sinicae, 2020, 56(7): 1-11.

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谱系指数 Phylogenetic index	森林类型 Forest type	林下层次Undergrowth layer
谱系指数 Phylogenetic index	森林类型 Forest type	草本层 Herb	灌木层 Shrub	小乔木层 Small tree	亚林层 Sub-canopy
NRI	原始林Primary forest	0.19±0.31Aab	0.22±0.57ABa	-0.03±1.06Aab	-1.14±0.42Ab
	1950―1969年次生林 1950―1969 secondary forest	-0.60±0.56Aa	0.40±0.28Aa	0.23±0.17Aa	0.37±0.28Ba
	1970―1989年次生林 1970―1989 secondary forest	-0.50±0.34Aab	-0.40±0.14Bbc	-1.84±0.42Bc	0.35±0.23Ba
NTI	原始林Primary forest	0.31±0.37Aa	0.63±0.44Aa	0.40±0.29Aa	-0.96±0.46Ab
	1950―1969年次生林 1950―1969 secondary forest	-0.34±0.50Aa	0.79±0.22Aa	0.52±0.19Aa	0.64±0.21Ba
	1970―1989年次生林 1970―1989 secondary forest	-0.97±0.16Aa	-0.76±0.20Ba	-1.89±0.32Ba	0.47±0.28Bb

森林类型 Forest type	林下层次 Undergrowth layer	相关系数Correlation coefficient
森林类型 Forest type	林下层次 Undergrowth layer	H′ & NRI	H′ & NTI
原始林 Primary forest	草本层Herb	-0.866	-0.614
	灌木层Shrub	0.143	0.173
	小乔木层Small tree	-0.097	0.296
	亚林层Sub-canopy	0.690	0.823^*
1950―1969年次生林 1950―1969 secondary forest	草本层Herb	-0.323	-0.171
	灌木层Shrub	0.472	0.228
	小乔木层Small tree	0.296	0.010
	亚林层Sub-canopy	0.822^*	0.705
1970―1989年次生林 1970―1989 secondary forest	草本层Herb	-0.120	-0.169
	灌木层Shrub	-0.515	-0.004
	小乔木层Small tree	-0.619	-0.683
	亚林层Sub-canopy	-0.111	0.038

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川西亚高山暗针叶林及其采伐次生林林下分层谱系结构

Phylogenetic Structure of Undergrowth Layers across Subalpine Dark Coniferous Forests and Their Post-Harvesting Secondary Forests in Western Sichuan

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