Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests

doi:10.1016/j.pld.2025.06.004

Plant Diversity ›› 2025, Vol. 47 ›› Issue (05): 784-792.DOI: 10.1016/j.pld.2025.06.004

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Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests

Zhaochen Zhang (张昭臣)^a, Fang Wang (王芳)^b, Xiaoran Wang (王潇然)^b, Mufan Sun (孙慕梵)^b, Pu Zheng (郑普)^b, Jingchao Zhao (赵静超)^b, Junhong Chen (陈俊红)^b, Min Guan (关敏)^b, Pengcheng Liu (刘鹏程)^b, Xiaofan Shang (商晓凡)^b, Yaoshun Lu (卢尧舜)^b, Qingpei Yang (杨清培)^c, Qingni Song (宋庆妮)^c, Lin Chen (陈琳)^d, Quying Zhong (钟曲颖)^d, Jian Zhang (张健)^e

a. Lushan Botanical Garden, Jiangxi Province and Chinese Academy of Sciences, Jiujiang 332900, China;
b. School of Ecological and Environmental Sciences, East China Normal University, Shanghai 200241, China;
c. College of Forestry, Jiangxi Agricultural University, Nanchang 330045, China;
d. Administration of Guanshan National Nature Reserve, Yichun 336300, China;
e. State Key Laboratory of Biocontrol, School of Life Sciences, Sun Yat-Sen University, Guangzhou 510275, China

Received:2025-03-11 Revised:2025-06-04 Online:2025-09-29 Published:2025-09-29
Contact: Jian Zhang,E-mail:zhangjian6@mail.sysu.edu.cn
Supported by:
We gratefully acknowledge financial support from the Jiangxi Natural Science Foundation (20242BAB25345) to Z.Z. and the Innovation Program of Shanghai Municipal Education Commission (2023ZKZD36) to J.Z.

Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests

a. Lushan Botanical Garden, Jiangxi Province and Chinese Academy of Sciences, Jiujiang 332900, China;
b. School of Ecological and Environmental Sciences, East China Normal University, Shanghai 200241, China;
c. College of Forestry, Jiangxi Agricultural University, Nanchang 330045, China;
d. Administration of Guanshan National Nature Reserve, Yichun 336300, China;
e. State Key Laboratory of Biocontrol, School of Life Sciences, Sun Yat-Sen University, Guangzhou 510275, China

通讯作者: Jian Zhang,E-mail:zhangjian6@mail.sysu.edu.cn
基金资助:
We gratefully acknowledge financial support from the Jiangxi Natural Science Foundation (20242BAB25345) to Z.Z. and the Innovation Program of Shanghai Municipal Education Commission (2023ZKZD36) to J.Z.

Abstract

Abstract: The ecological and evolutionary mechanisms underlying montane biodiversity patterns remain unresolved. To understand which factors determined community assembly rules in mountains, biogeographic affinity that represents the biogeographic and evolutionary history of species should incorporate with current environments. We aim to address two following questions: 1) How does plant taxonomic and phylogenetic diversity with disparate biogeographic affinities vary along the subtropical elevational gradient? 2) How do biogeographic affinity and environmental drivers regulate the community assembly? We collected woody plant survey data of 32 forest plots in a subtropical mountain of Mt. Guanshan with typical transitional characteristics, including 250 woody plant species belonging to 56 families and 118 genera. We estimated the effects of biogeographic affinity, climate and soil properties on taxonomic and phylogenetic diversity of plant communities employing linear regression and structural equation models. We found that the richness of temperate-affiliated species increased with elevations, but the evenness decreased, while tropical-affiliated species had no significant patterns. Winter temperature directly or indirectly via biogeographic affinity shaped the assemblage of woody plant communities along elevations. Biogeographic affinity affected what kind of species could colonize higher elevations while local environment determined their fitness to adapt. These results suggest that biogeographic affinity and local environment jointly lead to the dominance of temperate-affiliated species at higher elevations and shape the diversity of woody plant communities along elevational gradients. Our findings highlight the legacy effect of biogeographic affinity on the composition and structure of subtropical montane forests.

Key words: Taxonomic diversity, Phylogenetic diversity, Biogeographic affinity, Cold tolerance, Phylogenetic niche conservatism

摘要： The ecological and evolutionary mechanisms underlying montane biodiversity patterns remain unresolved. To understand which factors determined community assembly rules in mountains, biogeographic affinity that represents the biogeographic and evolutionary history of species should incorporate with current environments. We aim to address two following questions: 1) How does plant taxonomic and phylogenetic diversity with disparate biogeographic affinities vary along the subtropical elevational gradient? 2) How do biogeographic affinity and environmental drivers regulate the community assembly? We collected woody plant survey data of 32 forest plots in a subtropical mountain of Mt. Guanshan with typical transitional characteristics, including 250 woody plant species belonging to 56 families and 118 genera. We estimated the effects of biogeographic affinity, climate and soil properties on taxonomic and phylogenetic diversity of plant communities employing linear regression and structural equation models. We found that the richness of temperate-affiliated species increased with elevations, but the evenness decreased, while tropical-affiliated species had no significant patterns. Winter temperature directly or indirectly via biogeographic affinity shaped the assemblage of woody plant communities along elevations. Biogeographic affinity affected what kind of species could colonize higher elevations while local environment determined their fitness to adapt. These results suggest that biogeographic affinity and local environment jointly lead to the dominance of temperate-affiliated species at higher elevations and shape the diversity of woody plant communities along elevational gradients. Our findings highlight the legacy effect of biogeographic affinity on the composition and structure of subtropical montane forests.

关键词: Taxonomic diversity, Phylogenetic diversity, Biogeographic affinity, Cold tolerance, Phylogenetic niche conservatism

Zhaochen Zhang (张昭臣), Fang Wang (王芳), Xiaoran Wang (王潇然), Mufan Sun (孙慕梵), Pu Zheng (郑普), Jingchao Zhao (赵静超), Junhong Chen (陈俊红), Min Guan (关敏), Pengcheng Liu (刘鹏程), Xiaofan Shang (商晓凡), Yaoshun Lu (卢尧舜), Qingpei Yang (杨清培), Qingni Song (宋庆妮), Lin Chen (陈琳), Quying Zhong (钟曲颖), Jian Zhang (张健). Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests[J]. Plant Diversity, 2025, 47(05): 784-792.

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Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests

Biogeographic affinity partly shapes woody plant diversity along an elevational gradient in subtropical forests

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