Direct and indirect effects of climate on richness drive the latitudinal diversity gradient in forest trees

Chengjin Chu(Sun Yat-sen University), James A. Lutz(Utah State University), Kamil Král(Landscape Research Institute), Tomáš Vrška(Landscape Research Institute), Xue Yin(Sun Yat-sen University), Jonathan A. Myers(Washington University in St. Louis), Iveren Abiem(University of Jos), Alfonso Alonso(Smithsonian Conservation Biology Institute), Norm Bourg(United States Geological Survey), David F. R. P. Burslem(University of Aberdeen), Min Cao(Xishuangbanna Tropical Botanical Garden), Hazel Chapman(University of Canterbury), Richard Condit(Morton Arboretum), Suqin Fang(Sun Yat-sen University), Gunter A. Fischer(Tai Po Hospital), Lian‐Ming Gao(Kunming Institute of Botany), Zhanqin Hao(Chinese Academy of Sciences), Billy C. H. Hau(University of Hong Kong), Qing He(Sun Yat-sen University), Andy Hector(University of Oxford), Stephen P. Hubbell(University of California, Los Angeles), Mingxi Jiang(Wuhan Botanical Garden), Guangze Jin(Northeast Forestry University), David Kenfack(Smithsonian Tropical Research Institute), Jiangshan Lai(Chinese Academy of Sciences), Buhang Li(Sun Yat-sen University), Xiankun Li(Guangxi Institute of Botany), Yide Li(Research Institute of Tropical Forestry), Juyu Lian(South China Botanical Garden), Luxiang Lin(Xishuangbanna Tropical Botanical Garden), Yankun Liu(Heilongjiang Academy of Forestry), Yu Liu(Heilongjiang Academy of Forestry), Ya‐Huang Luo(Kunming Institute of Botany), Keping Ma(Chinese Academy of Sciences), William J. McShea(Smithsonian Conservation Biology Institute), Hervé Memiaghe(Centre National de la Recherche Scientifique et Technologique), Xiangcheng Mi(Chinese Academy of Sciences), Ming Ni(Sun Yat-sen University), Michael J. O’Brien(East Asia Research), Alexandre A. Oliveira(Universidade de São Paulo), David A. Orwig(Harvard University), Geoffrey G. Parker(Smithsonian Environmental Research Center), Xiujuan Qiao(Wuhan Botanical Garden), Haibao Ren(Chinese Academy of Sciences), Glen Reynolds(East Asia Research), Weiguo Sang(Minzu University of China), Guochun Shen(East China Normal University), Zhiyao Su(South China Agricultural University), Xinghua Sui(Sun Yat-sen University), I‐Fang Sun(National Dong Hwa University), Songyan Tian(Heilongjiang Academy of Forestry), Bin Wang(Guangxi Institute of Botany), Xihua Wang(Institute of Applied Ecology), Xugao Wang(Chinese Academy of Sciences), Youshi Wang(Sun Yat-sen University), George D. Weiblen(University of Minnesota), Shujun Wen(Guangxi Institute of Botany), Nianxun Xi(Sun Yat-sen University), Wusheng Xiang(Guangxi Institute of Botany), Han Xu(Research Institute of Tropical Forestry), Kun Xu(Kunming Institute of Botany), Wanhui Ye(South China Botanical Garden), Bingwei Zhang(Sun Yat-sen University), Jiaxin Zhang(Wuhan Botanical Garden), Xiaotong Zhang(Sun Yat-sen University), Ying‐Ming Zhang(Fanjingshan National Nature Reserve), Kai Zhu(University of California, Santa Cruz), Jess K. Zimmerman(University of Puerto Rico System), David Štorch(Charles University), Jennifer L. Baltzer(Wilfrid Laurier University), Kristina J. Anderson‐Teixeira(Smithsonian Tropical Research Institute), Gary G. Mittelbach(Michigan State University), Fangliang He(University of Alberta)
Ecology Letters
December 12, 2018
10.1111/ele.13175
Cited by 149Open Access
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Abstract

Climate is widely recognised as an important determinant of the latitudinal diversity gradient. However, most existing studies make no distinction between direct and indirect effects of climate, which substantially hinders our understanding of how climate constrains biodiversity globally. Using data from 35 large forest plots, we test hypothesised relationships amongst climate, topography, forest structural attributes (stem abundance, tree size variation and stand basal area) and tree species richness to better understand drivers of latitudinal tree diversity patterns. Climate influences tree richness both directly, with more species in warm, moist, aseasonal climates and indirectly, with more species at higher stem abundance. These results imply direct limitation of species diversity by climatic stress and more rapid (co-)evolution and narrower niche partitioning in warm climates. They also support the idea that increased numbers of individuals associated with high primary productivity are partitioned to support a greater number of species.

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