Global predation pressure redistribution under future climate change

被引:62
|
作者
Romero, Gustavo Q. [1 ]
Goncalves-Souza, Thiago [2 ]
Kratina, Pavel [3 ]
Marino, Nicholas A. C. [4 ]
Petry, William K. [5 ]
Sobral-Souza, Thadeu [6 ]
Roslin, Tomas [7 ,8 ]
机构
[1] Univ Estadual Campinas, Inst Biol, Dept Anim Biol, Lab Multitroph Interact & Biodivers, Sao Paulo, Brazil
[2] Univ Fed Rural Pernambuco, Dept Biol, Lab Ecol Synth & Biodivers Conservat, Recife, PE, Brazil
[3] Queen Mary Univ London, Sch Biol & Chem Sci, London, England
[4] Univ Fed Rio de Janeiro, Inst Biol, Dept Ecol, Ctr Ciencias Saude,Lab Limnol, Rio De Janeiro, Brazil
[5] Eidgenoss Tech Hsch Zurich, Inst Integrat Biol, Zurich, Switzerland
[6] Univ Estadual Paulista, Biosci Inst, Dept Ecol, Spatial Ecol & Conservat Lab, Sao Paulo, Brazil
[7] Swedish Univ Agr Sci, Dept Ecol, Spatial Foodweb Ecol Grp, Uppsala, Sweden
[8] Univ Helsinki, Dept Agr Sci, Spatial Foodweb Ecol Grp, Helsinki, Finland
来源
NATURE CLIMATE CHANGE | 2018年 / 8卷 / 12期
基金
巴西圣保罗研究基金会; 芬兰科学院;
关键词
SPECIES INTERACTIONS; TEMPERATURE; PRECIPITATION; PATTERNS; MODELS; DISTRIBUTIONS; DEPENDENCE; LATITUDE; NICHES; PLANTS;
D O I
10.1038/s41558-018-0347-y
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
How climate affects biotic interactions is a question of urgent concern(1-3). Theory predicts that biotic interactions are stronger at lower latitudes(4-6). However, the role of climate in governing these patterns is typically assumed, rather than explicitly tested. Here, we dissected the influence of climatic descriptors on predation pressure using data from a global experiment with model caterpillars. We then used projections of future climate change to predict shifts in predation pressure. Climate, particularly components of temperature, explained latitudinal and elevational patterns of predation better than latitude or elevation by themselves. Projected predation pressure was greater under higher temperatures and more stable climates. Increased climatic instability projected for the near future predicts a general decrease in predation pressure over time. By identifying the current climatic drivers of global patterns in a key biotic interaction, we show how shifts in these drivers could alter the functioning of terrestrial ecosystems and their associated services.
引用
收藏
页码:1087 / +
页数:7
相关论文
共 50 条
  • [1] Global predation pressure redistribution under future climate change
    Gustavo Q. Romero
    Thiago Gonçalves-Souza
    Pavel Kratina
    Nicholas A. C. Marino
    William K. Petry
    Thadeu Sobral-Souza
    Tomas Roslin
    Nature Climate Change, 2018, 8 : 1087 - 1091
  • [2] Future aridity under conditions of global climate change
    Zarch, Mohammad Amin Asadi
    Sivakumar, Bellie
    Malekinezhad, Hossein
    Sharma, Ashish
    JOURNAL OF HYDROLOGY, 2017, 554 : 451 - 469
  • [3] Future challenges for global food security under climate change
    Sade, Nir
    Peleg, Zvi
    PLANT SCIENCE, 2020, 295
  • [4] Climate velocity and the future global redistribution of marine biodiversity
    Garciá Molinos J.
    Halpern B.S.
    Schoeman D.S.
    Brown C.J.
    Kiessling W.
    Moore P.J.
    Pandolfi J.M.
    Poloczanska E.S.
    Richardson A.J.
    Burrows M.T.
    Nature Climate Change, 2016, 6 (1) : 83 - 88
  • [5] Climate velocity and the future global redistribution of marine biodiversity
    Molinos, Jorge Garcia
    Halpern, Benjamin S.
    Schoeman, David S.
    Brown, Christopher J.
    Kiessling, Wolfgang
    Moore, Pippa J.
    Pandolfi, John M.
    Poloczanska, Elvira S.
    Richardson, Anthony J.
    Burrows, Michael T.
    NATURE CLIMATE CHANGE, 2016, 6 (01) : 83 - +
  • [6] Migration, climate change and the futures of global population redistribution
    Skeldon, Ronald
    NEW ZEALAND ECONOMIC PAPERS, 2024,
  • [7] Future projections for Mexican faunas under global climate change scenarios
    A. Townsend Peterson
    Miguel A. Ortega-Huerta
    Jeremy Bartley
    Victor Sánchez-Cordero
    Jorge Soberón
    Robert H. Buddemeier
    David R. B. Stockwell
    Nature, 2002, 416 : 626 - 629
  • [8] Global prediction of gross primary productivity under future climate change
    Lu, Qikai
    Liu, Hui
    Wei, Lifei
    Zhong, Yanfei
    Zhou, Zheng
    SCIENCE OF THE TOTAL ENVIRONMENT, 2024, 912
  • [9] Past and future global transformation of terrestrial ecosystems under climate change
    Nolan, Connor
    Overpeck, Jonathan T.
    Allen, Judy R. M.
    Anderson, Patricia M.
    Betancourt, Julio L.
    Binney, Heather A.
    Brewer, Simon
    Bush, Mark B.
    Chase, Brian M.
    Cheddadi, Rachid
    Djamali, Morteza
    Dodson, John
    Edwards, Mary E.
    Gosling, William D.
    Haberle, Simon
    Hotchkiss, Sara C.
    Huntley, Brian
    Ivory, Sarah J.
    Kershaw, A. Peter
    Kim, Soo-Hyun
    Latorre, Claudio
    Leydet, Michelle
    Lezine, Anne-Marie
    Liu, Kam-Biu
    Liu, Yao
    Lozhkin, A. V.
    McGlone, Matt S.
    Marchant, Robert A.
    Momohara, Arata
    Moreno, Patricio I.
    Mueller, Stefanie
    Otto-Bliesner, Bette L.
    Shen, Caiming
    Stevenson, Janelle
    Takahara, Hikaru
    Tarasov, Pavel E.
    Tipton, John
    Vincens, Annie
    Weng, Chengyu
    Xu, Qinghai
    Zheng, Zhuo
    Jackson, Stephen T.
    SCIENCE, 2018, 361 (6405) : 920 - 923
  • [10] Future projections for Mexican faunas under global climate change scenarios
    Peterson, AT
    Ortega-Huerta, MA
    Bartley, J
    Sánchez-Cordero, V
    Soberón, J
    Buddemeier, RH
    Stockwell, DRB
    NATURE, 2002, 416 (6881) : 626 - 629
12345