Density-dependent network structuring within and across wild animal systems

IF 13.9 1区生物学 Q1 ECOLOGY

Nature ecology & evolution Pub Date : 2025-09-04 DOI:10.1038/s41559-025-02843-z

Gregory F. Albery, Daniel J. Becker, Josh A. Firth, Delphine De Moor, Sanjana Ravindran, Matthew Silk, Amy R. Sweeny, Eric Vander Wal, Quinn Webber, Bryony Allen, Simon A. Babayan, Sahas Barve, Mike Begon, Richard J. Birtles, Theadora A. Block, Barbara A. Block, Janette E. Bradley, Sarah Budischak, Christina Buesching, Sarah J. Burthe, Aaron B. Carlisle, Jennifer E. Caselle, Ciro Cattuto, Alexis S. Chaine, Taylor K. Chapple, Barbara J. Cheney, Timothy Clutton-Brock, Melissa Collier, David J. Curnick, Richard J. Delahay, Damien R. Farine, Andy Fenton, Francesco Ferretti, Laura Feyrer, Helen Fielding, Vivienne Foroughirad, Celine Frere, Michael G. Gardner, Eli Geffen, Stephanie S. Godfrey, Andrea L. Graham, Phil S. Hammond, Maik Henrich, Marco Heurich, Paul Hopwood, Amiyaal Ilany, Joseph A. Jackson, Nicola Jackson, David M. P. Jacoby, Ann-Marie Jacoby, Miloš Ježek, Lucinda Kirkpatrick, Alisa Klamm, James A. Klarevas-Irby, Sarah Knowles, Lee Koren, Ewa Krzyszczyk, Jillian M. Kusch, Xavier Lambin, Jeffrey E. Lane, Herwig Leirs, Stephan T. Leu, Bruce E. Lyon, David W. Macdonald, Anastasia E. Madsen, Janet Mann, Marta Manser, Joachim Mariën, Apia Massawe, Robbie A. McDonald, Kevin Morelle, Johann Mourier, Chris Newman, Kenneth Nussear, Brendah Nyaguthii, Mina Ogino, Laura Ozella, Craig Packer, Yannis P. Papastamatiou, Steve Paterson, Eric Payne, Amy B. Pedersen, Josephine M. Pemberton, Noa Pinter-Wollman, Serge Planes, Aura Raulo, Rolando Rodríguez-Muñoz, Lauren Rudd, Christopher Sabuni, Pratha Sah, Robert J. Schallert, Ben C. Sheldon, Daizaburo Shizuka, Andrew Sih, David L. Sinn, Vincent Sluydts, Orr Spiegel, Sandra Telfer, Courtney A. Thomason, David M. Tickler, Tom Tregenza, Kimberley VanderWaal, Sam Walmsley, Eric L. Walters, Klara M. Wanelik, Hal Whitehead, Elodie Wielgus, Jared Wilson-Aggarwal, Caroline Wohlfeil, Shweta Bansal

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Abstract

Theory predicts that high population density leads to more strongly connected spatial and social networks, but how local density drives individuals’ positions within their networks is unclear. This gap reduces our ability to understand and predict density-dependent processes. Here we show that density drives greater network connectedness at the scale of individuals within wild animal populations. Across 36 datasets of spatial and social behaviour in >58,000 individual animals, spanning 30 species of fish, reptiles, birds, mammals and insects, 80% of systems exhibit strong positive relationships between local density and network centrality. However, >80% of relationships are nonlinear and 75% are shallower at higher values, indicating saturating trends that probably emerge as a result of demographic and behavioural processes that counteract density’s effects. These are stronger and less saturating in spatial compared with social networks, as individuals become disproportionately spatially connected rather than socially connected at higher densities. Consequently, ecological processes that depend on spatial connections are probably more density dependent than those involving social interactions. These findings suggest fundamental scaling rules governing animal social dynamics, which could help to predict network structures in novel systems.

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野生动物系统内部和之间的密度依赖网络结构

理论预测，高人口密度会导致更紧密的空间和社会网络联系，但地方密度如何驱动个人在其网络中的位置尚不清楚。这种差距降低了我们理解和预测依赖于密度的过程的能力。在这里，我们展示了密度在野生动物种群个体的规模上推动了更大的网络连接。在36个空间和社会行为数据集中，58000个个体动物，涵盖30种鱼类、爬行动物、鸟类、哺乳动物和昆虫，80%的系统在局部密度和网络中心性之间表现出强烈的正相关关系。然而，80%的关系是非线性的，75%的关系在较高值时较浅，这表明饱和趋势可能是抵消密度影响的人口和行为过程的结果。与社会网络相比，这些网络在空间上更强大，饱和度更低，因为个体在空间上的联系比在高密度下的社会联系更大。因此，依赖于空间联系的生态过程可能比那些涉及社会互动的生态过程更依赖于密度。这些发现表明了控制动物社会动态的基本尺度规则，这有助于预测新系统中的网络结构。

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来源期刊

Nature ecology & evolution Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics

CiteScore

22.20

自引率

2.40%

发文量

282

期刊介绍： Nature Ecology & Evolution is interested in the full spectrum of ecological and evolutionary biology, encompassing approaches at the molecular, organismal, population, community and ecosystem levels, as well as relevant parts of the social sciences. Nature Ecology & Evolution provides a place where all researchers and policymakers interested in all aspects of life's diversity can come together to learn about the most accomplished and significant advances in the field and to discuss topical issues. An online-only monthly journal, our broad scope ensures that the research published reaches the widest possible audience of scientists.