Navigating uncertainty in maximum body size in marine metazoans

Craig R. McClain; Thomas J. Webb; Noel A. Heim; Matthew L. Knope; Pedro M. Monarrez; Jonathan L. Payne

doi:10.1002/ece3.11506

Ecology and Evolution (Jun 2024)

Navigating uncertainty in maximum body size in marine metazoans

Craig R. McClain,
Thomas J. Webb,
Noel A. Heim,
Matthew L. Knope,
Pedro M. Monarrez,
Jonathan L. Payne

Affiliations

Craig R. McClain: Department of Biology University of Louisiana at Lafayette Lafayette Louisiana USA
Thomas J. Webb: Ecology & Evolutionary Biology, School of Biosciences University of Sheffield Sheffield UK
Noel A. Heim: Department of Earth and Climate Sciences Tufts University Medford Massachusetts USA
Matthew L. Knope: Department of Biology University of Hawaiʻi at Hilo Hilo Hawaii USA
Pedro M. Monarrez: Department of Earth and Planetary Sciences Stanford University Stanford California USA
Jonathan L. Payne: Department of Earth and Planetary Sciences Stanford University Stanford California USA

DOI: https://doi.org/10.1002/ece3.11506
Journal volume & issue: Vol. 14, no. 6
pp. n/a – n/a

Abstract

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Abstract Body size is a fundamental biological trait shaping ecological interactions, evolutionary processes, and our understanding of the structure and dynamics of marine communities on a global scale. Accurately defining a species' body size, despite the ease of measurement, poses significant challenges due to varied methodologies, tool usage, and subjectivity among researchers, resulting in multiple, often discrepant size estimates. These discrepancies, stemming from diverse measurement approaches and inherent variability, could substantially impact the reliability and precision of ecological and evolutionary studies reliant on body size data across extensive species datasets. This study examines the variation in reported maximum body sizes across 69,570 individual measurements of maximum size, ranging from 45 m, for 27,271 species of marine metazoans. The research aims to investigate how reported maximum size variations within species relate to organism size, taxonomy, habitat, and the presence of skeletal structures. The investigation particularly focuses on understanding why discrepancies in maximum size estimates arise and their potential implications for broader ecological and evolutionary studies relying on body size data. Variation in reported maximum sizes is zero for 38% of species, and low for most species, although it exceeds two orders of magnitude for some species. The likelihood of zero variation in maximum size decreased with more measurements and increased in larger species, though this varied across phyla and habitats. Pelagic organisms consistently had low maximum size range values, while small species with unspecified habitats had the highest variation. Variations in maximum size within a species were notably smaller than interspecific variation at higher taxonomic levels. Significant variation in maximum size estimates exists within marine species, and partially explained by organism size, taxonomic group, and habitat. Variation in maximum size could be reduced by standardized measurement protocols and improved meta‐data. Despite the variation, egregious errors in published maximum size measurements are rare, and their impact on comparative macroecological and macroevolutionary research is likely minimal.

Published in Ecology and Evolution

ISSN: 2045-7758 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Science: Biology (General): Ecology
Website: https://onlinelibrary.wiley.com/journal/20457758

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Abstract

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