Marine extinction risk shaped by trait-environment interactions over 500 million years

Perhaps the most pressing issue in predicting biotic responses to present and future global change is understanding how environmental factors shape the relationship between ecological traits and extinction risk. The fossil record provides millions of years of insight into how extinction selectivity...

Full description

Bibliographic Details
Published in:	Global Change Biology
Main Authors:	Orzechowski, Emily A, Lockwood, Rowan, Byrnes, Jarrett E.K, Anderson, Sean C, Finnegan, Seth, Finkel, Zoe V, Harnik, Paul G, Lindberg, David R, Liow, Lee Hsiang, Lotze, Heike K, Mcclain, Craig R, Mcguire, Jenny L, O'Dea, Aaron, Pandolfi, John M, Simpson, Carl, Tittensor, Derek P
Format:	Article in Journal/Newspaper
Language:	English
Published:	Wiley-Blackwell Publishing 2015
Subjects:	Differential extinction risk Extinction selectivity Geographic range Life habit Mass extinction Mollusk Survivorship 2300 Environmental Science 2303 Ecology 2304 Environmental Chemistry 2306 Global and Planetary Change Ocean acidification
Online Access:	https://espace.library.uq.edu.au/view/UQ:365583

id	ftunivqespace:oai:espace.library.uq.edu.au:UQ:365583
record_format	openpolar
spelling	ftunivqespace:oai:espace.library.uq.edu.au:UQ:365583 2023-05-15T17:51:48+02:00 Marine extinction risk shaped by trait-environment interactions over 500 million years Orzechowski, Emily A Lockwood, Rowan Byrnes, Jarrett E.K Anderson, Sean C Finnegan, Seth Finkel, Zoe V Harnik, Paul G Lindberg, David R Liow, Lee Hsiang Lotze, Heike K Mcclain, Craig R Mcguire, Jenny L O'Dea, Aaron Pandolfi, John M Simpson, Carl Tittensor, Derek P 2015-01-01 https://espace.library.uq.edu.au/view/UQ:365583 eng eng Wiley-Blackwell Publishing doi:10.1111/gcb.12963 issn:1365-2486 issn:1354-1013 orcid:0000-0003-3047-6694 EF-0905606 Not set DP 130100250 2015-R/RCM-39 KI 806/7-1 1325683 1325379 Differential extinction risk Extinction selectivity Geographic range Life habit Mass extinction Mollusk Survivorship 2300 Environmental Science 2303 Ecology 2304 Environmental Chemistry 2306 Global and Planetary Change Journal Article 2015 ftunivqespace https://doi.org/10.1111/gcb.12963 2020-12-08T00:10:51Z Perhaps the most pressing issue in predicting biotic responses to present and future global change is understanding how environmental factors shape the relationship between ecological traits and extinction risk. The fossil record provides millions of years of insight into how extinction selectivity (i.e., differential extinction risk) is shaped by interactions between ecological traits and environmental conditions. Numerous paleontological studies have examined trait-based extinction selectivity; however, the extent to which these patterns are shaped by environmental conditions is poorly understood due to a lack of quantitative synthesis across studies. We conducted a meta-analysis of published studies on fossil marine bivalves and gastropods that span 458 million years to uncover how global environmental and geochemical changes covary with trait-based extinction selectivity. We focused on geographic range size and life habit (i.e., infaunal vs. epifaunal), two of the most important and commonly examined predictors of extinction selectivity. We used geochemical proxies related to global climate, as well as indicators of ocean acidification, to infer average global environmental conditions. Life-habit selectivity is weakly dependent on environmental conditions, with infaunal species relatively buffered from extinction during warmer climate states. In contrast, the odds of taxa with broad geographic ranges surviving an extinction (>2500 km for genera, >500 km for species) are on average three times greater than narrow-ranging taxa (estimate of odds ratio: 2.8, 95% confidence interval = 2.3–3.5), regardless of the prevailing global environmental conditions. The environmental independence of geographic range size extinction selectivity emphasizes the critical role of geographic range size in setting conservation priorities. Article in Journal/Newspaper Ocean acidification The University of Queensland: UQ eSpace Global Change Biology 21 10 3595 3607
institution	Open Polar
collection	The University of Queensland: UQ eSpace
op_collection_id	ftunivqespace
language	English
topic	Differential extinction risk Extinction selectivity Geographic range Life habit Mass extinction Mollusk Survivorship 2300 Environmental Science 2303 Ecology 2304 Environmental Chemistry 2306 Global and Planetary Change
spellingShingle	Differential extinction risk Extinction selectivity Geographic range Life habit Mass extinction Mollusk Survivorship 2300 Environmental Science 2303 Ecology 2304 Environmental Chemistry 2306 Global and Planetary Change Orzechowski, Emily A Lockwood, Rowan Byrnes, Jarrett E.K Anderson, Sean C Finnegan, Seth Finkel, Zoe V Harnik, Paul G Lindberg, David R Liow, Lee Hsiang Lotze, Heike K Mcclain, Craig R Mcguire, Jenny L O'Dea, Aaron Pandolfi, John M Simpson, Carl Tittensor, Derek P Marine extinction risk shaped by trait-environment interactions over 500 million years
topic_facet	Differential extinction risk Extinction selectivity Geographic range Life habit Mass extinction Mollusk Survivorship 2300 Environmental Science 2303 Ecology 2304 Environmental Chemistry 2306 Global and Planetary Change
description	Perhaps the most pressing issue in predicting biotic responses to present and future global change is understanding how environmental factors shape the relationship between ecological traits and extinction risk. The fossil record provides millions of years of insight into how extinction selectivity (i.e., differential extinction risk) is shaped by interactions between ecological traits and environmental conditions. Numerous paleontological studies have examined trait-based extinction selectivity; however, the extent to which these patterns are shaped by environmental conditions is poorly understood due to a lack of quantitative synthesis across studies. We conducted a meta-analysis of published studies on fossil marine bivalves and gastropods that span 458 million years to uncover how global environmental and geochemical changes covary with trait-based extinction selectivity. We focused on geographic range size and life habit (i.e., infaunal vs. epifaunal), two of the most important and commonly examined predictors of extinction selectivity. We used geochemical proxies related to global climate, as well as indicators of ocean acidification, to infer average global environmental conditions. Life-habit selectivity is weakly dependent on environmental conditions, with infaunal species relatively buffered from extinction during warmer climate states. In contrast, the odds of taxa with broad geographic ranges surviving an extinction (>2500 km for genera, >500 km for species) are on average three times greater than narrow-ranging taxa (estimate of odds ratio: 2.8, 95% confidence interval = 2.3–3.5), regardless of the prevailing global environmental conditions. The environmental independence of geographic range size extinction selectivity emphasizes the critical role of geographic range size in setting conservation priorities.
format	Article in Journal/Newspaper
author	Orzechowski, Emily A Lockwood, Rowan Byrnes, Jarrett E.K Anderson, Sean C Finnegan, Seth Finkel, Zoe V Harnik, Paul G Lindberg, David R Liow, Lee Hsiang Lotze, Heike K Mcclain, Craig R Mcguire, Jenny L O'Dea, Aaron Pandolfi, John M Simpson, Carl Tittensor, Derek P
author_facet	Orzechowski, Emily A Lockwood, Rowan Byrnes, Jarrett E.K Anderson, Sean C Finnegan, Seth Finkel, Zoe V Harnik, Paul G Lindberg, David R Liow, Lee Hsiang Lotze, Heike K Mcclain, Craig R Mcguire, Jenny L O'Dea, Aaron Pandolfi, John M Simpson, Carl Tittensor, Derek P
author_sort	Orzechowski, Emily A
title	Marine extinction risk shaped by trait-environment interactions over 500 million years
title_short	Marine extinction risk shaped by trait-environment interactions over 500 million years
title_full	Marine extinction risk shaped by trait-environment interactions over 500 million years
title_fullStr	Marine extinction risk shaped by trait-environment interactions over 500 million years
title_full_unstemmed	Marine extinction risk shaped by trait-environment interactions over 500 million years
title_sort	marine extinction risk shaped by trait-environment interactions over 500 million years
publisher	Wiley-Blackwell Publishing
publishDate	2015
url	https://espace.library.uq.edu.au/view/UQ:365583
genre	Ocean acidification
genre_facet	Ocean acidification
op_relation	doi:10.1111/gcb.12963 issn:1365-2486 issn:1354-1013 orcid:0000-0003-3047-6694 EF-0905606 Not set DP 130100250 2015-R/RCM-39 KI 806/7-1 1325683 1325379
op_doi	https://doi.org/10.1111/gcb.12963
container_title	Global Change Biology
container_volume	21
container_issue	10
container_start_page	3595
op_container_end_page	3607
_version_	1766159065033998336

Marine extinction risk shaped by trait-environment interactions over 500 million years

Similar Items