Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv

Dead species remain dead. The diversity record of life is littered with examples of declines and radiations, yet no species has ever re-evolved following its true extinction. In contrast, functional traits can transcend diversity declines, often develop iteratively and are taxon-free allowing applic...

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Main Authors: Lorna E. Kearns (11080326), Steven M. Bohaty (2841293), K. M. Edgar (11080329), Sandra Nogué (8541123), Thomas H. G. Ezard (5483597)
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Online Access:https://doi.org/10.3389/fevo.2021.679722.s005
id ftsmithonian:oai:figshare.com:article/14914026
record_format openpolar
spelling ftsmithonian:oai:figshare.com:article/14914026 2023-05-15T18:00:30+02:00 Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv Lorna E. Kearns (11080326) Steven M. Bohaty (2841293) K. M. Edgar (11080329) Sandra Nogué (8541123) Thomas H. G. Ezard (5483597) 2021-07-06T04:22:48Z https://doi.org/10.3389/fevo.2021.679722.s005 unknown https://figshare.com/articles/dataset/Table_4_Searching_for_Function_Reconstructing_Adaptive_Niche_Changes_Using_Geochemical_and_Morphological_Data_in_Planktonic_Foraminifera_csv/14914026 doi:10.3389/fevo.2021.679722.s005 CC BY 4.0 CC-BY Evolutionary Biology Ecology Invasive Species Ecology Landscape Ecology Conservation and Biodiversity Behavioural Ecology Community Ecology (excl. Invasive Species Ecology) Ecological Physiology Freshwater Ecology Marine and Estuarine Ecology (incl. Marine Ichthyology) Population Ecology Terrestrial Ecology functional trait ecological niches paleoclimate paleoecology planktonic foraminifera Dataset 2021 ftsmithonian https://doi.org/10.3389/fevo.2021.679722.s005 2021-07-25T17:52:15Z Dead species remain dead. The diversity record of life is littered with examples of declines and radiations, yet no species has ever re-evolved following its true extinction. In contrast, functional traits can transcend diversity declines, often develop iteratively and are taxon-free allowing application across taxa, environments and time. Planktonic foraminifera have an unrivaled, near continuous fossil record for the past 200 million years making them a perfect test organism to understand trait changes through time, but the functional role of morphology in determining habitat occupation has been questioned. Here, we use single specimen stable isotopes to reconstruct the water depth habitat of individual planktonic foraminifera in the genus Subbotina alongside morphological measurements of the tests to understand trait changes through the Middle Eocene Climatic Optimum [MECO: ∼40 Myr ago (mega annum, Ma)]. The MECO is a geologically transient global warming interval that marks the beginning of widespread biotic reorganizations in marine organisms spanning a size spectrum from diatoms to whales. In contrast to other planktonic foraminiferal genera, the subbotinids flourished through this interval despite multiple climatic perturbations superimposed on a changing background climate. Through coupled trait and geochemical analysis, we show that Subbotina survival through this climatically dynamic interval was aided by trait plasticity and a wider ecological niche than previously thought for a subthermocline dwelling genus supporting a generalist life strategy. We also show how individually resolved oxygen isotopes can track shifts in depth occupancy through climatic upheaval. During and following the MECO, temperature changes were substantial in the thermocline and subthermocline in comparison to the muted responses of the surface ocean. In our post-MECO samples, we observe restoration of planktonic foraminifera depth stratification. Despite these changing temperatures and occupied depths, we do not detect a contemporaneous morphological response implying that readily available traits such as test size and shape do not have a clear functional role in this generalist genus. Modern imaging measurement technologies offer a promising route to gather more informative morphological traits for functional analysis, rather than the traditional candidates that are most easily measured. Dataset Planktonic foraminifera Unknown
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Evolutionary Biology
Ecology
Invasive Species Ecology
Landscape Ecology
Conservation and Biodiversity
Behavioural Ecology
Community Ecology (excl. Invasive Species Ecology)
Ecological Physiology
Freshwater Ecology
Marine and Estuarine Ecology (incl. Marine Ichthyology)
Population Ecology
Terrestrial Ecology
functional trait
ecological niches
paleoclimate
paleoecology
planktonic foraminifera
spellingShingle Evolutionary Biology
Ecology
Invasive Species Ecology
Landscape Ecology
Conservation and Biodiversity
Behavioural Ecology
Community Ecology (excl. Invasive Species Ecology)
Ecological Physiology
Freshwater Ecology
Marine and Estuarine Ecology (incl. Marine Ichthyology)
Population Ecology
Terrestrial Ecology
functional trait
ecological niches
paleoclimate
paleoecology
planktonic foraminifera
Lorna E. Kearns (11080326)
Steven M. Bohaty (2841293)
K. M. Edgar (11080329)
Sandra Nogué (8541123)
Thomas H. G. Ezard (5483597)
Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
topic_facet Evolutionary Biology
Ecology
Invasive Species Ecology
Landscape Ecology
Conservation and Biodiversity
Behavioural Ecology
Community Ecology (excl. Invasive Species Ecology)
Ecological Physiology
Freshwater Ecology
Marine and Estuarine Ecology (incl. Marine Ichthyology)
Population Ecology
Terrestrial Ecology
functional trait
ecological niches
paleoclimate
paleoecology
planktonic foraminifera
description Dead species remain dead. The diversity record of life is littered with examples of declines and radiations, yet no species has ever re-evolved following its true extinction. In contrast, functional traits can transcend diversity declines, often develop iteratively and are taxon-free allowing application across taxa, environments and time. Planktonic foraminifera have an unrivaled, near continuous fossil record for the past 200 million years making them a perfect test organism to understand trait changes through time, but the functional role of morphology in determining habitat occupation has been questioned. Here, we use single specimen stable isotopes to reconstruct the water depth habitat of individual planktonic foraminifera in the genus Subbotina alongside morphological measurements of the tests to understand trait changes through the Middle Eocene Climatic Optimum [MECO: ∼40 Myr ago (mega annum, Ma)]. The MECO is a geologically transient global warming interval that marks the beginning of widespread biotic reorganizations in marine organisms spanning a size spectrum from diatoms to whales. In contrast to other planktonic foraminiferal genera, the subbotinids flourished through this interval despite multiple climatic perturbations superimposed on a changing background climate. Through coupled trait and geochemical analysis, we show that Subbotina survival through this climatically dynamic interval was aided by trait plasticity and a wider ecological niche than previously thought for a subthermocline dwelling genus supporting a generalist life strategy. We also show how individually resolved oxygen isotopes can track shifts in depth occupancy through climatic upheaval. During and following the MECO, temperature changes were substantial in the thermocline and subthermocline in comparison to the muted responses of the surface ocean. In our post-MECO samples, we observe restoration of planktonic foraminifera depth stratification. Despite these changing temperatures and occupied depths, we do not detect a contemporaneous morphological response implying that readily available traits such as test size and shape do not have a clear functional role in this generalist genus. Modern imaging measurement technologies offer a promising route to gather more informative morphological traits for functional analysis, rather than the traditional candidates that are most easily measured.
format Dataset
author Lorna E. Kearns (11080326)
Steven M. Bohaty (2841293)
K. M. Edgar (11080329)
Sandra Nogué (8541123)
Thomas H. G. Ezard (5483597)
author_facet Lorna E. Kearns (11080326)
Steven M. Bohaty (2841293)
K. M. Edgar (11080329)
Sandra Nogué (8541123)
Thomas H. G. Ezard (5483597)
author_sort Lorna E. Kearns (11080326)
title Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
title_short Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
title_full Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
title_fullStr Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
title_full_unstemmed Table_4_Searching for Function: Reconstructing Adaptive Niche Changes Using Geochemical and Morphological Data in Planktonic Foraminifera.csv
title_sort table_4_searching for function: reconstructing adaptive niche changes using geochemical and morphological data in planktonic foraminifera.csv
publishDate 2021
url https://doi.org/10.3389/fevo.2021.679722.s005
genre Planktonic foraminifera
genre_facet Planktonic foraminifera
op_relation https://figshare.com/articles/dataset/Table_4_Searching_for_Function_Reconstructing_Adaptive_Niche_Changes_Using_Geochemical_and_Morphological_Data_in_Planktonic_Foraminifera_csv/14914026
doi:10.3389/fevo.2021.679722.s005
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fevo.2021.679722.s005
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