Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition

The Ediacara Biota-the oldest communities of complex, macroscopic fossils-consists of three temporally distinct assemblages: the Avalon (ca. 575-560 Ma), White Sea (ca. 560-550 Ma), and Nama (ca. 550-539 Ma). Generic diversity varies among assemblages, with a notable decline at the transition from W...

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Main Authors: Evans, Scott D, Tu, Chenyi, Rizzo, Adriana, Surprenant, Rachel L, Boan, Phillip C, McCandless, Heather, Marshall, Nathan, Xiao, Shuhai, Droser, Mary L
Format: Text
Language:unknown
Published: DigitalCommons@TMC 2022
Subjects:
Animals
Biological Evolution
Fossils
Extinction
Biological
Biota
Oceans and Seas
Bioinformatics
Biomedical Informatics
Medical Sciences
Medical Specialties
Medicine and Health Sciences
Oncology
White Sea
Online Access:https://digitalcommons.library.tmc.edu/uthgsbs_docs/704
https://digitalcommons.library.tmc.edu/context/uthgsbs_docs/article/1690/viewcontent/pnas.202207475_compressed.pdf
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record_format openpolar
spelling fttexasmc:oai:digitalcommons.library.tmc.edu:uthgsbs_docs-1690 2024-09-15T18:40:39+00:00 Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition Evans, Scott D Tu, Chenyi Rizzo, Adriana Surprenant, Rachel L Boan, Phillip C McCandless, Heather Marshall, Nathan Xiao, Shuhai Droser, Mary L 2022-11-16T08:00:00Z application/pdf https://digitalcommons.library.tmc.edu/uthgsbs_docs/704 https://digitalcommons.library.tmc.edu/context/uthgsbs_docs/article/1690/viewcontent/pnas.202207475_compressed.pdf unknown DigitalCommons@TMC https://digitalcommons.library.tmc.edu/uthgsbs_docs/704 https://digitalcommons.library.tmc.edu/context/uthgsbs_docs/article/1690/viewcontent/pnas.202207475_compressed.pdf Journal Articles Animals Biological Evolution Fossils Extinction Biological Biota Oceans and Seas Bioinformatics Biomedical Informatics Medical Sciences Medical Specialties Medicine and Health Sciences Oncology text 2022 fttexasmc 2024-09-03T14:08:01Z The Ediacara Biota-the oldest communities of complex, macroscopic fossils-consists of three temporally distinct assemblages: the Avalon (ca. 575-560 Ma), White Sea (ca. 560-550 Ma), and Nama (ca. 550-539 Ma). Generic diversity varies among assemblages, with a notable decline at the transition from White Sea to Nama. Preservation and sampling biases, biotic replacement, and environmental perturbation have been proposed as potential mechanisms for this drop in diversity. Here, we compile a global database of the Ediacara Biota, specifically targeting taphonomic and paleoecological characters, to test these hypotheses. Major ecological shifts in feeding mode, life habit, and tiering level accompany an increase in generic richness between the Avalon and White Sea assemblages. We find that ∼80% of White Sea taxa are absent from the Nama interval, comparable to loss during Phanerozoic mass extinctions. The paleolatitudes, depositional environments, and preservational modes that characterize the White Sea assemblage are well represented in the Nama, indicating that this decline is not the result of sampling bias. Counter to expectations of the biotic replacement model, there are minimal ecological differences between these two assemblages. However, taxa that disappear exhibit a variety of morphological and behavioral characters consistent with an environmentally driven extinction event. The preferential survival of taxa with high surface area relative to volume may suggest that this was related to reduced global oceanic oxygen availability. Thus, our data support a link between Ediacaran biotic turnover and environmental change, similar to other major mass extinctions in the geologic record. Text White Sea Houston Academy of Medicine-Texas Medical Center (HAM-TMC): DigitalCommons@The Texas Medical Center
institution Open Polar
collection Houston Academy of Medicine-Texas Medical Center (HAM-TMC): DigitalCommons@The Texas Medical Center
op_collection_id fttexasmc
language unknown
topic Animals
Biological Evolution
Fossils
Extinction
Biological
Biota
Oceans and Seas
Bioinformatics
Biomedical Informatics
Medical Sciences
Medical Specialties
Medicine and Health Sciences
Oncology
spellingShingle Animals
Biological Evolution
Fossils
Extinction
Biological
Biota
Oceans and Seas
Bioinformatics
Biomedical Informatics
Medical Sciences
Medical Specialties
Medicine and Health Sciences
Oncology
Evans, Scott D
Tu, Chenyi
Rizzo, Adriana
Surprenant, Rachel L
Boan, Phillip C
McCandless, Heather
Marshall, Nathan
Xiao, Shuhai
Droser, Mary L
Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
topic_facet Animals
Biological Evolution
Fossils
Extinction
Biological
Biota
Oceans and Seas
Bioinformatics
Biomedical Informatics
Medical Sciences
Medical Specialties
Medicine and Health Sciences
Oncology
description The Ediacara Biota-the oldest communities of complex, macroscopic fossils-consists of three temporally distinct assemblages: the Avalon (ca. 575-560 Ma), White Sea (ca. 560-550 Ma), and Nama (ca. 550-539 Ma). Generic diversity varies among assemblages, with a notable decline at the transition from White Sea to Nama. Preservation and sampling biases, biotic replacement, and environmental perturbation have been proposed as potential mechanisms for this drop in diversity. Here, we compile a global database of the Ediacara Biota, specifically targeting taphonomic and paleoecological characters, to test these hypotheses. Major ecological shifts in feeding mode, life habit, and tiering level accompany an increase in generic richness between the Avalon and White Sea assemblages. We find that ∼80% of White Sea taxa are absent from the Nama interval, comparable to loss during Phanerozoic mass extinctions. The paleolatitudes, depositional environments, and preservational modes that characterize the White Sea assemblage are well represented in the Nama, indicating that this decline is not the result of sampling bias. Counter to expectations of the biotic replacement model, there are minimal ecological differences between these two assemblages. However, taxa that disappear exhibit a variety of morphological and behavioral characters consistent with an environmentally driven extinction event. The preferential survival of taxa with high surface area relative to volume may suggest that this was related to reduced global oceanic oxygen availability. Thus, our data support a link between Ediacaran biotic turnover and environmental change, similar to other major mass extinctions in the geologic record.
format Text
author Evans, Scott D
Tu, Chenyi
Rizzo, Adriana
Surprenant, Rachel L
Boan, Phillip C
McCandless, Heather
Marshall, Nathan
Xiao, Shuhai
Droser, Mary L
author_facet Evans, Scott D
Tu, Chenyi
Rizzo, Adriana
Surprenant, Rachel L
Boan, Phillip C
McCandless, Heather
Marshall, Nathan
Xiao, Shuhai
Droser, Mary L
author_sort Evans, Scott D
title Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
title_short Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
title_full Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
title_fullStr Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
title_full_unstemmed Environmental Drivers of the First Major Animal Extinction Across the Ediacaran White Sea-Nama Transition
title_sort environmental drivers of the first major animal extinction across the ediacaran white sea-nama transition
publisher DigitalCommons@TMC
publishDate 2022
url https://digitalcommons.library.tmc.edu/uthgsbs_docs/704
https://digitalcommons.library.tmc.edu/context/uthgsbs_docs/article/1690/viewcontent/pnas.202207475_compressed.pdf
genre White Sea
genre_facet White Sea
op_source Journal Articles
op_relation https://digitalcommons.library.tmc.edu/uthgsbs_docs/704
https://digitalcommons.library.tmc.edu/context/uthgsbs_docs/article/1690/viewcontent/pnas.202207475_compressed.pdf
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