Oxygen, temperature and the deep-marine stenothermal cradle of Ediacaran evolution
Oxygen, temperature and the deep-marine stenothermal cradle of Ediacaran evolution
Ediacaran fossils document the early evolution of complex megascopic life, contemporaneous with geochemical evidence for widespread marine anoxia. These data suggest early animals experienced frequent hypoxia. Research has thus focused on the concentration of molecular oxygen (O2) required by early animals, while also considering the impacts of climate. One model, the Cold Cradle hypothesis, proposed the Ediacaran biota originated in cold, shallow-water environments owing to increased O2 solubility. First, we demonstrate using principles of gas exchange that temperature does have a critical role in governing the bioavailability of O2—but in cooler water the supply of O2 is actually lower. Second, the fossil record suggests the Ediacara biota initially occur approximately 571 Ma in deep-water facies, before appearing in shelf environments approximately 555 Ma. We propose an ecophysiological underpinning for this pattern. By combining oceanographic data with new respirometry experiments we show that in the shallow mixed layer where seasonal temperatures fluctuate widely, thermal and partial pressure (pO2) effects are highly synergistic. The result is that temperature change away from species-specific optima impairs tolerance to low pO2. We hypothesize that deep and particularly stenothermal (narrow temperature range) environments in the Ediacaran ocean were a physiological refuge from the synergistic effects of temperature and low pO2.
Boag, Thomas H.
651eb670-969f-4a16-9f27-e7a7197ed851
Stockey, Richard G.
005ca449-f5c9-4049-835f-0a9c6df3a93d
Elder, Leanne E.
98ac4665-b68a-4fc0-896b-6fd2beca8f40
Hull, Pincelli M.
56b9ec5b-7112-453b-92fd-b4b84cfcc326
Sperling, Erik A.
0c67e5ac-bf08-438f-8bb1-55f8f0522a7f
19 December 2018
Boag, Thomas H.
651eb670-969f-4a16-9f27-e7a7197ed851
Stockey, Richard G.
005ca449-f5c9-4049-835f-0a9c6df3a93d
Elder, Leanne E.
98ac4665-b68a-4fc0-896b-6fd2beca8f40
Hull, Pincelli M.
56b9ec5b-7112-453b-92fd-b4b84cfcc326
Sperling, Erik A.
0c67e5ac-bf08-438f-8bb1-55f8f0522a7f
Boag, Thomas H., Stockey, Richard G., Elder, Leanne E., Hull, Pincelli M. and Sperling, Erik A.
(2018)
Oxygen, temperature and the deep-marine stenothermal cradle of Ediacaran evolution.
Proceedings of the Royal Society B: Biological Sciences.
(doi:10.1098/rspb.2018.1724).
Abstract
Ediacaran fossils document the early evolution of complex megascopic life, contemporaneous with geochemical evidence for widespread marine anoxia. These data suggest early animals experienced frequent hypoxia. Research has thus focused on the concentration of molecular oxygen (O2) required by early animals, while also considering the impacts of climate. One model, the Cold Cradle hypothesis, proposed the Ediacaran biota originated in cold, shallow-water environments owing to increased O2 solubility. First, we demonstrate using principles of gas exchange that temperature does have a critical role in governing the bioavailability of O2—but in cooler water the supply of O2 is actually lower. Second, the fossil record suggests the Ediacara biota initially occur approximately 571 Ma in deep-water facies, before appearing in shelf environments approximately 555 Ma. We propose an ecophysiological underpinning for this pattern. By combining oceanographic data with new respirometry experiments we show that in the shallow mixed layer where seasonal temperatures fluctuate widely, thermal and partial pressure (pO2) effects are highly synergistic. The result is that temperature change away from species-specific optima impairs tolerance to low pO2. We hypothesize that deep and particularly stenothermal (narrow temperature range) environments in the Ediacaran ocean were a physiological refuge from the synergistic effects of temperature and low pO2.
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Published date: 19 December 2018
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Local EPrints ID: 474749
URI: http://eprints.soton.ac.uk/id/eprint/474749
ISSN: 0962-8452
PURE UUID: 7a2cdb99-ba67-4467-bbf3-c499179adf4d
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Date deposited: 02 Mar 2023 17:40
Last modified: 17 Mar 2024 04:15
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Author:
Thomas H. Boag
Author:
Richard G. Stockey
Author:
Leanne E. Elder
Author:
Pincelli M. Hull
Author:
Erik A. Sperling
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