Early metazoan life: divergence, environment and ecology

Erwin, Douglas H.

doi:10.1098/rstb.2015.0036

Cited by 119 publications

(90 citation statements)

References 60 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Molecular clock estimates indicate an origin for the metazoan crown group at 750 to 800 Ma (Erwin et al ., ; Erwin, ) which, if correct, would indicate that these early animals survived panglaciations, and that the divergence and proliferation of life began well before the Cambrian explosion of diverse skeletonized organisms. However, nearly all geological evidence for these early animals, prior to the Gaskiers glaciation (late Ediacaran) (Figs and ), is disputed.…”

Section: Biotic Responses and Innovationsmentioning

confidence: 97%

Sedimentological perspectives on climatic, atmospheric and environmental change in the Neoproterozoic Era

2016

View full text Add to dashboard Cite

Sedimentological insights underpin many of the important recent advances in understanding of Earth system behaviour in the Neoproterozoic Era. This article reviews three main areas: (i) chemical proxies and their preservation, with emphasis on carbonate facies; (ii) glacial and post-glacial facies, including their age constraints; (iii) sedimentary evidence for biotic innovations and responses. Chemostratigraphy plays an important role in ordering Neoproterozoic events and defining disturbances to the carbon cycle. There is increasing attention being paid to assessing the role of diagenetic origination or modification of chemostratigraphic signals. Alongside this, new criteria for identifying primary dolomite and precursor metastable phases such as ikaite have been developed. In respect of oxygenation, geochemical proxies substantiate the concept of a Neoproterozoic Oxygenation Event as a very gradual transition, the ocean being at any one time a heterogeneous assemblage of ferruginous, sulphidic and oxic conditions, with some evidence of increasing deep-sea oxidation through the Ediacaran Period. Techniques such as Fe-speciation need to be supplemented with proxies sensitive to suboxic conditions. More generally, it is predicted that petrographically constrained microanalytical studies will also become more important in reconstructing palaeoenvironmental conditions. The global distribution of Neoproterozoic glacial deposits combined with palaeomagnetic evidence supports the concept of panglaciations in which ice sheets reached sea-level in the tropics. Advances in radiometric dating have demonstrated the synchronous onset of global (Sturtian) glaciation at 717 Ma and the demise of a second (Marinoan) glaciation at 635 Ma, and plausibly indicate long durations for each (55 Myr for Sturtian and 5 to 15 Myr for Marinoan). However, a compilation of radiometric dates indicates ambiguities indicating the need for further improvements to the radiometric and Sr-isotope database to understand events within the Sturtian time frame, the timing of onset of Marinoan glaciations, and the age and synchroneity of individual negative d 13 C anomalies. Sturtian deposits are typically thick, rift-related successions containing a range of environments influenced or dominated by dynamic glaciers, as well as ice-free marine intervals. Marinoan glacial deposits, by contrast, tend to be thin and continental. During the latter interval, oxygen isotope systematics of sulphate demonstrate that atmospheric CO 2 was high, as predicted by Snowball Earth theory, and that sedimentation was influenced by orbital forcing. The Sturtian record, by comparison, needs to be searched for evidence of cold-climate hiatuses on the one hand and orbital forcing on the other. Cap carbonate formation appears to have coincided with rising sea-levels following panglaciations. Snowball theory considers that they formed rapidly in the postglacial greenhouse, but an alternative (2016) 63, 253-306 doi: 10.1111/sed.12261 STATE OF THE SCIENCE model o...

show abstract

Section: Biotic Responses and Innovationsmentioning

confidence: 97%

Sedimentological perspectives on climatic, atmospheric and environmental change in the Neoproterozoic Era

2016

View full text Add to dashboard Cite

show abstract

“…Molecular clock data suggest that the origin of metazoans predates the late Ediacaran period, with many major clades radiating during the Cryogenian and early Ediacaran (dos Reis et al 2015;Erwin 2015). There is no convincing direct evidence for triploblastic features and complex internal organs among the Ediacaran macrofossils and a simple diploblastic bauplan consisting of multiple modules along a polarized body axis is typically invoked for these organisms Budd & Jensen 2015), with the possible exception of the latest Ediacaran mollusc-like Kimberella (e.g.…”

mentioning

confidence: 99%

Ediacaran pre-placozoan diploblasts in the Avalonian biota: the role of chemosynthesis in the evolution of early animal life

Dufour

McIlroy

2016

View full text Add to dashboard Cite

The large, enigmatic members of the Ediacaran biota have received much attention regarding their possible affinities and mode of life. Fossil evidence reveals that many Ediacaran animals, such as the rangeomorphs, were characterized by extensive surface areas, lived in close association with the seafloor and were non-motile. We argue for the presence of a simple, diploblastic body plan in these early animals and discuss the means by which they probably derived nutrients from chemosynthetic bacteria thriving at the sediment-water interface. We consider that the large surface area of some Ediacaran organisms in the Avalonian biota may have been an adaptation for maximizing a phagocytotic or chemosymbiotic surface. Ediacaran animals probably increased the availability of oxygen along their ventral surface either by diffusion or ciliary pumping. This increased supply of oxygen to the sediment is inferred to have simultaneously increased the productivity of their food source (chemosynthetic bacteria) and restricted the build-up of toxic sulphides in the pore waters below their bodies. This is an example of a very simple form of ecosystem engineering.Gold Open Access: This article is published under the terms of the CC-BY 3.0 license.

show abstract

“…Sedimentary biomarker hydrocarbons derived from algae and demosponges provide further evidence for the presence of a productive biosphere during the Cryogenian Epoch (Grosjean, Love, Stalvies, Fike, & Summons, ; Love et al., ). Molecular clock data suggest that animal phyla, and specifically sponges, appeared in the time window just prior to the Snowball Earth Epoch (Dohrmann & Wörheide, ; Erwin, ) and well before the Doushantuo embryos which comprise the earliest body fossil evidence for metazoans, dated to about 600 Ma, and which precede the earliest documented Ediacaran biota of ~571 Ma (Erwin, ; Pu et al., ). If so, there must have been refugia capable of supporting complex ecosystems during Cryogenian times.…”

Section: Introductionmentioning

confidence: 99%

“…If sufficient in areal extent, cryoconite pans could then have played a significant role in the Cryogenian carbon cycle (Hoffman, ; Hoffman et al., ). Cryoconite pans, ice‐covered lakes, and other meltwater environments may have been habitats where early metazoa thrived (Christner, Kvitko, & Reeve, ) and evolved, potentially accounting for the absence of any apparent eukaryotic bottleneck during the Cryogenian Period (Erwin, ; Erwin et al., ). For a contrary view, see Cohen and Macdonald ().…”

Section: Introductionmentioning

confidence: 99%

The “Dirty Ice” of the McMurdo Ice Shelf: Analogues for biological oases during the Cryogenian

et al. 2018

View full text Add to dashboard Cite

The Cryogenian (~717-636 Ma) is characterized by widespread glaciation and dramatic fluctuations in biogeochemical cycling during the Sturtian and Marinoan glaciations. The Snowball Earth hypothesis posits that during this period, ice-covered oceans of more or less global extent shut down or greatly diminished photosynthesis in the marine realm. However, rather than suffering a catastrophic loss of biodiversity, fossil evidence suggests that major eukaryotic lineages survived and, indeed, the end of the Cryogenian marks the onset of a rapid diversification of eukaryotic life. Persistence of diverse life forms through glaciations is thought to have occurred in supraglacial refugia although the exact nature and full extent of such habitats remain uncertain. We present further evidence for the diversity and characteristics of supraglacial ecosystems on the McMurdo Ice Shelf in Antarctica and suggest that refugia analogous to "dirty ice," that is debris-covered ice shelf ecosystems, potentially provided nutrient-rich and long-lasting biological Cryogenian oases. We also discuss how features of the McMurdo Ice Shelf indicate that mechanisms exist whereby material can be exchanged between the shallow sea floor and the surfaces of ice shelves along continental margins, providing vectors whereby ice shelf ecosystems can nourish underlying seafloor communities and vice versa.

show abstract

Early metazoan life: divergence, environment and ecology

Cited by 119 publications

References 60 publications

Sedimentological perspectives on climatic, atmospheric and environmental change in the Neoproterozoic Era

Sedimentological perspectives on climatic, atmospheric and environmental change in the Neoproterozoic Era

Ediacaran pre-placozoan diploblasts in the Avalonian biota: the role of chemosynthesis in the evolution of early animal life

The “Dirty Ice” of the McMurdo Ice Shelf: Analogues for biological oases during the Cryogenian

Contact Info

Product

Resources

About