News Release

Diversification in ancient tadpole shrimps challenges the term 'living fossil'

New genetic study of tadpole shrimps (a group which includes Triops) casts doubt on the validity of the term 'living fossil'

Peer-Reviewed Publication

PeerJ

Image of a <i>Triops cancriformis</i>, the European Tadpole Shrimp

image: This is an image of a Triops cancriformis, the European Tadpole Shrimp. view more 

Credit: Africa Gomez, available for full re-use under a CC-BY 3.0 license.

The term 'living fossil' has a controversial history. For decades, scientists have argued about its usefulness as it appears to suggest that some organisms have stopped evolving. New research has now investigated the origin of tadpole shrimps, a group commonly regarded as 'living fossils' which includes the familiar Triops. The research reveals that living species of tadpole shrimp are much younger than the fossils they so much resemble, calling into question the term 'living fossil'.

Darwin informally introduced the term 'living fossil' in On the Origin of Species when talking about the platypus and lungfish, groups that appear to have diversified little and appear not to have changed over millions of years. For him living fossils were odd remnants of formerly more diverse groups, and suggestive of a connection between different extant groups. Ever since, the term has been widely used to describe organisms such as the coelacanth, the horseshoe crab and the ginkgo tree. The term has been controversial, as it appears to suggest that evolution has stopped altogether for these organisms, and some scientists have argued that it should be abandoned.

Tadpole shrimps are a small group of ancient crustaceans (a group which includes the familiar Triops) that are often called 'living fossils', because the living species look virtually identical to fossils older than the dinosaurs. Analysing DNA sequences of all known tadpole shrimps, and using fossils from related crustacean groups – such as the water flea and the brine shrimp – the team of researchers, from the University of Hull, University of Leicester and the Natural History Museum in London, showed that tadpole shrimps have in fact undergone several periods of radiation and extinction. The new study is published today in PeerJ, a new peer reviewed open access journal in which all articles are freely available to everyone (https://PeerJ.com).

Different species of tadpole shrimp often look very similar (they are called 'cryptic species'), and so it is only with the advent of DNA sequencing that scientists have realized that they are a surprisingly diverse group. The team's results uncovered a total of 38 species, many of them still undescribed. This abundance of 'cryptic species' makes it very difficult for fossils to be assigned to any particular species as they all look remarkably similar. For example, 250-million-year-old fossils have been assigned to the living European species Triops cancriformis whereas the team's results indicate that the living T. cancriformis evolved less than 25 million years ago. First author Tom Mathers says "In groups like tadpole shrimps where cryptic speciation is common, the fossil record says very little about patterns of evolution and diversification and so the term 'living fossil' can be quite misleading. For this reason, we used fossils from related groups to gain an understanding about the evolution of tadpole shrimps".

The lead author Africa Gómez said, "Living fossils evolve like any other organism, they just happen to have a good body plan that has survived the test of time. A good analogy could be made with cars. For example the Mini has an old design that is still selling, but newly made Minis have electronic windows, GPS and airbags: in that sense, they are still 'evolving', they are not unchanged but most of the change has been 'under the hood' rather than external. By comparison, organisms labeled as 'living fossils' such as tadpole shrimps, are constantly fine-tuning their adaptation to their environment. Although outwardly they look very similar to tadpole shrimp fossils from the age of the dinosaurs, their DNA and reproductive strategies are relatively hidden features that are constantly evolving. The flexibility of their reproductive strategies, which our research has revealed, could be the evolutionary trick that has allowed them to persist as a morphologically conservative group for so long"

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Background Information

Tadpole shrimps include the familiar Triops - which is often sold as dried eggs in toy shops - that can easily be grown at home. Their fossils can be found from the Carboniferous, 300 million years ago, and the group has survived several mass extinction events. Currently, tadpole shrimps occupy a range of temporal aquatic habitats with different water chemistry conditions, such as hypersaline Australian lakes, rice fields, coastal pools, river floodplains and arctic ponds. Their eggs can survive in a dry state for several decades, only hatching when suitable conditions return.

EMBARGOED until Apr 2nd 2013: 7 am EST; 12 midday UK time

Link to the Published Version of the article (quote this link in your story – the link will ONLY work after the embargo lifts): https://peerj.com/articles/62 - your readers will be able to freely access this article at this URL.

This article is published in PeerJ, a recently launched (on Feb 12th) Open Access Journal. There is a separate Press Release for the PeerJ launch, at: http://bit.ly/PeerJPR02052013

Funding Statement (from the article): "This work was part of TCM's Ph.D., funded by a NERC CASE Studentship NE/G012318/1. AG was supported by a NERC Advanced fellowship NE/B501298/1.The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript."

Handling Academic Editor (conducted the peer review and approved the publication): Keith Crandall, George Washington University.

PeerJ encourages authors to publish the peer reviews, and author rebuttals, for their article. For the purposes of due diligence by the Press, we provide these materials as a PDF at the following link (this link will NOT work after the embargo lifts – after that time the review comments will be accessible via the live article URL noted above): http://bit.ly/MathersPeerJReviews

Citation to the article: Mathers et al. (2013), Multiple global radiations in tadpole shrimps challenge the concept of 'living fossils'. PeerJ 1:e62; DOI 10.7717/peerj.62

About PeerJ

PeerJ is an Open Access publisher of peer reviewed articles, which offers researchers a lifetime membership, for a single low price, giving them the ability to openly publish all future articles for free. The launch of PeerJ occurred on February 12th, 2013. PeerJ is based in San Francisco, CA and London, UK and can be accessed at https://peerj.com/.

All works published in PeerJ are Open Access and published using a Creative Commons license (CC-BY 3.0). Everything is immediately available—to read, download, redistribute, include in databases and otherwise use—without cost to anyone, anywhere, subject only to the condition that the original authors and source are properly attributed.

PeerJ Media Resources (including logos) can be found at: https://peerj.com/about/press/

Media Contacts

For the Authors:

Tom Mather: +44 793 609 7966 (UK timezone) - t.cmathers@2006.hull.ac.uk

For PeerJ: press@peerj.com +1 415 413 4596 (PST) https://peerj.com/about/press/

Abstract (from the article)

'Living fossils', a phrase first coined by Darwin, are defined as species with limited recent diversification and high morphological stasis over long periods of evolutionary time. Morphological stasis, however, can potentially lead to diversification rates being underestimated. Notostraca, or tadpole shrimps, is an ancient, globally distributed order of branchiopod crustaceans regarded as 'living fossils' because their rich fossil record dates back to the early Devonian and their morphology is highly conserved. Recent phylogenetic reconstructions have shown a strong biogeographic signal, suggesting diversification due to continental breakup, and widespread cryptic speciation. However, morphological conservatism makes it difficult to place fossil taxa in a phylogenetic context. Here we reveal for the first time the timing and tempo of tadpole shrimp diversification by inferring a robustmultilocus phylogeny of Branchiopoda and applying Bayesian divergence dating techniques using reliable fossil calibrations external to Notostraca. Our results suggest at least two bouts of global radiation in Notostraca, one of them recent, so questioning the validity of the 'living fossils' concept in groups where cryptic speciation is widespread.


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