Large–scale heterogeneity of the fossil record: implications for Phanerozoic biodiversity studies

Smith, Andrew B.

doi:10.1098/rstb.2000.0768

Cited by 297 publications

(331 citation statements)

References 69 publications

(83 reference statements)

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“…The intervening middle through to the Late Cretaceous is a period of particularly low sampling, both in terms of number of collections and number of occurrences (figure 1). A similar pattern has been documented in the fossil record of continental vertebrates [26,27] and there is still debate as to whether this is attributable to larger global processes, such as marine transgressive and regressive cycles [28,29]. Our occurrence database permits an additional quantitative description of the variation in sampling over time, obtained as the proportion of families that range through an interval (i.e.…”

Section: Results and Discussion (A) Samplingmentioning

confidence: 97%

The fossil record and macroevolutionary history of the beetles

Smith

Marcot

2015

Proc. R. Soc. B.

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Coleoptera (beetles) is the most species-rich metazoan order, with approximately 380 000 species. To understand how they came to be such a diverse group, we compile a database of global fossil beetle occurrences to study their macroevolutionary history. Our database includes 5553 beetle occurrences from 221 fossil localities. Amber and lacustrine deposits preserve most of the beetle diversity and abundance. All four extant suborders are found in the fossil record, with 69% of all beetle families and 63% of extant beetle families preserved. Considerable focus has been placed on beetle diversification overall, however, for much of their evolutionary history it is the clade Polyphaga that is most responsible for their taxonomic richness. Polyphaga had an increase in diversification rate in the Early Cretaceous, but instead of being due to the radiation of the angiosperms, this was probably due to the first occurrences of beetle-bearing amber deposits in the record. Perhaps, most significant is that polyphagan beetles had a family-level extinction rate of zero for most of their evolutionary history, including across the Cretaceous-Palaeogene boundary. Therefore, focusing on the factors that have inhibited beetle extinction, as opposed to solely studying mechanisms that may promote speciation, should be examined as important determinants of their great diversity today.

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Section: Results and Discussion (A) Samplingmentioning

confidence: 97%

The fossil record and macroevolutionary history of the beetles

Smith

Marcot

2015

Proc. R. Soc. B.

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“…This is especially true in the fossil record where patterns of global diversity often reflect patterns of fossiliferous rock availability (Raup 1972;Peters & Foote 2001;Smith 2001;Smith & McGowan 2005). In this study, we use an alternative approach by sampling individual fossil communities (Alroy et al 2001).…”

Section: Methodsmentioning

confidence: 99%

Recovery from the most profound mass extinction of all time

2008

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The end-Permian mass extinction, 251 million years (Myr) ago, was the most devastating ecological event of all time, and it was exacerbated by two earlier events at the beginning and end of the Guadalupian, 270 and 260 Myr ago. Ecosystems were destroyed worldwide, communities were restructured and organisms were left struggling to recover. Disaster taxa, such as Lystrosaurus, insinuated themselves into almost every corner of the sparsely populated landscape in the earliest Triassic, and a quick taxonomic recovery apparently occurred on a global scale. However, close study of ecosystem evolution shows that true ecological recovery was slower. After the end-Guadalupian event, faunas began rebuilding complex trophic structures and refilling guilds, but were hit again by the end-Permian event. Taxonomic diversity at the alpha (community) level did not recover to pre-extinction levels; it reached only a low plateau after each pulse and continued low into the Late Triassic. Our data showed that though there was an initial rise in cosmopolitanism after the extinction pulses, large drops subsequently occurred and, counter-intuitively, a surprisingly low level of cosmopolitanism was sustained through the Early and Middle Triassic.

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“…Studies of marine data sets show close correlation of diversity and map area, interpreted as evidence of a rock volume control on apparent diversity (e.g. Smith 2001Smith , 2007Smith & McGowan 2008), although a study of global map areas of terrestrial sediments found no such control on terrestrial diversity data (Kalmar & Currie 2010).…”

Section: Diversification Of Life On Landmentioning

confidence: 99%

“…For example, Padian & Clemens (1985), Behrensmeyer et al (2000) and Smith (2001) note that the terrestrial fossil record is poorer than the marine because sedimentation is typically more sporadic, many organisms live in habitats such as deserts, forests and mountains where deposition is limited, and terrestrial rocks are harder to date than marine. These are valid points, and yet the important question is not whether the terrestrial fossil record is perfect, or even good, but whether it is adequate for the studies in hand.…”

Section: Diversification Of Life On Landmentioning

confidence: 99%

The origins of modern biodiversity on land

Benton

2010

Phil. Trans. R. Soc. B

139

107

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Comparative studies of large phylogenies of living and extinct groups have shown that most biodiversity arises from a small number of highly species-rich clades. To understand biodiversity, it is important to examine the history of these clades on geological time scales. This is part of a distinct 'phylogenetic expansion' view of macroevolution, and contrasts with the alternative, nonphylogenetic 'equilibrium' approach to the history of biodiversity. The latter viewpoint focuses on density-dependent models in which all life is described by a single global-scale model, and a case is made here that this approach may be less successful at representing the shape of the evolution of life than the phylogenetic expansion approach. The terrestrial fossil record is patchy, but is adequate for coarse-scale studies of groups such as vertebrates that possess fossilizable hard parts. New methods in phylogenetic analysis, morphometrics and the study of exceptional biotas allow new approaches. Models for diversity regulation through time range from the entirely biotic to the entirely physical, with many intermediates. Tetrapod diversity has risen as a result of the expansion of ecospace, rather than niche subdivision or regional-scale endemicity resulting from continental break-up. Tetrapod communities on land have been remarkably stable and have changed only when there was a revolution in floras (such as the demise of the Carboniferous coal forests, or the Cretaceous radiation of angiosperms) or following particularly severe mass extinction events, such as that at the end of the Permian.

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Large–scale heterogeneity of the fossil record: implications for Phanerozoic biodiversity studies

Cited by 297 publications

References 69 publications

The fossil record and macroevolutionary history of the beetles

The fossil record and macroevolutionary history of the beetles

Recovery from the most profound mass extinction of all time

The origins of modern biodiversity on land

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