Periodic Reporting for period 4 - TERRA (375 Million Years of the Diversification of Life on Land: Shifting the Paradigm?)
Période du rapport: 2020-01-01 au 2020-06-30
- Contribution of a significant volume of new data, and improvement of existing data, on the stratigraphic and geographic distribution and taxonomy of terrestrial tetrapods within the Paleobiology Database.
- Compilation and analysis of datasets on fossil record completeness through time for major vertebrate groups. Data were collected for 12 major tetrapod groups. Analyses have demonstrated different patterns of fossil record completeness between marine and terrestrial realms, between different body size and taphonomic classes, and across major extinction events (e.g. Brown et al. 2019, Palaeontology; Cashmore et al. 2019, 2020, Palaeontology). We generated new methods for assessing taxonomic 'diagnosability' of preserved fossil remains - i.e. how useful taxonomic and phylogenetic information is distributed through the vertebrate skeleton (Cashmore 2019, PhD thesis).
- Development of improved methods for estimating diversity change in deep time. Our results clearly demonstrate that diversity estimators that interpolate based on coverage of the underlying species-abundance distribution are the best methods available for estimating relative changes in diversity through time (Close et al. 2018, Methods in Ecology & Evolution). Based on these insights, we developed a new approach that allows fossil diversity to be estimated while holding the geographic spread of sampled localities constant (Close et al. 2017, Nature Communications; Close et al. 2020, Proceedings of the Royal Society B; Close et al. 2020, Science).
- Analyses of local and regional scale richness of tetrapod communities do not support the paradigm of exponential or unconstrained diversification on land (Close et al. 2017, Nature Communications; Close et al. 2019, Nature Ecology & Evolution; Close et al. 2020, Proceedings of the Royal Society B). Instead, diversity appears to be strongly constrained, implying biotic controls such as competition for resources are important in limiting diversification. Similar results for the marine realm are obtained when classic data for marine animals are re-analysed (Close et al. 2020, Science), suggesting similar processes operating on land and in the sea. The Cretaceous-Paleogene mass extinction played a dramatic role in structuring the evolution of diversity, with diversity on land and in the sea reaching a new higher equilibrium in the aftermath of the extinction. This suggests that mass extinctions play a key role in restructuring ecosystems and resetting limits to diversification (Close et al. 2019, Nature Ecology & Evolution; Close et al. 2020, Proceedings of the Royal Society B; Close et al. 2020, Science).
- Results suggest large-scale environmental changes play an important role in driving long-term patterns of diversity change for individual groups. For example, the 'Carboniferous Rainforest Collapse', driven by climate changes, appears to have led to reduced diversity but more cosmopolitan faunas in its aftermath (Dunne et al. 2018, Proceedings of the Royal Society B). Climate change was also a key driver of the evolution of pseudosuchian archosaurs (Mannion et al. 2015, Nature Communications) and early dinosaurs (Dunne 2019, PhD thesis; Dunne et al. in press).
- The large increase in terrestrial tetrapod diversity following the Cretaceous-Paleogene mass extinction results from the diversification of mammals (Close et al. 2019, Nature Ecology & Evolution; Close et al. 2020, Proceedings of the Royal Society B). Critically, however, diversity increased across all body size classes, suggesting an ability of eutherian mammals to more finely partition ecological space than their Mesozoic predecessors (Benevento et al. in review).