Your search keyword '"Donoghue, Philip C. J."' showing total 17 results

1. Evolution of metazoan morphological disparity

Author

Deline, Bradley, Greenwood, Jennifer M., Clark, James W., Puttick, Mark N., Peterson, Kevin J., and Donoghue, Philip C. J.

Published

2018

2. The Efficacy of Consensus Tree Methods for Summarizing Phylogenetic Relationships from a Posterior Sample of Trees Estimated from Morphological Data

Author

O’Reilly, Joseph E. and Donoghue, Philip C. J.

Published

2018

3. Fossilization can mislead analyses of phenotypic disparity.

Author

Smith, Thomas J., Sansom, Robert S., Pisani, Davide, and Donoghue, Philip C. J.

Subjects

PHENOTYPES, PHENOTYPIC plasticity, FOSSILIZATION, FOSSILS, TAPHONOMY, EXTRAPOLATION

Abstract

Analyses of morphological disparity can incorporate living and fossil taxa to facilitate the exploration of how phenotypic variation changes through time. However, taphonomic processes introduce non-random patterns of data loss in fossil data and their impact on perceptions of disparity is unclear. To address this, we characterize how measures of disparity change when simulated and empirical data are degraded through random and structured data loss. We demonstrate that both types of data loss can distort the disparity of clades, and that the magnitude and direction of these changes varies between the most commonly employed distance metrics and disparity indices. The inclusion of extant taxa and exceptionally preserved fossils mitigates these distortions and clarifies the full extent of the data lost, most of which would otherwise go uncharacterized. This facilitates the use of ancestral state estimation and evolutionary simulations to further control for the effects of data loss. Where the addition of such reference taxa is not possible, we urge caution in the extrapolation of general patterns in disparity from datasets that characterize subsets of phenotype, which may represent no more than the traits that they sample. [ABSTRACT FROM AUTHOR]

Published

2023

4. Postcranial disparity of galeaspids and the evolution of swimming speeds in stem-gnathostomes.

Author

Gai, Zhikun, Lin, Xianghong, Shan, Xianren, Ferrón, Humberto G, and Donoghue, Philip C J

Subjects

SPEED, ANATOMY, SWIMMING competitions, SWIMMERS, SWIMMING, MORPHOLOGY, VERTEBRATES

Abstract

Galeaspids are extinct jawless relatives of living jawed vertebrates whose contribution to understanding the evolutionary assembly of the gnathostome bodyplan has been limited by absence of postcranial remains. Here, we describe Foxaspis novemura gen. et sp. nov., based on complete articulated remains from a newly discovered Konservat-Lagerstätte in the Early Devonian (Pragian, ∼410 Ma) of Guangxi, South China. F. novemura had a broad, circular dorso-ventrally compressed headshield, slender trunk and strongly asymmetrical hypochordal tail fin comprised of nine ray-like scale-covered digitations. This tail morphology contrasts with the symmetrical hypochordal tail fin of Tujiaaspis vividus , evidencing disparity in galeaspid postcranial anatomy. Analysis of swimming speed reveals galeaspids as moderately fast swimmers, capable of achieving greater cruising swimming speeds than their more derived jawless and jawed relatives. Our analyses reject the hypothesis of a driven trend towards increasingly active food acquisition which has been invoked to characterize early vertebrate evolution. [ABSTRACT FROM AUTHOR]

Published

2023

5. Phylogenetic sampling affects evolutionary patterns of morphological disparity.

Author

Smith, Thomas J., Puttick, Mark N., O'Reilly, Joseph E., Pisani, Davide, Donoghue, Philip C. J., and Ruta, Marcello

Subjects

FOSSILS, TREE branches, NONEXPANSIVE mappings, PHENOTYPES, PHYLOGENY

Abstract

Cladistic character matrices are routinely repurposed in analyses of morphological disparity. Unfortunately, the sampling of taxa and characters within such datasets reflects their intended application (to resolve phylogeny, rather than distinguish between phenotypes) resulting in tree shapes that often misrepresent broader taxonomic and morphological diversity. Here we use tree shape as a proxy to explore how sampling can affect perceptions of evolving morphological disparity. Through analyses of simulated and empirical data, we demonstrate that sampling can introduce biases in morphospace occupation between clades that are predicted by differences in tree symmetry and branch length distribution. Symmetrical trees with relatively long internal branches predict more expansive patterns of morphospace occupation. Conversely, asymmetrical trees with relatively short internal branches predict more compact distributions. Additionally, we find that long external branches predict greater phenotypic divergence by peripheral morphotypes. Taken together, our results caution against the uncritical repurposing of cladistic datasets in disparity analyses. However, they also demonstrate that when morphological diversity is proportionately sampled, differences in tree shape between clades can speak to genuine differences in morphospace occupation. While cladistic datasets may serve as a useful starting point, disparity datasets must attempt to achieve uniformity in lineage sampling across time and topology. Only when all potential sources of bias are accounted for can evolutionary phenomena be distinguished from artefactual signals. It must be accepted that the non‐uniformity of the fossil record may preclude representative sampling and, therefore, a faithful characterization of the evolution of morphological disparity. [ABSTRACT FROM AUTHOR]

Published

2021

6. Fossilization processes have little impact on tip‐calibrated divergence time analyses.

Author

O'Reilly, Joseph E., Donoghue, Philip C. J., and Rahman, Imran

Subjects

*FOSSILIZATION, *MISSING data (Statistics), *TIME perception, *AGE differences, *TAPHONOMY, *DATA distribution

Abstract

The importance of palaeontological data in divergence time estimation has increased with the introduction of Bayesian total‐evidence dating methods, which use fossil taxa directly for calibration, facilitated by the joint analysis of morphological and molecular data. Fossil taxa are invariably incompletely known as a consequence of taphonomic processes, resulting in the decidedly non‐random distribution of missing data. The impact of non‐random missing data on the accuracy and precision of clade age estimation is unknown. In an attempt to constrain the impact of taphonomy on tip‐calibrated dating analyses, we compared clade ages estimated from a very complete morphological matrix to ages estimated from the same matrix permuted to simulate the progressive loss of anatomical information resulting from taphonomic processes. We demonstrate that systematically distributed missing data negatively influence clade age estimates, but that successive stages within the taphonomic process introduce greater differences in age estimates, when compared to estimates obtained from untreated data. Despite these effects, the general influence of missing data is weak, presumably due to the compensatory effect of extensive morphological data from extant taxa. We suggest that, in the absence of models that can explicitly account for taphonomic processes, morphological datasets should be constructed to minimize the impact of taphonomy on divergence time estimation. [ABSTRACT FROM AUTHOR]

Published

2021

7. Empirical distributions of homoplasy in morphological data.

Author

Murphy, Jodie L., Puttick, Mark N., O'Reilly, Joseph E., Pisani, Davide, Donoghue, Philip C. J., and Ruta, Marcello

Subjects

HOMOPLASY, CONVERGENT evolution, CROCODILIANS

Abstract

Cladistic datasets of morphological characters are comprised of observations that exhibit varying degrees of consistency with underlying phylogenetic hypotheses, reflecting the acquisition and retention of character states (highly consistent characters), or the convergent evolution and loss of character states (less consistent characters). The consistency between phylogenetic history and individual character histories has a bearing both on the evolutionary process and on the relative ease with which phylogenetic history may be inferred from morphological data. We surveyed 486 tetrapod morphological cladistic datasets to establish an empirical distribution of consistency among characters and datasets. Average dataset size has increased in the number of characters and taxa through time. The Consistency Index measure of homoplasy decreases as more characters are added but the most significant decreases result from the addition of taxa. Retention Index and Homoplasy Excess Ratio remain relatively constant with changes in taxa and character number. Our sampling of larger datasets confirms that the positive relationship between dataset size and homoplasy is primarily caused by an increase in taxa, not an increase in characters. Genealogies of cladistic data matrices for early vertebrates, scalidophorans and crocodilians, which have been modified in succession, show a trend of generally consistent quality through research time. Thus, we find no support for the widely shared conjecture that in the search for phylogenetic resolution, high quality phylogenetic characters are quickly exhausted, with subsequent research leading to the inclusion of potentially misleading characters exhibiting high levels of homoplasy. [ABSTRACT FROM AUTHOR]

Published

2021

8. Anatomy of the Ediacaran rangeomorph Charnia masoni.

Author

Dunn, Frances S., Wilby, Philip R., Kenchington, Charlotte G., Grazhdankin, Dmitriy V., Donoghue, Philip C. J., Liu, Alexander G., and Sevastopulo, George

Subjects

EDIACARAN fossils, ARCHAEOLOGICAL assemblages

Abstract

The Ediacaran macrofossil Charnia masoni Ford is perhaps the most iconic member of the Rangeomorpha: a group of seemingly sessile, frondose organisms that dominates late Ediacaran benthic, deep‐marine fossil assemblages. Despite C. masoni exhibiting broad palaeogeographical and stratigraphical ranges, there have been few morphological studies that consider the variation observed among populations of specimens derived from multiple global localities. We present an analysis of C. masoni that evaluates specimens from the UK, Canada and Russia, representing the largest morphological study of this taxon to date. We describe substantial morphological variation within C. masoni and present a new morphological model for this species that has significant implications both for interpretation of rangeomorph architecture, and potentially for existing taxonomic schemes. Previous reconstructions of Charnia include assumptions regarding the presence of structures seen in other rangeomorphs (e.g. an internal stalk) and of homogeneity in higher order branch morphology; observations that are not borne out by our investigations. We describe variation in the morphology of third and fourth order branches, as well as variation in gross structure near the base of the frond. The diagnosis of Charnia masoni is emended to take account of these new features. These findings highlight the need for large‐scale analyses of rangeomorph morphology in order to better understand the biology of this long‐enigmatic group. [ABSTRACT FROM AUTHOR]

Published

2019

9. Probabilistic methods outperform parsimony in the phylogenetic analysis of data simulated without a probabilistic model.

Author

Puttick, Mark N., O'Reilly, Joseph E., Pisani, Davide, Donoghue, Philip C. J., and Rahman, Imran

Subjects

PHYLOGENY, PARSIMONIOUS models, HOMOPLASY, ANIMAL morphology, MARKOV processes

Abstract

To understand patterns and processes of the diversification of life, we require an accurate understanding of taxon interrelationships. Recent studies have suggested that analyses of morphological character data using the Bayesian and maximum likelihood Mk model provide phylogenies of higher accuracy compared to parsimony methods. This has proved controversial, particularly studies simulating morphology‐data under Markov models that assume shared branch lengths for characters, as it is claimed this leads to bias favouring the Bayesian or maximum likelihood Mk model over parsimony models which do not explicitly make this assumption. We avoid these potential issues by employing a simulation protocol in which character states are randomly assigned to tips, but datasets are constrained to an empirically realistic distribution of homoplasy as measured by the consistency index. Datasets were analysed with equal weights and implied weights parsimony, and the maximum likelihood and Bayesian Mk model. We find that consistent (low homoplasy) datasets render method choice largely irrelevant, as all methods perform well with high consistency (low homoplasy) datasets, but the largest discrepancies in accuracy occur with low consistency datasets (high homoplasy). In such cases, the Bayesian Mk model is significantly more accurate than alternative models and implied weights parsimony never significantly outperforms the Bayesian Mk model. When poorly supported branches are collapsed, the Bayesian Mk model recovers trees with higher resolution compared to other methods. As it is not possible to assess homoplasy independently of a tree estimate, the Bayesian Mk model emerges as the most reliable approach for categorical morphological analyses. [ABSTRACT FROM AUTHOR]

Published

2019

10. The Efficacy of Consensus Tree Methods for Summarizing Phylogenetic Relationships from a Posterior Sample of Trees Estimated from Morphological Data.

Author

O'REILLY, JOSEPH E. and DONOGHUE, PHILIP C. J.

Subjects

*MOLECULAR phylogeny, *ECOLOGICAL heterogeneity, *EVOLUTIONARY theories, *BIOLOGICAL evolution, *GENETIC correlations

Abstract

Consensus trees are required to summarize trees obtained through MCMC sampling of a posterior distribution, providing an overview of the distribution of estimated parameters such as topology, branch lengths, and divergence times. Numerous consensus tree construction methods are available, each presenting a different interpretation of the tree sample. The rise of morphological clock and sampled-ancestormethods of divergence time estimation, in which times and topology are coestimated, has increased the popularity of the maximum clade credibility (MCC) consensus tree method. The MCC method assumes that the sampled, fully resolved topology with the highest clade credibility is an adequate summary of the most probable clades, with parameter estimates from compatible sampled trees used to obtain the marginal distributions of parameters such as clade ages and branch lengths. Using both simulated and empirical data, we demonstrate that MCC trees, and trees constructed using the similar maximum a posteriori (MAP) method, often include poorly supported and incorrect clades when summarizing diffuse posterior samples of trees. We demonstrate that the paucity of information in morphological data sets contributes to the inability of MCC and MAP trees to accurately summarise of the posterior distribution. Conversely, majority-rule consensus (MRC) trees represent a lower proportion of incorrect nodes when summarizing the same posterior samples of trees. Thus, we advocate the use of MRC trees, in place of MCC or MAP trees, in attempts to summarize the results of Bayesian phylogenetic analyses of morphological data. [ABSTRACT FROM AUTHOR]

Published

2018

11. Probabilistic methods surpass parsimony when assessing clade support in phylogenetic analyses of discrete morphological data.

Author

O'Reilly, Joseph E., Puttick, Mark N., Pisani, Davide, and Donoghue, Philip C. J.

Subjects

FOSSILS, ANIMAL species, BIOLOGICAL evolution, ANIMAL diversity, PARSIMONIOUS models, COMPUTER simulation

Abstract

Fossil taxa are critical to inferences of historical diversity and the origins of modern biodiversity, but realizing their evolutionary significance is contingent on restoring fossil species to their correct position within the tree of life. For most fossil species, morphology is the only source of data for phylogenetic inference; this has traditionally been analysed using parsimony, the predominance of which is currently challenged by the development of probabilistic models that achieve greater phylogenetic accuracy. Here, based on simulated and empirical datasets, we explore the relative efficacy of competing phylogenetic methods in terms of clade support. We characterize clade support using bootstrapping for parsimony and Maximum Likelihood, and intrinsic Bayesian posterior probabilities, collapsing branches that exhibit less than 50% support. Ignoring node support, Bayesian inference is the most accurate method in estimating the tree used to simulate the data. After assessing clade support, Bayesian and Maximum Likelihood exhibit comparable levels of accuracy, and parsimony remains the least accurate method. However, Maximum Likelihood is less precise than Bayesian phylogeny estimation, and Bayesian inference recaptures more correct nodes with higher support compared to all other methods, including Maximum Likelihood. We assess the effects of these findings on empirical phylogenies. Our results indicate probabilistic methods should be favoured over parsimony. [ABSTRACT FROM AUTHOR]

Published

2018

12. Uncertain-tree: discriminating among competing approaches to the phylogenetic analysis of phenotype data.

Author

O'Reilly, Joseph E., Fleming, James F., Clark, James, Holloway, Lucy, Parry, Luke A., Tarver, James E., Donoghue, Philip C. J., Puttick, Mark N., Lozano-Fernandez, Jesus, Pisani, Davide, and Tanner, Alastair R.

Subjects

PHYLOGENY, MORPHOLOGY, BAYESIAN analysis, PHENOTYPES, MAXIMUM likelihood statistics, PARSIMONIOUS models, PALEONTOLOGY, MATHEMATICAL models

Abstract

Morphological data provide the onlymeans of classifying the majority of life's history, but the choice between competing phylogenetic methods for the analysis of morphology is unclear. Traditionally, parsimony methods have been favoured but recent studies have shown that these approaches are less accurate than the Bayesian implementation of the Mk model. Here we expand on these findings in several ways: we assess the impact of tree shape andmaximum-likelihood estimation using theMk model, aswell as analysing data composed of both binary and multistate characters. We find that all methods struggle to correctly resolve deep clades within asymmetric trees, and when analysing small character matrices. The Bayesian Mk model is the most accurate method for estimating topology, but with lower resolution than other methods. Equal weights parsimony is more accurate than implied weights parsimony, and maximum-likelihood estimation using theMk model is the least accurate method. We conclude that the Bayesian implementation of the Mk model should be the default method for phylogenetic estimation from phenotype datasets, and we explore the implications of our simulations in reanalysing several empirical morphological character matrices. A consequence of our finding is that high levels of resolution or the ability to classify species or groups with much confidence should not be expected when using small datasets. It is now necessary to depart from the traditional parsimony paradigms of constructing character matrices, towards datasets constructed explicitly for Bayesian methods. [ABSTRACT FROM AUTHOR]

Published

2017

13. Embryo fossilization is a biological process mediated by microbial biofilms.

Author

Raff, Elizabeth C., Schollaert, Kaila L., Nelson, David E., Donoghue, Philip C. J., Thomas, Ceri-Wyn, Turner, F. Rudolf, Stein, Barry D., Xiping Dong, Bengtson, Stefan, HuIdtgren, Therese, Stampanoni, Marco, Yin Chongyu, and Raff, Rudolf A.

Subjects

FOSSILIZATION, CAMBRIAN paleontology, FOSSILS, BIOFILMS, PRESERVATION of organs, tissues, etc., NUCLEOTIDE sequence, MORPHOLOGY

Abstract

Fossilized embryos with extraordinary cellular preservation appear in the Late Neoproterozoic and Cambrian. coincident with the appearance of animal body fossils. It has been hypothesized that microbial processes are responsible for preservation and mineralization of organic tissues. However, the actions of microbes in preservation of embryos have not been demonstrated experimentally. Here, we show that bacterial biofllms assemble rapidly in dead marine embryos and form remarkable pseudomorphs in which the bacterial biofilm replaces and exquisitely models details of cellular organization and structure. The experimental model was the decay of cleavage stage embryos similar in size and morphology to fossil embryos. The data show that embryo preservation takes place in 3 distinct steps: (i) blockage of autolysis by reducing or anaerobic conditions, (ii) rapid formation of microbial biofilms that consume the embryo but form a replica that retains cell organization and morphology, and (ii,) bacterially catalyzed mineralization. Major bacterial taxa in embryo decay biofilms were identified by using 165 rDNA sequencing. Decay processes were similar in different taphonomic conditions, but the composition of bacterial populations depended on specific conditions. Experimental taphonomy generates preservation states similar to those in fossil embryos. The data show how fossilization of soft tissues in sediments can be mediated by bacterial replacement and mineralization, providing a foundation for experimentally creating biofilms from defined microbial species to model fossilization as a biological process. [ABSTRACT FROM AUTHOR]

Published

2008

14. Cutting the first ‘teeth': a new approach to functional analysis of conodont elements.

Author

Murdock, Duncan J. E., Sansom, Ivan J., and Donoghue, Philip C. J.

Subjects

CONODONTS, FUNCTIONAL analysis, MORPHOLOGY, VERTEBRATE anatomy, TEETH

Abstract

The morphological disparity of conodont elements rivals the dentition of all other vertebrates, yet relatively little is known about their functional diversity. Nevertheless, conodonts are an invaluable resource for testing the generality of functional principles derived from vertebrate teeth, and for exploring convergence in a range of food-processing structures. In a few derived conodont taxa, occlusal patterns have been used to derive functional models. However, conodont elements commonly and primitively exhibit comparatively simple coniform morphologies, functional analysis of which has not progressed much beyond speculation based on analogy. We have generated high-resolution tomographic data for each morphotype of the coniform conodont Panderodus acostatus. Using virtual cross sections, it has been possible to characterize changes in physical properties associated with individual element morphology. Subtle changes in cross-sectional profile have profound implications for the functional performance of individual elements and the apparatus as a whole. This study has implications beyond the ecology of a single conodont taxon. It provides a basis for reinterpreting coniform conodont taxonomy (which is based heavily on cross-sectional profiles), in terms of functional performance and ecology, shedding new light on the conodont fossil record. This technique can also be applied to more derived conodont morphologies, as well as analogous dentitions in other vertebrates and invertebrates. [ABSTRACT FROM AUTHOR]

Published

2013

15. Ontogeny and microstructure of the enigmatic Cambrian tommotiid Sunnaginia Missarzhevsky, 1969.

Author

MURDOCK, DUNCAN J. E., DONOGHUE, PHILIP C. J., BENGTSON, STEFAN, and MARONE, FEDERICA

Subjects

*FOSSIL animals, *ONTOGENY, *MORPHOLOGY, *BRACHIOPODA, *SCLEREIDS, *X-ray microscopy, *CAMBRIAN Period

Abstract

The tommotiids are a significant component of the earliest skeletal animal remains in the fossil record, occurring in large numbers in the Lower Cambrian. Sclerites of the tommotiid genus Sunnaginia have been implicated as integral to hypotheses regarding the evolution of the brachiopod body plan, with a morphology intermediate between the unspecialized sclerites of the tubular Eccentrotheca and the specialized sclerites of the tannuolinids. Abundant Sunnaginia ? imbricata sclerites, of a broad ontogenetic spectrum, were recovered from the Comley Limestone, Lower Cambrian (Stages 3-4), Shropshire, UK and compared to Sunnaginia imbricata from the Aldan River, Siberia (uppermost Tommotian). New microstructural data, collected using synchrotron radiation X-ray tomographic microscopy, reveal a unique microstructure for Sunnaginia ? imbricata sclerites among the tommotiids; interlamellar cavities spanned by a series of continuous pillars, giving a colonnaded appearance contrasting to that of S. imbricata. These data refute the inclusion of Eccentrotheca within the Sunnaginiidae and highlight the need for a revision of suprageneric classification of the tommotiids. Rather, structural similarities between Sunnaginia sclerites and those of the tannuolinids suggest a close affinity to this group. Recent phylogenetic hypotheses place the tannuolinids as stem-linguliform brachiopods, with Paterimitra plus the paterinid (and possibly rhynchonelliform) brachiopods as their sister group. Our new data therefore resolve Sunnaginia as close to the node defining crown-Brachiopoda. However, the characters supporting this phylogenetic scheme cannot be consistently applied to all taxa, nor do they define a series of nested clades. We therefore suggest that a more thorough phylogenetic analysis is required in the light of the data presented here and other recent descriptions. [ABSTRACT FROM AUTHOR]

Published

2012

16. The developmental biology of Charnia and the eumetazoan affinity of the Ediacaran rangeomorphs.

Author

Dunn, Frances S., Liu, Alexander G., Grazhdankin, Dmitriy V., Vixseboxse, Philip, Flannery-Sutherland, Joseph, Green, Emily, Harris, Simon, Wilby, Philip R., and Donoghue, Philip C. J.

Subjects

*MORPHOLOGY, *BIOLOGICAL evolution, *MOLECULAR clock, *LIFE sciences, *DEVELOPMENTAL biology, *NEUROANATOMY

Published

2021

17. Developmental biology of Helicoforamina reveals holozoan affinity, cryptic diversity, and adaptation to heterogeneous environments in the early Ediacaran Weng'an biota (Doushantuo Formation, South China).

Author

Zongjun Yin, Weichen Sun, Pengju Liu, Maoyan Zhu, and Donoghue, Philip C. J.

Subjects

*EDIACARAN fossils, *DEVELOPMENTAL biology, *BIOLOGICAL specimens, *MORPHOLOGY, *MARINE biology, *CAMBRIAN explosion (Evolution)

Abstract

The article offers presents a study related to developmental biology of Helicoforamina which reveals holozoan affinity, cryptic diversity, and adaptation to heterogeneous environments in the early Ediacaran Weng'an biota. It mentions the inclusion of Helicoforamina into life cycles assembled from other components of the Weng'an biota but support a holozoan affinity.

Published

2020