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The unprecedented detail with which contemporary molecular phylogenetics are visualizing infraspecific relationships within living species and species complexes cannot as yet be reliably extended into deep time. Yet paleontological systematics has routinely dealt in (mainly) morphotaxa envisaged in...

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Other Authors:	Dr Barry Fordham (hasAssociationWith), Dr Barry Fordham (isOwnedBy)
Format:	Other/Unknown Material
Language:	unknown
Published:	The Australian National University
Subjects:	Palaeontology (incl. Palynology) EARTH SCIENCES GEOLOGY Phylogeny and Comparative Analysis BIOLOGICAL SCIENCES EVOLUTIONARY BIOLOGY Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy) Palaeoclimatology PHYSICAL GEOGRAPHY AND ENVIRONMENTAL GEOSCIENCE evolutionary tree phylogeny timescale calibration data visualization morphospecies lineages stratophenetics biostratigraphy macroevolution TimeScale Creator Planktonic foraminifera
Online Access:	https://researchdata.ands.org.au/zehady-a-k-published-article/1384340 https://datacommons.anu.edu.au/DataCommons/item/anudc:5982 https://doi.org/10.25911/5db66fd8c5127 https://doi.org/10.1371/journal.pone.0204625 https://doi.org/10.1111/j.1469-185X.2011.00178.x

id	ftands:oai:ands.org.au::1384340
record_format	openpolar
institution	Open Polar
collection	Research Data Australia (Australian National Data Service - ANDS)
op_collection_id	ftands
language	unknown
topic	Palaeontology (incl. Palynology) EARTH SCIENCES GEOLOGY Phylogeny and Comparative Analysis BIOLOGICAL SCIENCES EVOLUTIONARY BIOLOGY Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy) Palaeoclimatology PHYSICAL GEOGRAPHY AND ENVIRONMENTAL GEOSCIENCE evolutionary tree phylogeny timescale calibration data visualization morphospecies lineages stratophenetics biostratigraphy macroevolution TimeScale Creator
spellingShingle	Palaeontology (incl. Palynology) EARTH SCIENCES GEOLOGY Phylogeny and Comparative Analysis BIOLOGICAL SCIENCES EVOLUTIONARY BIOLOGY Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy) Palaeoclimatology PHYSICAL GEOGRAPHY AND ENVIRONMENTAL GEOSCIENCE evolutionary tree phylogeny timescale calibration data visualization morphospecies lineages stratophenetics biostratigraphy macroevolution TimeScale Creator
topic_facet	Palaeontology (incl. Palynology) EARTH SCIENCES GEOLOGY Phylogeny and Comparative Analysis BIOLOGICAL SCIENCES EVOLUTIONARY BIOLOGY Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy) Palaeoclimatology PHYSICAL GEOGRAPHY AND ENVIRONMENTAL GEOSCIENCE evolutionary tree phylogeny timescale calibration data visualization morphospecies lineages stratophenetics biostratigraphy macroevolution TimeScale Creator
description	The unprecedented detail with which contemporary molecular phylogenetics are visualizing infraspecific relationships within living species and species complexes cannot as yet be reliably extended into deep time. Yet paleontological systematics has routinely dealt in (mainly) morphotaxa envisaged in various ways to have been components of past species lineages. Bridging these perspectives can only enrich both. Our integrated species–phenon tree merges ancestor–descendant proposals for fossil morphotaxa (phena) with reconstructed phylogenies of lineages (species), to digitally visualize infraspecific diversity within species through deep time. Aze & others’ important macroevolutionary dataset provides a case example to encourage mutual learnings between paleontological and molecular approaches. Supporting Data Functional Specification _ Integrated Species – Phenon Tree.docx Figure Datapacks: TSCEvolTree_IntTree2019Fig1ia,b.dpk TSCEvolTree_IntTree2019Fig1ic.dpk TSCEvolTree_IntTree2019Fig1iiia,b.dpk TSCEvolTree_IntTree2019Fig1iiic.dpk Figure Datasets: TSCEvolTree_IntTree2019Fig1ia,b.txt TSCEvolTree_IntTree2019Fig1ic.txt TSCEvolTree_IntTree2019Fig1iiia,b.txt TSCEvolTree_IntTree2019Fig1iiic.txt Figure Settings: TSCEvolTree_IntTree2019Fig1ia,b.tsc TSCEvolTree_IntTree2019Fig1ic.tsc TSCEvolTree_IntTree2019Fig1iiia,b.tsc TSCEvolTree_IntTree2019Fig1iiic.tsc Our graphics program just might provide common ground for evolutionary biologists and paleontologists to examine, together, evolutionary change though deep time; and in so doing gain valuable insights from each other. There is currently a burgeoning literature in molecular phylogenetics, richly detailing genetic complexity within living species and species complexes. But lesser known, at least to biological communities, is what’s coming out of that branch of paleontological research that is funded mainly because of the fundamental reliance of paleoclimatology on high-resolution microfossil stratigraphy. These microfossil studies typically embrace sequences of fossil-rich planktonic oozes extending over the past several tens of millions of years. And, like the molecular-phylogenetic literature, the microfossil studies also richly detail complexity — but within past species lineages, and in terms of morphology, geochemistry, and so on, profiled through long stretches of deep time. Recently this research area has produced quite a macroevolutionary breakthrough (by Aze & others, 2011): joint morphospecies and lineage phylogenetic trees for the same microfossil group (macroperforate planktonic foraminifera; some 340 morphospecies and 210 lineages in total), covering the entire Cenozoic Era from 66 millions years ago to the present living representatives. And, in parallel with this work, vigorous molecular-phylogenetic research has been conducted on the same microfossil group, resulting in very detailed genotypic characterisation of the living species. So, at least for these microfossils, there is an exciting opportunity to bring together these two branches of research — paleontological and molecular. However, synthesizing those morphospecies (phenon) and lineage (species) trees of Aze & others is a visual brain teaser. As a result, even though the lineage tree has proved a very rich source of macroevolutionary research in the intervening years, little has been done to uncover the rich interplay within these trees between morphologic change and lineage evolution and speciation, including any relationship with patterns emerging from the molecular studies. Our integrated species–phenon tree aims to redress this situation by augmenting a tree-drawing feature within a widely used Earth-history visualization platform (TimeScale Creator) and realizing a new, visually engaging representation of lineage evolution that will be accessible and relevant to both paleontologists and molecular biologists. In so doing, we hope to help bridge a gulf between these two research areas and mutually enrich both. 13. 9.13 MB.
author2	Dr Barry Fordham (hasAssociationWith) Dr Barry Fordham (isOwnedBy)
format	Other/Unknown Material
publisher	The Australian National University
url	https://researchdata.ands.org.au/zehady-a-k-published-article/1384340 https://datacommons.anu.edu.au/DataCommons/item/anudc:5982 https://doi.org/10.25911/5db66fd8c5127 https://doi.org/10.1371/journal.pone.0204625 https://doi.org/10.1111/j.1469-185X.2011.00178.x
op_coverage	Temporal: From 2014-08 to 2019-05
genre	Planktonic foraminifera
genre_facet	Planktonic foraminifera
op_source	http://anu.edu.au
op_relation	https://researchdata.ands.org.au/zehady-a-k-published-article/1384340 https://datacommons.anu.edu.au/DataCommons/item/anudc:5982 doi:10.25911/5db66fd8c5127 doi:10.1371/journal.pone.0204625 doi:10.1111/j.1469-185X.2011.00178.x
op_doi	https://doi.org/10.25911/5db66fd8c5127 https://doi.org/10.1371/journal.pone.0204625 https://doi.org/10.1111/j.1469-185X.2011.00178.x
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spelling	ftands:oai:ands.org.au::1384340 2023-05-15T18:01:17+02:00 Dr Barry Fordham (hasAssociationWith) Dr Barry Fordham (isOwnedBy) Temporal: From 2014-08 to 2019-05 https://researchdata.ands.org.au/zehady-a-k-published-article/1384340 https://datacommons.anu.edu.au/DataCommons/item/anudc:5982 https://doi.org/10.25911/5db66fd8c5127 https://doi.org/10.1371/journal.pone.0204625 https://doi.org/10.1111/j.1469-185X.2011.00178.x unknown The Australian National University https://researchdata.ands.org.au/zehady-a-k-published-article/1384340 https://datacommons.anu.edu.au/DataCommons/item/anudc:5982 doi:10.25911/5db66fd8c5127 doi:10.1371/journal.pone.0204625 doi:10.1111/j.1469-185X.2011.00178.x http://anu.edu.au Palaeontology (incl. Palynology) EARTH SCIENCES GEOLOGY Phylogeny and Comparative Analysis BIOLOGICAL SCIENCES EVOLUTIONARY BIOLOGY Stratigraphy (incl. Biostratigraphy and Sequence Stratigraphy) Palaeoclimatology PHYSICAL GEOGRAPHY AND ENVIRONMENTAL GEOSCIENCE evolutionary tree phylogeny timescale calibration data visualization morphospecies lineages stratophenetics biostratigraphy macroevolution TimeScale Creator collection ftands https://doi.org/10.25911/5db66fd8c5127 https://doi.org/10.1371/journal.pone.0204625 https://doi.org/10.1111/j.1469-185X.2011.00178.x 2020-01-05T22:28:05Z The unprecedented detail with which contemporary molecular phylogenetics are visualizing infraspecific relationships within living species and species complexes cannot as yet be reliably extended into deep time. Yet paleontological systematics has routinely dealt in (mainly) morphotaxa envisaged in various ways to have been components of past species lineages. Bridging these perspectives can only enrich both. Our integrated species–phenon tree merges ancestor–descendant proposals for fossil morphotaxa (phena) with reconstructed phylogenies of lineages (species), to digitally visualize infraspecific diversity within species through deep time. Aze & others’ important macroevolutionary dataset provides a case example to encourage mutual learnings between paleontological and molecular approaches. Supporting Data Functional Specification _ Integrated Species – Phenon Tree.docx Figure Datapacks: TSCEvolTree_IntTree2019Fig1ia,b.dpk TSCEvolTree_IntTree2019Fig1ic.dpk TSCEvolTree_IntTree2019Fig1iiia,b.dpk TSCEvolTree_IntTree2019Fig1iiic.dpk Figure Datasets: TSCEvolTree_IntTree2019Fig1ia,b.txt TSCEvolTree_IntTree2019Fig1ic.txt TSCEvolTree_IntTree2019Fig1iiia,b.txt TSCEvolTree_IntTree2019Fig1iiic.txt Figure Settings: TSCEvolTree_IntTree2019Fig1ia,b.tsc TSCEvolTree_IntTree2019Fig1ic.tsc TSCEvolTree_IntTree2019Fig1iiia,b.tsc TSCEvolTree_IntTree2019Fig1iiic.tsc Our graphics program just might provide common ground for evolutionary biologists and paleontologists to examine, together, evolutionary change though deep time; and in so doing gain valuable insights from each other. There is currently a burgeoning literature in molecular phylogenetics, richly detailing genetic complexity within living species and species complexes. But lesser known, at least to biological communities, is what’s coming out of that branch of paleontological research that is funded mainly because of the fundamental reliance of paleoclimatology on high-resolution microfossil stratigraphy. These microfossil studies typically embrace sequences of fossil-rich planktonic oozes extending over the past several tens of millions of years. And, like the molecular-phylogenetic literature, the microfossil studies also richly detail complexity — but within past species lineages, and in terms of morphology, geochemistry, and so on, profiled through long stretches of deep time. Recently this research area has produced quite a macroevolutionary breakthrough (by Aze & others, 2011): joint morphospecies and lineage phylogenetic trees for the same microfossil group (macroperforate planktonic foraminifera; some 340 morphospecies and 210 lineages in total), covering the entire Cenozoic Era from 66 millions years ago to the present living representatives. And, in parallel with this work, vigorous molecular-phylogenetic research has been conducted on the same microfossil group, resulting in very detailed genotypic characterisation of the living species. So, at least for these microfossils, there is an exciting opportunity to bring together these two branches of research — paleontological and molecular. However, synthesizing those morphospecies (phenon) and lineage (species) trees of Aze & others is a visual brain teaser. As a result, even though the lineage tree has proved a very rich source of macroevolutionary research in the intervening years, little has been done to uncover the rich interplay within these trees between morphologic change and lineage evolution and speciation, including any relationship with patterns emerging from the molecular studies. Our integrated species–phenon tree aims to redress this situation by augmenting a tree-drawing feature within a widely used Earth-history visualization platform (TimeScale Creator) and realizing a new, visually engaging representation of lineage evolution that will be accessible and relevant to both paleontologists and molecular biologists. In so doing, we hope to help bridge a gulf between these two research areas and mutually enrich both. 13. 9.13 MB. Other/Unknown Material Planktonic foraminifera Research Data Australia (Australian National Data Service - ANDS)

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