Your search keyword '"Bronwyn W Williams"' showing total 3 results

1. Phylogenomic Analysis of a Putative Missing Link Sparks Reinterpretation of Leech Evolution

Author

Alex Dornburg, Bronwyn W. Williams, Alan R. Lemmon, Frank E. Anderson, Emily Moriarty Lemmon, Samuel W. James, Anna J. Phillips, Christer Erséus, and Katerina L. Zapfe

Subjects

0106 biological sciences, animal structures, Leech, Acanthobdella, phylogeny, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Monophyly, Phylogenetics, sanguivory, Genetics, 14. Life underwater, Clade, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Reinterpretation, 0303 health sciences, biology, Phylogenetic tree, Branchiobdellida, biology.organism_classification, symbiosis, Evolutionary biology, Hirudinida, Research Article, anchored hybrid enrichment

Abstract

Leeches (Hirudinida) comprise a charismatic, yet often maligned group of organisms. Despite their ecological, economic, and medical importance, a general consensus on the phylogenetic relationships of major hirudinidan lineages is lacking. This absence of a consistent, robust phylogeny of early-diverging lineages has hindered our understanding of the underlying processes that enabled evolutionary diversification of this clade. Here, we used an anchored hybrid enrichment-based phylogenomic approach, capturing hundreds of loci to investigate phylogenetic relationships among major hirudinidan lineages and their closest living relatives. Our results suggest that a dramatic reinterpretation of early leech evolution is warranted. We recovered Branchiobdellida as sister to a clade that includes all major lineages of hirudinidans, but found Acanthobdella to be nested within Oceanobdelliformes. These results cast doubt on the utility of Acanthobdella as a “missing link” used to explain the origin of blood-feeding in hirudineans. Further, our results support a deep divergence between predominantly marine and freshwater lineages, while not supporting the reciprocal monophyly of jawed and proboscis-bearing leeches. To sum up, our phylogenomic resolution of early-diverging leeches provides a necessary foundation for illuminating the evolution of host–symbiont associations and key adaptations that have allowed leeches to colonize a wide diversity of habitats worldwide.

Published

2019

2. Editor’s Note: Phylogenomic Analysis of a Putative Missing Link Sparks Reinterpretation of Leech Evolution

Author

Samuel W. James, Emily Moriarty Lemmon, Katerina L. Zapfe, Bronwyn W. Williams, Alex Dornburg, Christer Erséus, Alan R. Lemmon, Anna J. Phillips, and Frank E. Anderson

Subjects

Reinterpretation, Editor's Note, Evolutionary biology, Genetics, Leech, Biology, Link (knot theory), Ecology, Evolution, Behavior and Systematics

Published

2019

3. Expression of concern: Phylogenomic Analysis of a Putative Missing Link Sparks Reinterpretation of Leech Evolution

Author

Samuel W. James, Anna J. Phillips, Frank E. Anderson, Katerina L. Zapfe, Alex Dornburg, Bronwyn W. Williams, Alan R. Lemmon, Christer Erséus, and Emily Moriarty Lemmon

Subjects

Reinterpretation, Expression of Concern, Leech, Sequence Analysis, DNA, Biology, Expression (architecture), Evolutionary biology, Leeches, Genetics, Animals, Link (knot theory), Symbiosis, Ecology, Evolution, Behavior and Systematics, Phylogeny

Abstract

Leeches (Hirudinida) comprise a charismatic, yet often maligned group of organisms. Despite their ecological, economic, and medical importance, a general consensus on the phylogenetic relationships of major hirudinidan lineages is lacking. This absence of a consistent, robust phylogeny of early-diverging lineages has hindered our understanding of the underlying processes that enabled evolutionary diversification of this clade. Here, we used an anchored hybrid enrichment-based phylogenomic approach, capturing hundreds of loci to investigate phylogenetic relationships among major hirudinidan lineages and their closest living relatives. Our results suggest that a dramatic reinterpretation of early leech evolution is warranted. We recovered Branchiobdellida as sister to a clade that includes all major lineages of hirudinidans, but found Acanthobdella to be nested within Oceanobdelliformes. These results cast doubt on the utility of Acanthobdella as a "missing link" used to explain the origin of blood-feeding in hirudineans. Further, our results support a deep divergence between predominantly marine and freshwater lineages, while not supporting the reciprocal monophyly of jawed and proboscis-bearing leeches. To sum up, our phylogenomic resolution of early-diverging leeches provides a necessary foundation for illuminating the evolution of host-symbiont associations and key adaptations that have allowed leeches to colonize a wide diversity of habitats worldwide.

Published

2019