Gregory A. Wray, Biology
Affiliations: | Duke University, Durham, NC |
Website:
http://www.biology.duke.edu/wraylab/Google:
"Gregory Wray"Mean distance: 17.27 (cluster 57)
Cross-listing: Evolution Tree
Parents
Sign in to add mentor| David R. McClay | grad student | 1987 | Duke (Evolution Tree) |
| Rudolf A. Raff | post-doc | 1987-1990 | Indiana University (Evolution Tree) |
| Richard R. Strathmann | post-doc | 1990-1992 | Friday Harbor Labs, University of Washington (Biomechanics Tree) |
Children
Sign in to add trainee| Chris J. Lowe | grad student | Duke | |
| Alexandra E. Bely | grad student | 1999 | SUNY Stony Brook (Evolution Tree) |
| Margaret Pizer | grad student | 1997-2001 | SUNY Stony Brook, Duke (Marine Ecology Tree) |
| Ehab Abouheif | grad student | 2002 | Duke (Evolution Tree) |
| Matthew V. Rockman | grad student | 2004 | Duke (FlyTree) |
| James P. Balhoff | grad student | 1999-2005 | Duke (Evolution Tree) |
| Ann L. Rouse | grad student | 2007 | Duke |
| Jenny Tung | grad student | 2010 | Duke |
| Ken D. Yokoyama | grad student | 2010 | Duke |
| David A. Garfield | grad student | 2011 | Duke (Evolution Tree) |
| Daniel E. Runcie | grad student | 2012 | Duke |
| Jonathan L. Boyd | grad student | 2014 | Duke |
| Jennifer Wygoda Israel | grad student | 2010-2015 | Duke |
| Alejandro Berrio | post-doc | 2016- | Duke |
| Lingyu Wang | post-doc | 2016-2017 | Duke |
BETA: Related publications
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Publications
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| Massri AJ, McDonald B, Wray GA, et al. (2023) Feedback circuits are numerous in embryonic gene regulatory networks and offer a stabilizing influence on evolution of those networks. Evodevo. 14: 10 |
| Henry JJ, Wray GA, Raff RA. (2023) Mechanism of an Alternate Type of Echinoderm Blastula Formation: The Wrinkled Blastula of the Sea Urchin Heliocidaris erythrogramma: (direct development/echinoderm development/morphogenesis/sea urchin embryos/wrinkled blastula). Development, Growth & Differentiation. 33: 317-328 |
| Devens HR, Davidson PL, Byrne M, et al. (2023) Hybrid epigenomes reveal extensive local genetic changes to chromatin accessibility contribute to divergence in embryonic gene expression between species. Biorxiv : the Preprint Server For Biology |
| Davidson PL, Guo H, Swart JS, et al. (2022) Recent reconfiguration of an ancient developmental gene regulatory network in Heliocidaris sea urchins. Nature Ecology & Evolution |
| Ketchum RN, Davidson PL, Smith EG, et al. (2022) A chromosome-level genome assembly of the highly heterozygous sea urchin Echinometra sp. EZ reveals adaptation in the regulatory regions of stress response genes. Genome Biology and Evolution |
| Davidson PL, Byrne M, Wray GA. (2022) Evolutionary changes in the chromatin landscape contribute to reorganization of a developmental gene network during rapid life history evolution in sea urchins. Molecular Biology and Evolution |
| Wray GA. (2021) Extreme phenotypic divergence and the evolution of development. Current Topics in Developmental Biology. 146: 79-112 |
| Massri AJ, Greenstreet L, Afanassiev A, et al. (2021) Developmental single-cell transcriptomics in the Lytechinus variegatus sea urchin embryo. Development (Cambridge, England) |
| Byrne M, Koop D, Strbenac D, et al. (2021) Transcriptomic analysis of Nodal - and BMP- associated genes during development to the juvenile seastar in Parvulastra exigua (Asterinidae). Marine Genomics. 100857 |
| Massri AJ, Schiebinger GR, Berrio A, et al. (2021) Methodologies for Following EMT In Vivo at Single Cell Resolution. Methods in Molecular Biology (Clifton, N.J.). 2179: 303-314 |