Clifford P. Brangwynne
Affiliations: | Chemical and Biological Engineering | Princeton University, Princeton, NJ |
Area:
self-assembly of biological materialsWebsite:
http://www.princeton.edu/cbe/people/faculty/brangwynne/Google:
"Clifford P. Brangwynne"Bio:
Cliff Brangwynne obtained his PhD (2007) at Harvard University working in the group of David Weitz. He was a visiting fellow at the Max Planck Institute for the Physics of Complex Systems in Dresden, and was awarded a Helen Hay Whitney Fellowship to work with Anthony Hyman at the Max Planck Institute for Molecular Cell Biology and Genetics in Dresden (2008–2010).
Mean distance: 9.76 | S | N | B | C | P |
Parents
Sign in to add mentor| David A. Weitz | grad student | 2007 | Harvard | |
| (Mechanics and dynamics of microtubule bending.) | ||||
| Anthony Hyman | post-doc | 2008-2010 | Max Planck Institute of Molecular Cell Biology and Genetics | |
Children
Sign in to add trainee| Anastasia Repouliou | research assistant | 2019-2020 | Princeton (FlyTree) |
| Joshua A. Riback | post-doc | 2018- | Princeton |
| Stephanie C. Weber | post-doc | 2011-2015 | Princeton |
| Yongdae Shin | post-doc | 2014-2017 | Princeton (Neurotree) |
BETA: Related publications
See more...
Publications
|
You can help our author matching system! If you notice any publications incorrectly attributed to this author, please sign in and mark matches as correct or incorrect. |
| Zhao JZ, Xia J, Brangwynne CP. (2024) Chromatin compaction during confined cell migration induces and reshapes nuclear condensates. Nature Communications. 15: 9964 |
| Strom AR, Kim Y, Zhao H, et al. (2024) Condensate interfacial forces reposition DNA loci and probe chromatin viscoelasticity. Cell |
| Riback JA, Eeftens JM, Lee DSW, et al. (2023) Viscoelasticity and advective flow of RNA underlies nucleolar form and function. Molecular Cell. 83: 3095-3107.e9 |
| Lee DSW, Choi CH, Sanders DW, et al. (2023) Size distributions of intracellular condensates reflect competition between coalescence and nucleation. Nature Physics. 19: 586-596 |
| Lee DSW, Strom AR, Brangwynne CP. (2022) The mechanobiology of nuclear phase separation. Apl Bioengineering. 6: 021503 |
| Eeftens JM, Kapoor M, Michieletto D, et al. (2021) Polycomb condensates can promote epigenetic marks but are not required for sustained chromatin compaction. Nature Communications. 12: 5888 |
| Rana U, Brangwynne CP, Panagiotopoulos AZ. (2021) Phase separation vs aggregation behavior for model disordered proteins. The Journal of Chemical Physics. 155: 125101 |
| Shimobayashi SF, Ronceray P, Sanders DW, et al. (2021) Nucleation landscape of biomolecular condensates. Nature |
| Zhang Y, Lee DSW, Meir Y, et al. (2021) Mechanical Frustration of Phase Separation in the Cell Nucleus by Chromatin. Physical Review Letters. 126: 258102 |
| Wei MT, Chang YC, Shimobayashi SF, et al. (2020) Nucleated transcriptional condensates amplify gene expression. Nature Cell Biology |