TY - JOUR
T1 - Genome-wide identification of post-translational modulators of transcription factor activity in human B cells
AU - Wang, Kai
AU - Saito, Masumichi
AU - Bisikirska, Brygida C.
AU - Alvarez, Mariano J.
AU - Lim, Wei Keat
AU - Rajbhandari, Presha
AU - Shen, Qiong
AU - Nemenman, Ilya
AU - Basso, Katia
AU - Margolin, Adam A.
AU - Klein, Ulf
AU - Dalla-Favera, Riccardo
AU - Califano, Andrea
N1 - Funding Information:
This work was supported by the US National Cancer Institute (R01CA109755), the National Institute of Allergy and Infectious Diseases (R01AI066116) and the National Centers for Biomedical Computing NIH Roadmap Initiative (U54CA121852). I.N. was supported in part by the National Institute for General Medical Sciences (R21GM080216). A.A.M. was supported by an IBM PhD fellowship.
PY - 2009/9
Y1 - 2009/9
N2 - The ability of a transcription factor (TF) to regulate its targets is modulated by a variety of genetic and epigenetic mechanisms, resulting in highly context-dependent regulatory networks. However, high-throughput methods for the identification of proteins that affect TF activity are still largely unavailable. Here we introduce an algorithm, modulator inference by network dynamics (MINDy), for the genome-wide identification of post-translational modulators of TF activity within a specific cellular context. When used to dissect the regulation of MYC activity in human B lymphocytes, the approach inferred novel modulators of MYC function, which act by distinct mechanisms, including protein turnover, transcription complex formation and selective enzyme recruitment. MINDy is generally applicable to study the post-translational modulation of mammalian TFs in any cellular context. As such it can be used to dissect context-specific signaling pathways and combinatorial transcriptional regulation.
AB - The ability of a transcription factor (TF) to regulate its targets is modulated by a variety of genetic and epigenetic mechanisms, resulting in highly context-dependent regulatory networks. However, high-throughput methods for the identification of proteins that affect TF activity are still largely unavailable. Here we introduce an algorithm, modulator inference by network dynamics (MINDy), for the genome-wide identification of post-translational modulators of TF activity within a specific cellular context. When used to dissect the regulation of MYC activity in human B lymphocytes, the approach inferred novel modulators of MYC function, which act by distinct mechanisms, including protein turnover, transcription complex formation and selective enzyme recruitment. MINDy is generally applicable to study the post-translational modulation of mammalian TFs in any cellular context. As such it can be used to dissect context-specific signaling pathways and combinatorial transcriptional regulation.
UR - http://www.scopus.com/inward/record.url?scp=70249108504&partnerID=8YFLogxK
U2 - 10.1038/nbt.1563
DO - 10.1038/nbt.1563
M3 - Article
C2 - 19741643
AN - SCOPUS:70249108504
SN - 1087-0156
VL - 27
SP - 829
EP - 837
JO - Nature Biotechnology
JF - Nature Biotechnology
IS - 9
ER -