Machine learning unveils RNA polymerase II binding as a predictor for SMAD2‐dependent transcription dynamics in response to Actvin signalling

Machine learning unveils RNA polymerase II binding as a predictor for SMAD2‐dependent transcription dynamics in response to Actvin signalling

Abstract The transforming growth factor‐β (TGF‐β) superfamily, including Nodal and Activin, plays a critical role in various cellular processes. Understanding the intricate regulation and gene expression dynamics of TGF‐β signalling is of interest due to its diverse biological roles. A machine learn...

Full description

Bibliographic Details
Main Authors:	Dan Shi, Weihua Feng, Zhike Zi
Format:	Article
Language:	English
Published:	Wiley 2024-02-01
Series:	IET Systems Biology
Subjects:	bioinformatics learning (artificial intelligence) signal transduction
Online Access:	https://doi.org/10.1049/syb2.12085

Similar Items

Smad signal transduction : Smads in proliferation, differentiation and disease /
by: Dijke, Peter Ten, et al.
Published: (2006)

Cloning of a novel signaling molecule, AMSH-2, that potentiates transforming growth factor β signaling
by: Pandey Akhilesh, et al.
Published: (2004-01-01)

Using bioinformatics tools for the discovery of Dengue RNA-dependent RNA polymerase inhibitors
by: Nomagugu B. Nncube, et al.
Published: (2018-09-01)

New core promoter element in RNA polymerase II-dependent transcription: sequence-specific DNA binding by transcription factor IIB.
by: Lagrange, T, et al.
Published: (1998)

Mediator and RNA polymerase II clusters associate in transcription-dependent condensates
by: Cho, Won-ki, et al.
Published: (2020)

Transcription termination by RNA Polymerase II
by: White, E
Published: (2012)

An unexpected INAD PDZ tandem-mediated plcβ binding in Drosophila photo receptors
by: Fei Ye, et al.
Published: (2018-12-01)

Arl15 upregulates the TGFβ family signaling by promoting the assembly of the Smad-complex
by: Shi, Meng, et al.
Published: (2022)

Gene Silencing Mediated by siRNA-binding Fusion Proteins Is Attenuated by Double-stranded RNA-binding Domain Structure
by: James C Geoghegan, et al.
Published: (2012-01-01)

Smad2/3 signaling involved in urotensin II-induced phenotypic differentiation, collagen synthesis and migration of rat aortic adventitial fibroblasts
by: Weizhao Lin, et al.
Published: (2023-08-01)

Constraint-based modeling and kinetic analysis of the Smad dependent TGF-beta signaling pathway.
by: Zhike Zi, et al.
Published: (2007-01-01)

Protocol to quantify the activation dynamics of tumor-associated T cells in mice by functional intravital microscopy
by: Shannon N. Geels, et al.
Published: (2024-12-01)

Characterizing intergenic transcription at RNA polymerase II binding sites in normal and cancer tissues
by: Pierre de Langen, et al.
Published: (2023-10-01)

Extragenic accumulation of RNA polymerase II enhances transcription by RNA polymerase III.
by: Imke Listerman, et al.
Published: (2007-11-01)

Possible role of ARF and AP2 transcription factors in marine and terrestrial evolutionary adaptation of Rhizophoraceae plants unveiled by transcriptomic analysis
by: HongMei Qiao, et al.
Published: (2024-12-01)

Sensitivity of mitochondrial transcription and resistance of RNA polymerase II dependent nuclear transcription to antiviral ribonucleosides.
by: Jamie J Arnold, et al.
Published: (2012-01-01)

The conserved protein Seb1 drives transcription termination by binding RNA polymerase II and nascent RNA
by: Wittmann, S, et al.
Published: (2017)

Role of R-loops in pause-dependent transcriptional termination of RNA polymerase II
by: Skourti-Stathaki, K
Published: (2012)

The MicroRNA-signaling-peroxisome proliferator-activated receptor gamma connection in the modulation of adipogenesis: bioinformatics projection on chicken
by: Chiu-Jung Huang, et al.
Published: (2022-08-01)

Exon tethering in transcription by RNA polymerase II.
by: Dye, M, et al.
Published: (2006)

Antisense RNA polymerase II divergent transcripts are P-TEFb dependent and substrates for the RNA exosome
by: Flynn, Ryan A., et al.
Published: (2014)

Disengaging polymerase: terminating RNA polymerase II transcription in budding yeast.
by: Mischo, H, et al.
Published: (2013)

Posttranscriptional Regulation in Response to Different Environmental Stresses in Campylobacter jejuni
by: Stephen Li, et al.
Published: (2022-06-01)

Protocol for stratification of triple-negative breast cancer patients using in silico signaling dynamics
by: Hiroaki Imoto, et al.
Published: (2022-09-01)

Multiple transcript cleavage precedes polymerase release in termination by RNA polymerase II.
by: Dye, M, et al.
Published: (2001)

Regulation of yeast RNA polymerase II holoenzyme transcription
by: Hengartner, Christoph J. (Christopher Johannes), 1968-
Published: (2014)

The transcription cycle of RNA polymerase II in living cells
by: Kimura, H, et al.
Published: (2002)

Assembly of RNA polymerase II transcription initiation complexes
by: Farnung, Lucas, et al.
Published: (2023)

The transcription cycle of RNA polymerase II in living cells.
by: Kimura, H, et al.
Published: (2002)

Turnover and function of noncoding RNA polymerase II transcripts.
by: Dye, M, et al.
Published: (2006)

RNA polymerase II pausing in development: orchestrating transcription
by: Abderhman Abuhashem, et al.
Published: (2022-01-01)

Genetic dissection of the RNA polymerase II transcription cycle
by: Shao-Pei Chou, et al.
Published: (2022-07-01)

Signal transducers and activators of transcription (STATs) : activation and biology /
by: Sehgal, Pravinkumar B., et al.
Published: (2003)

Association of the influenza A virus RNA-dependent RNA polymerase with cellular RNA polymerase II.
by: Engelhardt, O, et al.
Published: (2005)

The long non-coding RNA LINC00707 interacts with Smad proteins to regulate TGFβ signaling and cancer cell invasion
by: Caroline Gélabert, et al.
Published: (2023-10-01)

The glucose‐deprivation network counteracts lapatinib‐induced toxicity in resistant ErbB2‐positive breast cancer cells
by: Kakajan Komurov, et al.
Published: (2012-07-01)

Inferring cell communication using single-cell calcium spatiotemporal dynamics
by: Nika Taghdiri, et al.
Published: (2022-09-01)

Triptolide (TPL) inhibits global transcription by inducing proteasome-dependent degradation of RNA polymerase II (Pol II).
by: Ying Wang, et al.
Published: (2011-01-01)

Activins as Dual Specificity TGF-β Family Molecules: SMAD-Activation via Activin- and BMP-Type 1 Receptors
by: Oddrun Elise Olsen, et al.
Published: (2020-03-01)

Transmembrane Transcription Regulators Are Widespread in Bacteria and Archaea
by: Lucas M. Demey, et al.
Published: (2023-06-01)