Your search keyword '"Guisbert E"' showing total 2 results

1. Titration of SF3B1 Activity Reveals Distinct Effects on the Transcriptome and Cell Physiology.

Author

Kim Guisbert KS, Mossiah I, and Guisbert E

Subjects

Epoxy Compounds pharmacology, HEK293 Cells, Humans, Macrolides pharmacology, Nonsense Mediated mRNA Decay, Phosphoproteins genetics, RNA Splicing Factors genetics, RNA, Messenger genetics, Alternative Splicing, Cell Physiological Phenomena, Gene Expression Regulation drug effects, Phosphoproteins metabolism, RNA Splicing Factors metabolism, RNA, Messenger metabolism, Sequence Analysis, RNA methods, Transcriptome drug effects

Abstract

SF3B1 is a core component of the U2 spliceosome that is frequently mutated in cancer. We have previously shown that titrating the activity of SF3B1, using the inhibitor pladienolide B (PB), affects distinct steps of the heat shock response (HSR). Here, we identify other genes that are sensitive to different levels of SF3B1 (5 vs. 100 nM PB) using RNA sequencing. Significant changes to mRNA splicing were identified at both low PB and high PB concentrations. Changes in expression were also identified in the absence of alternative splicing, suggesting that SF3B1 influences other gene expression pathways. Surprisingly, gene expression changes identified in low PB are not predictive of changes in high PB. Specific pathways were identified with differential sensitivity to PB concentration, including nonsense-mediated decay and protein-folding homeostasis, both of which were validated using independent reporter constructs. Strikingly, cells exposed to low PB displayed enhanced protein-folding capacity relative to untreated cells. These data reveal that the transcriptome is exquisitely sensitive to SF3B1 and suggests that the activity of SF3B1 is finely regulated to coordinate mRNA splicing, gene expression and cellular physiology.

Published

2020

2. SF3B1 is a stress-sensitive splicing factor that regulates both HSF1 concentration and activity.

Author

Kim Guisbert KS and Guisbert E

Subjects

DNA-Binding Proteins genetics, Epoxy Compounds pharmacology, HeLa Cells, Heat Shock Transcription Factors, Heat-Shock Response drug effects, Heat-Shock Response genetics, Humans, Macrolides pharmacology, Phosphoproteins antagonists & inhibitors, Phosphoproteins genetics, RNA Interference, RNA Splicing, RNA Splicing Factors antagonists & inhibitors, RNA Splicing Factors genetics, RNA, Messenger metabolism, RNA, Small Interfering metabolism, Temperature, Transcription Factors genetics, DNA-Binding Proteins metabolism, Phosphoproteins metabolism, RNA Splicing Factors metabolism, Transcription Factors metabolism

Abstract

The heat shock response (HSR) is a well-conserved, cytoprotective stress response that activates the HSF1 transcription factor. During severe stress, cells inhibit mRNA splicing which also serves a cytoprotective function via inhibition of gene expression. Despite their functional interconnectedness, there have not been any previous reports of crosstalk between these two pathways. In a genetic screen, we identified SF3B1, a core component of the U2 snRNP subunit of the spliceosome, as a regulator of the heat shock response in Caenorhabditis elegans. Here, we show that this regulatory connection is conserved in cultured human cells and that there are at least two distinct pathways by which SF3B1 can regulate the HSR. First, inhibition of SF3B1 with moderate levels of Pladienolide B, a previously established small molecule inhibitor of SF3B1, affects the transcriptional activation of HSF1, the transcription factor that mediates the HSR. However, both higher levels of Pladienolide B and SF3B1 siRNA knockdown also change the concentration of HSF1, a form of HSR regulation that has not been previously documented during normal physiology but is observed in some forms of cancer. Intriguingly, mutations in SF3B1 have also been associated with several distinct types of cancer. Finally, we show that regulation of alternative splicing by SF3B1 is sensitive to temperature, providing a new mechanism by which temperature stress can remodel the transcriptome.

Published

2017