1. Academic Validation
  2. Overlaid transcriptome and proteome analyses identify mitotic kinesins as important targets of arylsulfonamide-mediated RBM39 degradation

Overlaid transcriptome and proteome analyses identify mitotic kinesins as important targets of arylsulfonamide-mediated RBM39 degradation

  • Mol Cancer Res. 2023 May 12;MCR-22-0541. doi: 10.1158/1541-7786.MCR-22-0541.
Seemon Coomar 1 Pedro Mota 2 Alexander Penson 3 Juerg Schwaller 4 Omar Abdel-Wahab 3 Dennis Gillingham 5
Affiliations

Affiliations

  • 1 University of Basel, 4056, Switzerland.
  • 2 University of Basel, Basel, Switzerland.
  • 3 Memorial Sloan Kettering Cancer Center, New York, NY, United States.
  • 4 University Children's Hospital Zurich, Basel, Switzerland.
  • 5 University of Basel, Basel, Basel-Stadt, Switzerland.
Abstract

Certain arylsulfonamides (ArSulfs) induce an interaction between the E3 Ligase substrate adaptor DCAF15 and the critical splicing factor RBM39, ultimately causing its degradation. However, degradation of a splicing factor introduces complex pleiotropic effects that are difficult to untangle, since, aside from direct protein degradation, downstream transcriptional effects also influence the proteome. By overlaying transcriptional data and proteome datasets, we distinguish transcriptional from direct degradation effects, pinpointing those proteins most impacted by splicing changes. Using our workflow, we identify and validate the upregulation of the argininie-and-serine rich protein (RSRP1) and the downregulation of the key Kinesin motor proteins KIF20A and KIF20B due to altered splicing in the absence of RBM39. We further show that Kinesin downregulation is connected to the multinucleation phenotype observed upon RBM39 depletion by ArSulfs. Our approach should be helpful in the assessment of potential Cancer drug candidates which target splicing factors. Implications: Our approach provides a workflow for identifying and studying the most strongly modulated proteins when splicing is altered; the work also uncovers a splicing-based approach toward pharmacological targeting of mitotic kinesins.

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