Your search keyword '"Stoilov P"' showing total 4 results

1. Uncovering the signaling landscape controlling breast cancer cell migration identifies novel metastasis driver genes

Author

Koedoot, E. (Esmee), Fokkelman, M. (Michiel), Rogkoti, V.-M., Smid, M. (Marcel), van de Sandt, I. (Iris), de Bont, H. (Hans), Pont, C., Klip, J.E. (Janna E.), Wink, S. (Steven), Timmermans, A.M. (Mieke), Wiemer, E.A.C. (Erik), Stoilov, P. (Peter), Foekens, J.A. (John), Le Dévédec, S.E. (Sylvia E.), Martens, J.W.M. (John), Van de Water, B. (Bob), Koedoot, E. (Esmee), Fokkelman, M. (Michiel), Rogkoti, V.-M., Smid, M. (Marcel), van de Sandt, I. (Iris), de Bont, H. (Hans), Pont, C., Klip, J.E. (Janna E.), Wink, S. (Steven), Timmermans, A.M. (Mieke), Wiemer, E.A.C. (Erik), Stoilov, P. (Peter), Foekens, J.A. (John), Le Dévédec, S.E. (Sylvia E.), Martens, J.W.M. (John), and Van de Water, B. (Bob)

Abstract

Ttriple-negative breast cancer (TNBC) is an aggressive and highly metastatic breast cancer subtype. Enhanced TNBC cell motility is a prerequisite of TNBC cell dissemination. Here, we apply an imaging-based RNAi phenotypic cell migration screen using two highly motile TNBC cell lines (Hs578T and MDA-MB-231) to provide a repository of signaling determinants that functionally drive TNBC cell motility. We have screened ~4,200 target genes individually and discovered 133 and 113 migratory modulators of Hs578T and MDA-MB-231, respectively, which are linked to signaling networks predictive for breast cancer progression. The splicing factors PRPF4B and BUD31 and the transcription factor BPTF are essential for cancer cell migration, amplified in human primary breast tumors and associated with metastasis-free survival. Depletion of PRPF4B, BUD31 and BPTF causes primarily down regulation of genes involved in focal adhesion and ECM-interaction pathways. PRPF4B is essential for TNBC metastasis formation in vivo, making PRPF4B a candidate for further drug development.

Published

2019

2. Uncovering the signaling landscape controlling breast cancer cell migration identifies novel metastasis driver genes

Author

Koedoot, E, Fokkelman, M, Rogkoti, VM, Smid, Marcel, van de Sandt, I, de Bont, H, Pont, C, Klip, JE, Wink, S, Timmermans, EA, Wiemer, Erik, Stoilov, P, Foekens, John, Le Devedec, SE, Martens, John, van de Water, B, Koedoot, E, Fokkelman, M, Rogkoti, VM, Smid, Marcel, van de Sandt, I, de Bont, H, Pont, C, Klip, JE, Wink, S, Timmermans, EA, Wiemer, Erik, Stoilov, P, Foekens, John, Le Devedec, SE, Martens, John, and van de Water, B

Published

2019

3. A consensus CaMK IV-responsive RNA sequence mediates regulation of alternative exons in neurons

Author

Xie, J Y, Xie, J Y, Jan, C, Stoilov, P, Park, J, Black, D L, Xie, J Y, Xie, J Y, Jan, C, Stoilov, P, Park, J, and Black, D L

Abstract

Neurons make extensive use of alternative pre-mRNA splicing to regulate gene expression and diversify physiological responses. We showed previously in a pituitary cell line that the Ca++/calmodulin-dependent protein kinase CaMK IV specifically repressed splicing of the BK channel STREX exon. This repression is dependent on a CaMK IV-responsive RNA element (CaRRE) within the STREX 3' splice site. Here, we report that similar Ca++ regulation of splicing, mediated by L-type calcium channels and CaM kinase IV, occurs in cultured neurons and in the brain. We identify a critical CaRRE motif (CACATNRTTAT) that is essential for conferring CaMK IV repression on an otherwise constitutive exon. Additional Ca++-regulated exons that carry this consensus sequence are also identified in the human genome. Thus, the Ca++/CaMK IV pathway in neurons controls the alternative splicing of a group of exons through this short CaRRE consensus sequence. The functions of some of these exons imply that splicing control through the CaMK IV pathway will alter neuronal activity.

Published

2005

4. A consensus CaMK IV-responsive RNA sequence mediates regulation of alternative exons in neurons

Author

Xie, J Y, Xie, J Y, Jan, C, Stoilov, P, Park, J, Black, D L, Xie, J Y, Xie, J Y, Jan, C, Stoilov, P, Park, J, and Black, D L

Abstract

Neurons make extensive use of alternative pre-mRNA splicing to regulate gene expression and diversify physiological responses. We showed previously in a pituitary cell line that the Ca++/calmodulin-dependent protein kinase CaMK IV specifically repressed splicing of the BK channel STREX exon. This repression is dependent on a CaMK IV-responsive RNA element (CaRRE) within the STREX 3' splice site. Here, we report that similar Ca++ regulation of splicing, mediated by L-type calcium channels and CaM kinase IV, occurs in cultured neurons and in the brain. We identify a critical CaRRE motif (CACATNRTTAT) that is essential for conferring CaMK IV repression on an otherwise constitutive exon. Additional Ca++-regulated exons that carry this consensus sequence are also identified in the human genome. Thus, the Ca++/CaMK IV pathway in neurons controls the alternative splicing of a group of exons through this short CaRRE consensus sequence. The functions of some of these exons imply that splicing control through the CaMK IV pathway will alter neuronal activity.

Published

2005