Oncogenic FGFR Fusions Produce Centrosome and Cilia Defects by Ectopic Signaling

Alexandru Nita; Sara P. Abraham; Pavel Krejci; Michaela Bosakova

doi:10.3390/cells10061445

Oncogenic FGFR Fusions Produce Centrosome and Cilia Defects by Ectopic Signaling

Cells ◽

10.3390/cells10061445 ◽

2021 ◽

Vol 10 (6) ◽

pp. 1445

Author(s):

Alexandru Nita ◽

Sara P. Abraham ◽

Pavel Krejci ◽

Michaela Bosakova

Keyword(s):

Cell Fate ◽

Mitotic Spindle ◽

Genetic Disorders ◽

Neoplastic Transformation ◽

Gene Fusions ◽

Substantial Portion ◽

Fibroblast Growth Factor Receptors ◽

Cell Fate Decisions ◽

And Control ◽

Abnormal Cilia

A single primary cilium projects from most vertebrate cells to guide cell fate decisions. A growing list of signaling molecules is found to function through cilia and control ciliogenesis, including the fibroblast growth factor receptors (FGFR). Aberrant FGFR activity produces abnormal cilia with deregulated signaling, which contributes to pathogenesis of the FGFR-mediated genetic disorders. FGFR lesions are also found in cancer, raising a possibility of cilia involvement in the neoplastic transformation and tumor progression. Here, we focus on FGFR gene fusions, and discuss the possible mechanisms by which they function as oncogenic drivers. We show that a substantial portion of the FGFR fusion partners are proteins associated with the centrosome cycle, including organization of the mitotic spindle and ciliogenesis. The functions of centrosome proteins are often lost with the gene fusion, leading to haploinsufficiency that induces cilia loss and deregulated cell division. We speculate that this complements the ectopic FGFR activity and drives the FGFR fusion cancers.

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Context-dependent roles of YAP/TAZ in stem cell fates and cancer

Cellular and Molecular Life Sciences ◽

10.1007/s00018-021-03781-2 ◽

2021 ◽

Author(s):

Lucy LeBlanc ◽

Nereida Ramirez ◽

Jonghwan Kim

Keyword(s):

Stem Cell ◽

Cell Fate ◽

Control Cell ◽

Substantial Portion ◽

Cell Fates ◽

Cell Fate Decisions ◽

Cell Death Pathways ◽

Multiple Context ◽

Cancer Cell Survival ◽

Context Dependent

AbstractHippo effectors YAP and TAZ control cell fate and survival through various mechanisms, including transcriptional regulation of key genes. However, much of this research has been marked by conflicting results, as well as controversy over whether YAP and TAZ are redundant. A substantial portion of the discordance stems from their contradictory roles in stem cell self-renewal vs. differentiation and cancer cell survival vs. apoptosis. In this review, we present an overview of the multiple context-dependent functions of YAP and TAZ in regulating cell fate decisions in stem cells and organoids, as well as their mechanisms of controlling programmed cell death pathways in cancer.

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Dynamic spatiotemporal coordination of neural stem cell fate decisions through local feedback in the adult vertebrate brain

10.1101/2020.07.15.205021 ◽

2020 ◽

Author(s):

Nicolas Dray ◽

Laure Mancini ◽

Udi Binshtok ◽

Felix Cheysson ◽

Willy Supatto ◽

...

Keyword(s):

Stem Cell ◽

Cell Fate ◽

Neural Stem Cell ◽

Life Time ◽

Population Level ◽

Dynamic Imaging ◽

Cell Fate Decisions ◽

Vertebrate Brain ◽

And Control

SUMMARYNeural stem cell (NSC) populations persist in the adult vertebrate brain over a life time, and their homeostasis is controlled at the population level. The nature and properties of these coordination mechanisms remain unknown. Here we combine dynamic imaging of entire NSC populations in their in vivo niche over weeks, pharmacological manipulations, mathematical modeling and spatial statistics, and demonstrate that NSCs use spatiotemporally resolved local feedbacks to coordinate their decision to divide. These involve a Notch-mediated inhibition from transient neural progenitors, and a dispersion effect from dividing NSCs themselves, exerted with a delay of 9-12 days. Simulations from a stochastic NSC lattice model capturing these interactions demonstrate that they are linked by lineage progression and control the spatiotemporal distribution of output neurons. These results highlight how local and temporally delayed interactions occurring between brain germinal cells generate self-propagating dynamics that maintain NSC population homeostasis with specific spatiotemporal correlations.

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Neoplastic Transformation by Notch Requires Nuclear Localization

Molecular and Cellular Biology ◽

10.1128/mcb.20.11.3928-3941.2000 ◽

2000 ◽

Vol 20 (11) ◽

pp. 3928-3941 ◽

Cited By ~ 86

Author(s):

Shawn Jeffries ◽

Anthony J. Capobianco

Keyword(s):

Plasma Membrane ◽

Notch Signaling ◽

Cell Fate ◽

Mammalian Cells ◽

Rat Kidney ◽

Neoplastic Transformation ◽

Notch Signaling Pathway ◽

Proteolytic Processing ◽

Cell Fate Decisions

ABSTRACT Notch proteins are plasma membrane-spanning receptors that mediate important cell fate decisions such as differentiation, proliferation, and apoptosis. The mechanism of Notch signaling remains poorly understood. However, it is clear that the Notch signaling pathway mediates its effects through intercellular contact between neighboring cells. The prevailing model for Notch signaling suggests that ligand, presented on a neighboring cell, triggers proteolytic processing of Notch. Following proteolysis, it is thought that the intracellular portion of Notch (Nic) translocates to the nucleus, where it is involved in regulating gene expression. There is considerable debate concerning where in the cell Notch functions and what proteins serve as effectors of the Notch signal. Several Notch genes have clearly been shown to be proto-oncogenes in mammalian cells. Activation of Notch proto-oncogenes has been associated with tumorigenesis in several human and other mammalian cancers. Transforming alleles of Notch direct the expression of truncated proteins that primarily consist of Nic and are not tethered to the plasma membrane. However, the mechanism by which Notch oncoproteins (generically termed here as Nic) induce neoplastic transformation is not known. Previously we demonstrated that N1ic and N2iccould transform E1A immortalized baby rat kidney cells (RKE) in vitro. We now report direct evidence that N1ic must accumulate in the nucleus to induce transformation of RKE cells. In addition, we define the minimal domain of N1ic required to induce transformation and present evidence that transformation of RKE cells by N1ic is likely to be through a CBF1-independent pathway.

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