Abstract
In glioblastoma (GBM), infiltration of primary tumor cells into the normal tissue and dispersal throughout the brain is a central challenge to successful treatment that remains unmet. Indeed, patients respond poorly to the current therapies of tumor resection followed by chemotherapy with radiotherapy and have only a 16-month median survival. It is therefore imperative to develop novel therapies. RSK2 is a kinase that regulates proliferation and adhesion and can promote metastasis. We demonstrate that active RSK2 regulates GBM cell adhesion and is essential for cell motility and invasion of patient-derived GBM neurospheres. RSK2 control of adhesion and migration is mediated in part by its effects on integrin-Filamin A complexes. Importantly, inhibition of RSK2 by either RSK inhibitors or shRNA silencing impairs invasion and combining RSK2 inhibitors with temozolomide improves efficacy in vitro. In agreement with the in vitro data, using public datasets, we find that RSK2 is significantly upregulated in vivo in human GBM patient tumors, and that high RSK2 expression significantly correlates with advanced tumor stage and poor patient survival. Together, our data provide strong evidence that RSK inhibitors could enhance the effectiveness of existing GBM treatment, and support RSK2 targeting as a promising approach for novel GBM therapy.
Highlights
Glioblastoma (GBM) is an aggressive cancer that arises from glial cells and their progenitors and is often diagnosed at a late stage [1, 2]
ribosomal S6 kinase 2 (RSK2) activity is required for GBM cell migration and invasion
We have found that RSK2 can drive GBM migration and invasion
Summary
Glioblastoma (GBM) is an aggressive cancer that arises from glial cells and their progenitors and is often diagnosed at a late stage [1, 2]. GBM cells are highly motile and invade the healthy brain tissue surrounding the primary tumor site. This makes a complete surgical resection of GBM difficult, contributing to high recurrence and mortality rates in GBM patients [3, 4]. GBM cells spread within the brain by migrating in a mesenchymal fashion along the extracellular matrix (ECM) of myelinated fiber tracts and blood vessels [7, 8]. This migration is mediated by dynamic interactions between the cancer cell and its surrounding ECM through transmembrane signaling receptors including the integrins [9, 10]
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