Abstract
Dispersal of Glioblastoma (GBM) renders localized therapy ineffective and is a major cause of recurrence. Previous studies have demonstrated that Dexamethasone (Dex), a drug currently used to treat brain tumor–related edema, can also significantly reduce dispersal of human primary GBM cells from neurospheres. It does so by triggering α5 integrin activity, leading to restoration of fibronectin matrix assembly (FNMA), increased neurosphere cohesion, and reduction of neurosphere dispersal velocity (DV). How Dex specifically activates α5 integrin in these GBM lines is unknown. Several chaperone proteins are known to activate integrins, including calreticulin (CALR). We explore the role of CALR as a potential mediator of Dex-dependent induction of α5 integrin activity in primary human GBM cells. We use CALR knock-down and knock-in strategies to explore the effects on FNMA, aggregate compaction, and dispersal velocity in vitro, as well as dispersal ex vivo on extirpated mouse retina and brain slices. We show that Dex increases CALR expression and that siRNA knockdown suppresses Dex-mediated FNMA. Overexpression of CALR in GBM cells activates FNMA, increases compaction, and decreases DV in vitro and on explants of mouse retina and brain slices. Our results define a novel interaction between Dex, CALR, and FNMA as inhibitors of GBM dispersal.
Highlights
Glioblastoma remains an intractable disease due to its propensity for early dispersal
We focus on CALR, since several studies have revealed a connection between disruption of CALR function and various malignancies including myeloproliferative disorders [6], osteocarcoma [7], ovarian and non-small cell lung cancer [8], breast cancer [9], and Glioblastoma (GBM) [10]
We addressed whether CALR-mediated activation of fibronectin matrix assembly (FNMA) is sufficient to elicit the dispersal inhibition exhibited by Dex-treated spheroids
Summary
Glioblastoma remains an intractable disease due to its propensity for early dispersal. Altering tumor behavior to keep cells “in place” may make targeted therapy for recurrence more effective. Previous studies have shown that Dexamethasone, a drug currently used to treat brain tumor related edema, is very effective in inhibiting dispersal of primary human GBM neurospheres but can reduce their growth rate. Inhibition of dispersal was demonstrated to be largely due to a Dex-mediated activation of α5 integrin function and subsequent reactivation of fibronectin matrix assembly (FNMA), a process that in a 3D neurosphere “glues” cells together, effectively inhibiting cell detachment from the primary mass. Integrin activation results in a significant re-localization of cortical actin into stress fibers, changes in cell morphology, stronger attachment to substrate, and decreased motility. The combination of increased intercellular cohesion and decreased motility significantly reduces the dispersal velocity of GBM neurospheres [1]. How Dex activates α5 integrin in these GBM lines is unknown
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