Abstract
Glioblastoma (GB) is the most lethal brain tumor, and Wingless (Wg)-related integration site (WNT) pathway activation in these tumors is associated with a poor prognosis. Clinically, the disease is characterized by progressive neurological deficits. However, whether these symptoms result from direct or indirect damage to neurons is still unresolved. Using Drosophila and primary xenografts as models of human GB, we describe, here, a mechanism that leads to activation of WNT signaling (Wg in Drosophila) in tumor cells. GB cells display a network of tumor microtubes (TMs) that enwrap neurons, accumulate Wg receptor Frizzled1 (Fz1), and, thereby, deplete Wg from neurons, causing neurodegeneration. We have defined this process as "vampirization." Furthermore, GB cells establish a positive feedback loop to promote their expansion, in which the Wg pathway activates cJun N-terminal kinase (JNK) in GB cells, and, in turn, JNK signaling leads to the post-transcriptional up-regulation and accumulation of matrix metalloproteinases (MMPs), which facilitate TMs' infiltration throughout the brain, TMs' network expansion, and further Wg depletion from neurons. Consequently, GB cells proliferate because of the activation of the Wg signaling target, β-catenin, and neurons degenerate because of Wg signaling extinction. Our findings reveal a molecular mechanism for TM production, infiltration, and maintenance that can explain both neuron-dependent tumor progression and also the neural decay associated with GB.
Highlights
Fz1, Frizzled1; GB, Glioma-induced neurodegeneration glioblastoma; GFP, green fluorescent protein; grnd, Grindelwald; Interference hedgehog (Ihog), interference hedgehog; JNK, cJun N-terminal kinase; TM, tumor microtube; TRE-Red fluorescent protein (RFP), RFP fluorescent protein regulated by a transcriptional response element of JNK pathway
In addressing the mechanism by which GB cells infiltrate into the brain and affect the neighboring neurons, we have shown in the Drosophila glioma model that GB cells display a network of TMs that enwrap neurons, accumulate Fz1, and vampirize neuronal Wg causing neurodegeneration, as evidenced by transmission electron microscopy (TEM) images, Wg and Fz1 staining, Wg pathway activity reporters, GFP Reconstitution Across Synaptic Partners (GRASP), and proximity ligation assay (PLA) experiments
In addressing the mechanism by which GB cells infiltrate into the brain, we have shown that GB cells establish a positive feedback loop to promote their TMs expansion, in which the Wg pathway activates JNK in GB cells, and JNK signaling leads to the post-transcriptional up-regulation and accumulation of matrix metalloproteinase (MMP), which facilitate TMs infiltration throughout the brain allowing further Wg depletion from neurons
Summary
The major aim of this study is to better characterize the complex world of interactions between neurons of the brain on one side and tumor cells on the other
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