Abstract
Abstract BACKGROUND In glioblastomas (GBM), the pleiotropic cytokine interleukin-6 (IL-6) upregulates PD-L1 expression. This results in local immunosuppression favorable to tumor progression, and may account for the limited efficacy of immune checkpoint inhibition. Additionally, IL-6 increases synaptogenesis during development, and contributes to neuronal network remodeling following focal brain or spinal cord injury. Therefore, the aim was to determine whether IL-6 contributes to GBM-induced circuit remodeling from a structural and electrophysiological perspective. METHODS In magnetoencephalography (MEG)-based intratumoral regions of High- (HFC) and Low-Functional Connectivity (LFC) from GBM patients, the expression of IL-6 and GAP43 was compared using bulk and single-cell RNA sequencing and immunofluorescence staining in biological replicates (n=44). In mouse postnatal cortical neurons and primary patient-derived GBM cell cocultures, the expression of Ki67, GAP43, tumor connectivity and neuronal activity were monitored after exogenous application of recombinant human IL-6 (rIL-6) or microglial depletion using PLX5622. Results. IL-6 and GAP43 were overexpressed in HFC compared to LFC regions. In neuron-GBM cocultures, the tumour proliferation index was significantly increased by rIL-6 and decreased by PLX5622. Morphologically, the number of microtubes per tumor cell was significantly increased by rIL-6 and decreased by PLX5622. The expression of GAP43 was inconstantly increased by rIL-6, suggesting the regulation of other pathways involved in tumour microtube formation. Multielectrode array recordings showed a significant increase or decrease in the neuronal activity, following the addition of rIL-6 or microglial depletion, respectively. CONCLUSIONS IL-6-signaling increases proliferation, structural and electrophysiological connectivity in gliomas and may contribute to neuronal network hyper-excitability and synchrony. Microglial depletion provided opposite effects. Additional experiments are mandatory to determine whether the effects of IL-6 on GBM cells depend on the presence of microglial cells or not. These data will be critical to design new therapeutic options, likely to improve the oncological and functional outcomes of patients treated for GBM.
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