Abstract

Abstract Glioblastomas (GBMs) are the most aggressive brain tumors. GBM cells form extensive tumoral networks to communicate with each other and with surrounding neurons. Neuronal activity promotes GBM cell proliferation by secreting protumorigenic factors and triggering neuronal-activity-dependent Ca2+ transients, which are persisted and transmitted via tumor networks to promote overall tumor growth and therapy resistance. While how these processes are regulated is largely unknown. Here we show the GBM networks and Ca2+ transients are regulated by a voltage-gated potassium channel complex comprised of EAG2 and Kvβ2. GBM cells selectively overexpress Kvβ2 isoform 4 to facilitate tumor-specific Kvβ2-EAG2 interaction, which regulates neuron-GBM contact-dependent localization of EAG2. Rationally designed interfering peptide K90-114TAT blocks EAG2-Kvβ2 interaction, leading to reduced tumor cell proliferation, increased apoptosis, and prolonged survival of patient-derived xenograft mouse models with no evidence of toxicity to normal tissue. Single-cell RNA sequencing revealed a subgroup of GBM cells is highly sensitive to K90-114TAT treatment. These cells exhibit neuronal signatures and are highly associated with TMZ resistance and worse prognosis. In accordance with the notion, we found neurons promote TMZ resistance of GBM cells, which is regulated by the EAG2-Kvβ2 complex. Treating TMZ-resistant GBM xenograft mice with K90-114TAT yielded significant tumor burden reduction and prolonged survival. Together, our findings revealed the EAG2-Kvβ2 channel complex as a key regulator of neuron promoted GBM progression and designed an interfering peptide with anti-GBM efficacy and low general toxicity, which may have significant clinical impact.

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