CNSC-43. TARGETING NEURONAL EXCITABILITY FOR NF1 LOW-GRADE GLIOMA THERAPY

Abstract

Abstract While neuronal activity has previously been implicated in malignant glioma growth control, we recently demonstrated that neuron excitability can also regulate low-grade (optic) glioma initiation and progression. In this prior study, we showed that NF1 germline mutation-dependent neuronal excitability sustains optic glioma growth through HCN channel-mediated midkine activation of a T cell-microglia stromal circuit. Relevant to clinical translation, lamotrigine modulation of HCN channel function reduced neuronal hyperexcitability, midkine production and optic glioma (OPG) growth. To establish an obligate role for neuronal activity and midkine (Mdk) production in OPG growth, we leveraged a series of unique genetically engineered mouse models. First, we demonstrate that midkine is necessary for gliomagenesis, as Nf1-OPG; Mdk-/- mice do not develop tumors and have restored retinal pathology, as evidenced by increased retinal ganglion cell (RGC) numbers and retinal nerve fiber layer thickness. Second, we show that midkine production and neuronal hyperactivity are interdependent, such that only tumor-associated germline Nf1 mutations result in increased RGC excitability and midkine production, whereas those mutations that do not cause optic gliomas lack RGC hyperexcitability or elevated midkine expression. Third, lamotrigine treatment both during and after Nf1-OPG development attenuates midkine levels and tumor proliferation. Moreover, this anti-tumoral effect is durable for months after the cessation of treatment. Fourth, oral treatment of Nf1-OPG-bearing mice with clinically relevant doses of lamotrigine (2.5-7.5mg/kg/day) during OPG development blocks tumor formation. Together, these data establish midkine and neuronal hyperexcitability as key drivers of Nf1 optic glioma growth, relevant to planned clinical trials of this anti-seizure medication for children with NF1-OPG.