Biom-41. citrullinated histone h3 elisa reveals netosis as a source of prognostic circulating cell-free dna in glioblastoma

Abstract BACKGROUND We have previously shown that higher concentrations of plasma cell free DNA (cfDNA), both at baseline and following chemoradiotherapy, are associated with worse survival in GBM. Because only scant amounts of GBM-derived cfDNA shed into the peripheral circulation, we sought to determine the predominant source of prognostic plasma cfDNA in these patients and hypothesized that this may help unravel the mechanism underlying the association of high cfDNA and survival. METHODS Plasma was obtained for 126 patients prior to resection of newly diagnosed GBM. A subset of 46 plasma samples had ccfDNA extracted, enzymatically converted, whole genome amplified, and analyzed on the Illumina Epic array for deconvolution of cfDNA methylation patterns. Based on these results demonstrating neutrophils as the predominant cfDNA source, we performed ELISA for citrullinated-histone 3 (citH3) in plasma from 113 of the patients as a specific marker of NETosis, a pro-tumor process of programmed neutrophil cell death during which DNA is released in web-like structures called neutrophil extracellular traps (NETs). RESULTS Deconvolution of cfDNA methylation patterns revealed that neutrophils were the dominant source of cfDNA (median percentage of cfDNA derived from neutrophils = 46% , range 17-67%) and correlated with baseline plasma cfDNA concentration (n = 46, r = 0.35, p = 0.017). Additionally, cfDNA concentration was significantly correlated with the concentration of citH3 (n = 113, r = 0.60, p < 0.0001), which was higher in GBM patients compared to 26 healthy controls (p < 0.0001). CONCLUSION Our findings suggest that NETosis may be the dominant source of plasma cfDNA, which we have previously shown to be highly prognostic in patients with GBM. Additional studies interrogating the tumor microenvironment for NETosis in GBM tumors are ongoing. These results lay the foundation for further exploration of NETosis as a therapeutic target and underscore the emerging importance of neutrophil biology in GBM.