DDRE-22. DISRUPTING REDOX BALANCE VIA THE TETRAHYDROBIOPTERIN PATHWAY IN GLIOBLASTOMA

Aberrant redox statuses are observed in glioblastoma (GBM), and we previously identified GTP cyclohydrolase I (GCH1) to be a redox regulator upregulated in brain tumor initiating cells (BTICs). GCH1 is a rate-limiting enzyme in the de novo synthesis of tetrahydrobiopterin (BH4), a cofactor that produces catecholamine precursors and nitric oxide (NO) and, once used, becomes 7,8-dihydrobiopterin (BH2). Regeneration of BH2 into BH4 by dihydrofolate reductase (DHFR) helps to maintain proper BH4/BH2 ratios for redox balance. Although the BH4 pathway has traditionally been studied in the vasculature system for its regulation of NO, our previous work and that of others suggests the GCH1/BH4 pathway plays a critical redox role including in neoplastic cells. In silico analysis of primary and recurrent gliomas indicate high expression of BH4 related enzymes that correlated with worse patient survival in both primary and recurrent gliomas. The observed elevation of the BH4 pathway not only emphasizes its importance, but a therapeutic opportunity for improving survival in glioma patients. By repurposing FDA approved drugs known to cross the blood brain barrier and previously suggested as anti-glioma therapies, combining inhibitors for the de novo synthesis (sulfasalazine) and regeneration (pyrimethamine) of BH4 could prove to be an effective strategy for targeting the GCH1/BH4 through redox disruption. Preliminary data BTICs isolated from patient derived xenografts (PDXs) indicated reduced viability when treated with sulfasalazine (SASP) and pyrimethamine (PYR). Furthermore, we observed lower/depleted levels of BH4 relative to BH2 when BTICs were treated with SASP and PYR. Lastly, there is an increase in mitochondrial ROS upon SASP and PYR treatment, suggesting dysregulated redox states. Importantly, temozolomide resistant GBM cells remained sensitive to SASP and PYR. Taken together, our preliminary data suggests the plausibility of targeting the GCH1/BH4 pathway with SASP and PYR to disrupt redox balance in glioma through the depletion of BH4.

DDEL-08. CONVECTION-ENHANCED DELIVERY OF NIMUSTINE HYDROCHLORIDE (ACNU) AGAINST PEDIATRIC DIFFUSE INTRINSIC PONTINE GLIOMAS

Diffuse intrinsic pontine gliomas (DIPGs) are amongst the most challenging tumors to treat. Surgery is not an option, the effects of radiation therapy are temporary, and no chemotherapeutic agent has demonstrated significant efficacy. Intracerebral infusion technique of convection-enhanced delivery (CED) for patients with brain tumors could offer a novel approach for effective chemotherapy. We have been working to develop an effective chemotherapy using nimustine hydrochloride (ACNU) with this drug delivery method. After several studies targeting supratentorial recurrent malignant gliomas and recurrent gliomas affecting brainstem, we conducted phase 1 study to evaluate the safety of combination of convection-enhanced delivery of nimustine hydrochloride and systemic temozolomide against recurrent gliomas affecting brainstem. In this study, we demonstrated the safety and feasibility of CED of ACNU as well as real time monitoring of drug distribution by mixing ACNU with contrast agent; Gd-DOTA. We also defined the maximum tolerable concentration in this study and proceeded to phase 2 trial against recurrent gliomas affecting brain stem. However, these trials revealed the difficulty of treating pediatric DIPG at the time of recurrence. Therefore, we decided to treat pediatric DIPG cases at their initial diagnosis in the subsequent study. Aiming at obtaining Shonin approval both for intraparenchymal infusion catheter and drug to infuse into brain parenchyma, we are now conducting Phase II physician-led trial against initially diagnosed pediatric DIPG cases.

IMMU-35. TRANSCRIPTIONALLY DEFINED IMMUNE CONTEXTURE IN HUMAN GLIOMAS AT SINGLE-CELL RESOLUTION

The brain tumor immune microenvironment (TIME) continuously evolves during glioma progression and a comprehensive understanding of the glioma-centric immune cell repertoire beyond a priori cell types and/or states is uncharted. Consequently, we performed single-cell RNA-sequencing on ~123,000 tumor-derived immune cells from 17-pathologically stratified, IDH (isocitrate dehydrogenase)-differential primary, recurrent human gliomas, and non-glioma brains. Our analysis delineated predominant 34-myeloid cell clusters (~75%) over 28-lymphoid cell clusters (~25%) reflecting enormous heterogeneity within and across gliomas. The glioma immune diversity spanned functionally imprinted phagocytic, antigen-presenting, hypoxia, angiogenesis and, tumoricidal myeloid to classical cytotoxic lymphoid subpopulations. Specifically, IDH-mutant gliomas were enriched for brain-resident microglial subpopulations in contrast to enhanced bone barrow-derived infiltrates in IDH-wild type, especially in a recurrent setting. Microglia attrition in IDH-wild type -primary and -recurrent gliomas were concomitant with invading monocyte-derived cells with semblance to dendritic cell and macrophage/microglia like transcriptomic features. Additionally, microglial functional diversification was noted with disease severity and mostly converged to inflammatory states in IDH-wild type recurrent gliomas. Beyond dendritic cells, multiple antigen-presenting cellular states expanded with glioma severity especially in IDH-wild type primary and recurrent- gliomas. Furthermore, we noted differential microglia and dendritic cell inherent antigen presentation axis viz, osteopontin, and classical HLAs in IDH subtypes and, glioma-wide non-PD1 checkpoints associations in T cells like Galectin9 and Tim-3. As a general utility, our immune cell deconvolution approach with single-cell-matched bulk RNA sequencing data faithfully resolved 58-cell states which provides glioma specific immune reference for digital cytometry application to genomics datasets. Resultantly, we identified prognosticator immune cell-signatures from TCGA cohorts as one of many potential immune responsiveness applications of the curated signatures for basic and translational immune-genomics efforts. Thus, we not only provide an unprecedented insight of glioma TIME but also present an immune data resource that can be exploited to guide pragmatic glioma immunotherapy designs.

PATH-08. EVALUATION OF MISMATCH REPAIR GENE EXPRESSION BY IMMUNOHISTOCHEMISTRY MAY DETECT EARLY PHASE OF MMR DEFICIENCY IN RECURRENT GLIOMAS

BACKGROUND Mismatch Repair (MMR) Deficiency is common in recurrent gliomas from IDH-mutant and IDH-wild-type tumors. Emergence of MMR deficit is strongly associated with the chemotherapy using TMZ, and it is considered to be a key mechanism of acquiring resistance to TMZ. Several studies showed MMR protein loss detected by immunohistochemistry was well concordant with molecular genetics sequencing data, and sometimes even more reliable in detecting MMR functional deficit. Here we evaluated Mismatch Repair protein expression by immunohistrochemistry for the pairs of primary and recurrent gliomas. METHODS We investigated the expression of 4 MMR proteins (MLH1/MSH2/MSH6/PMS2) in 37 cases of paired primary-recurrent gliomas (7 grade II & III astrocytomas, 16 grade II & III oligodendrogliomas, and 14 glioblastomas). Clinical information including history of chemo-radiotherapy after primary surgery were collected retrospectively. RESULTS Except for one case of GBM, all primary tumors retained 4 MMR proteins. 10 of 37 recurrent tumors lost one or more MMR protein expression (4 GBM 3 astrocytoma, 3 oligodendroglioma), including one case in which primary tumor already had MSH2/MSH6 loss. 2 recurrent GBM lost MMR protein expression homogenously, while in other 8 tumors, the patterns of MMR protein loss were heterogenous. 8 of 10 tumors that lost MMR protein expression were recurrence after TMZ treatment. CONCLUSION Although the interpretation of the heterogenous loss of MMR protein expression is somewhat difficult, the immunohistochemical evaluation of MMR proteins appears to be feasible, and may be able to detect early phase of MMR deficiency and the rise of hypermutator phenotype.