Oligodendrocyte Progenitor Research Articles

Oligodendroglial heterogeneity in health, disease, and recovery: deeper insights into myelin dynamics.

Decades of research asserted that the oligodendroglial lineage comprises two cell types: oligodendrocyte precursor cells and oligodendrocytes. However, recent studies employing single-cell RNA sequencing techniques have uncovered novel cell states, prompting a revision of the existing terminology. Going forward, the oligodendroglial lineage should be delineated into five distinct cell states: oligodendrocyte precursor cells, committed oligodendrocyte precursor cells, newly formed oligodendrocytes, myelin-forming oligodendrocytes, and mature oligodendrocytes. This new classification system enables a deeper understanding of the oligodendroglia in both physiological and pathological contexts. Adopting this uniform terminology will facilitate comparison and integration of data across studies. This, including the consolidation of findings from various demyelinating models, is essential to better understand the pathogenesis of demyelinating diseases. Additionally, comparing injury models across species with varying regenerative capacities can provide insights that may lead to new therapeutic strategies to overcome remyelination failure. Thus, by standardizing terminology and synthesizing data from diverse studies across different animal models, we can enhance our understanding of myelin pathology in central nervous system disorders such as multiple sclerosis, Alzheimer's disease, and amyotrophic lateral sclerosis, all of which involve oligodendroglial and myelin dysfunction.

Inhibition of histamine receptor 3 alleviates sevoflurane-induced hypomyelination and neurobehavioral deficits

BackgroundInhalational anesthetic sevoflurane can cause myelination damage in developing brain. This study examines the effects of histamine receptor 3 (H3) antagonist thioperamide on sevoflurane-induced hypomyelination and neurobehavioral deficits. MethodsNeonatal C57BL/6 mice were exposed to sevoflurane for consecutive three days and treated with H3 receptor antagonist thioperamide. Myelination was assessed in the hippocampus and corpus callosum. The neurobehavioral functions were also examined. Primary oligodendrocyte progenitor cells (OPCs) were used for in vitro experiments and the underlying mechanism. ResultsInhibition of H3 receptor with thioperamide significantly alleviated sevoflurane-induced impairments in myelination and neurobehavioral functions. In vitro experiments showed that thioperamide reversed the effects of sevoflurane on OPCs migration, proliferation and differentiation into mature oligodendrocytes. Mechanistically, thioperamide improved sevoflurane-induced hypomyelination may through H3 receptor-mediated GSK-3β/β-catenin pathway. ConclusionH3 receptor antogonist thioperamide could protect developing brain against hypomyelination and neurobehavioral deficits after repeated sevoflurane exposure. Therefore H3 receptor is a potential target for preventing anesthetic-induced developmental neurotoxicity.

Induction of Neural Differentiation and Protection by a Novel Slow-Release Nanoparticle Estrogen Construct in a Rat Model of Spinal Cord Injury

Spinal cord injury (SCI) is a complex debilitating condition leading to permanent life-long neurological deficits. Estrogen (E2) treatment is known to be neuroprotectant in SCI. This hormone is highly pleiotropic and has been shown to decrease apoptosis, modulate calcium signaling, regulate growth factor expression, act as an anti-inflammatory, and drive angiogenesis. These beneficial effects were found in our earlier study at the low dose of 10 µg/kg E2 in rats. However, the dose remains non-physiologic, which poses a safety hurdle for clinical use. Thus, we recently devised/constructed a fast release nanoparticle (NP) estrogen embedded (FNP-E2) construct and tested a focal delivery system in a contused SCI rat model which showed protection in the short run. In the current study, we have developed a novel slow-release NP estrogen (SNP-E2) delivery system that shows sustained release of E2 in the injured spinal cord and no systemic exposure in the host. The study of E2 release and kinetics of this SNP-E2 construct in vitro and in vivo supported this claim. Delivery of E2 to the injured spinal cord via this approach reduced inflammation and gliosis, and induced microglial differentiation of M1 to M2 in rats after SCI. Analysis of spinal cord samples showed improved myelination and survival signals (AKT) as demonstrated by western blot analysis. SNP-E2 treatment also induced astrocytic differentiation into neuron-like (MAP2/NeuN) cells, supported the survival of oligodendrocyte precursor cells (OPC), and improved bladder and locomotor function in rats following SCI. These data suggest that this novel delivery strategy of SNP-E2 to the injured spinal cord may provide a safe and effective therapeutic approach to treat individuals suffering from SCI.

Modulation of OPC Mitochondrial Function by Inhibiting USP30 Promotes Their Differentiation.

Multiple lines of evidence indicate that mitochondrial dysfunction occurs in demyelinating diseases, such as multiple sclerosis (MS). Failure of remyelination is thought to be caused in part by a block of oligodendrocyte progenitor cell (OPC) differentiation into oligodendrocytes, which generate myelin sheaths around axons. The process of OPC differentiation requires a substantial amount of energy and high demand for ATP which is supplied through the mitochondria. In this study, we highlight mitochondrial gene expression changes during OPC differentiation in two murine models of remyelination and in human postmortem MS brains. Given these transcriptional alterations, we then investigate whether genetic alteration of USP30, a mitochondrial deubiquitinase, enhances OPC differentiation and myelination. By genetic knockout of USP30, we observe increased OPC differentiation and myelination without affecting OPC proliferation and survival in invitro and exvivo assays. We also find that OPC differentiation is accelerated invivo following focal demyelination in USP30 knockout mice. The promotion of OPC differentiation and myelination observed is associated with increased oxygen consumption rates in USP30 knockout OPCs. Together, these data indicate a role for mitochondrial function and USP30 in OPC differentiation and myelination.

MAZ regulates ferroptosis, apoptosis and differentiation of oligodendrocyte precursor cells

Oligodendrocyte precursor cells (OPCs) respond rapidly to demyelination injury. However, the rescuing effects may be hindered by cell death of OPCs, leading to incomplete remyelination. This study aimed to explore the expression of MYC-associated zinc finger protein (MAZ) in demyelinated mice and the effects of MAZ on cell death form and differentiation of OPCs. Mice received demyelinating agent (cuprizone, CZ) for 5 weeks. Histological staining demonstrated that CZ feeding triggered demyelination in the corpus callosum (CC). Detection of iron content and ferroptosis markers indicated that ferroptosis was inducted in the CC of CZ-treated mice. Notably, we found CZ feeding resulted in a reduction of MAZ expression within the CC. Using CCK-8 assay, detection of iron content, MDA level, GSH level, and ferroptosis markers, lipid ROS detection, and immunofluorescence staining for 4-HNE, we found that knockdown of MAZ facilitated OPC ferroptosis. We also evaluated the susceptibility of MAZ-overexpressing OPCs to ferroptosis inducer, erastin, and demonstrated that MAZ-overexpressing OPCs were resistant to erastin-induced ferroptosis. TUNEL staining and western blot analysis indicated that MAZ knockdown promoted apoptosis of OPCs by inhibiting PI3K/Akt activation. Immunofluorescence staining of MBP indicated that knockdown of MAZ inhibited OPC differentiation. Moreover, we elucidate the mechanism responsible for MAZ’s protective effects on OPC death and differentiation, which may be achieved through transcriptional activation of SOX2. Our findings introduced MAZ as a beneficial modulator of OPC survival and differentiation, and it could serve as a potential therapeutic target for demyelination diseases.

Evolving cell states and oncogenic drivers during the progression of IDH-mutant gliomas.

Isocitrate dehydrogenase (IDH) mutants define a class of gliomas that are initially slow-growing but inevitably progress to fatal disease. To characterize their malignant cell hierarchy, we profiled chromatin accessibility and gene expression across single cells from low-grade and high-grade IDH-mutant gliomas and ascertained their developmental states through a comparison to normal brain cells. We provide evidence that these tumors are initially fueled by slow-cycling oligodendrocyte progenitor cell-like cells. During progression, a more proliferative neural progenitor cell-like population expands, potentially through partial reprogramming of 'permissive' chromatin in progenitors. This transition is accompanied by a switch from methylation-based drivers to genetic ones. In low-grade IDH-mutant tumors or organoids, DNA hypermethylation appears to suppress interferon (IFN) signaling, which is induced by IDH or DNA methyltransferase 1 inhibitors. High-grade tumors frequently lose this hypermethylation and instead acquire genetic alterations that disrupt IFN and other tumor-suppressive programs. Our findings explain how these slow-growing tumors may progress to lethal malignancies and have implications for therapies that target their epigenetic underpinnings.

Identification of biomarkers in Parkinson's disease by comparative transcriptome analysis and WGCNA highlights the role of oligodendrocyte precursor cells.

Parkinson's disease (PD) is an age-related neurodegenerative disease characterized by the death of dopamine neurons in the substantia nigra. A large number of studies have focused on dopamine neurons themselves, but so far, the pathogenesis of PD has not been fully elucidated. Here, we explored the significance of oligodendrocyte precursor cells (OPCs)/oligodendrocytes in the pathogenesis of PD using a bioinformatic approach. WGCNA analysis suggested that abnormal development of oligodendrocytes may play a key role in early PD. To verify the transcriptional dynamics of OPCs/oligodendrocytes, we performed differential analysis, cell trajectory construction, cell communication analysis and hdWGCNA analysis using single-cell data from PD patients. Interestingly, the results indicated that there was overlap between hub genes and differentially expressed genes (DEGs) in OPCs not in oligodendrocytes, suggesting that OPCs may be more sensitive to PD drivers. Then, we used ROC binary analysis model to identify five potential biomarkers, including AGPAT4, DNM3, PPP1R12B, PPP2R2B, and LINC00486. In conclusion, our work highlights the potential role of OPCs in driving PD.

The Mechanistic Link Between Tau-Driven Proteotoxic Stress and Cellular Senescence in Alzheimer's Disease.

In Alzheimer's disease (AD), tau dissociates from microtubules (MTs) due to hyperphosphorylation and misfolding. It is degraded by various mechanisms, including the 20S proteasome, chaperone-mediated autophagy (CMA), 26S proteasome, macroautophagy, and aggrephagy. Neurofibrillary tangles (NFTs) form upon the impairment of aggrephagy, and eventually, the ubiquitin chaperone valosin-containing protein (VCP) and heat shock 70 kDa protein (HSP70) are recruited to the sites of NFTs for the extraction of tau for the ubiquitin-proteasome system (UPS)-mediated degradation. However, the impairment of tau degradation in neurons allows tau to be secreted into the extracellular space. Secreted tau can be monomers, oligomers, and paired helical filaments (PHFs), which are seeding competent pathological tau that can be endocytosed/phagocytosed by healthy neurons, microglia, astrocytes, oligodendrocyte progenitor cells (OPCs), and oligodendrocytes, often causing proteotoxic stress and eventually triggers senescence. Senescent cells secrete various senescence-associated secretory phenotype (SASP) factors, which trigger cellular atrophy, causing decreased brain volume in human AD. However, the molecular mechanisms of proteotoxic stress and cellular senescence are not entirely understood and are an emerging area of research. Therefore, this comprehensive review summarizes pertinent studies that provided evidence for the sequential tau degradation, failure, and the mechanistic link between tau-driven proteotoxic stress and cellular senescence in AD.

A new player in the game: identification of C1ql1 as a novel factor driving OPC differentiation.

Oligodendrocytes (OLGs) are the myelin-producing cells in the central nervous system (CNS). Following injury, these cells are prone to death, leading to demyelination and, eventually, axonal loss and neurodegeneration. Upon injury, the damaged CNS repopulates the lesion with oligodendrocyte precursor cells (OPCs) that consequently mature into OLGs to repair the myelin damage and prevent further axonal loss. In this issue, Altunay etal. identified that complement component 1, q subcomponent-like-1 (C1ql1), a factor known to play a role in neuron-neuron synapses, is also expressed by OPCs and drives their differentiation into OLGs. These data suggest that C1ql1 or other downstream factors could be therapeutic targets in the context of demyelinating disorders in which remyelination fails, such as in multiple sclerosis (MS).

Pharmacogenomic screening identifies and repurposes leucovorin and dyclonine as pro-oligodendrogenic compounds in brain repair

Oligodendrocytes are critical for CNS myelin formation and are involved in preterm-birth brain injury (PBI) and multiple sclerosis (MS), both of which lack effective treatments. We present a pharmacogenomic approach that identifies compounds with potent pro-oligodendrogenic activity, selected through a scoring strategy (OligoScore) based on their modulation of oligodendrogenic and (re)myelination-related transcriptional programs. Through in vitro neural and oligodendrocyte progenitor cell (OPC) cultures, ex vivo cerebellar explants, and in vivo mouse models of PBI and MS, we identify FDA-approved leucovorin and dyclonine as promising candidates. In a neonatal chronic hypoxia mouse model mimicking PBI, both compounds promote neural progenitor cell proliferation and oligodendroglial fate acquisition, with leucovorin further enhancing differentiation. In an adult MS model of focal de/remyelination, they improve lesion repair by promoting OPC differentiation while preserving the OPC pool. Additionally, they shift microglia from a pro-inflammatory to a pro-regenerative profile and enhance myelin debris clearance. These findings support the repurposing of leucovorin and dyclonine for clinical trials targeting myelin disorders, offering potential therapeutic avenues for PBI and MS.

Single nucleus RNA-sequencing reveals transcriptional synchrony across different relationships.

As relationships mature, partners share common goals, improve their ability to work together, and experience coordinated emotions. However, the neural underpinnings responsible for this unique, pair-specific experience remain largely unexplored. Here, we used single nucleus RNA-sequencing to examine the transcriptional landscape of the nucleus accumbens (NAc) in socially monogamous prairie voles in peer or mating-based relationships. We show that, regardless of pairing type, prairie voles exhibit transcriptional synchrony with a partner. Further, we identify genes expressed in oligodendrocyte progenitor cells that are synchronized between partners, correlated with dyadic behavior, and sensitive to partner separation. Together, our data indicate that the pair-specific social environment profoundly shapes transcription in the NAc. This provides a potential biological mechanism by which shared social experience reinforces and strengthens relationships.

TMET-01. LIPID METABOLIC PROGRAMS DEFINE GLIOMA STATE IDENTITY, PLASTICITY AND DEPENDENCIES

Abstract Gliomas are lethal malignancies comprised of heterogeneous and dynamic subpopulations of cell states resembling normal neurodevelopmental cell types (radial glia (RG), oligodendrocyte progenitor cell (OPC), neuron progenitor cell (NPC), neuron, etc). While both intrinsic (genetics) and extrinsic (brain environment) cues are coupled to glioma state identity, the functional programs governing glioma cell state and plasticity are unknown. Here we performed a multi-omic interrogation of a large library (n=392) of glioma patient tumors, in vivo orthotopic xenografts and in vitro gliomasphere cultures. Comparisons of matched glioma samples across environments revealed the non-native in vitro environment constrains glioma state diversity specifically enriching for stem-like glioma cell states (RG, immune, vascular). This enrichment was linked to lipid metabolic flexibility, enabling tumors enriched for stem-like states to adapt to various tumor microenvironments. By contrast, “lineage-committed” cell states (OPC, NPC, and neuron) demonstrate restricted lipid metabolism, consequently having a dependence on lipid scavenging from the brain microenvironment for survival. These results connect intra-tumoral heterogeneity and plasticity of glioma to lipid metabolism, leveraging the functional diversity of cellular states to reveal potential therapeutic opportunities.

BIOM-21. SMALL EXTRACELLULAR VESICLES AS A NOVEL LIQUID BIOPSY APPROACH FOR GLIOBLASTOMA

Abstract Glioblastoma (GBM) remains the most common and aggressive primary malignant brain tumor, with limited treatment options and poor overall survival. Diagnosis, prognosis, and assessment of treatment effectiveness are hampered by the lack of sensitive, tumor-specific, non-invasive blood-based assays which could be followed serially. Small extracellular vesicles (sEV) are nano-sized (≤200 nm) membrane-bound bodies secreted by all cells, encapsulating cargo reflective of their parent cells. sEVs have emerged as promising molecular disease indicators. Here, we report the feasibility of isolating glioma-specific sEV (sEVglioma) from plasma and characterizing them for GBM-specific molecular biomarkers. Plasma samples were collected from 31 glioma patients (grades 3 and 4 GBM, grades 2 and 3 astrocytoma) and 9 healthy individuals. Total sEVs (TE) were isolated from plasma by a modified precipitation (ExoQuick™) method, followed by immunoprecipitation to isolate sEVglioma employing surface markers targeting the cellular origin of gliomas, including astrocyte (GLAST and EAAT2), oligodendrocyte precursor cell (OSP and MOG), and neural stem cell (CD133). The average size of sEVglioma was less than 200 nm. Importantly, compared to TE, sEVglioma showed significant enrichment for glioma-specific biomarkers such as ephrin type-A receptor 2 (14.7-fold), tenascin-C (22.7-fold), and glial fibrillary acidic protein (8.4-fold). Similarly, sEVglioma demonstrated higher expression of the GBM biomarker EGFRvIII (3.6-fold). These results were confirmed by confocal microscopy. Interestingly, the expression of specific miRNAs (miR-9a-5p, miR-16-5p, miR-21-5p) in sEVglioma was higher in glioma patients with shorter survival (<12 months) compared to longer survival (>20 months). Lastly, we successfully detected the existence of wild-type IDH1 and absence of mutated IDH1 R132H in sEVglioma from GBM patients, validated with cell line experiments. In conclusion, we present a novel liquid biopsy approach for isolating sEVglioma from blood, providing valuable molecular and genetic information. This approach promises early detection, potential to distinguish pseudo-progression, and assessment of treatment effectiveness with remarkable precision.

CNSC-43. NEUROTRANSMITTER DEPENDENCY UNDERLIES TUMOR GROWTH IN HUMANIZED PEDIATRIC LOW-GRADE GLIOMA MODELS

Abstract Brain tumors arise in close association with neurons, suggesting that these non-neoplastic cells may be critical stromal drivers of brain tumor initiation and growth. Previously, we have shown that murine low-grade optic glioma formation and progression in the setting of Neurofibromatosis type 1 (NF1) is dictated by neurons and neuronal activity. In these studies, these neuronal dependencies reflected neuronal activity-driven enzymatic cleavage of a growth factor (neuroligin-3) from oligodendrocyte precursors cells (tumor initiation) or neuronal production of a paracrine factor to stimulate T cell support of optic glioma growth (tumor progression). Since neurons typically communicate with other neurons through neurotransmitters, we sought to explore the possibility that neurotransmitters operate to modulate low-grade glioma growth using humanized mouse models of pilocytic astrocytoma (PA). Leveraging single cell RNA sequencing of three independent sets of pediatric PAs, we identified neurotransmitter pathway enrichment in the tumor cells. This neurotransmitter pathway enrichment reflected aberrant expression of specific neurotransmitter receptors, which we confirmed in three independently generated PA tissue microarrays and in five distinct primary PA cell lines grown in vitro. Moreover, this aberrant neurotransmitter receptor expression established differential neurotransmitter PA growth dependencies in vitro. Importantly, interruption of neurotransmitter signaling in human PA xenografts attenuated tumor growth and ERK activation in Rag1-/- mice in vivo. Finally, we discovered crosstalk between neurotransmitter receptor and receptor tyrosine kinase signaling that revealed another target for therapeutic inhibition. Taken together, these findings elucidate a previously unknown neurotransmitter PA growth dependency amenable to therapeutic targeting.

EXTH-36. SHIFTING FROM EPIGENETICS TO THE EPICHAPEROME: HSP90 AS A THERAPEUTIC TARGET FOR H3K27M DIFFUSE MIDLINE GLIOMA (DMG)

Abstract Diffuse midline gliomas (DMG) are lethal pediatric brain tumours, the majority of which have truncal histone (H3K27M) mutations. To investigate cellular vulnerabilities of histone mutant cells we generated oligodendrocyte precursor cells (OPC) isogenic cell lines and performed a high-throughput synthetic lethality drug screen (2400 small molecules). This identified HSP90 inhibitors as a potential therapeutic option for H3K27M DMG. We hypothesize that epichaperome HSP90 inhibitors present a new therapeutic approach targeting multiple aspects of DMG oncogenicity. HSP90 inhibitors, PU-H71 and PU-HZ151, effectively reduced viability of DMG lines in vitro in the low nanomolar range and result in caspase mediated cell death (p<0.0001 1 uM, p<0.05 500 nM, n=6). PU-HZ151 treated mice had a survival benefit vs control mice injected with orthotopic DMG xenografts (p=0.0012). In diseased cells, activated HSP90 forms a scaffold defined as the epichaperome. To unravel the molecular mechanisms of epichaperome inhibition in DMG cells, we performed epichaperomics – a pull down of epichaperome HSP90 with co-chaperones and clients followed by LC-MS/MS analysis. We identified an interactome enriched with proteins involved in cell cycling, RAS/MAPK signaling, immune response, and metabolic reprogramming. Proteomic and phosphoproteomic profiling of DMG cells post-PU-HZ151 treatment provided insights into the direct downstream effects critical for maintaining DMG viability, identified functional vulnerabilities primed by epichaperome inhibition including downregulation of cell cycling, and upregulation of HSF1 mediated cellular response to stress. In silico screening and kinase enrichment analysis highlighted CSNK2A1 as a top active kinase in DMG cells following PU-HZ151 treatment. To enhance the therapeutic efficacy of epichaperome inhibition, we employed the CSNK2A1 kinase inhibitor, CX-4945, in combination with PU-HZ151, resulting in the effective ablation of DMG patient cells in vitro. These data highlight the potential of epichaperome inhibitors for DMG treatment, as they target multiple DMG oncogenic pathways.

CSIG-24. BRAIN MICROENVIRONMENT-DEPENDENT NEURODEVELOPMENTAL LINEAGE PLASTICITY PROMOTES ADAPTATION TO ONCOGENE INHIBITION IN MALIGNANT GLIOMAS

Abstract Phenotypic plasticity drives non-genetic tumor adaptation in response to various microenvironmental and therapeutic pressures, consequently promoting tumor heterogeneity and progression. In malignant gliomas, the intrinsic and extrinsic mechanisms underlying phenotypic lineage plasticity and its contribution to drug resistance remain unclear. The epidermal growth factor receptor (EGFR) is frequently altered in glioma and serves as a critical regulator of normal radial glia (RG) cells – multipotent progenitors that give rise to cortical neurons and glia in the developing brain. Here, through interrogation of a large panel of diverse glioblastoma (GBM) patient-derived gliomaspheres and orthotopic xenografts, we find that enrichment of RG-like cells is significantly correlated with responses to pharmacological ablation of EGFR, highlighting EGFR as a crucial lineage survival factor for a population of malignant RG-like cells in GBM. Single-cell RNA sequencing and quantitative proteomics reveal that adaptation to EGFR inhibition is linked to a temporal contraction in RG-like cells and concomitant increase in lineage-restricted neuronal and oligodendrocyte progenitor (NPC/OPC)-like states exclusively in the orthotopic brain environment. This lineage transition is coupled to heightened RAS signaling gene expression programs and sustained activation of MAPK signaling, despite robust and durable inhibition of EGFR activation. Furthermore, constitutively active MEK – but not AKT – is sufficient to rescue tumor proliferation under EGFRi, suggesting that the brain microenvironment modulates RAS-MAPK oncogenic signaling to drive lineage transitions following EGFR blockade. Collectively, these results highlight a critical link between oncogenic signaling and neurodevelopmental lineage plasticity in malignant gliomas, presenting a compelling therapeutic opportunity to block tumor cell state transitions for more durable tumor responses in the native glioma tumor microenvironment.

TMOD-05. GLIOMA-ASSOCIATED OLIGODENDROCYTE PROGENITOR CELLS’ DYNAMIC PATTERNS SUGGEST FUNCTIONAL ADAPTATIONS DURING GLIOMA PROGRESSION IN A UNIQUE MOUSE MODEL

Abstract Gliomas account for more than one-third of brain tumors in children, with high fatality rate despite aggressive adjuvant treatment. Two-thirds of survivors suffer from health conditions due to the toxicity of conventional therapies. Notably, gliomas with the BRAFV600E mutation, occurring in ~20% of all glioma cases, are difficult to treat and have a high risk for progression, especially when combined with CDKN2A deletion. The mechanisms for glioma progression remain unclear and unraveling them could lead to therapies that inhibit glioma progression, preventing high-grade gliomas. Objectives: To gain mechanistic insights into glioma progression and exploit therapeutically for preventing progression. We developed two novel mouse models for BRAFV600E mutant progressive gliomas – one at high genetic risk for progression and one at intermediate genetic risk for progression. Expression of genetic alterations were induced by injecting compound transgenic mice with adenovirus-Cre. Our new mouse models therefore more faithfully recapitulated the genetic changes accompanying glioma formation and progression from low- to high-grade than earlier mouse models which used the RCAS system to overexpress the oncogene (PMCID: PMC11112369 ). Glioma formation was followed non-invasively by magnetic resonance imaging. Single cell RNA sequencing and spatial transcriptomics were performed and immunofluorescence was used for validation (PMCID: PMC10619673 ). We present new data showing that animal subject survival is significantly shorter in the high risk model than in the low risk model. Our two models with distinct latency can be used for preclinical studies and studies of the changes associated with progression, including in the glioma microenvironment. Analyses revealed temporal, functional, and spatial changes in glioma-associated oligodendrocyte progenitor cells (GA-OPCs) at distinct stages (initiation, expansion, progression) and grades. Our findings that GA-OPCs closely interact with glioma cells and their morphological transformation as gliomas progress, suggest changing functions, including potential roles in phagocytosis and immunomodulation. Understanding the unclear role of glioma microenvironment OPCs in promoting glioma progression could reveal an Achilles heel for targeted therapies.

EPCO-26. LONGITUDINAL SINGLE-CELL ANALYSES IDENTIFY DRIVERS OF GENETIC, EPIGENOMIC, AND CELLULAR EVOLUTION IN IDH-MUTANT GLIOMA

Abstract Despite standard treatment, IDH-mutant gliomas inevitably recur. Previous studies suggest that therapeutic resistance may result from a combination of intratumoral cellular heterogeneity, epigenetic evolution, and acquired genetic alterations. However, how these multilayered molecular features interact to influence the evolutionary paths of IDH-mutant gliomas remains incompletely understood. To chart this evolution, 75 glioma samples were longitudinally collected from 35 patients (n = 13 oligodendroglioma, n = 22 astrocytoma) and profiled using single nucleus RNA sequencing, ATAC sequencing, and bulk DNA sequencing. Analysis of 331,016 nuclei (snRNA) revealed eight tumor microenvironment cell types and five pan-IDH-mutant malignant cellular states. The malignant states were distributed along a cellular hierarchy of stem-like populations (neural progenitor cell-like, oligodendrocyte progenitor cell-like, and undifferentiated) and more differentiated populations (mesenchymal-like and astrocyte-like) with cycling cells enriched in the stem-like populations. Joint open chromatin accessibility data (snATAC) was available for a subset of malignant cells (71,088 nuclei) and state-specific differentially accessible peaks supported that these states are epigenetically encoded. Across both subtypes, higher tumor grade was associated with reduced malignant cell differentiation and increased cycling populations. Between the two time points, we identified that there was a longitudinal increase in the cycling, undifferentiated, and mesenchymal-like populations with a corresponding decrease in the astrocyte-like population. Longitudinal genetic analysis revealed that 19 of 35 tumors acquired at least one of the following genetic alterations: treatment-associated hypermutation, cell cycle alteration, or large changes in copy number alterations. Importantly, tumors that acquired these key genetic alterations demonstrated significant shifts towards reduced differentiation and increased cycling populations while those tumors that did not had more stable malignant profiles. Collectively, our results suggest a common cellular hierarchy across IDH-mutant gliomas with a shift towards reduced differentiation, increased cycling populations during disease progression that is driven by acquired genetic alterations.

DDDR-26. IDENTIFICATION OF MODULATORS OF IDH INHIBITOR SENSITIVITY INIDH-MUTATED DIFFUSE GLIOMAS

Abstract Driver mutations in IDH1 and IDH2 characterize a substantial proportion of lower-grade diffuse gliomas in adults. Mutated IDH molecules cause the accumulation of D-2-hydroxyglutarate (D-2-HG), which perturbs many cellular functions, including metabolism, epigenetic regulation, and the ability to differentiate. This is notably associated with DNA and histone hyper-methylation. Recently, the newly developed IDH inhibitor, vorasidenib, was shown to delay tumor progression and the need for additional treatment in the groundbreaking INDIGO clinical trial. Nevertheless, the responses to vorasidenib were variable between patients, and so far have been established only for less aggressive disease. In addition, it is unclear to what extent vorasidenib can cause tumor regression. This highlights the need to identify molecules and pathways that control IDH inhibitor sensitivity. Towards this goal, we generated a new mouse model that combines Idh1R132H and Trp53 loss-of-function, targeted to oligodendrocyte progenitors. All the mutant mice develop diffuse gliomas that recapitulate the cardinal features of the corresponding human disease. We established multiple cell lines from these tumors, which retained expression of mutant IDH. The cells robustly produced D-2-HG, which was concentration-dependently suppressed by vorasidenib. Accordingly, vorasidenib could lower DNA methylation, and induce the expression of mature glial cell markers. To identify determinants of vorasidenib sensitivity, we performed genome-wide loss-of-function CRISPR/Cas9 functional genomics screens. In those experiments, targeting genes associated with astrocyte differentiation or Notch signaling enhanced cell fitness in the presence of vorasidenib, consistent with the anticipated effects of the drug on inducing cell differentiation. Conversely, vorasidenib-treated cells were more sensitive to the loss of regulators of cell growth and metabolism, and of some epigenetic regulators. These studies point to strategies that may enhance the efficacy of IDH inhibitors for the treatment of IDH mutated gliomas.

Heterogeneity in oligodendrocyte precursor cell proliferation is dynamic and driven by passive bioelectrical properties

Oligodendrocyte precursor cells (OPCs) generate myelinating oligodendrocytes and are the main proliferative cells in the adult central nervous system. OPCs are a heterogeneous population, with proliferation and differentiation capacity varying with brain region and age. We demonstrate that during early postnatal maturation, cortical, but not callosal, OPCs begin to show altered passive bioelectrical properties, particularly increased inward potassium (K+) conductance, which correlates with G1 cell cycle stage and affects their proliferation potential. Neuronal activity-evoked transient K+ currents in OPCs with high inward K+ conductance potentially release OPCs from cell cycle arrest. Eventually, OPCs in all regions acquire high inward K+ conductance, the magnitude of which may underlie differences in OPC proliferation between regions, with cells being pushed into a dormant state as they acquire high inward K+ conductance and released from dormancy by synchronous neuronal activity. Age-related accumulation of OPCs with high inward K+ conductance might contribute to differentiation failure.