Patient-derived Xenograft Research Articles

PATH-68. THE CLINICAL AND PROTEOMIC CLASSIFICATION FOR THE PRECISION TREATMENT STRATEGY OF CHORDOMA

Abstract Chordoma is a rare and heterogeneous mesenchymal malignancy, with distinct clinical and biological behaviors. Till now, its comprehensive clinical-molecular characteristics and accurate molecular classification remain obscure, leading to numerous diagnostic and therapeutic challenges. In this research, we enroll a large cohort of chordoma (102 patients) and describe their clinical, imageological and histopathological features. Through tandem mass tag-based proteomic analysis and nonnegative matrix factorization clustering, we classify chordoma into the following three molecular subtypes: bone microenvironment dominant, mesenchymal derived, and mesenchymal to epithelial transition mediated pattern. The three subtypes exhibit discrete clinical prognosis and distinct biological attributes of osteoclastogenesis and immunogenicity, oxidative phosphorylation, and receptor tyrosine kinase activation, suggesting targeted therapeutic strategies of Denosumab, S-Gboxin and Anlotinib, respectively. Notably, these approaches demonstrate positive treatment outcomes for each subtype in vivo and in vitro, as well as in patient-derived xenograft models. Altogether, this work sheds light on the clinical-proteomic characteristics of chordoma that deepens our understanding of this rare disease and provides candidate precision treatment strategy for chordoma according to molecular classification, underscoring their potential for clinical application.

EPCO-01. FROM HIERARCHY TO GEOGRAPHY: MULTI-CLONES DRIVE THE CELLULAR DIVERSITY AND EVOLUTION OF HUMAN MEDULLOBLASTOMA

Abstract We’ve curated a comprehensive multi-omics database of medulloblastoma (MB) serving as a resource to understand spatiotemporal organization and guide therapeutic strategies. Herein, our analysis encompasses single-nucleus transcriptome (n = 51), chromatin accessibility (n = 46), and spatial transcriptomic profiles (n = 31) from human MB samples and patient-derived xenograft lines spanning four subgroups, augmented by bulk RNA (n = 322), whole-genome short-sequencing (n = 279), and bisulfite sequencing (n = 300) from matched samples. We delineate the malignant cellular hierarchy, identifying MB cancer stem-like cells (MB-CSCs), cycling cells, and more differentiated populations. Gene signatures of different cell subpopulations strongly correlate to clinical outcomes, while spatial character of patient-derived materials emphasizes the geographically heterogeneous nature of MB. Examination of somatic copy number variants (CNVs) and transcriptional signatures at single-nucleus resolution reveals geographically defined subclones harboring distinct CNVs, suggesting a competitive agglomeration of co-existing multi-clones for MB. Alongside the trajectorial transition, we observe distinct chromosomal alterations in apical MB-CSCs compared to more differentiated cells, indicative of extensive subclone-primed spatiotemporal evolution. Further analysis of reagent-gene interactions of subclonal lineages contributes to predicting the druggable candidates for treatment optimization. Integration of spatial architecture data highlights the recapitulation of subclone-determined niches through colocation with identified malignant lineages and their own inflammatory or fibrotic adaptions. Taken together, this comprehensive database, comprising five or six kinds of datatypes on the same MB cases, facilitates combinatorial analyses across different genomic modalities, offering genetic and geographic insights into therapeutic advancements.

CSIG-13. TARGETING GENETIC DEPENDENCIES EXPOSES DIFFUSE MIDLINE GLIOMA CELL OF ORIGIN VULNERABILITIES

Abstract Diffuse midline glioma (DMG), including diffuse intrinsic pontine glioma (DIPG), are uniformly fatal brain cancers affecting children, adolescents, and young adults. These tumors are characterized by ‘oncohistone’ mutations in histone H3 genes (H3F3A, HIST1H3B, HIST1H3C), resulting in the substitution of lysine 27 to methionine (H3K27M), resulting in dominant negative hypomethylation at lysine 27 (H3K27) and a global loss of gene silencing. CRISPR-Cas9 loss-of-function gene deletion screens identified mutation-independent dependencies on PIK3CA and MTOR genes for tumor growth and proliferation, highlighting a targetable molecular dependency across DMG patient-derived models (n=38). However, systemic PI3K/mTOR inhibition increased blood glucose and insulin levels, promoting hyperinsulinemia/hyperglycemia and reduced efficacy in vivo. To exploit genetic dependencies while maintaining compliance and therapeutic benefit, we optimized combinations of clinically relevant PI3K inhibitors (paxalisib, GCT007, everolimus) with the antiglycemic drug metformin to restore glucose homeostasis and decrease DMG insulin receptor activity in vivo, extending the survival of DIPG xenograft models. Phosphoproteomic profiling of DIPG models treated with PI3K/mTOR inhibitors promoted calcium-activated PKC signaling. The brain-penetrant PKC inhibitor enzastaurin in combination with paxalisib, synergistically extended the survival of DIPG xenograft models, including those mimicking disease progression, with further benefits potentiated using metformin in a multimodality approach. Combined PI3K-PKC inhibition in vivo promoted differentiation of OPC-like DMG to more OC-like cells, enhancing PDGFRA-JAK/STAT proinflammatory signaling, showing features of demyelination and MHC-II+ antigen expression, including PD1/PDL1. In parallel, combined PI3K/mTOR and PDGFRA inhibition using paxalisib and avapritinib synergistically extended the survival of patient-derived xenograft models, showing the preclinical relevance of simultaneously targeting these vulnerabilities. Together, we reveal that therapeutic inhibition of PI3K/mTOR and compensatory PKC signaling, while mitigating side effects with metformin, altered the chromatin architecture, leading to cellular differentiation and opening the door for clinically relevant checkpoint inhibitors. This combination strategy addresses DMG genetic dependencies, cellular and systemic responses to precision therapies, while harnessing the immune system for potential clinical translation.

TMIC-36. EVALUATING PHARMACOLOGICAL INHIBITION OF LSD1 IN MODELS OF DIFFUSE MIDLINE GLIOMA AND EFFECTS ON IMMUNE MICROENVIRONMENT SIGNALING

Abstract BACKGROUND Diffuse midline glioma (DMG) is the leading cause of death for pediatric brain tumor patients. DMG is remarkably immunologically senescent, even in comparison to other “immune-cold” tumors like adult glioblastoma. Lysine specific demethylase-1 (LSD1) is a histone demethylase exerting context-specific mechanisms of gene repression and activation and can be inhibited pharmacologically. We found LSD1 regulates the expression of inflammatory cytokines such as Interleukin 18 (IL18) and immune signaling receptors in DMG. Here, we investigated whether IL18 is transcriptionally regulated by LSD1 in vitro and in vivo using clinically relevant small molecule inhibitors. METHODS LSD1 binding to the IL-18 promoter was evaluated using chromatin immunoprecipitation. Transcript and protein expression using qRT-PCR and western blotting assessed the impact of LSD1 inhibition on IL18-related pathways and immune signaling pathways. LSD1 inhibitors (IMG-7289 or GSKLSD1) were evaluated patient-derived xenograft models. Results. We found elevated LSD1 binding on the IL18 promoter in DIPG VI cells. Subsequent qRT-PCR and western blot analyses demonstrated increased IL18 protein levels following treatment with GSKLSD1 or IMG-7289 in DIPG VI cells, alongside heightened IL18 mRNA expression compared to DMSO-treated cells. Either GSKLSD1 or IMG-7289 treatment in DIPG IV cells also led to significantly elevated IL18 binding protein mRNA levels. Orthotopic xenografts using DIPG IV bearing mice dosed with LSD1 inhibitors over the course of 35 days several weeks showed a decrease in IL-18R, and an increase in IL-18 BP transcript levels alongside a significant increase in Slamf7 transcript levels. Some evidence of tumor inhibition was seen in male but not female mice treated with GSKLSD1. CONCLUSIONS Our investigation revealed IL18 as a direct target of LSD1 specifically in DIPG VI, and gender specific effects of GSKLSD1 treatment in vivo. Future studies will prioritize validating and elucidating the underlying mechanisms the therapeutic potential of LSD1 inhibition in DMG.

TMET-40. UPREGULATION OF URIDINE SALVAGE IN MESENCHYMAL GLIOBLASTOMA STEM-LIKE CELLS

Abstract Glioblastoma is a heterogenous tumor comprised of multiple molecular subtypes of cancer cells and cancer stem-like cells. Of particular importance are the cancer stem-like cell niche population as they are believed to be more resistant to existing therapies and re-seed the tumor following initial response to standard-of-care treatment. To better understand glioblastoma stem-like cells we completed an untargeted proteomic analysisof 35 patient derived glioblastoma stem cell lines. This system driven analysis revealed an increase in several important proteins, in the mesenchymal subtype, involved in the uridine salvage pathway. A subset of these proteins, including ecto-5’-nucleotidase (NT5E/CD73), uridine phosphorylase (UPP1), phosphoglucomutase-2-like-1 (PGM2L1), nicotinamide phosphoribosyltransferase (NAMPT), and nicotinamide N-methyltransferase (NNMT), suggest an augmented pathway for utilization of UMP and uridine as a fuel source and to replenish NAD+. Uridine and UMP are present in human serum and are enriched in the tumor microenvironment providing a sustainable resource to resupply the tumor. The upregulation of this pathway was validated in established cell lines and orthogonal patient-derived xenograft cell lines not included in the proteomics study. Further work is underway to selectively inhibit or exploit this pathway with small molecule inhibitors.

TMET-35. UPREGULATION OF THE URIDINE SALVAGE PATHWAY IN MESENCHYMAL GLIOBLASTOMA STEM-LIKE CELLS

Abstract Glioblastoma is a heterogenous tumor comprised of multiple molecular subtypes of cancer cells and cancer stem-like cells. Of particular importance are the cancer stem-like cell niche population as they are believed to be more resistant to existing therapies and re-seed the tumor following initial response to standard-of-care treatment. To better understand glioblastoma stem-like cells we completed an untargeted proteomic analysis of 35 patient derived glioblastoma stem cell lines. This revealed an increase in several important proteins involved in the uridine salvage pathway, in the mesenchymal subtype. A subset of these proteins, including ecto-5’-nucleotidase (NT5E/CD73), uridine phosphorylase (UPP1), phosphoglucomutase-2-like-1 (PGM2L1), nicotinamide phosphoribosyltransferase (NAMPT), and nicotinamide N-methyltransferase (NNMT), suggest an augmented pathway for utilization of UMP and uridine as a fuel source and to replenish NAD+. Uridine and UMP are present in human serum and are enriched in the tumor microenvironment, providing a sustainable resource to resupply the tumor. The upregulation of this pathway was validated in established cell lines and orthogonal patient-derived xenograft cell lines not included in the proteomics study. Further work is underway to selectively inhibit or exploit this pathway with small molecule inhibitors.

CNSC-56. DIVERSE, FUNCTIONAL NEUROTRANSMITTER RECEPTOR EXPRESSION ON GLIOBLASTOMA CELLS ENABLES EXTENSIVE NEURON-TO-GLIOMA COMMUNICATION

Abstract Glioblastomas are invasive yet incurable brain tumors. Recent data have shown that glutamatergic neuron-to-glioma synapses drive glioblastoma proliferation and invasion. In this study, we set out to investigate whether glioblastoma could communicate with neurons via various neuron-derived neurotransmitters through a functional neurotransmitter receptor screening. For this purpose, we stably transduced glioblastoma cells with a genetically encoded calcium indicator and sequentially and locally applied eight different neurotransmitters to glioblastoma cells in neuron-glioma co-cultures. These neurotransmitters included acetylcholine, ATP, dopamine, glutamate, GABA, adrenaline, serotonin, and glycine. We observed functional responses to acetylcholine, glutamate, ATP, dopamine, indicating a potential role for diverse neuron-to-glioma communication. Further, we investigated in patient-derived xenograft models and human tissues the existence of putative neuron-to-glioma synapses that could signal via acetlycholine, ATP and dopamine. In conclusion, this study reveals that glioblastoma cells express a heterogeneous set of functional neurotransmitter receptors, which may facilitate neuron-to-tumor communication across broad neuronal populations and warrant further investigation into their role for tumor biology.

DNAR-11. INHIBITION OF RAD52 ACTIVITY INDUCES DNA DAMAGE BY ACCUMULATING R-LOOPS IN DIFFUSE MIDLINE GLIOMA

Abstract Diffuse midline glioma (DMG) is one of the most devastating childhood cancers with a median survival of < 1year from diagnosis. There is a critical need for new therapeutics for improving treatment outcomes for DMG patients. We performed genome-wide CRISPR/Cas9 screening and identified RAD52 as a potential therapeutic target in DMG cells. RAD52 inhibition, using shRNA-mediated RAD52 depletion and treatment with RAD52 inhibitor, D-I03, suppressed DMG cell proliferation. Western blotting revealed that RAD52 inhibition increased DNA double-starand breaks (DSBs) marker γH2AX while it decreased repair markers BRCA1 and RAD51. Also, RAD52 inhibition causes a sustained level of phosphorylated RAD50 and γH2AX in irradiated DMG cells over 24 hours. Immunocytochemistry (ICC) of γH2AX and repair marker 53BP1 showed that RAD52 inhibition sustained DNA damage with high levels of γH2AX at 24 hours following radiation while the level of 53BPI was decreased, thereby inhibiting DNA DSB repair. DNA repair assay showed that RAD52 inhibition suppressed DNA DSB repair through a homologous recombination pathway. RNA sequencing showed that RAD52 inhibition downregulated genes associated with the DNA repair pathway. Importantly, RAD52 inhibition increased the radiosensitivity of DMG cells. To understand the mechanism of RAD52 inhibition on DNA damage, we performed dot plot assay and ICC of S9.6 which recognizes DNA-RNA hybrids (also known as R-loops) and found accumulation of R-loop formation in DMG cells treated with RAD52 inhibitor. In addition, RAD52 inhibition decreased the expression of RNA polymerase II. Finally, the combination therapy of RAD52 inhibitor and radiation inhibited tumor growth and increased survival of mice bearing DMG patient-derived xenografts, outperforming either monotherapy. Together, our results highlight that RAD52 inhibition induces DNA damage by accumulating R-loops, results in reducing DMG cell proliferation, while also increase DMG radiosensitivty, and providing a rationale for developing combination therapy with radiation for the treatment of DMG.

Primary intracranial sarcoma associated with DICER1 mutant: a case report and preclinical investigation.

Primary intracranial sarcoma (PIS) is a rare and aggressive pediatric brain tumor, which is partially associated with DICER1 mutant. Although the molecular genetic characteristics of this tumor have previously been investigated, novel therapeutic targets remain unclear. Further, the lack of faithful preclinical models has hampered the development of novel therapeutic strategies. Herein, we describe a pediatric case of PIS with DICER1 mutant and describe the development of the first novel patient-derived xenograft (PDX) model of this rare tumor. Somatic genomic profiling of the tumor revealed mutations in DICER1, TP53, and ATRX. Germline analysis further revealed a pathogenic variant of DICER1, significant for the diagnosis and management of hereditary tumor predisposition syndrome. Overall, we demonstrated that the PDX model faithfully retained the phenotype and genotype of the patient's tumor, as well as the DNA methylation profile. Through high-throughput drug screening using PDX tumor cells, we found that activation of the retinoic acid receptor (RAR) signaling pathway reduced tumor cell viability. These findings indicate that the RAR signaling pathway is a potential therapeutic target for PIS in DICER1 mutant.

Multiomic Analyses Reveal New Targets of Polycomb Repressor Complex 2 in Schwann Lineage Cells and Malignant Peripheral Nerve Sheath Tumors

Abstract Background Malignant peripheral nerve sheath tumors (MPNST) can arise from atypical neurofibromas (ANF). Loss of the polycomb repressor complex 2 (PRC2) is a common event. Previous studies on PRC2-regulated genes in MPNST used genetic addback experiments in highly aneuploid MPNST cell lines which may miss PRC2-regulated genes in NF1-mutant ANF-like precursor cells. A set of PRC2-regulated genes in human Schwann cells has not been defined. We hypothesized PRC2 loss has direct and indirect effects on gene expression resulting in MPNST, so we sought to identify PRC2-regulated genes in immortalized human Schwann cells (iHSCs). Methods We engineered NF1-deficient iHSCs with loss of function SUZ12 or EED mutations. RNA sequencing revealed 1,327 differentially expressed genes to define PRC2-regulated genes. To investigate MPNST pathogenesis we compared genes in iHSCs to consistent gene expression differences between ANF and MPNSTs. Chromatin immunoprecipitation sequencing was used to further define targets. Methylome and proteomic analyses were performed to further identify enriched pathways. Results We identified potential PRC2-regulated drivers of MPNST progression. Pathway analysis indicates many upregulated cancer-related pathways. We found transcriptional evidence for activated Notch and Sonic Hedgehog signaling in PRC2-deficient iHSCs. Functional studies confirm Notch signaling is active in MPNST cell lines, patient-derived xenografts, and transient cell models of PRC2 deficiency. A combination of MEK and γ-secretase inhibition shows synergy in MPNST cell lines. Conclusions We identified PRC2-regulated genes and potential drivers of MPNSTs. Our findings support the Notch pathway as a druggable target in MPNSTs. Our identification of PRC2-regulated genes and pathways could result in more novel therapeutic approaches.

Utilizing Patient-derived Xenografts to Model Precision Oncology for Biliary Tract Cancer.

Biliary tract cancers (BTCs), which are rare and aggressive malignancies, are rich in clinically actionable molecular alterations. A major challenge in the field is the paucity of clinically relevant BTC models which recapitulate the diverse molecular profiles of these tumors. The purpose of this study was to curate a collection of patient-derived xenograft (PDX) models that reflect the spectrum of genomic alterations present in BTCs to create a resource for modeling precision oncology. PDXs were derived from BTC collected from surgical resections or metastatic biopsies. Alterations present in the PDXs were identified by whole exome sequencing and RNASeq. PDXs were treated with approved and investigational agents. Efficacy was assessed by change in tumor volume from baseline. Event-free survival was defined as time to tumor doubling from baseline. Responses were categorized at day 21: >30% decrease=partial response; >20% increase in tumor volume=progressive disease, and any non-PR/PD was considered stable disease. Genomic sequencing demonstrated key actionable alterations across this cohort, including alterations in FGFR2, IDH1, ERRB2, PIK3CA, PTEN and KRAS. RNAseq demonstrated fusions and expression of antibody drug conjugate targets including TROP2, HER2 and Nectin4. Therapeutic matching revealed objective responses to approved and investigational agents that have been shown to have antitumor activity clinically. Here, we developed a catalog of BTC PDXs which underwent comprehensive molecular profiling and therapeutic modeling. To date, this is one of the largest collections of BTC PDX models and will facilitate the development of personalized treatments for patients with these aggressive malignancies.

Modeling Drug Responses and Evolutionary Dynamics using Patient-Derived Xenografts Reveals Precision Medicine Strategies for Triple Negative Breast Cancer.

The inter- and intra-tumor heterogeneity of triple negative breast cancers (TNBC), which is reflected in diverse drug responses, interplays with tumor evolution. Here, we developed a preclinical experimental and analytical framework using treatment-naive TNBC patient-derived tumor xenografts (PDTX) to test their predictive value in personalized cancer treatment approaches. Patients and their matched PDTX exhibited concordant drug responses to neoadjuvant therapy using two trial designs and dosing schedules. This platform enabled analysis of non-genetic mechanisms involved in relapse dynamics. Treatment resulted in permanent phenotypic changes with functional and therapeutic consequences. High throughput drug screening methods in ex vivo patient derived tumor xenograft cells (PDTCs) revealed patient-specific drug response changes dependent on first-line therapy. This was validated in vivo, as exemplified by a change in olaparib sensitivity in tumors previously treated with clinically relevant cycles of standard-of-care chemotherapy. In summary, PDTXs provide a robust tool to test patient drug responses and therapeutic regimens and to model evolutionary trajectories. However, high inter-model variability and permanent non-genomic transcriptional changes constrain their use for personalized cancer therapy. This work highlights important considerations associated with preclinical drug response modeling and potential uses of the platform to identify efficacious and preferential sequential therapeutic regimens.

Upregulation of ENAH by a PI3K/AKT/β-catenin cascade promotes oral cancer cell migration and growth via an ITGB5/Src axis

BackgroundOral cancer accounts for 2% of cancer-related deaths globally, with over 90% of cases being oral cavity squamous cell carcinomas (OSCCs). Approximately 50% of patients with OSCC succumb to the disease within 5 years, primarily due to the advanced stage at which it is typically diagnosed. This underscores an urgent need to identify proteins related to OSCC progression to develop effective diagnostic and therapeutic strategies.MethodsTo identify OSCC progression-related proteins, we conducted integrated proteome and transcriptome analyses on cancer tissues from patients and patient-derived xenograft (PDX) model mice. We investigated the role of protein-enabled homolog (ENAH), identified as an OSCC progression-associated protein, through proliferation, transwell migration, and invasion assays in OSCC cells. The mechanisms underlying ENAH-mediated functions were elucidated using gene knockdown and ectopic expression techniques in OSCC cells.ResultsENAH was identified as a candidate associated with OSCC progression based on integrated analyses, which showed increased ENAH levels in primary OSCC tissues compared with adjacent noncancerous counterparts, and sustained overexpression in the cancer tissues of PDX models. We confirmed that level of ENAH is increased in OSCC tissues and that its elevated expression correlates with poorer survival rates in patients with OSCC. Furthermore, the upregulation of ENAH in OSCC cells results from the activation of the GSK3β/β-catenin axis by the EGFR/PI3K/AKT cascade. ENAH expression enhances cell proliferation and mobility by upregulating integrin β5 in oral cancer cells.ConclusionsThe upregulation of ENAH through a PI3K/AKT/β-catenin signaling cascade enhances oral cancer cell migration and growth via the ITGB5/Src axis. These findings offer a new interpretation of the ENAH function in the OSCC progression and provide crucial information for developing new OSCC treatment strategies.

CD70-Targeted Immuno-PET/CT Imaging of Clear Cell Renal Cell Carcinoma: A Translational Study.

The diagnosis and surveillance of clear cell renal cell carcinoma (ccRCC) remains a clinical challenge. The high and specific expression of the cluster of differentiation 70 (CD70) in ccRCC makes it a potential diagnostic and therapeutic target. Methods: We detected and analyzed CD70 expression in various renal cell carcinomas (RCCs) and normal kidneys using immunohistochemical staining. Two novel CD70-specific single-domain antibodies, RCCB3 and RCCB6, were produced and labeled with 68Ga to develop radiotracers. We performed immuno-PET/CT imaging with [68Ga]Ga-NOTA-RCCB3 and [68Ga]Ga-NOTA-RCCB6 in subcutaneous ccRCC patient-derived xenograft models. We recruited 8 RCC patients in a pilot clinical trial (ClinicalTrials.gov identifier: NCT06148220) to evaluate the diagnostic utility of [68Ga]Ga-NOTA-RCCB3 and [68Ga]Ga-NOTA-RCCB6 immuno-PET/CT. Results: Expression of CD70 is associated with sex, tumor differentiation, tumor thrombus, necrosis, distant metastasis, and overall survival of RCC patients. RCCB3 and RCCB6 had high affinities for recombinant human CD70. Immuno-PET/CT imaging with [68Ga]Ga-NOTA-RCCB3 and [68Ga]Ga-NOTA-RCCB6 rapidly visualized subcutaneous ccRCC with clarity. Tumor uptake of [68Ga]Ga-NOTA-RCCB6 was significantly reduced after the blockade of CD70. [68Ga]Ga-NOTA-RCCB6 PET/CT in ccRCC patients outperformed traditional 18F-FDG PET/CT in specifically identifying CD70-positive ccRCC metastases. Conclusion: CD70-targeted immuno-PET/CT imaging with [68Ga]Ga-NOTA-RCCB6 or [68Ga]Ga-NOTA-RCCB3 is a precise and superior method for evaluating tumor burden and suspected metastases in ccRCC patients. This advancement in imaging technology has the potential to improve the clinical decision-making process for this patient cohort significantly.

The third generation AKR1C3-activated prodrug, ACHM-025, eradicates disease in preclinical models of aggressive T-cell acute lymphoblastic leukemia

T-cell acute lymphoblastic leukemia (T-ALL) is an aggressive hematological malignancy that expresses high levels of the enzyme aldo-keto reductase family 1 member C3 (AKR1C3). To exploit this finding, we developed a novel prodrug, ACHM-025, which is selectively activated by AKR1C3 to a nitrogen mustard DNA alkylating agent. We show that ACHM-025 has potent in vivo efficacy against T-ALL patient-derived xenografts (PDXs) and eradicated the disease in 7 PDXs. ACHM-025 was significantly more effective than cyclophosphamide both as a single agent and when used in combination with cytarabine/6-mercaptopurine. Notably, ACHM-025 in combination with nelarabine was curative when used to treat a chemoresistant T-ALL PDX in vivo. The in vivo efficacy of ACHM-025 directly correlated with AKR1C3 expression levels, providing a predictive biomarker for response. Together, our work provides strong preclinical evidence highlighting the potential of ACHM-025 as a targeted and effective therapy for aggressive forms of T-ALL.

A computational analysis of the oncogenic and anti-tumor immunity role of P4HA3 in human cancers

Prolyl-4-hydroxylase subunit alpha3 (P4HA3) is a triple helical procollagen synthesis protein. The role of P4HA3 in cancer development is not well known and lacks comprehensive analyses among human cancers. This study aimed to investigate the relationship between P4HA3 expression and anti-tumor immunity and its prognostic value in pan-cancer. P4HA3 expression was analyzed from TIMER2.0, GTEx, GEPIA2.0 and TCGA databases. Genetic and DNA methylation alterations, survival analysis and proteins co-expression analysis of P4HA3 in cBio Cancer Genomics Portal, TCGA, GSCA and TIMER2.0. The correlation between P4HA3 expression and immune infiltration was analyzed by TIDE, XCELL, MCPCOUNTER, and EPIC. We performed EdU and transwell experiments to evaluate the influence of P4HA3 on the proliferation, migration and invasion abilities of different tumors. Patients derived xenograft (PDX) and subcutaneous transplantation models were utilized to explore the correlation between P4HA3 and immunotherapy response in triple-negative breast cancer (TNBC). Among 33 types of cancers, P4HA3 had generally different expression between different tumors, further analysis showed that the expression of P4HA3 was correlated with the cells infiltration of the tumor microenvironment (TME). The expression of P4HA3 was positively with the cell proliferation markers and epithelial-mesenchymal transition (EMT) markers. Moreover, P4HA3 deficiency inhibited the proliferation, migration and invasion abilities of tumor cells, and promoted anti-tumor immunotherapy of PD-1/PD-L1 inhibitor. This pan-cancer analysis of P4HA3 provides a comprehensive understanding of its oncogenic and prognosis role in different cancers, P4HA3 abnormal expression could be a useful biomarker for predicting the effectiveness of immunotherapy in cancer patients.

TPX2 serves as a novel target for expanding the utility of PARPi in pancreatic cancer through conferring synthetic lethality

BackgroundPARP inhibitors (PARPi) have been licensed for the maintenance therapy of patients with metastatic pancreatic cancer carrying pathogenic germline BRCA1/2 mutations. However, mutations in BRCA1/2 are notably rare in pancreatic...

IMPA1-derived inositol maintains stemness in castration-resistant prostate cancer via IMPDH2 activation.

Acquisition of prostate cancer stem cells (PCSCs) manifested during androgen ablation therapy (ABT) contributes to castration-resistant prostate cancer (CRPC). However, little is known about the specific metabolites critically orchestrating this process. Here, we show that IMPA1-derived inositol enriched in PCSCs is a key metabolite crucially maintaining PCSCs for CRPC progression and ABT resistance. Notably, conditional Impa1 knockout in the prostate abrogates the pool and properties of PCSCs to orchestrate CRPC progression and prolong the survival of TRAMP mice. IMPA1-derived inositol serves as a cofactor that directly binds to and activates IMPDH2, which synthesizes guanylate nucleotides for maintaining PCSCs with ARlow/- features leading to CRPC progression and ABT resistance. IMPA1/inositol/IMPDH2 axis is upregulated in human prostate cancer, and its overexpression predicts poor survival outcomes. Genetically and pharmacologically targeting the IMPA1/inositol/IMPDH2 axis abrogates CRPC and overcomes ABT resistance in various CRPC xenografts, patient-derived xenograft (PDX) tumor models, and TRAMP mouse models. Our study identifies IMPDH2 as an inositol sensor whose activation by inositol represents a key mechanism for maintaining PCSCs for CRPC and ABT resistance.

YAP signaling orchestrates the endothelin-1-guided invadopodia formation in high-grade serous ovarian cancer.

The high-grade serous ovarian cancer (HG-SOC) is a notoriously challenging disease, characterized by a rapid peritoneal dissemination. HG-SOC cells leverage actin-rich membrane protrusions, known as invadopodia, to degrade the surrounding extracellular matrix (ECM) and invade, initiating the metastatic cascade. In HG-SOC, the endothelin-1 (ET-1)/endothelin A receptor (ETAR)-driven signaling coordinates invadopodia activity, however how this axis integrates pro-oncogenic signaling routes, as YAP-driven one, impacting on the invadopodia-mediated ECM degradation and metastatic progression, deserves a deeper investigation. Herein, we observed that downstream of the ET-1/ET-1R axis, the RhoC and Rac1 GTPases, acting as signaling intermediaries, promote the de-phosphorylation and nuclear accumulation of YAP. Conversely, the treatment with the dual ETA/ETB receptor antagonist, macitentan, inhibits the ET-1-driven YAP activity. Similarly, RhoC silencing, or cell transfection with a dominant inactive form of Rac1, restore the YAP phosphorylated and inhibited state. Mechanistically, the ET-1R/YAP signal alliance coordinates invadopodia maturation into ECM-degrading structures, indicating how such ET-1R-guided protein network represents a route able to enhance the HG-SOC invasive potential. At functional level, we found that the interconnection between the ET-1R/RhoC and YAP signals is required for MMP-2 and MMP-9 proteolytic functions, cell invasion, and cytoskeleton architecture changes, supporting the HG-SOC metastatic strength. In HG-SOC patient-derived xenografts (PDX) macitentan, turning-off the invadopodia regulators RhoC/YAP, halt the metastatic colonization. ET-1R targeting, hindering the YAP activity, weakens the invadopodia machinery, embodying a promising therapeutic avenue to prevent peritoneal dissemination in HG-SOC.

Epigenetic Activation of the CMTM6-IGF2BP1-EP300 Positive Feedback Loop Drives Gemcitabine Resistance in Pancreatic Ductal Adenocarcinoma.

Pancreatic ductal adenocarcinoma (PDAC) is a highly malignant tumor with a dismal prognosis. Gemcitabine-based chemotherapy has emerged as a first-line treatment for PDAC. However, the development of gemcitabine resistance often results in therapeutic failure. In order to uncover the underlying mechanisms of gemcitabine resistance, gemcitabine-resistant PDAC cell lines and patient-derived xenograft (PDX) models are established and subjected to RNA sequencing. It is found that CMTM6 is closely related to gemcitabine resistance in PDAC. Multi-omics analysis revealed that EP300-mediated H3K27ac modification is involved in the transcriptional activation of CMTM6, which maintains IGF2BP1 expression by preventing its ubiquitination. The m6A reader IGF2BP1 stabilizes the EP300 and MYC mRNAs by recognizing m6A modifications, forming a positive feedback loop that enhances tumor stemness and ultimately contributes to PDAC resistance. The combined application of the EP300 inhibitor inobrodib and gemcitabine exerts a synergistic effect on PDAC. Overall, these findings reveal that the EP300-CMTM6-IGF2BP1 positive feedback loop facilitates gemcitabine resistance via epigenetic reprogramming and the combined use of inobrodib and gemcitabine represents a promising strategy for overcoming chemoresistance in PDAC, warranting further investigation in clinical trials.