Opioids are essential analgesics for managing severe pain but can paradoxically increase pain sensitivity (hyperalgesia) and diminish analgesic efficacy (tolerance). Hyperactivity of NMDA-type glutamate receptors (NMDARs) at primary afferent terminals in the spinal cord contributes to both phenomena; however, the underlying signaling mechanisms remain unclear. Here, we report that morphine administration in rats promoted the translocation of monomeric BRAF, an oncogenic kinase, from the dorsal root ganglion (DRG) to spinal cord synaptosomes, leading to increased MEK-ERK phosphorylation at nociceptor central terminals. BRAF physically interacted with NMDARs in both rat and human spinal cords. Inhibition of BRAF activity with vemurafenib reversed morphine-induced NMDAR phosphorylation and synaptic localization of α2δ-1–bound NMDARs. Vemurafenib also abolished morphine-induced presynaptic NMDAR hyperactivity in spinal dorsal horn neurons. Correspondingly, conditional Braf knockout in DRG neurons normalized morphine-enhanced NMDAR phosphorylation, synaptic trafficking of α2δ-1–bound NMDARs, and NMDAR hyperactivity in the spinal cord. Furthermore, pharmacological inhibition of BRAF or MEK, or Braf deletion in DRG neurons, enhanced morphine analgesia while mitigated morphine-induced hyperalgesia and tolerance. These findings identify BRAF overactivity at nociceptor central terminals as a key mediator of opioid-induced NMDAR hyperactivity. Clinically approved BRAF inhibitors could be repurposed to enhance opioid analgesia while minimizing adverse effects.
Daozhong Jin, Hong Chen, Yuying Huang, Shao-Rui Chen, Hui-Lin Pan
Our research uncovers a new role for ATR in responding to extracellular matrix (ECM) stiffness and promoting epithelial-to-mesenchymal transition (EMT) and metastasis. ATR, when deubiquitinated and upregulated by USP21 under enhanced ECM stiffness conditions, phosphorylates the nuclear protein SUN2 which promotes β-catenin nuclear translocation and EMT. ATM mediated EMT promotes polymorphonuclear myeloid-derived suppressor cell recruitment and inhibits CD103+ dendritic cells, fostering an immunosuppressive tumor milieu. ATR inhibition disrupts this malignant cascade by promoting mesenchymal to epithelial transition to enhance anti-tumor immunity and mitigate metastases. Consistently, circulating HLA-DR+ dendritic cells were also enhanced following treatment with the ATR inhibitor, Berzosertib, in patients with therapeutically resistant early-stage breast cancer. Our data suggest that ATR targeted therapy may be optimized by considering both DNA damage dependent and EMT inducing effects of ATR.
Xinyi Tu, Xiangyu Zeng, Yaoliang Sun, Yaobin Ouyang, Lingling Zhu, Ping Yin, Kevin D. Pavelko, Roberto A. Leon-Ferre, Yanxia Jiang, Haidong Dong, Jodi M. Carter, Shouhai Zhu, Jann N. Sarkaria, Liewei Wang, Jinzhou Huang, Kuntian Luo, Yiqun Han, Zheming Wu, Zhenkun Lou, Robert W. Mutter
ATR inhibition is under evaluation for treatment of high-grade serous ovarian cancer (HGSOC) to reverse acquired resistance to poly (ADP-ribose) polymerase (PARP) inhibition and to exacerbate chemotherapy-induced replicative stress. Here, we define PTEN deficiency as a predictive biomarker for response to ATR inhibition, as monotherapy and in combination with PARP inhibition or gemcitabine. In response to ATR inhibition and compared to PTEN-proficient cells, PTEN-deficient cells are prone to (1) uncoupling of DNA polymerase and helicase activities, leading to excessive single-stranded DNA and replication stress; (2) cytoplasmic sequestration of CHK1, compromising cell cycle checkpoint control with reduced compensatory effects by ATM and DNA-PK, leading to mitotic catastrophe; and (3) reduced RAD51 recruitment, exacerbating replication fork instability, also leading to lethality. Retrospective analyses demonstrate that patients with HGSOC expressing low PTEN levels experience greater clinical benefit on ATR inhibitor-based trials than those with high levels. These results justify prospective trials evaluating ATR inhibition as a therapeutic strategy for PTEN-deficient tumors.
Jie Hao, Bose Kochupurakkal, Timothy B. Branigan, Ozge Sezin Somuncu, Renyan Liu, Heta Jadhav, Alexandre Andre B.A. da Costa, Yuqing Jiao, Jenny Z. Yu, David B. Martignetti, Golbahar Sadatrezaei, Sirisha Mukkavalli, Prafulla C. Gokhale, Su-Chun Cheng, Steven J. Skates, Dimitrios Nasioudis, Panagiotis A. Konstantinopoulos, Joyce F. Liu, Stephanie L. Gaillard, Robert L. Giuntoli II, Lainie P. Martin, Janos L. Tanyi, Nawar Latif, Ian S. Heller, Fiona Simpkins, Kalindi Parmar, Alan D. D'Andrea, Geoffrey I. Shapiro
YAP and TAZ, key effectors of the Hippo pathway, are often hyperactivated in cancer, promoting tumor progression and therapy resistance. Their oncogenic role depends on interaction with TEAD transcription factors, making the TEAD-YAP/TAZ complex a promising therapeutic target. Using translational mouse models, we showed here that sustained systemic YAP/TAZ depletion caused severe side effects. These could be avoided through pulsed inhibition, which effectively suppressed tumor growth, even at advanced stages. We identified Tgfb2 as a critical YAP/TAZ target gene for tumor formation and demonstrated that YAP/TAZ drove T cell exclusion via activation of tissue remodeling genes. Consequently, YAP/TAZ inhibition enhanced immune cell infiltration. However, infiltrating T cells rapidly underwent exhaustion. Combining YAP/TAZ inhibition with immune checkpoint blockade (ICB) reversed this exhaustion and sensitized resistant tumors to immunotherapy. This combination reshaped the tumor microenvironment to support immune cell infiltration and activation, representing a therapeutic strategy that maximizes anti-tumor immunity while minimizing toxicity.
Marco Jessen, KyungMok Kim, Marie Tollot-Wegner, Anita Cindric Vranesic, Cagla Dönmez, Celina Junker, Tina Lehmann, Advitiya Khandelwal, Yuliya Kurlishchuk, Tom Hünniger, Christin Ritter, Evaristo Di Napoli, Shyam Murali, Konrad Bücking, Viktoria Haug, Sabine Muth, Tracy T. Tang, Andreas Rosenwald, Markus Radsak, Donato Inverso, Tanja Deckert-Gaudig, Volker Deckert, Orlando Paciello, Björn von Eyss
MDM2 is transcriptionally activated by the ST-MYCL-Tip60 complex in virus-positive Merkel cell carcinoma (MCC). MDM2 suppresses p53 and is a rational therapeutic target. MDM2 inhibitors face an intrinsic limitation: p53 activation induces MDM2 transcription, creating a feedback loop that blunts inhibitor efficacy. We demonstrate that MDM2 degraders KTX-049 and KT-253 overcome this limitation by collapsing the p53/MDM2 negative feedback loop. KTX-049 was >100-fold more potent than the MDM2 inhibitor DS-3032 across WT p53 MCC cell lines, and this superior potency was quantitatively supported by mechanistic mathematical modeling. In vivo, KT-253 produced deep and durable tumor regressions, including complete responses in patient-derived xenograft models. Acquired resistance was strongly associated with acquisition of TP53 mutations, confirming on-target pathway pressure. These findings establish feedback architecture as a critical determinant of therapeutic response and position MDM2 degradation as a qualitatively distinct strategy that produces more durable pathway engagement than MDM2 inhibition, providing a preclinical rationale for prioritizing MDM2 degraders in WT TP53 MCC.
Varsha Ananthapadmanabhan, Simone Bruno, Leonard Vonk, Yu-Chen Cheng, Abeba Teshager, Benjamin K. Eschle, Charles L. Howarth, Joana S. Rodrigues, Julia Schnabel, Ananya Kodali, Prafulla C. Gokhale, Rujuta Kshirsagar, Susanne B. Breitkopf, Kirti Sharma, Joao A. Paulo, Yvonne Li, Andrew D. Cherniack, Franziska Michor, Yogesh Chutake, Joyoti Dey, James A. DeCaprio
BACKGROUND. B cell maturation antigen (BCMA) is a key therapeutic target in multiple myeloma (MM), yet its whole-body in vivo distribution and role in disease assessment remain incompletely defined. We aimed to evaluate the safety, diagnostic performance, and clinical utility of a novel BCMA-targeted PET tracer, 68Ga-PFBC01, in patients with plasma cell disorders. METHODS. We conducted a single-center, prospective, single-arm phase I trial (ClinicalTrials.gov NCT06717113). Fifty patients underwent 68Ga-PFBC01 PET/CT, including 40 with paired 18F-FDG PET/CT for head-to-head comparison. Primary outcomes included diagnostic performance (sensitivity, specificity, PPV, NPV, and inter-reader agreement). Secondary outcomes included correlations with clinical biomarkers, treatment response assessment, impact on clinical decision-making, and safety. RESULTS.68Ga-PFBC01 PET/CT demonstrated superior diagnostic performance compared with 18F-FDG PET/CT (sensitivity 96.9% vs 84.6%; specificity 71.4% vs 60.0%). Quantitative PET-derived tumor burden correlated with M protein (R = 0.325, P = 0.026), free light chains (R = 0.340–0.437, P ≤ 0.015), soluble BCMA (R = 0.433, P = 0.050), and bone marrow plasma cells (R = 0.682, P < 0.001). Imaging findings altered clinical management in multiple cases, enabling both therapy escalation and de-escalation. Blood-pool uptake strongly correlated with soluble BCMA (R = 0.899, P < 0.001) and overall disease burden (R = 0.736, P < 0.001). No serious tracer-related adverse events were observed; two patients (4%) experienced mild events. CONCLUSION.68Ga-PFBC01 PET/CT provides biologically specific, whole-body assessment of MM, outperforming 18F-FDG and enabling integrated evaluation of tumor burden and systemic disease activity, with direct implications for clinical decision-making. TRIAL REGISTRATION. ClinicalTrials.gov NCT06717113. FUNDING. National Natural Science Foundation of China (82472018, 82402320) to Prof. Lei Kang, 82402320 to Dr. Tianyao Wang); Beijing Nova Program (20240484725) to Prof. Lei Kang; National High Level Hospital Clinical Research Funding (Interdisciplinary Research Project of Peking University First Hospital, 2024IR07, Scientific and Technological Achievements Transformation Incubation Guidance Fund Project of Peking University First Hospital, 2025CX38, 2024CX18) to Prof. Lei Kang.
Tingfei Gu, Zhao Chen, Bo Tang, Tianyao Wang, Qi Yang, Huihui Liu, Zeyin Liang, Qian Wang, Yang Zhang, Yuhua Sun, Mingyi Di, Tingting Yuan, Yongkang Qiu, Yimeng Du, Lele Song, Shengnan Wu, Wei Wang, Xiaojie Xu, Yujun Dong, Lei Kang
Glioblastoma is a fatal primary malignant brain tumor, with an average survival of 15 months despite surgical resection, chemotherapy, and radiation therapy. Due to the concurrent deregulation of numerous genes in glioblastoma, molecular monotherapies have not improved clinical outcomes. Evidence suggests that targeting multiple deregulated molecules is essential for better therapies; however, this is limited by the lack of suitable drugs and increased toxicity of combination therapies. To address this, we hypothesized that miRNAs, small gene-regulatory RNAs that suppress mRNA, could simultaneously inhibit multiple deregulated genes in glioblastoma, and be used for more effective therapies. We identified regulatory miRNAs — those that target several deregulated genes in glioblastoma — using a combination of PAR-CLIP screening, TCGA data analyses and an algorithm to rank target importance and miRNA therapeutic potential. We selected two tumor suppressor miRNAs, miR-340 and miR-382, and one oncogenic miRNA, miR-17 and showed that they target critical glioblastoma pathways and alter cell growth, survival, invasion, and in vivo tumor growth. We developed and successfully applied a miRNA therapeutic delivery approach using Brain Penetrating Nanoparticles combined with MRI-guided focused ultrasound and microbubbles, to inhibit established tumor growth and to extend animal survival. This strategy offers a promising approach for translating miRNA-based therapies into clinical trials for glioblastoma and other cancers.
Shekhar Saha, Ying Zhang, Myron K. Gibert Jr., Collin Dube, Farina Hanif, Elizabeth Qian Xu Mulcahy, Sylwia Bednarek, Yunan Sun, Pawel Marcinkiewicz, Xiantao Wang, Gijung Kwak, Ahsan H. Polash, Haolin Li, Kadie Hudson, Manikarna Dinda, Tapas Saha, Matthew McCord, Fadila Guessous, Nichola Cruickshanks, Rossymar Rivera Colon, Lily Dell'Olio, Rajitha Anbu, Wenjie Liu, Songy Choi, Benjamin Kefas, Pankaj Kumar, Alexander L. Klibanov, David Schiff, Jung Soo Suk, Justin Hanes, Jamie Mata, Markus Hafner, Roger Abounader
Metastatic castration-resistant prostate cancer (mCRPC) is an aggressive subtype of prostate cancer (PC) without curative treatments. Antibody-drug conjugates (ADCs) emerged as promising cancer therapeutics that selectively deliver cytotoxic agents (payloads) to the tumors. Although ADCs have been successfully applied in the treatment of hematological and solid tumors, ADC monotherapy has not demonstrated durable responses in mCRPC, and the mechanisms of PC resistance to ADCs have not been thoroughly investigated. Our study aimed to improve ADC efficacy using a new integrated approach for the custom ADC design and multiplexing. To nominate rational combinations of ADC targets and ADC payloads, we (1) examined protein co-expression of three clinically relevant surface antigens - B7 homolog 3 (B7-H3), prostate specific membrane antigen (PSMA), and six-transmembrane epithelial antigen of prostate-1 (STEAP1) - in a series of human mCRPCs, and (2) screened established ADC payloads and their combinations in mCRPC cell lines with different molecular backgrounds. Identified synergistic interactions between DNA-damaging payloads and BCL-XL inhibitor A-1331852 as well as their coordinated induction of intrinsic apoptosis pathway were evaluated in a panel of PC cell lines. Functional relevance between isolated p53 loss and PC responses to three genotoxic ADCs - B7-H3 - seco-DUBA (vobramitamab duocarmazine), PSMA - SG3249, and STEAP1 – DXd and their combinations with A-1331852 was established using genetic knockout models. Lastly, enhanced in vivo antitumor activity of vobramitamab duocarmazine by systemic A-1331852 was shown. Collectively, our findings provide rationale for the development of ADC therapies combining genotoxic payloads with BCL-XL inhibitors for mCRPC.
Galina Semenova, Sander B. Frank, Ruth Dumpit, Wanting Han, Ilsa Coleman, Roman Gulati, Canan D. Dirican, Tarana Arman, Jessica Maruwan, Colm Morrissey, Michael C. Haffner, Peter S. Nelson, John K. Lee
Obesity is increasingly implicated in hematopoietic malignancies, yet its role in mutation-driven myeloid leukemias remains unclear. Using UK Biobank data from over 440,000 individuals, we found obesity traits including elevated BMI and waist-to-hip ratio were associated with type 2 diabetes, increased plasma IL-17A (interleukin-17A), reduced GLP-1R (glucagon like peptide 1 receptor) expression, and heightened risk of myeloid malignancies. Transplantation of protein tyrosine phosphatase non-receptor type 11, PTPN11 (Shp2E76K/+) mutant hematopoietic stem/progenitors into obese mice demonstrated that metabolic inflammation accelerates leukemogenesis via myeloid cell expansion, lipid metabolic rewiring, IL-17A activation, and accumulation of M2-like tumor-associated macrophages (TAMs), accompanied by T-cell exhaustion and impaired antigen presentation. Notably, dual therapy with an anti-IL-17A antibody and a GLP-1R agonist reversed these effects, by reducing M2-like TAMs, restoring Ciita-dependent antigen presentation, Tyk2-mediated IFNγ signaling, reactivated T-cell responses, and reducing leukemic burden. These findings establish IL-17A driven, metabolism-coupled immunosuppression as a mechanistic link between obesity and SHP2-mutant myeloid leukemias, highlighting a tractable therapeutic strategy for high-risk obese patients.
Reuben Kapur, Linke Li, Rahul Kanumuri, Kanaka Sai Ram Padam, Baskar Ramdas, Chiranjeevi Pasala, Gabriela Chiosis, Lakshmi Reddy Palam, Ramesh Kumar, Satoshi Koyama, Pradeep Natarajan, Laura S. Haneline, Zhi Yu, Santhosh Kumar Pasupuleti
CIC::DUX4 sarcoma (CDS) is a lethal cancer driven by a fusion between tumor suppressor Capicua (CIC) and pioneer transcription factor double homeobox 4 (DUX4). We previously generated three genetically engineered mouse models (GEMMs) of CDS with CIC::DUX4 regulated by loxP-STOP-loxP cassettes, however, all three models developed spontaneous tumors without Cre recombinase. Here, we established a next-generation GEMM of CDS (dFLEx CDS) that employs a dual recombinase (Cre + FLPE) FLEx-switch design to activate CIC::DUX4 expression and initiate sarcomagenesis in a spatially and temporally-controlled manner. Because CIC::DUX4 drives sarcoma development by activating a oncogenic transcriptional program, we performed a drug screen on human-derived CDS cell lines using a library of compounds that modulate transcription. This screen identified Minnelide, an inhibitor of RNA polymerase II-mediated transcription, as a selective inhibitor of CDS. Mechanistically, Minnelide acted through xeroderma pigmentosum type B to alter phosphorylation of RPB1, the largest subunit of RNA polymerase II. Subsequently, RPB1 underwent degradation leading to apoptosis of CDS cells. Minnelide demonstrated in vivo efficacy in dFLEx CDS GEMMs and in human CDS xenografts. As Minnelide has already been demonstrated to be safe in clinical trials, these findings nominate Minnelide as a potential therapeutic option to test in CDS patients.
MaKenna R. Browne, Axel V. Silver, Risha Banerjee, Brendan C. Dickson, Benigno Aquino, Kristianne M. Oristian, Jonathon E. Himes, Peter G. Hendrickson, David G. Kirsch