Efficacy In Mouse Model Research Articles

The Photodynamic Agent Designed by Involvement of Hydrogen Atom Transferfor Enhancing Photodynamic Therapy.

Although Type-I photodynamic therapy has attracted increasingly growing interest due to its reduced dependence on oxygen, the design of effective Type-I photosensitizers remains a challenge. In this work, we report a design strategy for Type-I photosensitizers by the involvement of hydrogen atom transfer (HAT). As a proof of concept, a HAT-involved Type-I PS, which simultaneously generates superoxide and carbon-centered radicals under light-irradiation, was synthesized. This photosensitizer is comprised of a fluorene-substituted BODIPY unit as an electron acceptor covalently linked with a triphenylamine moiety as an electron donor. Under light-irradiation, photo-induced intramolecular electron transfer occurs to generate the BODIPY anion radical and triphenylamine cation radical. The former transfers electrons to oxygen to generate O2-•, while the latter loses a proton to produce a benzyl carbon-centered radical which is well characterized. The resulting carbon-centered radicals efficiently oxidize NADH by HAT reaction. This photosensitizer demonstrates remarkable photocytotoxicity even under hypoxic conditions, along with outstanding in vivo antitumor efficacy in mouse models bearing HeLa tumors. This work offers a novel strategy for the design of Type-I photosensitizers by involvement of HAT.

167 (PB155): Discovery of first-in-class precision antibody drug conjugates with a potent SMARCA2/4 dual degrader payload that safely achieve maximal and tumor specific degradation and efficacy in mouse models

167 (PB155): Discovery of first-in-class precision antibody drug conjugates with a potent SMARCA2/4 dual degrader payload that safely achieve maximal and tumor specific degradation and efficacy in mouse models

Abstract A070: Time-Dependent Oxidation and Aggregation of Vimentin upon Binding by β-lap Induced Immunogenic Cell Death

Abstract β-lapachone (β-lap) has been demonstrated as an NAD(P)H:quinone oxidoreductase1 (NQO1) bioactivatable compound. It initiated a futile redox cycle catalyzed by NQO1, resulting in reactive oxygen species (ROS) generation, with consumption of the reductive NAD(P)H. After a 4-h pulse of sufficiently lethal dose of β-lap, high levels of ROS diffused into nuclei to induce tumor-selective DNA damage and programmed necrosis in cancers overexpressing NQO1. Recently, our experiments showed that prolonged low dose β-lap administration exerted significant and NQO1 independent antitumor efficacy in mouse models with no overt signs of toxicity. Thus, we synthesized a photoactive β-lap probe to identify the molecular target of β-lap. Vimentin, a major constituent of the intermediate filament family of proteins, was identified as the direct binding target of β-lap. Vimentin was highly upregulated in multiple cancers including PDAC, and was a binding partner of β-lap with a dissociation constant at micromolar levels. Ligand binding assays in Panc1 cells employing β-lap as a specific competitor showed that vimentin was bound by β-lap-probe in a β-lap-competitive manner, and further confirmed that the in vivobinding target of β-lap was vimentin. Moreover, it was manifested that endogenous vimentin mRNA levels directly correlated with sensitivity to prolonged exposure of β-lap in a panel of pancreatic cancer cell lines, and knockout of vimentin in Panc1 cells markedly decreased lethality after prolonged exposure of β-lap. Mechanistically, we revealed that β-lap bound to vimentin and induced disulfide bonds that participated in disulfide cross-linking between a pair of vimentin dimers in a concentration and time dependent manner, forming vimentin oligomers of approximately 150 kDa. Prolonged exposure of β-lap promoted the disruption of filament architecture and vimentin degradation, ultimately resulting in cell death. In addition, the cell death by targeting vimentin exhibited a more inflammatory condition and enhanced DC activation. Together, our findings unveiled an unknown molecular target for β-lap and provided valuable insights into its mechanism of action. Targeting vimentin also presented a new strategy that inhibited the tumor growth and synergized with immunotherapy to disrupt immune evasion and reduce immune suppression against pancreatic cancers. Citation Format: Feng Qian, Lei Dou, Kaixin Wang, Yi Xia, Zhidong Chen, Yumeng Zu, Shuang Xi. Time-Dependent Oxidation and Aggregation of Vimentin upon Binding by β-lap Induced Immunogenic Cell Death [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr A070.

Abstract C001: Transforming Growth Factor-β Blockade in Pancreatic Cancer Enhances Sensitivity to Combination Chemotherapy in Mice

Abstract Background: TGFβ plays a critical role in promoting pancreatic tumor progression, attenuating CD8 T cell proliferation and cytokine production, enhancing the differentiation of myofibroblasts and the deposition of extracellular matrix. However, single agent TGFβ blockade has shown limited efficacy in mouse models of pancreatic cancer. Methods: We evaluated the TGFβ- blocking antibody NIS793 in combination with gemcitabine/nanoparticle (albumin-bound)- paclitaxel or FOLFIRINOX (folinic acid [FOL], 5-fluorouracil [F], irinotecan [IRI] and oxaliplatin [OX]) in orthotopic pancreatic cancer models. Single-cell RNA sequencing and immunofluorescence were used to evaluate changes in tumor cell state and the tumor microenvironment. Results: Blockade of TGFβ with chemotherapy reduced tumor burden in poorly immunogenic pancreatic cancer, without affecting the metastatic rate of cancer cells. Efficacy of combination therapy was not dependent on CD8 T cells, because response to TGFβ blockade was preserved in CD8-depleted or recombination activating gene 2 (RAG2-/-) mice. TGFβ blockade decreased total α-smooth muscle actin-positive fibroblasts but had minimal effect on fibroblast heterogeneity. Bulk RNA sequencing on tumor cells sorted ex vivo revealed that tumor cells treated with TGFβ blockade adopted a classical lineage consistent with enhanced chemosensitivity, and immunofluorescence for cleaved caspase 3 confirmed that TGFβ blockade increased chemotherapy-induced cell death in vivo. Conclusions: TGFβ regulates pancreatic cancer cell plasticity between classical and basal cell states. TGFβ blockade in orthotropic models of pancreatic cancer enhances sensitivity to chemotherapy by promoting a classical malignant cell state. This study provides scientific rationale for evaluation of NIS793 with FOLFIRINOX or gemcitabine/nanoparticle (albumin-bound) paclitaxel chemotherapy backbone in the clinical setting and supports the concept of manipulating cancer cell plasticity to increase the efficacy of combination therapy regimens. This study provided the scientific rationale for the evaluation of TGFβ with both chemotherapy backbones in the clinical setting. Ongoing evaluation of samples from the stopped clinical trials will inform as to the role of TGFb in human PDAC. Citation Format: Li Qiang, Megan Hoffman, Lestat Ali, Jaime Ivan Castillo Silva, Lauren Kageler, Ayantu Temesgen, Patrick Lenehan, Jennifer Wang, Elisa Bello, Victoire Cardot-Ruffino, Giselle Uribe, Annan Yang, Michael Dougan, Andrew Aguirre, Srivatsan Raghavan5, Marc Pelletier, Viviana Cremasco, Stephanie Dougan. Transforming Growth Factor-β Blockade in Pancreatic Cancer Enhances Sensitivity to Combination Chemotherapy in Mice [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr C001.

Inhibitor of the non-structural protein 2 protease shows promising efficacy in mouse models of chikungunya

Chikungunya virus (CHIKV) is responsible for the most endemic alphavirus infections called Chikungunya. The endemicity of Chikungunya has increased over the past two decades, and it is a pathogen with pandemic potential. There is currently no approved direct-acting antiviral to treat the disease. As part of our antiviral drug discovery program focused on alphaviruses and the non-structural protein 2 protease, we discovered that J12 and J13 can inhibit CHIKV nsP2 protease and block the replication of CHIKV in cell cultures. Both compounds are metabolically stable to human liver microsomal and S9 enzymes. J13 has excellent oral bioavailability in pharmacokinetics studies in mice and ameliorated Chikungunya symptoms in preliminary efficacy studies in mice. J13 exhibited an excellent safety profile in in vitro safety pharmacology and off-target screening assays, making J13 and its analogs good candidates for drug development against Chikungunya.

Double-Stranded RNA to Mimic Viral Infection for Cancer Immunotherapy.

The presence of moieties denoting viral infection is crucial to mount powerful cytotoxic T-cell immune responses acting through innate receptors such as Toll-like receptor 3. For cancer immunotherapy, several safe analogues of viral double-stranded RNA are under clinical development following compelling evidence for efficacy in mouse models. See related article by van Eijck et al., p. 3447.

Lidocaine HCl-Loaded Polyelectrolyte Complex -Poloxamer Thermoresponsive Hydrogel: In Vitro- In Vivo Anesthetic Evaluations for Tooth Socket Wound Delivery.

Local anesthesia is essential in dental practices, particularly for managing pain in tooth socket wounds, yet improving drug delivery systems remains a significant challenge. This study explored the physicochemical characteristics of lidocaine hydrochloride (LH) incorporated into a polyelectrolyte complex and poloxamer thermosensitivity hydrogel, assessing its local anesthetic efficacy in mouse models and its onset and duration of action as topical anesthetics in clinical trials. The thermoresponsive hydrogel exhibited a rapid phase transition within 1-3minutes and demonstrated pseudo-plastic flow behavior. Its release kinetics followed Korsmeyer-Peppas, with 50% of biodegradation occurring over 48h. In mouse models, certain thermogels showed superior anesthetic effects, with rapid onset and prolonged action, as evidenced by heat tolerance in tail-flick and hot plate models. In clinical trials, the LH-loaded thermoresponsive hydrogel provided rapid numbness onset, with anesthesia (Ton) beginning at an average of 46.5 ± 22.5seconds and lasting effectively (Teff) for 202.5 ± 41.0seconds, ranging from 120 to 240seconds, indicating sustained release. These results highlight the promising properties of these formulations: rapid onset, prolonged duration, mucoadhesion, biodegradability, and high anesthesia effectiveness. This study demonstrates the potential for advancing local anesthesia across various medical fields, emphasizing the synergy between material science and clinical applications to improve patient care and safety.

Botensilimab, an Fc-enhanced anti-CTLA-4 antibody, is effective against tumors poorly responsive to conventional immunotherapy.

Conventional immune checkpoint inhibitors (ICI) targeting CTLA-4 elicit durable survival, but primarily in patients with immune-inflamed tumors. Although the mechanisms underlying response to anti-CTLA-4 remain poorly understood, Fc-gamma receptor (FcγR) IIIA co-engagement appears critical for activity, potentially explaining the modest clinical benefits of approved anti-CTLA-4 antibodies. We demonstrate that anti-CTLA-4 engineered for enhanced FcγR affinity leverages FcγR-dependent mechanisms to potentiate T cell responsiveness, reduce intratumoral Tregs, and enhance antigen presenting cell activation. Fc-enhanced anti-CTLA-4 promoted superior efficacy in mouse models and remodeled innate and adaptive immunity versus conventional anti-CTLA-4. These findings extend to patients treated with botensilimab, an Fc-enhanced anti-CTLA-4 antibody, with clinical activity across multiple poorly immunogenic and ICI treatment-refractory cancers. Efficacy was independent of tumor neoantigen burden or FcγRIIIA genotype. However, FcγRIIA and FcγRIIIA expression emerged as potential response biomarkers. These data highlight the therapeutic potential of Fc-enhanced anti-CTLA-4 antibodies in cancers unresponsive to conventional ICI therapy.

Discovery of Novel Pyrimidine-Based Derivatives as Nav1.2 Inhibitors with Efficacy in Mouse Models of Epilepsy.

Dysfunction of voltage-gated sodium channel Nav1.2 causes various epileptic disorders, and inhibition of the channel has emerged as an attractive therapeutic strategy. However, currently available Nav1.2 inhibitors exhibit low potency and limited structural diversity. In this study, a novel series of pyrimidine-based derivatives with Nav1.2 inhibitory activity were designed, synthesized, and evaluated. Compounds 14 and 35 exhibited potent activity against Nav1.2, boasting IC50 values of 120 and 65 nM, respectively. Compound 14 displayed favorable pharmacokinetics (F = 43%) following intraperitoneal injection and excellent brain penetration potency (B/P = 3.6). Compounds 14 and 35 exhibited robust antiepileptic activities in the maximal electroshock test, with ED50 values of 3.2 and 11.1 mg/kg, respectively. Compound 35 also demonstrated potent antiepileptic activity in a 6 Hz (32 mA) model, with an ED50 value of 18.5 mg/kg. Overall, compounds 14 and 35 are promising leads for the development of new small-molecule therapeutics for epilepsy.

Discovery of autophagy-tethering compounds as potent NLRP3 degraders for IBD Immunotherapy

Nucleotide-binding oligomerization domain-like receptor pyrin domain containing 3 (NLRP3) constitutes an essential inflammasome sensor protein, pivotal in the orchestration of innate immunity. Given its paramount role, NLRP3 has recently emerged as an enticing therapeutic target for disorders associated with inflammation. In this study, we embarked on the design and synthesis of two series of compounds, endowed with the capacity to induce NLRP3 degradation via autophagy-tethering compounds (ATTECs)—an innovative targeted protein degradation technology. Notably, MC-ND-18 emerged as the most potent agent for effectuating NLRP3 degradation through autophagic mechanisms and concurrently exhibited marked anti-inflammatory efficacy in mice model of dextran sulfate sodium (DSS)-induced colitis. Consequently, we have successfully developed a pioneering NLRP3 protein degrader, offering a novel therapeutic avenue for ameliorating NLRP3-associated pathologies.

Comparative immunogenic and immunoprotective activities of PCV2d Cap and Rep antigens delivered by an efficient eukaryotic expression system engineered into a Salmonella vaccine vector

Porcine circovirus type 2 (PCV2) stands as a predominant etiological agent in porcine circovirus-associated diseases. To manage the spread of the disease, it is necessary to develop a next-generation vaccine expressing PCV2 antigens that target the prevailing genotype such as PCV2d. A bacterial-mediated vaccine delivery by live-attenuated Salmonella has attracted interest for its low-cost production and highly effective vaccine delivery. Thus, in this study, we utilized the advantages of the Salmonella-mediated vaccine delivery by cloning PCV2d cap and rep into a eukaryotic expression plasmid pJHL204 and electroporation into an engineered live-attenuated Salmonella Typhimurium JOL2500 (Δlon, ΔcpxR, ΔsifA, Δasd). The eukaryotic antigen expression by JOL2995 (p204:cap) and JOL2996 (p204:rep) was confirmed in vitro and in vivo which showed efficient antigen delivery. Furthermore, vaccination of mice model with the vaccine candidates elicited humoral and cell-mediated immune responses as depicted by high levels of PCV2-specific antibodies, CD4+ and CD8+ T cells, and neutralizing antibodies, especially by JOL2995 (p204:cap) which correlated with the significant decrease in the viral load in PCV2d-challenged mice. Interestingly, JOL2996 (p204:rep) may not have elicited high levels of neutralizing antibodies and protective efficacy, but it elicited considerably higher cell-mediated immune responses. This study demonstrated Salmonella-mediated vaccine delivery system coupled with the eukaryotic expression vector can efficiently deliver and express the target PCV2d antigens for strong induction of immune response and protective efficacy in mice model, further supporting the potential application of the Salmonella-mediated vaccine delivery system as an effective novel approach in vaccine strategies for PCV2d.

A novel anti-LAG-3/TIGIT bispecific antibody exhibits potent anti-tumor efficacy in mouse models as monotherapy or in combination with PD-1 antibody

We report the generation of a novel anti-LAG-3/TIGIT bispecific IgG4 antibody, ZGGS15, and evaluated its anti-tumor efficacy in mouse models as monotherapy or in combination with a PD-1 antibody. ZGGS15 exhibited strong affinities for human LAG-3 and TIGIT, with KDs of 3.05 nM and 2.65 nM, respectively. ZGGS15 has EC50s of 0.69 nM and 1.87 nM for binding to human LAG-3 and TIGIT on CHO-K1 cells, respectively. ZGGS15 competitively inhibited the binding of LAG-3 to MHC-II (IC50 = 0.77 nM) and the binding of TIGIT to CD155 (IC50 = 0.24 nM). ZGGS15 does not induce ADCC, CDC, or obvious cytokine production. In vivo results showed that ZGGS15 had better anti-tumor inhibition than single anti-LAG-3 or anti-TIGIT agents and demonstrated a synergistic effect when combined with nivolumab, with a significantly higher tumor growth inhibition of 95.80% (p = 0.001). The tumor volume inhibition rate for ZGGS15 at 2 mg/kg was 69.70%, and for ZGGS15 at 5 mg/kg plus nivolumab at 1 mg/kg, it was 94.03% (p < 0.001). Our data reveal that ZGGS15 exhibits potent anti-tumor efficacy without eliciting ADCC or CDC or causing cytokine production, therefore having a safe profile.

Antifungal Activity of 3-Hydrazinoquinoxaline-2-Thiol, a Novel Quinoxaline Derivative against Candida Species

Candida ranks as among the most frequently encountered fungal infections that associated with high morbidity and mortality. Quinoxaline derivatives are a group of small molecules that showed a promising antimicrobial activity. This study aimed to investigate the fungicidal effects of 3-hydrazinoquinoxaline-2-thiol against Candida in comparison with Amphotericin B in vitro as a reference. Also, we aim to assess the efficacy of 3-hydrazinoquinoxaline-2-thiol in vivo using mice oral candidiasis model. Fifty-six Candida isolates were subjected to susceptibility testing by broth microdilution method for 3-hydrazinoquinoxaline-2-thiol and Amphotericin B. Therefore, Minimal inhibitory concentrations (MIC) were assessed and compared. The oral candidiasis mice model was used to evaluate the activity of 3-hydrazinoquinoxaline-2-thiol in vivo. Microbiological evaluation of progression and ELISA were used in this study. 3-hydrazinoquinoxaline-2-thiol was more effective than Amphotericin B against most clinical isolates of Candida albicans. Higher effectiveness was seen against Candida glabrata and Candida parapsilosis isolates. However, the efficiency against Candida tropicalis isolates varies. 3-hydrazinoquinoxaline-2-thiol was also effective against Pichia kudriavzevii and Clavispora lusitaniae. 3-hydrazinoquinoxaline-2-thiol showed a good efficacy in mice model against C. albicans cells ATCC 10231. 3-hydrazinoquinoxaline-2-thiol has shown promising antifungal and anti-inflammatory activity against different Candida species. More tests and experiments are needed.

Abstract LB168: A selective, potent, and orally bioavailable CDK7 inhibitor demonstrates superior anti-cancer activity in colorectal cancer models

Abstract Dysregulated cell cycle and gene expression are pivotal factors in cancer development and the regulators of these processes are attractive targets for cancer treatment. The success of CDK4/6 inhibitors such as palbociclib, ribociclib, and abemaciclib underscores the promising role of targeting cell cycle regulators in anti-cancer therapy. On the other hand, a robust correlation has been established between the overexpression of oncogenes and super-enhancer (SE). The genes associated with SE show increased vulnerability to transcription factor disruption compared to genes with typical enhancers. It has been demonstrated in previous studies that inhibiting transcription factors can effectively decrease the expression of SE-associated oncogenes, including c-MYC, thereby highlighting potential anticancer effects for oncogene-addicted cancers. Currently, agents targeting transcription factors are undergoing clinical trials, offering promising therapeutic options for patients with various types of cancers. CDK7 plays a crucial role in orchestrating cell cycle progression and transcription by phosphorylating CDKs, the C-terminal domain of RNA polymerase II, and hormone receptors like estrogen and androgen receptors. The inhibition of CDK7 has been shown to effectively inhibit tumor growth through various mechanisms, including inducing cell cycle arrest and inhibiting transcription, thereby leading to the death of cancer cells. Notably, ongoing clinical studies have demonstrated that small-molecule CDK7 inhibitors effectively control cancer progression as a stand-alone and in combination with other anti-cancer agents. C-16661, a selective, potent, orally bioavailable, and reversible ATP-competitive inhibitor of CDK7, displayed a single-digit nanomolar IC50 value in both biochemical and cellular assays. It exhibited excellent selectivity in a kinase panel assay, and remarkable potency in a human cancer cell line panel assay. C-16661 treatment resulted in strong inhibition of both its direct and indirect downstream targets including pS5-POLII, pT161-CDK1, c-MYC, and MCL1 in HCT116, a human colorectal carcinoma cell line. While C-16661 exhibited good PK profiles in animals, it demonstrated excellent tumor growth inhibition without any tolerability issues in a colorectal cancer CDX mouse efficacy model. Citation Format: Heuijoon Park, Kyoungwan Seo, Jihyun Yu, Jieun Kim, Min Sung Joo, Sungeun Kim, Joonhyung Lee, Jeonghyeon Lee, Eun-Jung Kim, Joonwoo Nam, Wooseok Han. A selective, potent, and orally bioavailable CDK7 inhibitor demonstrates superior anti-cancer activity in colorectal cancer models [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 2 (Late-Breaking, Clinical Trial, and Invited Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(7_Suppl):Abstract nr LB168.

N-oleoyl alanine attenuates nicotine reward and spontaneous nicotine withdrawal in mice

BackgroundAs nicotine dependence represents a longstanding major public health issue, new nicotine cessation pharmacotherapies are needed. Administration of N-oleoyl glycine (OlGly), an endogenous lipid signaling molecule, prevents nicotine-induced conditioned place preference (CPP) through a peroxisome proliferator-activated receptor-alpha (PPARα) dependent mechanism, and also ameliorated withdrawal signs in nicotine-dependent mice. Pharmacological evidence suggests that the methylated analog of OlGly, N-oleoyl alanine (OlAla), has an increased duration of action and may offer translational benefit. Accordingly, OlAla was assessed in nicotine CPP and dependence assays as well as its pharmacokinetics compared to OlGly. MethodsICR female and male mice were tested in nicotine-induced CPP with and without the PPARα antagonist GW6471. OlAla was also assessed in nicotine-dependent mice following removal of nicotine minipumps: somatic withdrawal signs, thermal hyper-nociception and altered affective behavior (i.e., light/dark box). Finally, plasma and brain were collected after administration of OlGly or OlAla and analyzed by high-performance liquid chromatography tandem mass spectrometry. ResultsOlAla prevented nicotine-induced CPP, but this effect was not blocked by GW6471. OlAla attenuated somatic and affective nicotine withdrawal signs, but not thermal hyper-nociception in nicotine-dependent mice undergoing withdrawal. OlAla and OlGly showed similar time-courses in plasma and brain. ConclusionsThe observation that both molecules showed similar pharmacokinetics argues against the notion that OlAla offers increased metabolic stability. Moreover, while these structurally similar lipids show efficacy in mouse models of reward and dependence, they reduce nicotine reward through distinct mechanisms.

A novel dual mechanism-of-action bispecific PD-1-IL-2v armed by a "βγ-only" interleukin-2 variant.

Interleukin-2 (IL-2) is one of the first cytokines to be discovered as an immune agonist for cancer immunotherapy. Biased IL-2 variants had been discovered to eliminate Treg activation or enhance the tumor specific T cell cytotoxicity. However, all the biased IL-2 variants pose the risk to overstimulate immune response at a low-dose range. Here, we introduce a novel dual-MOA bispecific PD-1-IL-2v molecule with great anti-tumor efficacy in a high dosed manner. The novel IL-2 variant was designed by structural truncation and shuffling. The single armed bispecific PD-1-IL-2v molecule and IL-2v were studied by immune cell activations in vitro and in vivo and anti-tumor efficacy in mouse model. The IL-2 variant in this bispecific antibody only binds to IL-2Rβγ complex in a fast-on/off manner without α, β or γ single receptor binding. This IL-2v mildly activates T and NK cells without over stimulation, meanwhile it diminishes Treg activation compared to the wild type IL-2. This unique bispecific molecule with "βγ-only" IL-2v can not only "in-cis" stimulate and expand CD8 T and NK cells moderately without Treg activation, but also block the PD-1/L1 interaction at a similar dose range with monoclonal antibody.

Abstract 3056: Copper chelation modulates YTHDF2 RNA-binding protein localization and global translation, in neuronal cancers

Abstract Cancers are dependent on copper for growth, angiogenesis and metastasis and copper chelators are in clinical trials against breast cancer, however the mechanisms of this emerging cancer treatment are still largely unexplored. We previously demonstrated that copper chelation has efficacy in mouse models of neuroblastoma and glioma. Multiomics analyses in neuronal cancers suggested that RNA-binding proteins were deregulated by copper chelator treatment. We found that the “RNA Binding” gene set was the most significantly ranked molecular function list using differentially expressed RNAs after copper chelation treatment (GO:0003723, p-value 1.02e−32). We subsequently found that the copper chelator drug decreased global protein synthesis, MYC/MYCN expression, as well as the amount a key methylated (m6A) RNA-binding protein called YTHDF2 in glioma cells, by RNA-seq (-log2FC 0.3, p-value 0.005) and western blot. This downregulation was also clear in neuroblastoma and glioblastoma cell lines. Interestingly, copper chelation also shifted YTHDF2 protein location into the nucleus. YTHDF2 knock-out (DepMAP Chronos dependency score, -0.32) and knock-down studies (siRNA pool, 38% decrease in cell confluence) in neuroblastoma cell lines and others, indicated that YTHDF2 depletion is selective against neuronal cancer cell growth. YTHDF2 was found to be a MYCN transcriptional target. Moreover, as YTHDF2 protein also binds MYCN transcripts (the principal oncogene in neuroblastoma), and copper signaling mRNAs, it appears that copper signaling, YTHDF2 and MYCs operates in an oncogenic-axis. Ongoing studies are investigating novel YTHDF2 inhibitors and their neuronal cancer efficacy. Our work represents a significant breakthrough in drugging oncogenic post-transcriptional processes either directly, or indirectly via depleting copper. Citation Format: Jessica L. Bell, Domenico K. Abruzzese, Erin Kasiou, Vu Vu Pham, Jean B. Bertoldo, Filip Michniewicz, Orazio Vittorio. Copper chelation modulates YTHDF2 RNA-binding protein localization and global translation, in neuronal cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 3056.

Abstract 5301: Tumor-targeted activation of CD137 using Bicycles: New insights into mechanism of action and discovery of BT7455, a clinical candidate for the treatment of EphA2-expressing cancers

Abstract Introduction: Clinical studies in cancer patients have validated CD137 agonism as an activator of the immune system to enable tumor rejection. We have demonstrated that small, chemically synthetic bicyclic peptides can drive tumor-localized agonism of CD137 and anti-tumor immunity in mouse models. Here, we report the next stage of our work - delving into the mechanism of action of these novel agents and extending our program to serve patients whose tumors express EphA2. Experimental Procedures: MultiOmyx™ hyperplexed immunofluorescence assay was used to evaluate the expression of CD137 and EphA2 in head and neck squamous cell carcinoma samples. Human PBMC/tumor cell co-culture assays were used to assess CD137 Bicycle TICA™ in vitro bioactivity and syngeneic mouse tumor models were used to evaluate CD137 Bicycle TICA anti-tumor activity as mono- or combination therapies. Pharmacodynamic activity was evaluated by transcriptional profiling using NanoString assays or single cell RNA sequencing. Summary of the Data: Studies utilizing a syngeneic mouse model and deep RNA sequencing of tumors from CD137 Bicycle TICA-treated mice implicated intratumoral dendritic cells in addition to T cells as early responders to localized CD137 agonism and potential contributors to the anti-tumor response. Furthermore, a mouse efficacy model demonstrated synergy with checkpoint inhibitor therapy. Multiplex imaging revealed that EphA2 and CD137 are co-expressed in human tumors of high unmet medical need and therefore, using our highly modular Bicycle platform, we discovered BT7455, a Bicycle TICA that engages EphA2 and CD137 with high affinity, resulting in potent EphA2-dependent activity in vitro and robust anti-tumor activity in vivo with intermittent dosing in mouse models. Gene expression profiling of tumors revealed that BT7455 led to increased production of cytokines and chemokines known to drive T cell infiltration, the extent of which differentiated it from both a checkpoint inhibitor and an anti-CD137 monoclonal antibody agonist. BT7455 was well tolerated in preclinical species and liver function tests indicated no evidence of hepatic toxicity. Statement of Conclusions: In summary, we have identified EphA2 as a promising target to pair with a CD137 agonist. In addition to CD8+ T cells, tumor-resident dendritic cells are a likely contributor to anti-tumor immunity following treatment with Bicycle® TICAs, supporting utility for Bicycle® tumor-targeted CD137 agonists in solid tumors beyond those that are highly T cell-infiltrated. We have advanced a clinical development candidate, BT7455, to realize this potential for patients with EphA2-expressing cancers. Citation Format: Johanna Lahdenranta, Kristen Hurov, Heather Cohen, Lia Luus, Cara Bray, Peter Brown, Anna Devlen, Carly Campbell, Matthew Gray, Mike Kelly, Gemma Mudd, Punit Upadhyaya, Sailaja Battula, Kelvin Zhang, Anne-Sophie Dugast, Kevin McDonnell, Phil Brandish, Nicholas Keen. Tumor-targeted activation of CD137 using Bicycles: New insights into mechanism of action and discovery of BT7455, a clinical candidate for the treatment of EphA2-expressing cancers [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 5301.

PH-Activatable Pre-Nanozyme Mediated H2S Delivery for Endo-Exogenous Regulation of Oxidative Stress in Acute Kidney Injury.

Oxidative stress induced by excess reactive oxygen species (ROS) is a primary pathogenic cause of acute kidney injury (AKI). Development of an effective antioxidation system to mitigate oxidative stress for alleviating AKI remains to be investigated. This study presents the synthesis of an ultra-small Platinum (Pt) sulfur cluster (Pt5.65S), which functions as a pH-activatable prefabricated nanozyme (pre-nanozyme). This pre-nanozyme releases hydrogen sulfide (H2S) and transforms into a nanozyme (Ptzyme) that mimics various antioxidant enzymes, including superoxide dismutase and catalase, within the inflammatory microenvironment. Notably, the Pt5.65S pre-nanozyme exhibits an endo-exogenous synergy-enhanced antioxidant therapeutic mechanism. The Ptzyme reduces oxidative damage and inflammation, while the released H2S gas promotes proneurogenesis by activating Nrf2 and upregulating the expression of antioxidant molecules and enzymes. Consequently, the Pt5.65S pre-nanozyme showscytoprotective effects against ROS/reactive nitrogen species (RNS)-mediated damage at remarkably low doses, significantly improving treatment efficacy in mouse models of kidney ischemia-reperfusion injury and cisplatin-induced AKI. Based on these findings, the H2S-generating pre-nanozyme may represent a promising therapeutic strategy for mitigating inflammatory diseases such as AKI and others.

A CAG repeat threshold for therapeutics targeting somatic instability in Huntington's disease.

The Huntington's disease mutation is a CAG repeat expansion in the huntingtin gene that results in an expanded polyglutamine tract in the huntingtin protein. The CAG repeat is unstable and expansions of hundreds of CAGs have been detected in Huntington's disease post-mortem brains. The age of disease onset can be predicted partially from the length of the CAG repeat as measured in blood. Onset age is also determined by genetic modifiers, which in six cases involve variation in DNA mismatch repair pathways genes. Knocking-out specific mismatch repair genes in mouse models of Huntington's disease prevents somatic CAG repeat expansion. Taken together, these results have led to the hypothesis that somatic CAG repeat expansion in Huntington's disease brains is required for pathogenesis. Therefore, the pathogenic repeat threshold in brain is longer than (CAG)40, as measured in blood, and is currently unknown. The mismatch repair gene MSH3 has become a major focus for therapeutic development, as unlike other mismatch repair genes, nullizygosity for MSH3 does not cause malignancies associated with mismatch repair deficiency. Potential treatments targeting MSH3 currently under development include gene therapy, biologics and small molecules, which will be assessed for efficacy in mouse models of Huntington's disease. The zQ175 knock-in model carries a mutation of approximately (CAG)185 and develops early molecular and pathological phenotypes that have been extensively characterized. Therefore, we crossed the mutant huntingtin allele onto heterozygous and homozygous Msh3 knockout backgrounds to determine the maximum benefit of targeting Msh3 in this model. Ablation of Msh3 prevented somatic expansion throughout the brain and periphery, and reduction of Msh3 by 50% decreased the rate of expansion. This had no effect on the deposition of huntingtin aggregation in the nuclei of striatal neurons, nor on the dysregulated striatal transcriptional profile. This contrasts with ablating Msh3 in knock-in models with shorter CAG repeat expansions. Therefore, further expansion of a (CAG)185 repeat in striatal neurons does not accelerate the onset of molecular and neuropathological phenotypes. It is striking that highly expanded CAG repeats of a similar size in humans cause disease onset before 2 years of age, indicating that somatic CAG repeat expansion in the brain is not required for pathogenesis. Given that the trajectory for somatic CAG expansion in the brains of Huntington's disease mutation carriers is unknown, our study underlines the importance of administering treatments targeting somatic instability as early as possible.