Xenograft Mouse Research Articles

Dysregulation of the p53 pathway provides a therapeutic target in aggressive pediatric sarcomas with stem-like traits.

Pediatric sarcomas are bone and soft tissue tumors that often exhibit high metastatic potential and refractory stem-like phenotypes, resulting in poor outcomes. Aggressive sarcomas frequently harbor a disrupted p53 pathway. However, whether pediatric sarcoma stemness is associated with abrogated p53 function and might be attenuated via p53 reactivation remains unclear. We utilized a unique panel of pediatric sarcoma models and tumor tissue cohorts to investigate the correlation between the expression of stemness-related transcription factors, p53 pathway dysregulations, tumorigenicity in vivo, and clinicopathological features. TP53 mutation status was assessed by next-generation sequencing. Major findings were validated via shRNA-mediated silencing and functional assays. The p53 pathway-targeting drugs were used to explore the effects and selectivity of p53 reactivation against sarcoma cells with stem-like traits. We found that highly tumorigenic stem-like sarcoma cells exhibit dysregulated p53, making them vulnerable to drugs that restore wild-type p53 activity. Immunohistochemistry of mouse xenografts and human tumor tissues revealed that p53 dysregulations, together with enhanced expression of the stemness-related transcription factors SOX2 or KLF4, are crucial features in pediatric osteosarcoma, rhabdomyosarcoma, and Ewing's sarcoma development. p53 dysregulation appears to be an important step for sarcoma cells to acquire a fully stem-like phenotype, and p53-positive pediatric sarcomas exhibit a high frequency of early metastasis. Importantly, reactivating p53 signaling via MDM2/MDMX inhibition selectively induces apoptosis in aggressive, stem-like Ewing's sarcoma cells while sparing healthy fibroblasts. Our results indicate that restoring canonical p53 activity provides a promising strategy for developing improved therapies for pediatric sarcomas with unfavorable stem-like traits.

Depletion of Tregs from CD4+ CAR-Tcells enhances the tumoricidal effect of CD8+ CAR-Tcells in anti-CD19 CAR-T therapy.

Chimeric antigen receptor T (CAR-T) cell therapy, which targets CD19 for hematological malignancies, represents a breakthrough in cancer immunotherapy. However, some patients may develop resistance to CAR-T treatment, underscoring the importance of optimizing CAR-T design to enhance responsiveness. Here, we investigated the impact of different subpopulations in anti-CD19 CAR-T cells on the tumoricidal effect. Different populations of anti-CD19 CAR-T cells were isolated by magnetic-activated cell sorting (MACS). Their lytic activities on the acute lymphocytic leukemia cell line SUP-B15 and diffuse large B-cell lymphoma EB-3 cell line were examined in a co-culture system. The anti-tumorigenic outcome of different CAR-T cell compositions was evaluated in a xenograft mouse model of EB-3 cells. CD8+CAR-T cells exhibited the most potent tumoricidal activity against SUP-B15 and EB-3 cells. Additionally, CD4+ T helper cells enhanced the lytic effects of CD8+ CAR-T cells by increasing the availability of interleukin-2 (IL-2). Depleting CD25+Treg (T regulatory) cells from CD4+CAR-T population further augmented the tumoricidal activity of CD8+CAR-T cells by preventing IL-2 deprivation. Consistently, in vivo experiments demonstrated that the CD4+CD25+ Treg population dampened the antitumor activity of CD8+CAR-T cells, while depletion of Tregs from CD4+CAR-T cells enhanced the tumoricidal effect. These findings emphasize the potential role of CAR Treg cells in therapeutic resistance, suggesting that the depletion of Tregs in the anti-CD19 CAR-T population may serve as a strategy to augment the anticancer effect of CD8+CAR-T cells.

Polyethylene glycol-phospholipid functionalized single-walled carbon nanotubes for enhanced siRNA systemic delivery

Small interfering RNAs (siRNA) technology has emerged as a promising therapeutic tool for human health conditions like cancer due to its ability to regulate gene silencing. Despite FDA-approved, their delivery remains localized and limiting their systemic use. This study used single-walled carbon nanotubes (SWNTs) functionalized with polyethylene glycolated (PEGylated) phospholipids (PL-PEG) derivatives for systemic siRNA delivery. We developed an siRNA systemic delivery vehicle (SWNT-siRNA) by conjugating SWNT functionalized with PL-PEG containing either amine (PA) or maleimide (MA). The functionalized SWNT with a lower molecular weight of PA produced the SWNT-siRNA conjugate system with the highest stability and high siRNA loading quantity. The system delivered siRNA to a panel of tumour cell lines of different organs (i.e. HeLa, H1299 and MCF-7) and a non-cancerous human embryonic kidney 293 cells (HEK293T) with high biocompatibility and low toxicity. The cellular uptake of SWNT-siRNA conjugates by epithelial cells was found to be energy dependent. Importantly, the presence of P-glycoprotein, a marker for drug resistance, did not inhibit SWNT-mediated siRNA delivery. Mouse xenograft model further confirmed the potential of SWNT-siRNA conjugates with a significant gene knock-down without signs of acute toxicity. These findings pave the way for potential gene therapy applications using SWNTs as delivery vehicles.

Targeting autophagy in HCC treatment: exploiting the CD147 internalization pathway

Background/AimsChemotherapy resistance in liver cancer is a major clinical issue, with CD147 playing a vital role in this process. However, the specific mechanisms underlying these processes remain largely unknown. This study investigates how CD147 internalization leads to cytoprotective autophagy, contributing to chemotherapy resistance in hepatocellular carcinoma (HCC).MethodsUtilizing bioinformatics methods for KEGG pathways enrichment and screening key molecules associated with chemotherapy resistance through analyses of GEO and TCGA databases. An overexpression/knockdown system was used to study how CD147 internalization leads to autophagy in vitro and in vivo. The process was observed using microscopes, and molecular interactions and autophagy flux were analyzed. Analyzing the internalization of CD147 intracellular domains and the interaction with G3BP1 in clinical chemotherapy recurrence HCC tissues by immunohistochemistry, tissue immunofluorescence, and mass spectrometry. A tumor xenograft mice model was used to study cytoprotective autophagy induced by CD147 and test the effectiveness of combining cisplatin with an autophagy inhibitor in nude mice models.ResultsIn our study, we identified the tumor-associated membrane protein CD147, which implicated in chemoresistance lysosome pathways, by evaluating its protein degree value and betweenness centrality using Cytoscape. Our findings revealed that CD147 undergoes internalization and interacts with G3BP1 following treatment with cisplatin and methyl-β-cyclodextrin, forming a complex that is transported to lysosomes via Rab7A. Notably, higher doses of cisplatin enhanced CD147-mediated lysosomal transport while concurrently inhibiting SG assembly. The CD147-G3BP1 complex additionally inhibits mTOR activity, promoting autophagy and augmenting chemoresistance in hepatoma cells. In vivo studies investigations and analyses of clinical samples revealed that elevated internalization of CD147 is associated with chemotherapy recurrence in liver cancer and the maintenance of stem cells. Mice experiments found that the combined administration of cisplatin and hydroxychloroquine enhanced the efficacy of treatment.ConclusionsThis study reveals that CD147 internalization and CD147-G3BP1 complex translocation to lysosomes induce cytoprotective autophagy, reducing chemotherapy sensitivity by suppressing mTOR activity. It is also shown that chemotherapy drugs combined with autophagy inhibitors can improve the therapeutic effect of cancer, providing new insights into potential targeted therapeutic approaches in treating HCC.

Dual rectification of metabolism abnormality in pancreatic cancer by a programmed nanomedicine

Pancreatic ductal adenocarcinoma (PDAC) is a highly aggressive and lethal malignancy characterized by dysregulated energy and stromal metabolism. It is strongly supported by activated pancreatic stellate cells (PSC) which drive excessive desmoplasia and tumor growth via metabolic crosstalk. Herein, a programmed nanosystem is designed to dual rectify the metabolism abnormalities of the PDAC cells, which overexpress glucose transporter 1(GLUT1) and CD71, and the PSC for oncotherapy. The nanosystem is based on a tumor microenvironment-responsive liposome encapsulating an NF-κB inhibitor (TPCA-1) and a CD71 aptamer-linked Glut1 siRNA. TPCA-1 reverses the activated PSC to quiescence, which hampers metabolic support of the PSC to PDAC cells and bolsters the PDAC cell-targeting delivery of the siRNA. Aerobic glycolysis and the following enhancement of oxidative phosphorylation are restrained by the nano-modulation so as to amplify anti-PDAC efficacy in an orthotopic xenograft mouse model, which implies more personalized PDAC treatment based on different energy metabolic profiles.

YKL-06-061 exerts antitumor effect through G1/S phase arrest by downregulating c-Myc and inhibition of metastasis via SIK1 upregulation in pancreatic cancer.

Pancreatic cancer ranks fourth among cancer-related deaths with a low 5-year overall survival rate of less than 13%. At present, treatment of pancreatic cancer is still based on chemotherapy, but the efficacy is limited. Thus, a novel therapeutic agent for pancreatic cancer therapy is urgently needed. A library of compounds was screened, and YKL-06-061, a selective inhibitor of salt-inducible kinases (SIKs), was discovered for its ability of inhibiting the proliferation and metastasis of pancreatic cancer cells in vitro and reducing the growth of xenografts in nude mice in vivo. The results from transcriptome analysis showed that YKL-06-061 influenced the mRNA levels of many genes related to c-Myc and SIK1 signals. Based on this, it was found that YKL-06-061 induced cell cycle arrest at the G1 phase and decreased the levels of c-Myc, CDK4, and cyclin D1 protein. At the same time, YKL-06-061 inhibited invasion and metastasis of cancer cells, increased the levels of SIK1 and E-cadherin protein, and lowered vimentin and ZEB-1. Moreover, YKL-06-061 effectively enhanced the antiproliferation of gemcitabine or doxorubicin in pancreatic cancer cells in a synergistic manner. Collectively, these findings implicate YKL-06-061 as a promising therapeutic agent for patients with pancreatic cancer.

Human leukocyte antigen DR alpha inhibits renal cell carcinoma progression by promoting the polarization of M2 macrophages to M1 via the NF-κB pathway

Human leukocyte antigen DR alpha (HLA-DRA) is recognized for its inhibitory effect on the progression of clear cell renal cell carcinoma (ccRCC); high HLA-DRA expression levels are positively correlated with improved prognosis in patients with ccRCC. In this study, we evaluated HLA-DRA expression in ccRCCs, its effects on tumor-associated macrophage recruitment, and the influence of polarization. Clinical cohort analyses revealed that elevated HLA-DRA expression in ccRCC cells was correlated with enhanced tumor infiltration by M1-type macrophages. In addition, ccRCC prognosis was predicted by combining HLA-DRA expression level analysis and the M1/M2 macrophage ratio. In vitro studies demonstrated that ccRCC cells with increased HLA-DRA expression promoted THP-1 cell migration and induced macrophage polarization toward the M1 phenotype. The effect was further substantiated in a mouse xenograft model in which an increase in M1 macrophages was observed. In addition, co-culturing macrophages with the supernatant from cells overexpressing HLA-DRA induced the expression of proteins associated with both M1 and M2 macrophage polarization. HLA-DRA was intricately linked to the expression and secretion of chemokines, including CCL2, CCL5, MIP-1ɑ, and CXCL-10. Moreover, the NF-κB pathway activation promoted polarization to M1 macrophages. This study shows that HLA-DRA and the M1/M2 ratio are indicators of favorable prognosis in patients with ccRCC. HLA-DRA promotes M1-like polarization by regulating NF-κB, which can be used as a therapeutic target to enhance anti-tumor immunity.

CX43-mediated mitochondrial transfer maintains stemness of KG-1a leukemia stem cells through metabolic remodeling

BackgroundAcute myeloid leukemia (AML) is characterized by abundant immature myeloid cells, relapse and refractory due to leukemia stem cells (LSCs). Bone marrow mesenchymal stem/ stromal cells (BMSCs) supported LSCs survival, meanwhile, chemotherapy improved connexin43 (CX43) expression. CX43, as the most intercellular gap junction, facilitated transmit mitochondria from BMSCs into AML. We hypothesized that increased mitochondria transferred from BMSCs supported metabolic remodeling in LSCs to sustain their stemness.MethodsPrimary BMSCs from AML patients were isolated. CX43-BMSCs, overexpressing CX43, were cocultured with KG-1a cells. Fluorescence and confocal microscopy observed mitochondrial transfer. Flow cytometry, EdU assay, and clonogenicity evaluated cell cycle, proliferation, and clonogenic potential. Xenograft mouse models were used to evaluate the tumorigenicity of KG-1a in vivo. Seahorse, RNA-seq, and LC-MS assessed mitochondrial function, transcriptomes, and metabolites post-coculture.ResultsCX43-BMSCs promoted unidirectional mitochondrial transfer, enhancing KG-1a adhesion and proliferation to maintain LSCs stemness in vitro and vivo. RNA-seq revealed coculture with CX43-BMSCs upregulated genes related to adhesion, proliferation, and migration in KG-1a cells. Elevated CX43 expression strengthened BMSCs-KG-1a interaction, facilitating mitochondrial transfer and nucleoside metabolism, fueling KG-1a cells. This enhanced mitochondrial energy metabolism, promoting metabolic reprogramming and clonogenicity.ConclusionCX43-mediated mitochondrial transfer from BMSCs to KG-1a enhances LSCs adhesion, proliferation, clonogenicity, and metabolic reprogramming. CX43 emerges as a potential therapeutic target for AML by sustaining LSCs stemness through metabolic remodeling.

The preclinical pharmacokinetics of Tolinapant-A dual cIAP1/XIAP antagonist with invivo efficacy.

AT-IAP (1-{6-[(4-fluorophenyl)methyl]-3,3-dimethyl-1H,2H,3H-pyrrolo[3,2-b]pyridin-1-yl}-2-[(2R,5R)-5-methyl-2-{[(3R)-3-methylmorpholin-4-yl]methyl}piperazin-1-yl]ethan-1-one) was identified as a novel potent non-alanine small molecule dual inhibitor of cIAP1/XIAP protein. AT-IAP was assessed in preclinical species, demonstrating favorable bioavailability in rodent species and oral efficacy at 30 mg/kg in MDA-MB-231 mouse xenograft models. The major metabolic route of AT-IAP was identified to be CYP3A driven, resulting in low oral exposure in non-human primate (NHP) studies, given the comparatively high expression of equivalent CYP3A. AT-IAP metabolite identification studies determined ring opening of the morpholino or piperazine moiety. An extensive campaign of optimisation resulted in increased polarity by the addition of a hydroxymethyl, which led to the identification of tolinapant (1-(6-[(4-Fluorophenyl)methyl]-5-(hydroxymethyl)-3,3-dimethyl-1 H,2 H,3 H-pyrrolo[3,2- b]pyridin-1-yl)-2-[(2 R,5 R)-5-methyl-2-([(3R)-3-methylmorpholin-4-yl]methyl)piperazin-1-yl]ethan-1-one) with reduced CYP3A metabolism. Tolinapant showed oral bioavailability in rodents and NHP in the range 12-34% at 5 mg/kg. Non-linear pharmacokinetics in NHP were observed at oral doses in the range 5-75 mg/kg. Pharmacodynamic modulation and efficacy were demonstrated in A375 mouse xenograft models at dose ranges between 5 and 20 mg/kg. On-target engagement, as measured by reduction of cIAP 1 protein levels, was confirmed in NHP surrogate tissues and applied to target activity assessments in tolinapant phase1/2 clinical trials.

Peimine induces apoptosis of glioblastoma cells through regulation of the PI3K/AKT signaling pathway.

Glioblastoma (GBM) is one of the most malignant forms of intracranial tumors, with high mortality rates and invariably poor prognosis, due to the limited clinical treatment strategies available. As a natural compound, peimine's favorable pharmacological activities have been widely revealed. However, potential inhibitory effects of peimine on GBM have not been explored. In the present study, both in vitro and in vivo experiments were performed to elucidate the effects of peimine on GBM and to further delineate the underlying molecular mechanism of action. Different doses (0, 25 and 50 µM) of peimine were added to U87 cells, before MTT, colony formation, wound healing, Transwell migration and invasion, reactive oxygen species and mitochondrial transmembrane potential assays were used to measure proliferation, migration, invasion and apoptosis. Furthermore, western blotting was used to examine the possible effects of peimine on the expression of proteins associated with apoptosis and the PI3K/AKT signaling pathway. Subsequently, a GBM mouse xenograft model was used to assess the effects of peimine in vivo. The findings showed that peimine inhibited GBM proliferation, migration and invasion in a dose-dependent manner, whilst also inducing apoptosis. Peimine also reduced tumor growth in vivo. Mechanistically, peimine downregulated the expression of Bcl-2 and Caspase 3, whilst upregulating the protein expression levels of p53, Bax and Cleaved-Caspase 3 in a dose-dependent manner. In addition, PI3K and AKT phosphorylation levels were found to be decreased by peimine in a dose-dependent manner. In conclusion, these findings suggest that peimine may limit GBM growth by regulating the PI3K/AKT signaling pathway both in vitro and in vivo. These findings may have promising clinical implications.

Diosmin reduces the stability of Snail and Cyclin D1 by targeting FAK to inhibit NSCLC progression

BackgroundIn different tumours, focal adhesion kinase (FAK), a nonreceptor tyrosine kinase, is upregulated and hence, it represents a promising target for cancer therapy. However, the development of FAK kinase inhibitors has faced a number of challenges. It is therefore imperative that new, effective FAK kinase inhibitors be identified promptly. MethodsSmall molecules that target FAK were identified through molecular docking and validated through surface plasmon resonance (SPR) and cell thermal shift analysis. We investigated the pharmacological effects of FAK kinase inhibitors using CCK-8, colony formation, EdU, and Transwell assays and cell cycle analysis. The molecular mechanism was determined via methods such as coimmunoprecipitation, RNA pull-down and RNA immunoprecipitation. ResultsHere, we confirmed that diosmin (Dio) is an inhibitor of FAK and demonstrated its anti-proliferative and anti-metastatic effects in lung adenocarcinoma. Mechanistically, Dio inhibited tumour proliferation and metastasis by impeding the catalytic activity of FAK. Dio activated the ubiquitin proteasome pathway to induce Cyclin D1 degradation, while inhibiting tumour proliferation and reversing the epithelial mesenchymal transition (EMT) process by reducing the mRNA stability of Snail, thereby inhibiting cancer metastasis. In addition, the inhibitory effect of Dio on lung adenocarcinoma was validated in a mouse xenograft model. ConclusionThese results support the tumour-promoting role of FAK in lung adenocarcinoma by stabilizing Cyclin D1 and Snail and suggest that Dio is a promising candidate for FAK inhibition.

Synthesis and Anti-gastric Cancer Activity by Targeting FGFR1 Pathway of Novel Asymmetric Bis-chalcone Compounds.

Bis-chalcone compounds with symmetrical structures, either isolated from natural products or chemically synthesized, have multiple pharmacological activities. Asymmetric Bis-chalcone compounds have not been reported before, which might be attributed to the synthetic challenges involved, and it remains unknown whether these compounds possess any potential pharmacological activities. The aim of this study is to investigate the synthesis route of asymmetric bis-chalcone compounds and identify potential candidates with efficient anti-tumor activity. The two-step structural optimization of the bis-chalcone compounds was carried out sequentially, guided by the screening of the compounds for their growth inhibitory activity against gastric cancer cells by MTT assay. The QSAR model of compounds was established through random forest (RF) algorithm. The activities of the optimal compound J3 on growth inhibition, apoptosis, and apoptosis-inducing protein expression in gastric cancer cells were investigated sequentially by colony formation assay, flow cytometry, and western blotting. Further, the inhibitory effects of J3 on the FGFR1 signaling pathway were explored by Western Blotting, shRNA, and MTT assays. Finally, the in vivo anti-tumor activity and mechanism of J3 were studied through nude mice xenograft assay, western blotting. 27 asymmetric bis-chalcone compounds, including two types (N and J) were sequentially designed and synthesized. Some N-class compounds have good inhibitory activity on the growth of gastric cancer cells. The vast majority of J-class compounds optimized on the basis of N3 exhibit excellent inhibitory activity on gastric cancer cell growth. We established a QSAR model (R2 = 0.851627) by applying random forest algorithms. The optimal compound J3, which had better activity, concentration-dependently inhibited the formation of gastric cancer cell colonies and led to cell apoptosis by inducing the expression of the pro-apoptotic protein cleaved PARP in a dose-dependent manner. J3 may exert anti-gastric cancer effects by inhibiting the activation of FGFR1/ERK pathway. Moreover, at a dose of 10 mg/kg/day, J3 inhibited tumor growth in nude mice by nearly 70% in vivo with no significant toxic effect on body weight and organs. In summary, this study outlines a viable method for the synthesis of novel asymmetric bischalcone compounds. Furthermore, the compound J3 demonstrates substantial promise as a potential candidate for an anti-tumor drug.

Personalized Membrane Protein Vaccine Based on a Lipid Nanoparticle Delivery System Prevents Postoperative Recurrence in Colorectal Cancer Models

While accessing tumor neoantigens and developing effective delivery systems have posed significant challenges in therapeutic oncology vaccines, this study introduces a cost- and time-efficient personalized tumor vaccine demonstrating potent anti-tumor effects in a mouse xenograft model. This vaccine utilizes a lipid nanoparticle (C5 LNP) system loaded with membrane protein antigens (mAg) derived from surgically excised tumor tissue. Its safety and efficacy were validated in a B16-OVA murine model. C5/OVA exhibited significant uptake by dendritic cells (DCs), leading to cross-presentation, maturation, and subsequent initiation of robust cell-mediated and humoral immune responses. This resulted in clear tumor growth suppression and extended survival in the B16-OVA model. Furthermore, the personalized C5/mAg vaccine effectively inhibited tumor growth in a colorectal carcinoma model. When combined with anti-PD-1 therapy, it notably increased complete remission (CR) rates in the CT26 xenograft model. Vaccinated mice demonstrated 100% resistance to tumor rechallenge, underscoring the vaccine's ability to induce long-term immune memory. This study presents a promising personalized cancer vaccine delivery system with potential for both treatment and prevention of carcinoma in clinical applications. Statement of significanceIn this paper, we present a scheme for manufacturing personalized tumor vaccines. The vaccine component consists of lipid nanoparticles (LNPs) designated C5 and membrane protein antigens (mAg) derived from autologous tumor tissue surgically resected from the patient. Our study demonstrates that the personalized mAg-C5 vaccine for colorectal carcinoma significantly inhibits tumor growth. Furthermore, conjugation with anti-PD-1 therapy demonstrably increased the complete remission (CR) rate in the murine CT26 xenograft tumor model. Additionally, mice treated with the C5/mAg vaccine exhibited 100% resistance to tumor growth in a colon carcinoma rechallenge model, indicating the induction of immune memory by the vaccine.Our research results suggest that the mAg-LNP vaccine is a simple, cost-effective treatment that clinicians can easily and quickly integrate into routine practice.

GSTA1/CTNNB1 axis facilitates sorafenib resistance via suppressing ferroptosis in hepatocellular carcinoma

The emergence of sorafenib resistance has become a predominant impediment and formidable dilemma in the therapeutic approach for hepatocellular carcinoma (HCC). Although the approval of next-generation drugs as alternatives to sorafenib is a significant development, the concurrent use of inhibitors that target additional key molecular pathways remains an effective strategy to mitigate the acquisition of resistance. Here, we identified Glutathione S-Transferase Alpha 1 (GSTA1) as a critical modulator of sorafenib resistance (SR) in hepatocellular carcinoma (HCC) based on our findings from experiments conducted on recurrent liver cancer tissues, xenograft mouse models, organoids, and sorafenib-resistant cells. Elevated GSTA1 levels are strongly associated with adverse clinical prognoses. The knockout of GSTA1 reinstates sorafenib sensitivity, whereas its overexpression attenuates drug efficacy. Mechanistically, GSTA1 enhances the accumulation of lipid peroxides and suppresses ferroptosis by exerting its peroxidase function to regulate the SR. Notably, the upregulation of GSTA1 expression is mediated by the transcription factor CTNNB1 (β-catenin), resulting in the formation of a cytoplasmic complex between GSTA1 and CTNNB1. This complex facilitates the nuclear translocation of CTNNB1, establishing a positive feedback loop. The combined use of GSTA1 and CTNNB1 inhibitors demonstrated synergistic anti-tumour effects through the induction of ferroptosis both in vitro and in vivo. Our findings reveal a novel regulatory role of the GSTA1/CTNNB1 axis in ferroptosis, suggesting that targeting GSTA1 and CTNNB1 could be a promising strategy to circumvent sorafenib resistance in HCC.

Combinatorial immunotherapy of anti-MCAM chimeric antigen receptor modified expanded natural killer cells and NKTR-255 against neuroblastoma

Pediatric patients with recurrent metastatic neuroblastoma (NB) have a dismal 5-year survival. Novel therapeutic approaches are urgently needed. The melanoma cell adhesion molecule (MCAM/CD146/MUC18) is expressed in a variety of pediatric solid tumors, including NB, and constitutes anovel target for immunotherapy. Here, we developed a chimeric antigen receptor (CAR) expressing natural killer (NK) cell-targeting MCAM by non-viral electroporation of CAR mRNA into exvivo expanded NK cells. Expression of anti-MCAM CAR significantly enhanced NK cell cytotoxic activity compared to mock NK cells against MCAMhigh but not MCAMlow/knockout NB cells invitro. Anti-MCAM-CAR-NK cell treatment significantly decreased tumor growth and prolonged animal survival in an NB xenograft mouse model. NKTR-255, a polymer-conjugated recombinant human interleukin-15 agonist, significantly stimulated NK cell proliferation and expansion and further enhanced the in vitro cytotoxic activity and invivo anti-tumor efficacyofanti-MCAM-CAR-NK cells against NB. Our preclinical studies demonstrate that exvivo expanded andmodified anti-MCAM-CAR-NK cells alone and/or incombination with NKTR-255 are promising novel alternative therapeutic approaches to targeting MCAMhigh malignant NB.

Longikaurin A induces ferroptosis and inhibits glioblastoma progression through DNA methylation - Mediated GPX4 suppression.

Glioblastoma (GBM) is the most common primary intracranial tumor highly resistant to conventional clinical chemotherapy. Recently, the induction of ferroptosis is emerging as a putative strategy to treat various tumors. However, the identification of the effective and applicable tumor ferroptosis-inducing agents remains challenging. In this study, we showed that longikaurin A (LK-A), a natural diterpenoid isolated from the medicinal plant Isodon ternifolius with strong anti-GBM capacities, induced remarkable GBM cell ferroptosis along with suppressing the key anti-ferroptosis factor glutathione peroxidase 4 (GPX4). GPX4 promoter contains conserved CpG islands. The LK-A-induced GPX4 suppression coincided with the inhibition of ten-eleven translocation 2 (TET2), a key DNA demethylation enzyme and an increase in the hypermethylation of the GPX4 promoter. Further, LK-A promoted the GBM ferroptotic alterations and inhibited GBM progression in both subcutaneous and orthotopic xenograft mouse models, whereas GPX4 overexpression largely abrogated its anti-GBM effects both in vitro and in vivo, suggesting that LK-A inductions of the DNA methylation-incurred GPX4 suppression and ferroptosis are crucial for its anti-GBM functions. Together, our study has elaborated an important epigenetic pathway of GBM ferroptosis and uncovered a critical pharmacological property of LK-A for treating GBM patients.

Farrerol suppresses epithelial-mesenchymal transition in hepatocellular carcinoma via suppression of TGF-β1/Smad2/3 signaling

BackgroundEpithelial-mesenchymal transition (EMT) is an essential process for the metastasis of multiple malignancies, including hepatocellular carcinoma (HCC). Farrerol is a plant-derived flavonoid and has significant pharmacological effects. However, the anticancer activities of farrerol have not been fully elucidated. Here, we investigated the effects of farrerol on HCC progression. MethodsThe potential of farrerol to prevent HCC cell migration and invasiveness was evaluated by wound healing and transwll matrix assays. Immunoblotting, immunofluorescence, and qPCR were used to detect the levels of EMT-related proteins. Transforming growth factor beta (TGF-β) (10ng/ml) was used to stimulate HCC cells, followed by measurement of cell migration, invasiveness, and the EMT. TGF-β1/Smads signaling was examined by immunoblotting. A xenograft mouse model was used to assess the anticancer efficacy of farrerol in vivo. The expression levels of EMT- and angiogenesis-related proteins in xenograft tumors were evaluated by immunoblotting or immunohistochemistry. ResultsWe found that farrerol blocked HCC cell migration and invasiveness. Farrerol upregulated E-cadherin levels and reduced N-cadherin and vimentin levels. Farrerol also downreuglated the expression levels of EMT-related transcription factors including slug, snail, twist, and zeb1. Furthermore, farrerol suppressed TGF-β-stimulated migration, invasiveness, and the EMT in HCC cells. The phosphorylation of Smad 2/3 induced by TGF-β was inhibited by farrerol. Importantly, farrerol suppressed HCC growth and the EMT in vivo. Farrerol also inhibited tumor angiogenesis by inhibiting hypoxia-inducible factor-1 alpha (HIF-1α) and vascular endothelial growth factor (VEGF) in vivo. ConclusionOverall, farrerol suppresss HCC by inhibiting migration, invasiveness, the EMT, and angiogenesis, implying that farrerol could be a promising antimetastasis agent for HCC.

Cellulose nanocrystals/cellulose nanofibrils-combined astaxanthin nanoemulsion for reinforcement of targeted tumor delivery of gastric cancer cells

Nanoemulsion based nanomaterial (NE) was carried out in the present study to evaluate the efficacy and its antitumor potential of the gastric cancer cells. NE was prepared with astaxanthin/alpha-tocopherol- cellulose nanocrystals/cellulose nanofibrils based nanoemulsions for gastric cancer treatment. The cytotoxic potential was tested against cancer cells and evaluated in terms of its cell proliferation, migration, and cellular uptake by the standard methods. NE was examined for its synergetic effect with photodynamic therapy (PDT) in a xenograft mouse model. The results confirmed the synergetic effect of PDT and NEs in the in vivo animal model. The regulated expression of proteins manifested the reduced toxicity and inhibition of cell proliferation and migration. The antitumor study showed that NE inhibited the growth of human colon cancer in vivo. Immunohistological analysis confirmed the regulation of PI3K/AKT signaling pathway. The present study demonstrates that NEs can enhance anti-cancer effect against human gastric cancer through the immunomodulatory signaling pathway.

Anti-tumor Effects of Idarubicin Hydrochloride in Desmoid Tumors.

Desmoid tumors (DTs), also referred to as aggressive fibromatosis, originate from connective tissues and typically manifest with a propensity for local invasion. Despite extensive research efforts aimed at exploring novel anti-tumor agents for DTs, the development of effective clinical management strategies remains an ongoing challenge due to the limited success of current treatments, which frequently lead to inconsistent outcomes and a high recurrence rate of DTs. To overcome these limitations, we focused our research aim on a drug repositioning approach to identify existing medications that could be effective against DTs. Mouse models with Apc mutations, specifically Apc1638N/+ and Apc1638N/+/Trp53-/-, were generated to study DTs. Primary desmoid cells were isolated from these models for experimental analysis. Idarubicin hydrochloride (IDH), a topoisomerase II (TOPO II) inhibitor, was tested on these primary cells, colorectal cancer (CRC) cell lines, and tumor organoids derived from Apc1638N/+ mice. Cell viability was determined with the WST reagent and colony formation assay was evaluated. The anti-tumor efficacy of IDH was tested in an in vivo CRC xenograft model using HCT-116 cells. The TOPO II inhibitor IDH showed significant growth inhibition effects on Apc1638N/+ and Apc1638N/+/Trp53-/- cells. IDH also showed remarkable anti-tumor effects on CRC cell lines and tumor organoids derived from intestinal tumor cells of the Apc1638N/+ mouse model. Furthermore, IDH exerted dramatic anti-tumor effects on an HCT-116 cell line xenograft mouse model. IDH could be a promising therapeutic agent for inhibiting DTs and CRC by targeting TOPO II.

GEFT inhibits the GSDM-mediated proptosis signalling pathway, promoting the progression and drug resistance of rhabdomyosarcoma

The metastasis or recurrence of rhabdomyosarcoma (RMS) is the primary cause of tumour-related deaths. Patients with high-risk RMS have poor prognosis with a 5-year overall survival rate of 20–30%. The lack of specific drug-targeted therapy and chemotherapy resistance are the main reasons for treatment failure. Drugs or molecular target inhibitors can induce the pyroptosis of tumour cells or increase their sensitivity to chemotherapy, making pyroptosis an effective strategy for antitumour therapies. Pyroptosis is mediated by gasdermin (GSDM) family members. Here, we found that the expression of NLRP3, caspase-1, caspase-3, GSDMD and GSDME in RMS was remarkably lower than that in skeletal muscle tissues. Nigericin and dactinomycin in RMS cells achieved their regulatory effect on pyroptosis through the NLRP3/caspase-1/GSDMD pathway and caspase-3/GSDME pathway, respectively. Necrosulfonamide reversed the pyroptosis-related changes induced by nigericin, and siGSDME converted the dactinomycin-induced pyroptosis into apoptosis. Additionally, GEFT inhibited the GSDMD and GSDME pyroptosis pathways, thereby promoting the progression and drug resistance of RMS. Mouse xenograft and tumour analysis confirmed that nigericin and dactinomycin can effectively improve the therapeutic effect of RMS by activating the pyroptosis pathway. To the best of our knowledge, this study was the first to focus on pyroptosis in RMS. Overall, our investigation demonstrated that nigericin and dactinomycin play therapeutic roles in tumours by promoting RMS cell pyroptosis. Interference with GEFT and drug combination can exert a great inhibitory effect on tumours.