Chemoresistant Cells Research Articles

DYRK2 controls GSTPI expression through ubiquitination and degradation of Twist1 to reduce chemotherapy resistance caused by EMT in breast cancer.

Breast cancer (BC) poses a significant global health challenge, with chemotherapy resistance, especially to docetaxel, remaining a major obstacle in effective treatment. The molecular mechanisms underlying this resistance are critical for developing targeted therapeutic strategies. This study aims to explore the role of dual-specificity tyrosine phosphorylation-regulated kinase 2 (DYRK2), a member of the DYRK family, in docetaxel resistance in breast cancer cells and investigate its impact on cellular responses, including drug sensitivity and migration. Additionally, potential interactions between DYRK2 and Twist1, associated with epithelial-mesenchymal transition (EMT) and drug resistance, are explored. Docetaxel-resistant breast cancer cells were induced, and the expression levels of DYRK2, Twist1, and related genes were evaluated using real-time PCR and Western blotting. Lentivirus-mediated DYRK2 overexpression was employed to assess its effect on drug sensitivity, migratory ability, and Twist1 expression. The relationship between DYRK2 and Twist1 was examined, focusing on Twist1 ubiquitination. The impact of Twist1 on chemotherapy resistance and its binding to the Glutathione S-transferase Pi 1 (GSTP1) promoter were also investigated. Docetaxel-resistant cells exhibited down-regulated DYRK2 and up-regulated Twist1 expression. DYRK2 overexpression reversed drug resistance, decreased migration, and attenuated Twist1 and GST-π expression. DYRK2 was found to suppress Twist1 expression through ubiquitination, supported by decreased Twist1 phosphorylation and increased ubiquitination after DYRK2 overexpression. Twist1 overexpression counteracted DYRK2-induced drug sensitivity enhancement, promoting GST-π expression, EMT, migration, and proliferation. Twist1 was shown to bind to the GSTP1 promoter, enhancing its transcription. In vivo experiments confirmed DYRK2's ability to suppress chemoresistance in breast cancer cells. DYRK2 plays a pivotal role in overcoming docetaxel resistance in breast cancer cells by suppressing Twist1 expression through ubiquitination, impacting downstream signaling and cellular responses. This study provides valuable insights for developing targeted therapies to improve breast cancer treatment outcomes.

M2 macrophages secrete CCL20 to regulate iron metabolism and promote daunorubicin resistance in AML cells

Chemotherapy resistance is a significant clinical challenge in the treatment of leukemia. M2 macrophages have been identified as key contributors to the development of chemotherapy resistance in cancer, yet the precise mechanisms by which macrophages regulate this resistance remain elusive. Our study has identified CCL20 as a pivotal factor in the promotion of chemoresistance in AML cells by M2 macrophages. The chemotherapeutic agent daunorubicin induces a marked increase in ROS and lipid peroxidation levels within AML cells. This is accompanied by the inhibition of the SLC7A11/GCL/GPX4 signaling axis, elevated levels of intracellular free iron, disrupted iron metabolism, and consequent mitochondrial damage, ultimately leading to ferroptosis. Notably, CCL20 enhances the ability of AML cells to maintain iron homeostasis by upregulating SLC7A11 protein activity, mitigating mitochondrial damage, and inhibiting ferroptosis, thereby contributing to chemotherapy resistance. Furthermore, in vivo experiments demonstrated that blocking CCL20 effectively restores the sensitivity of AML cells to daunorubicin chemotherapy. Collectively, these findings underscore the complex interplay between M2 macrophages, CCL20 signaling, and chemotherapy resistance in AML, highlighting potential therapeutic avenues for intervention.

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.

Coptisine enhances the sensitivity of chemoresistant breast cancer cells by inhibiting the function and expression of ABC transporters

BackgroundMultidrug resistance (MDR), mainly caused by ATP-binding cassette transporters (ABCTs) efflux, makes it difficult for many anticancer drugs to treat breast cancer (BC). Phytochemicals can reverse cancer’s MDR by modifying ABC transporter expression and function, as well as working synergistically with anticancer drugs to target other molecules. The reversal effect of the isoquinoline alkaloid coptisine (COP) was assessed on four breast cell lines; Two sensitive MCF-7 cell lines with positive estrogen, androgen, progesterone, and glucocorticoid receptors, as well as MDB-MB-231 cells with negative estrogen, progesterone, and HER2 receptors, and two doxorubicin-resistant cell lines, MCF-7/ADR and MDB-MB-231/ADR.MethodsThe cytotoxicity of COP and its ability to improve doxorubicin (DOX) cytotoxicity were assessed using the MTT assay. The effectiveness of COP in reversing DOX resistance was evaluated by calculating resistance ratio (RR) values, combination index (CI), and isobologram (IB). The inhibitory effect of COP on ABCT efflux function in comparison to verapamil (VER) was evaluated by measuring the cellular accumulation of Rho123 using flow cytometry. The impact of COP, either alone or in combination with DOX, on the gene expression of ABCTs (P-gp/MDR1, BCRP, and MRP1) of investigated cell lines was assessed by RT-PCR.ResultsThe COP showed modest cytotoxicity on the examined cell lines. In MCF-7/ADR and MDA-MB-231/ADR cells, COP (31 μM) enhanced DOX cytotoxicity with CI (0.77 and 0.75), RR (2.58 and 3.33), and IB suggesting synergism. COP significantly inhibits ABCT function in resistant BC cell lines, increases Rho123 accumulation, and decreases efflux more than VER; 2.1 and 1.2-fold, respectively. The combination of COP and DOX had a strong inhibitory effect on ABCT function (3.1 and 3.9 times VER, P< 0.001) and downregulated the genes and protein expression of ABCT.ConclusionCOP reversed ABCT-mediated multidrug resistance in vitro, indicating its potential as a multidrug resistance-reversing agent in cancer chemotherapy.

Mimicking Retinoblastoma Treatment With Repeated Topotecan or Melphalan Develops Cross-Resistance to Classic Agents But Not to Repurposed Drugs.

Refractory or recurrent retinoblastoma results from acquired chemoresistance and the management of these eyes often requires surgical removal. Our objective was to develop retinoblastoma models resistant to chemotherapy by exposing cancer cells to repeated chemotherapy mimicking the clinical scenario. These newly resistant cells were used to evaluate potential novel therapies. Chemoresistant cells were obtained by exposing two primary retinoblastoma cell cultures to three weekly doses of melphalan or topotecan. The sensitivity of these resistant cells to each chemotherapy was evaluated, and cross-resistance to topotecan, melphalan, and carboplatin was assessed. Genomic alterations and differential expression of efflux/influx transporters between chemoresistant and parental cells were analyzed. Subsequently, sensitivity of both resistant and parental cells to the repurposed agents digoxin, methylene blue, and gemcitabine was assessed. Four chemoresistant models were successfully established, showing significantly higher half-maximal inhibitory concentration (IC50) values for melphalan and topotecan compared to their corresponding parental cells (P < 0.05). Cross-resistance between melphalan and topotecan was demonstrated, with a 3-fold increase in the IC50. Chemoresistant cells also showed reduced sensitivity to carboplatin (P < 0.05) compared to parental cells, whereas sensitivity to the evaluated repurposed agents remained unchanged. Genomic analysis revealed no selective alterations in the resistant cells, although differential expression of influx/efflux transporters was observed across all chemoresistant models. In vitro simulation of patient treatment was useful to establish chemoresistant retinoblastomas and to identify strategies to overcome resistance to topotecan or melphalan through drug repurposed. Our results warrant further investigation to support the clinical translation.

Myeloid activation clears ascites and reveals IL27-dependent regression of metastatic ovarian cancer.

Patients with metastatic ovarian cancer (OvCa) have a 5-year survival rate of <30% due to the persisting dissemination of chemoresistant cells in the peritoneal fluid and the immunosuppressive microenvironment in the peritoneal cavity. Here, we report that intraperitoneal administration of β-glucan and IFNγ (BI) induced robust tumor regression in clinically relevant models of metastatic OvCa. BI induced tumor regression by controlling fluid tumor burden and activating localized antitumor immunity. β-glucan alone cleared ascites and eliminated fluid tumor cells by inducing intraperitoneal clotting in the fluid and Dectin-1-Syk-dependent NETosis in the omentum. In omentum tumors, BI expanded a novel subset of immunostimulatory IL27+ macrophages and neutralizing IL27 impaired BI efficacy in vivo. Moreover, BI directly induced IL27 secretion in macrophages where single agent treatment did not. Finally, BI extended mouse survival in a chemoresistant model and significantly improved chemotherapy response in a chemo-sensitive model. In summary, we propose a new therapeutic strategy for the treatment of metastatic OvCa.

Inhibition of XIST restrains paclitaxel resistance in breast cancer cells by targeting hsa-let-7d-5p/ATG16L1 through regulation of autophagy

Breast cancer is a fatal malignant tumor in women worldwide. The development of paclitaxel resistance remains a challenge. Autophagy is considered to have a significant part in the chemotherapeutic stress mechanism. This study aimed to investigate the function of long non-coding RNA (lncRNA) in breast cancer cell chemoresistance and autophagy. The paclitaxel (PTX)-resistant breast cancer cells were established. The function of X-inactive specific transcript (XIST) was demonstrated using in vitro and in vivo experiments. Transmission electron microscope (TEM) was used to observe autophagy vesicles. Protein and mRNA levels were determined using western blotting and quantitative real time polymerase chain reaction (qRT-PCR). We discovered that autophagic activity was correlated with chemoresistance in PTX-resistant breast cancer cells. In vitro and in vivo studies showed that XIST inhibition reduced cell resistance to paclitaxel, caused autophagy to be suppressed by regulating hsa-let-7d-5p and ATG16L1 expression. Mechanically, threonine protein kinase B (PKB; also known as AKT) - mammalian target of rapamycin (mTOR) pathway was activated when knockdown of XIST, while was reversed by inhibition of hsa-let-7d-5p. Our results verified that XIST played a significant role in developing chemoresistance via mediating autophagy in PTX-resistant breast cancer cells. It may be a potential target for breast cancer treatment strategies.

LMAN2 Promotes Breast Cancer Tumorigenesis and Drug Resistance by Interacting With MAPK9 via Activation of the MAPK Pathway

ABSTRACTIntroductionBreast cancer (BC) is the most prevalent malignancy among women worldwide. Lectin, mannose‐binding 2 (LMAN2) is a cargo receptor engaged in the transport and sorting of glycoproteins. Despite its ubiquity, the function and underlying mechanisms of LMAN2 in BC continue to elude understanding.MethodsMultiple databases were employed to examine the expression of LMAN2 in breast cancer. Immunohistochemistry(IHC), qRT‐PCR, and Western blot were performed to quantify LMAN2 expression in BC cell lines and clinical samples. Heat map analysis and Kaplan–Meier analysis were used to analyze the correlation between LMAN2 and clinicopathological features. SiRNAs and overexpression plasmids were transfected into two BC cells to assess the effect of LMAN2 on malignant phenotypes. Coimmunoprecipitation and immunofluorescence were used to screen for potential interacting proteins. Additionally, tumor subcutaneous xenograft mode was constructed to explore tumor chemoresistance.ResultLMAN2 expression was significantly higher in BC compared to that in matched, adjacent normal tissues, and its higher expression level was correlated with worse patient prognosis. In vitro, we found that LMAN2 functions as an oncogene, promoting BC cell proliferation, cell cycle progression, invasion, and chemoresistance while preventing apoptosis. Coimmunoprecipitation and colocalization experiments confirmed the direct binding of LMAN2 to MAPK9 in BC cells. Our investigation of signaling pathways suggested that LMAN2 is involved in the regulation of the MAPK signaling pathway, utilizing this pathway to confer cisplatin resistance. Furthermore, knockdown of LMAN2 improves the sensitivity of drug‐resistant BC cells to cisplatin (DDP) in vivo.ConclusionLMAN2 was a novel diagnostic and prognostic biomarker for BC that promotes chemoresistance via interaction with MAPK9 and activation of the MAPK pathway.

Cancer-associated fibroblasts regulate mitochondrial metabolism and inhibit chemosensitivity via ANGPTL4-IQGAP1 axis in prostate cancer.

Cancer-associated fibroblasts (CAFs) are a critical component of the tumor microenvironment, being implicated in enhancing tumor growth and fostering drug resistance. Nonetheless, the mechanisms underlying their function in prostate cancer (PCa) remain incompletely understood, which is essential for devising effective therapeutic strategies. The main objective of this study was to explore the mechanisms by which CAFs mediate PCa growth and chemoresistance. We validated through data analysis and experimentation that CAFs significantly impact PCa cell proliferation and chemoresistance. Subsequently, we conducted a comprehensive proteomic analysis of the conditioned media from CAFs and PCa cells and identified angiopoietin-like protein 4 (ANGPTL4) as a key factor. We employed ELISA and multiplex immunofluorescence assays, all of which indicated that ANGPTL4 was primarily secreted by CAFs.Next, we conducted metabolomics analysis, GST pull-down assays, Co-IP, and other experiments to explore the specific molecular mechanisms of ANGPTL4 and its precise effects on PCa cells. Through drug screening, we identified Quercetin 3-O-(6'-galactopyranosyl)-β-D-galactopyranoside (QGGP) as an effective inhibitor of CAFs function. Finally, we thoroughly assessed the therapeutic potential of QGGP both as a monotherapy and in combination with docetaxel in PCa cells RESULTS: We discovered that the extracrine factor ANGPTL4 is primarily expressed in CAFs in PCa. When ANGPTL4 binds to IQ motif-containing GTPase-activating protein 1 (IQGAP1) on the PCa cell membrane, it activates the Raf-MEK-ERK-PGC1α axis, promoting mitochondrial biogenesis and OXPHOS metabolism, and thereby facilitating PCa growth and chemoresistance. Furthermore, virtual and functional screening strategies identified QGGP as a specific inhibitor of IQGAP1 that promotes its degradation. Combined with docetaxel treatment, QGGP can reverse the effects of CAFs and improve the responsiveness of PCa to chemotherapy. This study uncovers a paracrine mechanism of chemoresistance in PCa and proposes that targeting the stroma could be a therapeutic choice.

LncRNA SNHG14 Facilitates Cisplatin Resistance Through Upregulating Notch2 via Binding to U2AF2 in Nasopharyngeal Carcinoma.

Cisplatin (DDP) is one of the commonly used chemotherapeutic drugs for nasopharyngeal carcinoma (NPC) patients, and the resistance of tumor cells to cisplatin is main obstacle for NPC treatment. This study explored effect and possible mechanism of lncRNA small nucleolar RNA host gene 14 (SNHG14) on drug resistance of NPC cells to cisplatin. Levels of SNHG14 and Notch2 in NPC tissues and cells were confirmed using RT-qPCR. Western blot detected Notch2 and ABCB1 expression in NPC cells. IC50 of cisplatin-treated NPC cells was tested utilizing 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT). Cell proliferation and apoptosis were evaluated utilizing colony formation experiment and flow cytometry, respectively. RNA immunoprecipitation (RIP) assay was utilized to validate the target genes of U2AF2. Notch2 mRNA stability was tested using actinomycin D. SNHG14 level was increased in both cisplatin-resistant NPC tissues and cell lines. SNHG14 silencing in HNE1/DDP cells resulted in inhibition of chemoresistance to cisplatin. Conversely, upregulation of SNHG14 in HNE1 cells enhanced their resistance to cisplatin. SNHG14 exhibited an interaction with U2AF2, leading to stabilization of Notch2 mRNA. Finally, Notch2 was involved in SNHG14-mediated cisplatin resistance in NPC cells. Our findings demonstrate SNHG14 plays a significant role in promoting chemoresistance of NPC cells to cisplatin through U2AF2/Notch2 axis. These results highlight potential therapeutic targets for NPC treatment.

High CD44 expression and enhanced E-selectin binding identified as biomarkers of chemoresistant leukemic cells in human T-ALL.

T-cell acute lymphoblastic leukemia (T-ALL) is a hematopoietic malignancy characterized by increased proliferation and incomplete maturation of T-cell progenitors, for which relapse is often of poor prognosis. To improve patient outcomes, it is critical to understand the chemoresistance mechanisms arising from cell plasticity induced by the bone marrow (BM) microenvironment. Single-cell RNA sequencing of human T-ALL cells from adipocyte-rich and adipocyte-poor BM revealed a distinct leukemic cell population defined by quiescence and high CD44 expression (Ki67neg/lowCD44high). During in vivo treatment, these cells evaded chemotherapy, and were further called Chemotherapy-resistant Leukemic Cells (CLCs). Patient sample analysis revealed Ki67neg/lowCD44high CLCs at diagnosis and during relapse, with each displaying a specific transcriptomic signature. Interestingly, CD44high expression in T-ALL Ki67neg/low CLCs was associated with E-selectin binding. Analysis of 39 human T-ALL samples revealed significantly enhanced E-selectin binding activity in relapse/refractory samples compared with drug-sensitive samples. These characteristics of chemoresistant T-ALL CLCs provide key insights for prognostic stratification and novel therapeutic options.

Altered Mechanobiology of PDAC Cells with Acquired Chemoresistance to Gemcitabine and Paclitaxel.

Background: Pancreatic ductal adenocarcinoma acquired resistance to chemotherapy poses a major limitation to patient survival. Despite understanding some biological mechanisms of chemoresistance, much about those mechanisms remains to be uncovered. Mechanobiology, which studies the physical properties of cells, holds promise as a potential target for addressing the challenges of chemoresistance in PDAC. Therefore, we, here in an initial step, assessed the altered mechanobiology of PDAC cells with acquired chemoresistance to gemcitabine and paclitaxel. Methods: Five PDAC cell lines and six stably resistant subclones were assessed for force generation on elastic micropillar arrays. Those measurements of mechanical phenotype were complemented by single-cell motility and invasion in 3D collagen-based matrix assays. Further, the nuclear translocation of Yes-associated protein (YAP), as a measure of active mechanical status, was compared, and biomarkers of the epithelial-to-mesenchymal transition (EMT) were evaluated using RT-qPCR. Results: The PDAC cells with acquired chemoresistance exert higher traction forces than their parental/wild-type (WT) cells. In 2D, single-cell motility was altered for all the chemoresistant cells, with a cell-type specific pattern. In 3D, the spheroids of the chemoresistant PDAC cells were able to invade the matrix and remodel collagen more than their WT clones. However, YAP nuclear translocation and EMT were not significantly altered in relation to changes in other physical parameters. Conclusions: This is the first study to investigate and report on the altered mechanobiological features of PDAC cells that have acquired chemoresistance. A better understanding of mechanical features could help in identifying future targets to overcome chemoresistance in PDAC.

Abstract C052: Induction of senescence by paclitaxel in high-grade serous ovarian carcinoma (HGSOC) cells renders the cells resistant to paclitaxel but sensitizes them to BCL-xL targeting agents

Abstract High-grade serous ovarian carcinoma (HGSOC) is a very aggressive form of ovarian cancer, contributing to most ovarian cancer deaths. Paclitaxel is one of the major components of the first line treatment for HGSOC, but the development of chemoresistance to paclitaxel leads to the frequent relapse of the disease and poor prognosis in HGSOC patients. However, the mechanism underlying the chemoresistance has not been well established nor have the strategies to overcome the resistance been developed, which was investigated in the present study using three representative HGSOC cell lines (i.e. Kuramochi, OVCAR4, and OVCAR3 cells) in vitro. The results from our study show that induction of senescence contributes to paclitaxel-induced chemoresistance in HGSOC cells. More importantly, we found that senescent HGSOC cells induced by paclitaxel became highly dependent on BCL-xL for survival and thus were very sensitive to BCL-xL targeting agents, particularly to DT2216 (a BCL-xL specific proteolysis targeting chimera or PROTAC) and 753b (a BCL-xL and BCL-2 dual PROTAC). Because these PROTACs are more potent against senescent HGSOC cells but less toxic to platelets than ABT263 (a BCL-xL and BCL-2 dual inhibitor), they have the potential to be developed as new senolytics to overcome HGSOC chemoresistance to paclitaxel without causing the on-target and dose-limiting thrombocytopenia associated with ABT263 treatment. Citation Format: Yang Yang. Induction of senescence by paclitaxel in high-grade serous ovarian carcinoma (HGSOC) cells renders the cells resistant to paclitaxel but sensitizes them to BCL-xL targeting agents [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr C052.

Abstract A006: Investigating the effects of fibroblasts derived from the primary versus the metastatic organ on 3D biomimetic models of pancreatic cancer

Abstract Pancreatic ductal adenocarcinoma (PDAC) is the 3rd leading cause of cancer death in the United States with a 5-year survival rate of only 13%. Early diagnosis is very difficult and thus 53% of patients are diagnosed after metastasis has already occurred, with the liver being the most frequently affected site. Both primary tumors and metastases have dense desmoplastic stroma due to a high percentage of fibroblasts within the tumor microenvironment (TME). Previously, we developed a tunable 3D biomimetic model of the liver metastatic niche (LMN) to investigate how local fibroblasts affect tumor growth and chemoresistance in PDAC liver metastasis. This study aims to investigate the contributions of fibroblasts at the primary versus metastatic sites. We used matched primary PDAC and liver metastatic (LM) organoids derived from the Kras+/LSL-G12D; Trp53+/LSL-R172H; Pdx1-Cre (“KPC”) genetically engineered mouse model. This allows us to compare the effects of primary PDAC cancer associated fibroblasts (CAFs) and liver metastasis associated fibroblasts (MAFs) on tumor cell growth and chemoresistance. Rheometry analyses were conducted to study the impact of local fibroblasts on the extracellular matrix (ECM) stiffness. Our results showed that both storage and loss moduli were enhanced only when PDAC CAFs were present in the co-cultured gels compared to gels with MAFs. Additionally, the 3D biomimetic model showed fibroblasts increased tumor growth and chemoresistance to gemcitabine, only when they were derived from the same site as the tumor cells. This highlighted the importance of studying the organ-specific microenvironment to develop better treatment options for patients with metastatic PDAC. To delve deeper into the molecular basis of these observations, we conducted RNA-sequencing to identify and compare the gene expression profiles in primary and metastatic tumor organoids exposed to conditioned media from CAFs and MAFs using a transwell membrane co-culture model. Our results showed significant differences in gene expression based on the type of fibroblasts co-cultured with the organoids. Moreover, we investigated the role of MAF-derived exosomes on LM growth and chemoresistance using exosome depletion and direct exosome addition to LM organoids. Lastly, we performed exosomes size and distribution characterizations using dynamic light scattering (DLS) analysis. Taken together, these findings highlight the critical role of the organ-specific microenvironment in tumor progression and the necessity of targeted therapies to improve patient outcomes in metastatic PDAC. Our results underscore the importance of developing a tunable 3D biomimetic model of the LMN, as it enables the testing of novel therapeutic strategies designed to disrupt interactions between MAFs and tumor cells, and potentially advancing treatments for metastatic PDAC. Citation Format: Mahsa Pahlavanneshan, Weikun Xiao, Eileen Fung, Vaidhyanathan Mahaganapathy, Chae Young Eun, Chang-Il Hwang, Shannon Mumenthaler, Reginald Hill. Investigating the effects of fibroblasts derived from the primary versus the metastatic organ on 3D biomimetic models of pancreatic cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Tumor-body Interactions: The Roles of Micro- and Macroenvironment in Cancer; 2024 Nov 17-20; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(22_Suppl):Abstract nr A006.

Targeting mitochondrial metabolism with CPI-613 in chemoresistant ovarian tumors

BackgroundThere is evidence indicating that chemoresistance in tumor cells is mediated by the reconfiguration of the tricarboxylic acid cycle, leading to heightened mitochondrial activity and oxidative phosphorylation (OXPHOS). Previously, we have shown that ovarian cancer cells that are resistant to chemotherapy display increased OXPHOS, mitochondrial function, and metabolic flexibility. To exploit this weakness in chemoresistant ovarian cancer cells, we examined the effectiveness of the mitochondrial inhibitor CPI-613 in treating preclinical ovarian cancer.MethodsChemosensitive OVCAR3, and chemoresistant CAOV3 and F2 ovarian cancer cells lines and their xenografts in nude mice were used. Functional metabolic studies were performed using Seahorse instrument. Metabolite quantification was performed using LC/MS/MS.ResultsMice treated with CPI-613 exhibited a notable increase in overall survival and a reduction in tumor development and burden in OVCAR3, F2, and CAOV3 xenografts. CPI-613 suppressed the activity of pyruvate dehydrogenase and alpha-ketoglutarate dehydrogenase complex, which are two of its targets. This led to a reduction in OXPHOS and tricarboxylic acid cycle activity in all 3 xenografts. The addition of CPI-613 enhanced the responsiveness of chemotherapy in the chemoresistant F2 and CAOV3 tumors, resulting in a notable improvement in survival rates and a reduction in tumor size as compared to using chemotherapy alone. CPI-613 reduced the chemotherapy-induced OXPHOS in chemoresistant tumors. The study revealed that the mechanism by which CPI-613 inhibits tumor growth is through mitochondrial collapse. This is evidenced by an increase in superoxide production within the mitochondria, a decrease in ATP generation, and the release of cytochrome C, which triggers mitochondria-induced apoptosis.ConclusionOur study demonstrates the translational potential of CPI-613 against chemoresistant ovarian tumors.

Abstract B070: Dissecting EV dynamics in the sequestration of doxorubicin from breast cancer cells

Abstract Background: Extracellular vesicles (EVs) are one of the three main analytes sought for in liquid biopsy development. EVs are released by all cell types including cancer cells and play a crucial role in cell-cell communication. Breast cancer cells have been shown to utilize EVs as a mechanism to sequester chemotherapeutic agents, thereby conferring resistance to treatment. This study investigates the role of EVs in doxorubicin (DOX) resistance in MDA-MB-231 breast cancer cells. Method: MDA-MB-231 cells were exposed to increasing dose of anthracycline for 6 and 12 months. Resistance was confirmed by cytotoxicity assay and western blot. Resistant and parent cells were labeled for immunohistochemistry and their EVs were isolated via ultracentrifugation. EVs were analysed using nanoscale flow cytometry and sent for mass spectrophotometry. Result: Using nanoscale flow cytometry, we optimized a method to detect DOX-carrying EVs based on the intrinsic fluorescence of the drug. We found that DOX-resistant cells exhibited lower intracellular DOX accumulation and higher expression of the EV marker CD63 compared to their parental counterparts. Conclusion: These results suggest that chemoresistant breast cancer cells may alter their EV production machinery to evade the lethal effects of DOX. Understanding this mechanism could lead to novel strategies to overcome chemoresistance in breast cancer. Citation Format: Sina Halvaei, Jing Xu, Suganthi Chittaranjan, Sharon Gorski, Karla Williams. Dissecting EV dynamics in the sequestration of doxorubicin from breast cancer cells [abstract]. In: Proceedings of the AACR Special Conference: Liquid Biopsy: From Discovery to Clinical Implementation; 2024 Nov 13-16; San Diego, CA. Philadelphia (PA): AACR; Clin Cancer Res 2024;30(21_Suppl):Abstract nr B070.

TNFAIP2 promotes HIF1α transcription and breast cancer angiogenesis by activating the Rac1-ERK-AP1 signaling axis

Angiogenesis is well known to play a critical role in breast cancer. We previously reported that TNFAIP2 activates Rac1 to promote triple-negative breast cancer (TNBC) cell proliferation, migration, and chemoresistance. However, the potential contribution of TNFAIP2 to tumor angiogenesis remains unknown. In this study, we demonstrated that TNFAIP2 promotes TNBC angiogenesis by activating the Rac1-ERK-AP1-HIF1α signaling axis. Under hypoxia, TNFAIP2 activates Rac1 and ERK sequentially. Following that, ERK activates the AP-1 (c-Jun/Fra1) transcription factor. By employing chromatin immunoprecipitation and luciferase reporter assays, we showed that AP-1 directly interacts with the HIF1α gene promoter, thereby enhancing its transcription. The combined application of ERK inhibitors, U0126 or trametinib, with the VEGFR inhibitor Apatinib, additively suppresses angiogenesis and tumor growth of HCC1806 in nude mice. These findings provide new therapeutic strategies for TNBC.

Antitumor Effect of Peptide-Camptothecin Conjugate Targeting CD133 Protein.

The peptide-drug conjugate (PDC) has emerged as one of the new approaches for cancer therapy, which has the advantages of improved drug target ability and reduced adverse effects compared with the traditional chemotherapy. CD133 is a surface antigen specific to cancer stem cells, which are thought to be responsible for the self-renewal, proliferation, metastasis, and chemoresistance of cancer cells. A PDC for CD133 was designed by us, and it consists of CD133 targeting peptide LS-7 (amino acid sequence LQNAPRS), a pH-sensitive linker (succinyl), and a cytotoxic payload, the cytotoxic molecule camptothecin (CPT) with potent toxicity in vivo and in vitro. An antitumor study exhibited that the conjugate LS-7-CPT has not only improved its cytotoxicity in tumor cells but also retained its anticancer effect in vivo. In addition, the acute toxicity in mice of LS-7-CPT has been improved and the maximum tolerated dose has been increased by at least 56.2-fold. Pull-down and in vivo fluorescent imaging results indicated that LS-7-CPT was enriched in mice tumors by targeting CD133 protein. As far as we know, this is the first report for a PDC molecule designed for CD133, which is important for the study of CPT drug development.

High expression of ADAR mediated by OGT promotes chemoresistance in colorectal cancer through the A-to-I editing pathway.

Colorectal cancer (CRC) is a malignant tumor with poor prognosis and adverse therapeutic effect. The study aims to elucidate the contribution of OGT-mediated glycosylation of ADAR to chemoresistance in CRC through its role and regulatory mechanisms. Variations in OGT expression levels and their impact on CRC cell chemoresistance were investigated using gain-of-function and loss-of-function assays. Through a series of molecular biology experiments, we confirmed that ADAR is the downstream target of OGT regulation, emphasizing the role of OGT-mediated glycosylation in stabilizing ADAR. Furthermore, RNA immunoprecipitation (RIP) assays were conducted to examine the effects of ADAR-mediated A-to-I editing on the mRNA stability and translation of genes associated with DNA damage repair. Elevated OGT expression was found to enhance CRC's malignancy and resistance to chemotherapy. OGT's influence leads to the glycosylation of ADAR, thereby increasing its protein levels. ADAR, through its role in A-to-I editing, modulates the mRNA editing of genes implicated in DNA damage repair. This regulation enhances the expression of these genes, improves DNA repair capabilities, and ultimately, fosters chemoresistance in CRC cells. In conclusion, ADAR promotes PARP1 expression under the positive regulation of OGT-mediated O-glycosylation modification to enhance drug resistance in COAD cells. It provides the research basis for overcoming the drug resistance of CRC.

Neutrophil extracellular traps promote tumor chemoresistance to anthracyclines.

The microenvironment plays an important role in promoting tumor cell chemoresistance, but the mechanisms responsible for this effect are not clear. Here, using models of multiple myeloma (MM) and solid cancers, we demonstrate a novel mechanism mediated by neutrophils, a major cell population in the bone marrow (BM), that protects cancer cells from chemotherapeutics. We show that in response to tumor-derived soluble factors, BM neutrophils release their DNA in the form of neutrophil extracellular traps (NETs). Cell-free DNA derived from NETs is then taken up by tumor cells via endocytosis and localizes to the cytoplasm. We found that both NETs and cell-free DNA taken up by tumor cells can bind anthracyclines, leading to tumor cell resistance to this class of chemotherapeutic agents. Targeting cell-free DNA with Pulmozyme or blocking NET formation with a PAD4 inhibitor abrogates the chemoprotective effect of neutrophils and restores sensitivity of tumor cells to anthracyclines.