Microbiota enterotoxigenic Bacteroides fragilis-secreted BFT-1 promotes breast cancer cell stemness and chemoresistance through its functional receptor NOD1.

JAK/STAT3-Regulated Fatty Acid β-Oxidation Is Critical for Breast Cancer Stem Cell Self-Renewal and Chemoresistance

Accumulating evidence suggests that the root of drug chemoresistance in breast cancer is tightly associated with subpopulations of cancer stem cells (CSCs), whose activation is largely dependent on taxol-promoting autophagy. Our pilot study identified GRP78 as a specific marker for chemoresistance potential of breast CSCs by regulating Wnt/β-catenin signaling. Ai Du Qing (ADQ) is a traditional Chinese medicine formula that has been utilized in the treatment cancer, particularly during the consolidation phase. In the present study, we investigated the regulatory effects and molecular mechanisms of ADQ in promoting autophagy-related breast cancer chemosensitivity. ADQ with taxol decreasing the cell proliferation and colony formation of breast cancer cells, which was accompanied by suppressed breast CSC ratio, limited self-renewal capability, as well as attenuated multi-differentiation. Furthermore, autophagy in ADQ-treated breast CSCs was blocked by taxol via regulation of β-catenin/ABCG2 signaling. We also validated that autophagy suppression and chemosensitizing activity of this formula was GRP78-dependent. In addition, GRP78 overexpression promoted autophagy-inducing chemoresistance in breast cancer cells by stabilizing β-catenin, while ADQ treatment downregulated GRP78, activated the Akt/GSK3β-mediated proteasome degradation of β-catenin via ubiquitination activation, and consequently attenuated the chemoresistance-promoted effect of GRP78. In addition, both mouse breast cancer xenograft and zebrafish xenotransplantation models demonstrated that ADQ inhibited mammary tumor growth, and the breast CSC subpopulation showed obscure adverse effects. Collectively, this study not only reveals the chemosensitizating mechanism of ADQ in breast CSCs, but also highlights the importance of GRP78 in mediating autophagy-promoting drug resistance via β-catenin/ABCG2 signaling.

The Association of Cancer Stem Cells and Chemo-Resistance in Breast, Colon and Prostate Cancer Cells

Background: Chemoresistance is a significant obstacle to the effective treatment of breast cancer (BC), resulting in more aggressive behavior and worse clinical outcome. The molecular mechanisms underlying breast cancer chemoresistance remain unclear. Our microarray analysis had identified the overexpression of a small molecular glycoprotein serglycin (SRGN) in multidrug-resistant BC cells. Here, we aimed to investigate the role of SRGN in chemoresistance of breast cancer and elucidate the underlying mechanisms.Methods: SRNG overexpression was identified using microarray analysis and its clinical relevance was analyzed. To investigate the role of SRGN, we performed various in vitro and in vivo studies, as well as characterization of serum and tissue samples from BC patients. Chemosensitivity measurement, gene expression interference, immunofluorescence staining, mammosphere assay, flow cytometry analysis, luciferase reporter assay, ChIP-qPCR, coimmunoprecipitation, and immunohistochemistry were performed to explore the potential functions and mechanisms of SRGN.Results: We confirmed overexpression of SRGN in chemoresistant BC cells and in serum and tissue samples from BC patients with poor response to chemotherapy. SRGN specifically predicted poor prognosis in BC patients receiving chemotherapy. Mechanistically, SRGN promoted chemoresistance both in vitro and in vivo by cross-talking with the transcriptional coactivator YES-associated protein (YAP) to maintain stemness in BC cells. Ectopic YAP expression restored the effects of SRGN knockdown. Inversely, YAP knockdown rescued the effects of SRGN overexpression. The secreted SRGN triggered ITGA5/FAK/CREB signaling to enhance YAP transcription. Reciprocally, YAP promoted SRGN transcription in a TEAD1-dependent manner to form a feed-forward circuit. Moreover, the YAP/RUNX1 complex promoted HDAC2 transcription to induce chemoresistance and stemness in BC cells. Importantly, the SRGN levels were positively correlated with the YAP and HDAC2 levels in chemoresistant BC tissues. YAP and HDAC2 acted downstream of SRNG and correlated with poor outcomes of BC patients receiving chemotherapy.Conclusions: Our findings clarify the roles and mechanisms of SRGN in mediating chemoresistance in breast cancer and suggest its use a potential biomarker for chemotherapeutic response. We believe that novel therapeutic strategies for breast cancer can be designed by targeting the signaling mediated by the crosstalk between SRGN and YAP.

UGCG promotes chemoresistance and breast cancer progression via NF-κB and Wnt/β-catenin pathway activation.

MiR-873/PD-L1 axis regulates the stemness of breast cancer cells

Introduction Resistance to therapeutics is one of the major concerns for treatment failure in breast cancer. The use of antimetabolite, 5 Fluorouracil (5-FU) based combinational therapies have been an ideal treatment blueprint for different types of solid tumors including breast cancer. However, the efficacy of 5-FU based treatment is limited due to development of resistance. Recently mitophagy has evolved as an important cell survival mechanisms in response to different stress stimuli associated with cancer treatments. Mitophagy is the selective form of autophagy that removes damaged mitochondria. Although mitophagy has dual role in context to cell survival and cell death, still a large number of evidences suggests their prosurvival role with respect to chemoresistance. Here we investigated the role of mitophagy in 5-FU induced breast cancer chemoresistance. Methodology Chemoresistant cell lines were established by continuous exposure to increasing concentration of 5-FU to breast cancer cell lines (MDA-MB-231 and MDA-MB-468). Chemoresistant cells were characterized by MTT assay, caspase assay and western blot. Induction of autophagy was confirmed by GFP LC3 transfection and western blot. Further prosurvival autophagy was asserted through FACS by using autophagy inhibitor chloroquine (CQ) and stable ATG5 lentiviral knockdown. Mitophagy was confirmed using MTDR (detects mitochondrial mass) and TMRM (detects mitochondrial membrane potential) through FACS. Further immunofluorescence and western blot were used to confirm key mitophagy markers (TOM20 and Porin) with CQ treatments. Involvement of parkin mediated mitophagy was later confirmed by cytosolic/mitochondrial fractionation assay and by siRNA knockdown. Results Characterization study reveals chemoresistant cells were more apoptosis resistant compared to their parental counterparts.The levels of the autophagy markers LC3-II, p62, ATG5 and Beclin-1 were elevated in chemoresistant cells while mitochondrial mass and mitochondrial membrane potential were reduced. Treatment of CQ and ATG5 knockdown significantly augment 5-FU sensitivity in chemoresistant cells. Simultaneously CQ treatment increased TOM20 and porin expression revealing induction of mitophagy in chemoresistant cells. Further cell fractionation assay and siRNA knockdown of Parkin confirm its mitochondrial localization and prosurvival function in 5-FU resistant breast cancer respectively. some important in vitro findings were also confirmed in xenograft breast cancer model. Conclusion Here we noticed that chemoresistant breast cancer cells exhibit greater apoptosis resistance to 5-FU compared to parental cells along with enhanced cytoprotective mitophagy, also underscoring the involvement of parkin mediated induction of mitophagy in chemoresistant breast cancer. Citation Format: Chandan Kanta Das, Bikash Chandra Jena, Subhayan Das, Aditya Parekh, Goutam Dey, Rashmi Bharti, Deblina Bharadwaj, Sujit Kumar Bhutia, Donat Kögel, Mahitosh Mandal. Parkin-mediated mitophagy regulates 5-fluorouracil-induced chemoresistance in breast cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1348.

PURPOSE: Hedgehog (HH) pathway has been implicated in maintenace and survival of breast cancer and cancer stem cells, EMT regulation, breast carcinogenesis and resistance to chemoradiation in solid tumors. Dysregulation of this pathway occurs in more than 50% of breast cancers. We have already demonstrated that immune-induced epithelial to mesenchymal transition (EMT) leads to the generation of breast cancer stem cells (BCSCs) from a parental epithelial breast cancer cell line in an in vivo murine model (Cancer Research 2009). The aim of our study is to demonstrate that resistance in the BCSCs is linked to HH hyperactivation and that the selective blockade of this pathway could eradicate this subpopulation of BCSCs in preclinical models. METHODS: One parental epithelial (E) and three mesenchymal BCSCs cell lines (M1, M2 and M3) were used for all the in vitro experiments. qRT-PCR was used to quantify the expression of the gene components of the pathway and gene targets. Measurement of Gli1, caspase 3 and Cyclin D1 protein expression was determined by Western blot. Cell viability assays were performed with Paclitaxel and the HH inhibitor GDC-0449. Apoptosis assays were performed when cell lines were treated with paclitaxel (10nM), GDC-0449 (25uM) or the combination of them. For the in vivo xenografted mouse model, 106 cells (E and M2) were inoculated sc respectively into the flank of 6–8 week-old syngeneic female FVB/N-TgN (MMTVneu) 202Mul/J mice. Treatment was started on daily GDC-0449 (ip), paclitaxel (ip on days 1, 4 and 8) or both drugs when tumors reached 0.5 cm2. Statistical analysis was performed using one-way ANOVA with the Bonferroni multiple comparison test. RESULTS: Activity of the HH measured by the expression of Gli1 was increased in BCSC cell lines as compared to E cell line (p < 0.001). This was antagonized as expected by treatment with GDC-0449. Reporter and expression assay showed that GDC-0449 decreases Gli1 transcriptional activity and levels of a HH downstream target gene, cyclin D1. In all BCSC lines (but not in the E cell line), a synergistic effect was showed with the combination treatment as compared to control (p ≤ 0.01) and to paclitaxel or GDC-0449 alone (p ≤ 0.05 respectively) as well as a highly increased apoptotic activity (p ≤ 0.001 with control and p ≤ 0.05 with monotherapy). Tumors derived from M2 injection regressed when the combination schedule was administered (p ≤ 0.05) at 2 weeks after the start of the treatment. CONCLUSION: The inhibition of the HH pathway with GDC-0449 plus paclitaxel demonstrates a synergistic therapeutic effect in comparison to monotherapy, as shown by increased apoptotic activity, cell cycle arrest and significant reduction of tumor size in vivo. Together these results provide the rationale for future clinical trials including the blockade HH and standard chemotherapy in order to eradicate the whole population of tumor cells (also BCSCs) within the tumors and avoid disease relapse and metastasis in breast cancer patients. Citation Information: Cancer Res 2012;72(24 Suppl):Abstract nr P5-03-07.

Chemotherapy resistance of breast cancer poses a great challenge to the survival of patients. During breast cancer treatment, the development of intrinsic and acquired drug resistance tends to further induce adverse prognosis, such as metastasis. In recent years, the progress of research on cytokine-modulated tumor microenvironment and breast cancer stem cells (BCSCs) has shed light on defining the mechanisms of drug resistance gradually. In this review, we have discussed cytokine regulation on breast cancer chemoresistance. Cytokines can affect tumor cell behavior or reprogram tumor niche through specific signaling pathways, thereby regulating the progress of drug resistance. In addition, we summarized the mutually regulatory networks between cytokines and BCSCs in mediating chemoresistance. Cytokines in the tumor microenvironment can regulate the self-renewal and survival of BCSCs in a variety of ways, sequentially promoting chemotherapeutic resistance. Therefore, the combinational treatment of BCSC targeting and cytokine blockade may have a positive effect on the clinical treatment of breast cancer.

The chemosensitizing activity of betulinic acid in suppressing macrophage polarization through GSK-3β/β-catenin/CXCL1 signaling in breast cancer.

CN06-02: Breast cancer stem cells.

<div>Abstract<p>Cancer stem cells (CSC) are supported by the tumor microenvironment, and non-CSCs can regain CSC phenotypes in certain niches, leading to limited clinical benefits of CSC-targeted therapy. A better understanding of the mechanisms governing the orchestration of the CSC niche could help improve the therapeutic targeting of CSCs. Here, we report that Rab13, a small GTPase, is highly expressed in breast CSCs (BCSC). Rab13 depletion suppressed breast cancer cell stemness, tumorigenesis, and chemoresistance by reducing tumor-stroma cross-talk. Accordingly, Rab13 controlled the membrane translocation of C-X-C chemokine receptor type 1/2 (CXCR1/2), allowing tumor cells to interact with tumor-associated macrophages and cancer-associated fibroblasts to establish a supportive BCSC niche. Targeting the Rab13-mediated BCSC niche with bardoxolone-methyl (C-28 methyl ester of 2-cyano-3, 12-dioxoolen-1, 9-dien-28-oic acid; CDDO-Me) prevented BCSC stemness <i>in vitro</i> and <i>in vivo</i>. These findings highlight the novel regulatory mechanism of Rab13 in BCSC, with important implications for the development of therapeutic strategies for disrupting the BCSC niche.</p>Significance:<p>Targeting Rab13 perturbs formation of the breast cancer stem cell niche by inhibiting cross-talk between cancer cells and the tumor microenvironment, providing a therapeutic opportunity for niche-targeted breast cancer treatment.</p></div>

<div>Abstract<p>Cancer stem cells (CSC) are supported by the tumor microenvironment, and non-CSCs can regain CSC phenotypes in certain niches, leading to limited clinical benefits of CSC-targeted therapy. A better understanding of the mechanisms governing the orchestration of the CSC niche could help improve the therapeutic targeting of CSCs. Here, we report that Rab13, a small GTPase, is highly expressed in breast CSCs (BCSC). Rab13 depletion suppressed breast cancer cell stemness, tumorigenesis, and chemoresistance by reducing tumor-stroma cross-talk. Accordingly, Rab13 controlled the membrane translocation of C-X-C chemokine receptor type 1/2 (CXCR1/2), allowing tumor cells to interact with tumor-associated macrophages and cancer-associated fibroblasts to establish a supportive BCSC niche. Targeting the Rab13-mediated BCSC niche with bardoxolone-methyl (C-28 methyl ester of 2-cyano-3, 12-dioxoolen-1, 9-dien-28-oic acid; CDDO-Me) prevented BCSC stemness <i>in vitro</i> and <i>in vivo</i>. These findings highlight the novel regulatory mechanism of Rab13 in BCSC, with important implications for the development of therapeutic strategies for disrupting the BCSC niche.</p>Significance:<p>Targeting Rab13 perturbs formation of the breast cancer stem cell niche by inhibiting cross-talk between cancer cells and the tumor microenvironment, providing a therapeutic opportunity for niche-targeted breast cancer treatment.</p></div>

SLC31A1 promotes chemoresistance through inducing CPT1A-mediated fatty acid oxidation in ER-positive breast cancer.

BackgroundCancer stem-like cell is a key barrier for therapeutic resistance and metastasis in various cancers, including breast cancer, yet the underlying mechanisms are still elusive. Through a genome-wide lncRNA expression profiling, we identified that LINC00115 is robustly upregulated in chemoresistant breast cancer stem-like cells (BCSCs).MethodsLncRNA microarray assay was performed to document abundance changes of lncRNAs in paclitaxel (PTX)-resistant MDA-MB-231 BCSC (ALDH+) and non-BCSC (ALDH−). RNA pull-down and RNA immunoprecipitation (RIP) assays were performed to determine the binding proteins of LINC00115. The clinical significance of the LINC00115 pathway was examined in TNBC metastatic lymph node tissues. The biological function of LINC00115 was investigated through gain- and loss-of-function studies. The molecular mechanism was explored through RNA sequencing, mass spectrometry, and the CRISPR/Cas9-knockout system. The therapeutic potential of LINC00115 was examined through xenograft animal models.ResultsLINC00115 functions as a scaffold lncRNA to link SETDB1 and PLK3, leading to enhanced SETDB1 methylation of PLK3 at both K106 and K200 in drug-resistant BCSC. PLK3 methylation decreases PLK3 phosphorylation of HIF1α and thereby increases HIF1α stability. HIF1α, in turn, upregulates ALKBH5 to reduce m6A modification of LINC00115, resulting in attenuated degradation of YTHDF2-dependent m6A-modified RNA and enhanced LINC00115 stability. Thus, this positive feedback loop provokes BCSC phenotypes and enhances chemoresistance and metastasis in triple-negative breast cancer. SETDB1 inhibitor TTD-IN with LINC00115 ASO sensitizes PTX-resistant cell response to chemotherapy in a xenograft animal model. Correlative expression of LINC00115, methylation PLK3, SETDB1, and HIF1α are prognostic for clinical triple-negative breast cancers.ConclusionsOur findings uncover LINC00115 as a critical regulator of BCSC and highlight targeting LINC00115 and SETDB1 as a potential therapeutic strategy for chemotherapeutic resistant breast cancer.