A Combined Bioinformatic and Nanoparticle-Based Study Reveal the Role of ABCG2 in the Drug Resistant Breast Cancer.

ATP-Binding Cassette subfamily G member 2 (ABCG2) is a semi-transport protein that plays a key role in human diseases, including bladder cancer and lung cancer, and maybe resistant to chemotherapy drugs. The present study aimed to determine the role and underlying mechanisms of breast cancer resistance protein (ABCG2) in breast cancer and to study the reversal effect of inhibiting ABCG2 expression on the drug resistance of breast cancer cells and provide new ideas for gene-targeted therapy of breast cancer. The structure and genomic alterations of ABCG2 were systematically investigated using GeneCards and cBioPortal to reveal the genetic alterations (including amplification and deep deletions) of ABCG2. We performed the correlation between ABCG2 expression and clinicopathological parameters using the data in bc-GenExMiner 4.4. Then, the protein-protein interaction and functional enrichment analysis of ABCG2 were performed based on the STRING, bc-GenExMiner 4.4, and Enrichr databases. Besides, we analyzed the pathway activity of genes that interact with ABCG2 using GSCALite and PharmGKB. Using magnetic nanoparticles polyMAG as the carrier of ABCG2-siRNA, polyMAG-ABCG2-siRNA was transfected into the Doxorubicin (DOX)-resistant breast cancer cell line MCF-7/ADR and directly into the tumors in nude mice. Patent US20150328485 points out that magnetic nanoparticles can be attached to an anti-cancer drug, such as an antibody-based anti-cancer drug. We found a statistically significant correlation between ABCG2 expression and clinicopathological parameters, such as Estrogen Receptor (ER), Progesterone Receptor (PR), and human epidermal growth factor receptor-2 (HER2), and nodal status in breast cancer patients. ABCG2 is closely related to SLC2A9, KIT, ABCG1, and MRPS7, which suggests that these proteins may be functional partners of breast cancer. The expression of ABCG2 is correlated with the activation or inhibition of multiple oncogenic pathways. Moreover, we found that ABCG2 is involved in the DOX signaling pathway. The small interfering RNA (siRNA) carried by magnetic nanoparticles can reduce the expression of ABCG2, thereby significantly improving the therapeutic effect of DOX on tumors. Our findings provide a more in-depth understanding of ABCG2 as a biomarker for predicting DOX-resistance and insights into the development of related therapeutic targets in breast cancer.

Huo Q ，Yuan J ，Zhu T ，Li Z ，Xie N ... -  《-》

GPER mediates decreased chemosensitivity via regulation of ABCG2 expression and localization in tamoxifen-resistant breast cancer cells.

Rescue chemotherapy is usually the preferred treatment for patients with advanced estrogen receptor-positive (ER+) breast cancer with endocrinotherapy resistance. However, these patients often simultaneously show a poor response to cytotoxic drugs, and thus the detailed mechanism of this resistance needs to be further investigated. Our previous research indicated that the G-protein-coupled estrogen receptor (GPER) is a novel mediator of the development of multidrug resistance, including resistance to both endocrinotherapy and chemotherapy, and ATP binding cassette subfamily G member 2 (ABCG2) has been identified as an engine that confers cancer cells with chemoresistance by expelling xenobiotics and chemotherapeutics. Here, we are the first to show that the expression levels of GPER and ABCG2 are markedly increased in tamoxifen-resistant ER + metastases compared to the corresponding primary tumors. A plasma membrane expression pattern of GPER and ABCG2 was observed in patients with metastases. Furthermore, both ER modulator tamoxifen, GPER-specific agonist G1 and pure ER antagonist ICI 182,780 significantly enhanced ABCG2 expression in tamoxifen-resistant breast cancer cells (MCF-7R) but not in tamoxifen-sensitive cells (MCF-7). The activated downstream GPER/EGFR/ERK and GPER/EGFR/AKT signaling pathways were responsible for regulating the expression and cell membrane localization of ABCG2, respectively, in MCF-7R cells. Interestingly, the above phenomenon could be alleviated by inhibitors of both the indicated signaling pathways and by knockdown of GPER in MCF-7R cells. More importantly, the tamoxifen-induced GPER/ABCG2 signaling axis was shown to play a pivotal role in the development of chemotherapy (doxorubicin) resistance both in vitro and in vivo. The clinical data further revealed that tamoxifen-resistant patients with high GPER/ABCG2 signaling activation had poor progression-free survival (PFS) when given rescue anthracycline chemotherapy. Therefore, our data provide novel insights into GPER-mediated chemoresistance and provide a rationale for the GPER/ABCG2 signaling axis being a promising target for reversing chemoresistance in patients with advanced ER + tamoxifen-resistant breast cancer.

Yu T ，Cheng H ，Ding Z ，Wang Z ，Zhou L ，Zhao P ，Tan S ，Xu X ，Huang X ，Liu M ，Peng M ，Qiu YA ... -  《-》

siRNAs targeting multidrug transporter genes sensitise breast tumour to doxorubicin in a syngeneic mouse model.

Tiash S ，Chowdhury EH 《-》

High expression of ABCG2 is associated with chemotherapy resistance of osteosarcoma.

Shu H ，Yuan B ，Huang Y ，Wang L ，He B ，Sun Q ，Sun L ... -  《Journal of Orthopaedic Surgery and Research》

Acyl-CoA synthetase-4 is implicated in drug resistance in breast cancer cell lines involving the regulation of energy-dependent transporter expression.

Acyl-CoA synthetase-4 (ACSL4) is an enzyme implicated in estrogen receptor α (ERα) negative regulation and hormone therapy resistance in breast cancer. In addition, ACSL4 has been associated to certain types of hormone resistance in prostate cancer. Chemotherapeutic treatment of disseminated breast cancer is usually faced with therapy resistance associated to ATP-binding cassette (ABC) transporter expression, which detect and eject anti-cancer drugs from cells. In this context, the aim of the present work was to study the role of ACSL4 in anti-cancer drug resistance and the involvement of ABC transporters in the underlying mechanisms. To this end, we used MCF-7 Tet-Off/ACSL4 and MDA-MB-231 mock cells, which overexpress ACSL4, and control line MCF-7 Tet-Off empty vector, MDA-MB-231 shRNA ACSL4 and MDA-MB-231 wild type cells. Assays were conducted on cell viability (MTT), cell proliferation (BrdU), drug efflux (flow cytometry), ACSL4-responsive drug resistance ABC transporter genes (RNA-Seq), transporter mRNA expression, protein levels and signaling pathway participation (real-time PCR and Western blot). Higher survival rates upon chemotherapeutic treatment were obtained in MCF-7 Tet-Off/ACSL4 and MDA-MB-231 mock cells, an effect counteracted by doxycycline- or shRNA-induced ACSL4 inhibition, respectively. A synergic effect of ACSL4 inhibitor triacsin C and chemotherapeutic drugs was observed on the inhibition of MDA-MB-231 wild type cell proliferation. MCF-7 Tet-Off/ACSL4 cells showed greater doxorubicin, Hoechst 33342 and calcein AM efflux. In contrast, MDA-MB-231 shRNA ACSL4 cells evidenced inhibition of chemotherapeutic drug efflux. ABCG2, ABCC4, and ABCC8 were identified as ACSL4-responsive drug resistance genes whose expression was increased in MCF-7 Tet-Off/ACSL4 cells but inhibited in MDA-MB-231 shRNA ACSL4 cells. Further cell survival assays in the presence of Ko 143 and Ceefourin 1, inhibitors of ABCG2 and ABCC4, respectively, upon chemotherapeutic treatment showed greater participation of ABCG2 in anti-cancer drug resistance in cells overexpressing ACSL4. In addition, ACSL4 inhibition and chemotherapeutic treatment combined with rapamycin-induced mTOR inhibition synergically inhibited proliferation and reduced ABCG2 expression in cells overexpressing ACSL4. In sum, ACSL4 may be regarded as a novel therapeutic target regulating the expression of transporters involved in anticancer drug resistance through the mTOR pathway to restore drug sensitivity in tumors with poor prognosis for disease-free and overall survival.

Orlando UD ，Castillo AF ，Medrano MAR ，Solano AR ，Maloberti PM ，Podesta EJ ... -  《-》