Perturbation-Based Modeling Unveils the Autophagic Modulation of Chemosensitivity and Immunogenicity in Breast Cancer Cells.
Isaac Quiros-FernandezLucía Figueroa-ProttiJorge L Arias-AriasNorman Brenes-CorderoFrancisco SilesJavier MoraRodrigo Antonio Mora-RodríguezPublished in: Metabolites (2021)
In the absence of new therapeutic strategies, chemotherapeutic drugs are the most widely used strategy against metastatic breast cancer, in spite of eliciting multiple adverse effects and having low responses with an average 5-year patient survival rate. Among the new therapeutic targets that are currently in clinical trials, here, we addressed the association between the regulation of the metabolic process of autophagy and the exposure of damage-associated molecular patterns associated (DAMPs) to immunogenic cell death (ICD), which has not been previously studied. After validating an mCHR-GFP tandem LC3 sensor capacity to report dynamic changes of the autophagic metabolic flux in response to external stimuli and demonstrating that both basal autophagy levels and response to diverse autophagy regulators fluctuate among different cell lines, we explored the interaction between autophagy modulators and chemotherapeutic agents in regards of cytotoxicity and ICD using three different breast cancer cell lines. Since these interactions are very complex and variable throughout different cell lines, we designed a perturbation-based model in which we propose specific modes of action of chemotherapeutic agents on the autophagic flux and the corresponding strategies of modulation to enhance the response to chemotherapy. Our results point towards a promising therapeutic potential of the metabolic regulation of autophagy to overcome chemotherapy resistance by eliciting ICD.
Keyphrases
- cell death
- cell cycle arrest
- clinical trial
- oxidative stress
- metastatic breast cancer
- endoplasmic reticulum stress
- breast cancer cells
- randomized controlled trial
- small molecule
- squamous cell carcinoma
- transcription factor
- cell proliferation
- high resolution
- liquid chromatography
- simultaneous determination
- high resolution mass spectrometry