Optimum inhibition of MCF-7 breast cancer cells by efficient targeting of the macropinocytosis using optimized paclitaxel-loaded nanoparticles.

AIMS: Breast cancer (BC) is the third leading cause of death among other cancer types. Worldwide, it is the most common harmful disease in women, representing 1/4 of all cancers. Treatment of BC remains an ongoing challenge to most researchers. Understanding how cancer cells differ from normal cells can enhance drug targeting and overall disease progression. Endocytosis is a major physiological process modified in cancer cells and affects the cellular uptake of chemotherapeutic agents. MCF-7 breast cancer cells exhibit constitutive macropinocytic activity in comparison to normal non-macropinocytic MCF-10A breast cells. Therefore, we hypothesized that blocking the macropinocytosis mechanism in MCF-7 cells may inhibit the cancer progression while maintaining the safety of normal cells. MAIN METHODS: Using nano-precipitation technique, paclitaxel-PLGA-NPs were successfully prepared in the size range and charge required to opt for macropinocytosis in MCF-7 cells. KEY FINDINGS: Uptake and endocytosis inhibitor assays indicated that the developed NPs acquired size and surface charges that efficiently target macropinocytosis of MCF-7 cells. Paclitaxel-loaded PLGA-NPs showed higher efficacy against MCF-7 cells, while providing no toxicity on normal MCF-10A cells. Metabolomics analysis indicated the nutrients deprivation because of occupying the macropinocytosis. However, treatment of fresh MCF-7 cancer cells by metabolites secreted from PLGA-NPs-treated MCF-7 cells showed a potential metastatic activity. Thus, co- administration with an anti-metastatic drug is advised. SIGNIFICANCE: Collectively, adjusting the size and surface characteristics of a drug can critically control its cellular uptake, affecting the efficacy of drugs and the microenvironment of cancer cells.

Role of Exosomes in Breast Cancer Management: Evidence-Based Review.

The field of cancer research has massively grown in recent decades, leading to a better understanding of the underlying causes and greatly improving the therapeutic approaches. Breast cancer (BC) is the third leading cause of mortality among all cancers and the most common malignant disease in women worldwide, representing one in four of all cancers in women. The crosstalk between cancer cells and the surrounding microenvironment is crucial for tumor progression and metastatic process. Tumor cells communicate not only through classical paracrine signaling mechanisms, including cytokines, chemokines, growth factors, but also through "exosomes". Exosomes are nano-vesicles that are released by various types of cells. Over the last decade, researchers have been attracted by the role of exosomes in breast cancer. It has been proven that exosomes influence major tumor-related pathways, including invasion, migration, epithelial-to-mesenchymal transition (EMT), metastasis, and drug resistance. Additionally, exosomes play important roles in clinical applications. Several studies have demonstrated the potential applications of exosomes in cancer therapy and diagnosis. Furthermore, exosomes have been engineered to function as nano-delivery systems of chemotherapeutic drugs. They can also be designed as vaccines to trigger the patient's immune system. This review discusses the recent progress regarding the use of exosomes as drug delivery systems, therapeutic agents, biomarkers, and vaccines against breast cancer.