Abstract

Triple-negative breast cancer (TNBC) accounts disproportionally for the majority of breast cancer-related deaths throughout the world. This is largely attributed to lack of a specific therapy capable of targeting both bulk tumor mass and cancer stem cells (CSC), as well as appropriate animal models to accurately evaluate treatment efficacy for clinical translation. Thus, development of effective and clinically translatable targeted therapies for TNBC is an unmet medical need. We developed a hybrid nanoparticles-based co-delivery platform containing both paclitaxel and verteporfin (PV-NP) to target TNBC patient-derived xenograft (PDX) tumor and CSCs. MRI and IVIS imaging were performed on mice containing PDX tumors to assess tumor vascularity and accumulation of NPs. NF-κB, Wnt, and YAP activities were measured by reporter assays. Mice bearing TNBC PDX tumor were treated with PV-NPs and controls, and tumors progression and CSC subpopulations were analyzed. MRI imaging indicated high vascularization of PDX tumors. IVIS imaging showed accumulation of NPs in PDX tumors. In comparison with control-NPs and free-drug combination, PV-NPs significantly retarded tumor growth of TNBC PDX. PV-NPs simultaneously repressed NF-κB, Wnt, and YAP that have been shown to be crucial for cancer growth, CSC development, and tumorigenesis. In conclusion, NPs containing two clinically used drugs concurrently inhibited NF-κB, Wnt, and YAP pathways and exhibited synergic effects on killing TNBC bulk tumor and CSCs. This combination nanotherapy evaluated with a PDX model may lead to an effective treatment of patients with TNBC.

Highlights

  • Breast cancer remains a leading cause of death in women worldwide [1]

  • Relapse has been closely associated with cancer stem cells (CSC) and is a major challenge in Triple-negative breast cancer (TNBC) wherein approximately one third of patients will experience a distant recurrence within 2.6 years [2]

  • We showed that paclitaxel and verteporfin in single lipid-hybrid nanoparticles (PV-NPs) suppressed NF-kB, Wnt, and YAP pathways that are crucial for cancer growth, CSC development, and tumorigenesis

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Summary

Introduction

Breast cancer remains a leading cause of death in women worldwide [1]. Among the various breast cancer subtypes, triple-negative breast cancer (TNBC, a highly heterogeneous disease) accounts for only one fifth of all breast cancers, but disproportionally accounts for the majority of breast cancer– related deaths. Relapse has been closely associated with cancer stem cells (CSC) and is a major challenge in TNBC wherein approximately one third of patients will experience a distant recurrence within 2.6 years [2]. In contrast to other breast cancer subtypes, due to lack of specific targets, conventional chemotherapy is still the clinical standard treatment for TNBC. In TNBC, CSCs have been found to coexist in two distinct but interconvertible subtypes: epithelial ALDHþ and mesenchymal CD44þ/CD24À subpopulations that are closely associated with chemoresistance, tumor regrowth, and disease relapse [4,5,6]. We hypothesize that www.aacrjournals.org therapeutic strategies capable of effectively delivering drugs into tumor to coinhibit NF-kB, Wnt, and YAP signals and evaluating therapeutic efficacy with a clinically translatable model may lead to the effective treatment of TNBC

Methods
Results
Conclusion

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