Abstract

In 2020, the National Cancer Institute (NCI) estimates 57,600 new cases and 47,050 deaths in the US due to pancreatic ductal adenocarcinoma (PDAC). A dismal 10% five-year overall survival rate in PDAC is attributed to late diagnosis, limited treatment options, a remarkably high metastasis rate, and resistance of this cancer to available therapies. Therefore, a better understanding of the mechanisms of how PDAC tumors acquire drug resistance and spread to distal parts of the body are necessary for developing novel therapeutic approaches. Exosomes, microscopic vesicles released from most cells (both tumor and non-tumor) have been recently established to play a significant role in cell to cell communication. Exosomes modulate their target cell responses systematically depending on the nature of exosomal cargoes (nucleic acids, proteins, and lipids). PDAC derived exosomes have been implicated to promote metastasis via forming a pre-metastatic niche of cells as well as enhancing drug resistance. Growth hormone (GH) secreted primarily by the pituitary gland promotes metastasis and drug resistance as shown by plethora of studies. No study has directly assessed the effect of GH on exosomal cargoes in terms of promoting metastases and drug resistance. In this report, we show that GH modulates various pancreatic cancer cell exosomal cargoes which in turn potentially amplifies tumor invasion and metastases. Our data shows that GH treatment on human and mouse PDAC cells increases the exosomal protein levels of TGFβ - a critical inducer of epithelial-to-mesenchymal transition (EMT, a process leading to metastasis). In addition, GH treatment also increases extracellular matrix-degrading enzymes, MMP2 and 9, as well as multi-drug efflux pump ABCC1, ABCB1, and ABCG2 in PDAC cells. These results strongly implicate GH action in driving EMT and chemoresistance via exosomes in pancreatic cancer. Exosomes have a crucial impact especially in the areas of diagnostics and therapeutics. This report is the first to show that GH modulates the effects of exosomes secreted by pancreatic cancer cells. Acknowledgement: This work was supported in part by the State of Ohio’s Eminent Scholar Program that includes a gift from Milton and Lawrence Goll, by the AMVETS, and Ohio University’s Student Enhancement Award and Edison Biotechnology Institute.

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