Abstract
In chronic lymphocytic leukemia (CLL) and very likely all cancer types, extracellular vesicles (EVs) are a common mechanism by which intercellular messages are communicated between normal, diseased, and transformed cells. Studies of EVs in CLL and other cancers have great variability and often lack reproducibility. For CLL patient plasma and cell lines, we sought to characterize current approaches used in isolating EV products and understand whether cell culture–conditioned media or complex biological fluids confound results. Utilizing nanoparticle tracking analysis, protein quantification, and electron microscopy, we show that ultracentrifugation with an OptiPrep cushion can effectively minimize contaminants from starting materials including plasma and conditioned media of CLL cell lines grown in EV-depleted complete RPMI media but not grown in the serum-free media AIM V commonly used in CLL experimental work. Moreover, we confirm the benefit of including 25 mM trehalose in PBS during EV isolation steps to reduce EV aggregation, to preserve function for downstream applications and characterization. Furthermore, we report the highest particles/μg EVs were obtained from our CLL cell lines utilizing the CELLine bioreactor flask. Finally, we optimized a proliferation assay that offers a functional evaluation of our EVs with minimal sample requirements.
Highlights
Extracellular vesicles (EVs) are a diverse group of membranous nanoparticles produced by normal, diseased, and neoplastic cells
We have previously shown that chronic lymphocytic leukemia (CLL) plasma–derived exosomes have a distinct microRNA signature, with miR-150, miR-155, and miR-29 family upregulated but miR-223 downregulated compared with healthy donors [8]
We report an optimized proliferation assay [26, 54] where we have utilized a stromal cell line with GFP fluorescence (HS5-GFP) that can allow us to monitor the effect of EVs at several time points with minimal sample requirements
Summary
Extracellular vesicles (EVs) are a diverse group of membranous nanoparticles produced by normal, diseased, and neoplastic cells. EVs carry DNA, RNAs, and membrane and soluble proteins [1,2,3,4]. EVs mediate the transfer of their biologically active cargo molecules, offering an intercellular means of communication [5]. Tumor-associated EVs have been implicated in cancer progression via microenvironment modulation and immune suppression [6, 7]. We have previously shown that chronic lymphocytic leukemia (CLL) plasma–derived exosomes have a distinct microRNA signature, with miR-150, miR-155, and miR-29 family upregulated but miR-223 downregulated compared with healthy donors [8]. With the great promise of EV research, it is critical to robustly isolate sufficient amounts of EVs in a reproducible manner, making standardization of isolation techniques a high-priority task
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