Polycarbonate Ultracentrifuge Tube Re-Use in Proteomic Analyses of Extracellular Vesicles

A detailed protocol is provided for cleaning and re-using polycarbonate ultracentrifuge tubes to perform extracellular vesicle isolation suitable for proteomics experiments.

Single-use laboratory plastics exacerbate the pollution crisis and contribute to consumable costs. In extracellular vesicle (EV) isolation, polycarbonate ultracentrifuge (UC) tubes are used to endure the associated high centrifugal forces. EV proteomics is an advancing field and validated re-use protocols for these tubes are lacking. Re-using consumables for low-yield protein isolation protocols and downstream proteomics requires reagent compatibility with mass spectroscopy acquisitions, such as the absence of centrifuge tube-derived synthetic polymer contamination, and sufficient removal of residual proteins.

This protocol describes and validates a method for cleaning polycarbonate UC tubes for re-use in EV proteomics experiments. The cleaning process involves immediate submersion of UC tubes in H₂O to prevent protein drying, washing in 0.1% sodium dodecyl sulfate (SDS) detergent, rinsing in hot tap water, demineralized water, and 70% ethanol. To validate the UC tube re-use protocol for downstream EV proteomics, used tubes were obtained following an experiment isolating EVs from cardiovascular tissue using differential UC and density gradient separation. Tubes were cleaned and the experimental process was repeated without EV samples comparing blank never-used UC tubes to cleaned UC tubes. The pseudo-EV pellets obtained from the isolation procedures were lysed and prepared for liquid chromatography-tandem mass spectrometry using a commercial protein sample preparation kit with modifications for low-abundance protein samples.

Following cleaning, the number of identified proteins was reduced by 98% in the pseudo-pellet versus the previous EV isolation sample from the same tube. Comparing a cleaned tube against a blank tube, both samples contained a very small number of proteins (≤20) with 86% similarity. The absence of polymer peaks in the chromatograms of the cleaned tubes was confirmed. Ultimately, the validation of a UC tube cleaning protocol suitable for the enrichment of EVs will reduce the waste produced by EV laboratories and lower the experimental costs.

Extracellular vesicles (EVs) are lipid-bilayer-delimited particles released from cells that carry biologically active cargo, such as protein, and participate in various biological processes, including cell-cell communication and the formation of biologic mineralization¹. These particles are found in all body fluids and tissues, and their biological activities and uses are a rapidly evolving field of scientific research. Isolation and validation of these nanoparticles present various challenges due to their small size and bio-similarity to other particles, such as liposomes and protein aggregates. The most recent International Society of Extrace....

1. Tube cleaning

NOTE: The EV isolation procedure uses both capped and uncapped polycarbonate UC tubes (detailed below). The same procedure was followed for both capped and uncapped tubes. In the case of capped tubes, the lid parts were cleaned individually and reassembled post drying and pre-storage.

1. Following the initial use of the polycarbonate tubes and removal of the sample, immediately submerge UC tubes in tap water to prevent drying of the sample to the side.......

To validate the cleaning protocol (Figure 1), two experiments were performed. First, the proteome of the "mock sample" from the cleaned tube was compared against the proteome of the tissue EV sample from the tube's initial use to determine the carryover of identified proteins. Representative chromatograms show a reduction in peak heterogeneity following cleaning of the tubes (Figure 2). In the original EV isolation, 806 proteins were identified with .......

Here we describe and validate a protocol for cleaning polycarbonate UC tubes for EV enrichment and proteomic applications. We demonstrated the successful removal of residual protein from the previous UC tube sample compared with a cleaned pseudo-pellet analysis below the limit of detection of this mass spectrometry acquisition protocol and showed the proteomic similarity of blank never-used UC tube compared to cleaned UC tube pseudo pellets.

First, to prevent the inadvertent adsorption of prot.......

This study was supported by a research grant from National Institutes of Health grants (NIH) R01HL147095, R01HL141917, and R01HL136431, Kowa Company, Ltd., and the European Union's Horizon 2020 Research and Innovation Program under the Marie Skłodowska-Curie Grant Agreement No. 101023041 (R. Cahalane). Figure 1 was created with Biorender.com. The current cleaning protocol was developed by modifying a recommended tube cleaning protocol presented at the International Society of Extracellular Vesicles 2023 Education Day (https://www.youtube.com/watch?v=DOebcOes6iI). Many thanks to Dr. Kathryn Howe and Dr. Sneha Raju from the University Health Ne....