Extracellular RNA (exRNA) is a particularly attractive molecular component of liquid biopsy because RNA species can be specifically amplified. Of the three major classes of exRNA vehicle?extracellular vesicles (EVs), lipoprotein particles (LPPs), and free ribonucleoproteins (RNPs)?EVs have so far received the most attention. Within each class, there is also tremendous diversity by physical characteristics of size, density, and surface charge. Indeed, to our knowledge, no study to date has profiled exRNA in multiple members of the three carrier classes that have been isolated rigorously from the same samples. There is a strong need to develop new strategies and controls to ensure that comparisons of exRNA carriers are not confounded by co- isolation (different classes of carriers present in the same fraction) or contamination (detection of uncomplexed and/or foreign RNAs introduced during sample collection and processing). To this end, we assemble a team of experts on EVs, LPPs, and RNPs, along with experts in cutting-edge separation and characterization methods. In an initial UG3 phase, we will first (Aim 1) use a combination of state-of-the-field physical and biochemical separation methods to separate a library of eight subtypes of EVs, LPPs, and RNPs from the same biological samples and with the best achievable purity. ?Gold standard? proteomic, lipidomic, glycomic, and RNomic datasets will be generated. Carefully designed ?process? controls will for the first time establish an across-the- board baseline of contaminants and other artifacts that may complicate interpretation.
In Aim 2, we will test asymmetric field-flow fractionation (AF4) and affinity capture platforms including the ExoView platform and sensitive electrochemical sensors as superior alternatives to the most commonly used legacy method, differential centrifugation. We will seek gains in speed, resolution, and purity compared with legacy techniques. If go/no-go criteria are met by the end of the second year (UG3), we will proceed to a UH3 phase. This phase will include an Aim 3, validating results in multiple locations and with approximately 6 times the original sample numbers to account for influence of sex and age. The AF4 method will be further developed with additional modifications based on our engineering and analytical chemistry expertise, while ExoView technology will be harnessed to screen antibodies and other affinity materials for rapid isolations and to detect abundant RNA species directly in immobilized exRNA carriers. Finally, an Aim 4 will assess the biological factor of diet with valuable samples from intervention studies, along with the possible desirability of collecting samples in RNase inhibitors to preserve more fragile RNA species. Overall, we hypothesize that 1) AF4, on its own or with methodologic modifications, as well as 2) novel affinity separation approaches will improve substantially on ultracentrifuge-based methods in ease and purity and on current state-of-the-art but tedious and lengthy exRNA carrier separation methods.
Ribonucleic acid molecules can be detected in biological fluids, where they are protected by three broad classes of molecular carriers and serve as indicators of the health of their cell and tissue of origin. Since our ability to harness these messages may be limited by the physical similarities of their vehicles, in this project, we use cutting-edge technologies to achieve faster and better ways to separate and characterize extracellular RNA carriers. Unbiased methods of measuring RNAs are deployed to compare novel methods with state-of- the-art standard materials, and the influence of variables such as biological sex, age, and diet are examined.
