Supermeres are functional extracellular nanoparticles replete with disease biomarkers and therapeutic targets

Zhang, Qin; Jeppesen, Dennis K.; Higginbotham, James N.; Graves‐Deal, Ramona; Trinh, Vincent Quoc‐Huy; Ramirez, Marisol; Sohn, Yoojin; Neininger, Abigail C.; Taneja, Nilay; McKinley, Eliot T.; Niitsu, Hiroaki; Cao, Zheng; Evans, Rachel; Glass, Sarah E.; Ray, Kevin C.; Fissell, William H.; Hill, Salisha; Rose, Kristie L.; Huh, Won Jae; Washington, Mary Kay; Ayers, Gregory D.; Burnette, Dylan T.; Sharma, Shivani; Rome, Leonard H.; Franklin, Jeffrey L.; Lee, Youngmin A.; Liu, Qi; Coffey, Robert J.

doi:10.1038/s41556-021-00805-8

Cited by 201 publications

(224 citation statements)

References 61 publications

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“…These steps attempt to remove miRNA in other carriers than EV or miRNA associated with the molecular corona on the EV surface [23,27,74,75]. Our detected miRNAs can therefore be located in or on EV or in other small-sized miRNA carriers remaining in the samples, including recently identified supermeres [27,76]. Other limitations of the study include relatively small sample numbers in the individual groups, which affects statistical power, and modest fold changes for some miRNAs.…”

Section: Discussionmentioning

confidence: 97%

Exploration of Extracellular Vesicle miRNAs, Targeted mRNAs and Pathways in Prostate Cancer: Relation to Disease Status and Progression

Puhka

Thierens

Nicorici

et al. 2022

Cancers

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Background: Prostate cancer (PCa) lacks non-invasive specific biomarkers for aggressive disease. We studied the potential of urinary extracellular vesicles (uEV) as a liquid PCa biopsy by focusing on the micro RNA (miRNA) cargo, target messenger (mRNA) and pathway analysis. Methods: We subjected uEV samples from 31 PCa patients (pre-prostatectomy) to miRNA sequencing and matched uEV and plasma EV (pEV) from three PCa patients to mRNA sequencing. EV quality control was performed by electron microscopy, Western blotting and particle and RNA analysis. We compared miRNA expression based on PCa status (Gleason Score) and progression (post-prostatectomy follow-up) and confirmed selected miRNAs by quantitative PCR. Expression of target mRNAs was mapped in matched EV. Results: Quality control showed typical small uEV, pEV, RNA and EV-protein marker enriched samples. Comparisons between PCa groups revealed mostly unique differentially expressed miRNAs. However, they targeted comprehensive and largely overlapping sets of cancer and progression-associated signalling, resistance, hormonal and immune pathways. Quantitative PCR confirmed changes in miR-892a (Gleason Score 7 vs. ≥8), miR-223-3p (progression vs. no progression) and miR-146a-5p (both comparisons). Their target mRNAs were expressed widely in PCa EV. Conclusions: PCa status and progression-linked RNAs in uEV are worth exploration in large personalized medicine trials.

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Section: Discussionmentioning

confidence: 97%

Exploration of Extracellular Vesicle miRNAs, Targeted mRNAs and Pathways in Prostate Cancer: Relation to Disease Status and Progression

Puhka

Thierens

Nicorici

et al. 2022

Cancers

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“…In this study, EVs were first isolated from from human colorectal cancer cells (DiFi) by ANM (asymetrical nanoporous membrane). Then specific EVs with EGFR membrane proteins were isolated by the MNM to accurately quantify the miRNA content of specific EVs.Based on analysis of EGFR-containing DiFi EVs, isolated EVs were likely exosomes based on tetraspanin content 34 . Some of the EVs released by the DiFi cells exhibited inactive EGFR and active EGFR 34 .…”

Section: Isolation and Purification Of Egfr Evs From Difi Cell Linesmentioning

confidence: 99%

“…Then specific EVs with EGFR membrane proteins were isolated by the MNM to accurately quantify the miRNA content of specific EVs.Based on analysis of EGFR-containing DiFi EVs, isolated EVs were likely exosomes based on tetraspanin content 34 . Some of the EVs released by the DiFi cells exhibited inactive EGFR and active EGFR 34 . We utilized a total EGFR antibody that captures both active and inactive EGFR in this experiment.…”

Section: Isolation and Purification Of Egfr Evs From Difi Cell Linesmentioning

confidence: 99%

Electrodeposited Magnetic Nanoporous Membrane (MNM) with a Multi-Edge Superparamagnetic Heterogeneous Wedge Junction for High-Yield and High-Throughput Immunocapture of Specific Extracellular Vesicles and Lipoproteins

Zhang

Huo

Zhu

et al. 2022

Preprint

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Superparamagnetic nanobeads offer several advantages over microbeads for immunocapture of specifc molecular nanocarriers (extracellular vesicles, lipoproteins, and viruses) in a bioassay: high-yield capture, reduction in incuba-tion time and higher capture capacity. However, nanobeads are difficult to “pull down” because their superparamag-netic feature requires high nanoscale magnetic field gradients in addition to high magnetic fields. Here, electroplated track-etched membrane is shown to produce a unique superparamagnetic nanowedge ring with multiple edges around each nanopore. With a uniform external magnetic field, the induced monopole and dipole of this nanowedge junction combine to produce a 10x higher nanobead trapping force. A dense nanobead suspension can be filtered through the magnetic nanoporous membrane (MNM) at a high-throughput with 99% bead capture rate. The capture yield of specific nanocarriers in heterogeneous media (filtered plasma and conditioned cell media) by nanobeads/MNM ex-ceeds 80%. Quantification of RNA cargo in captured extracellular vesicles demonstrate 60x increase in capture rate of a specific microRNA relative to magnetic bead columns. Reproducibility, low loss, and concentration-independent capture rates are also demonstrated. This new MNM material hence significantly expands the application of nano-bead immunocapture to heterogeneous physiological samples, such as blood and saliva, whose molecular analytes are cargoes of nanocarriers.

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“…The term “extracellular vesicles” refers to particles naturally released from the cell that do not contain a functional nucleus, i.e., they cannot replicate themselves ( Johnstone, 2005 ). Extracellular vesicles (EVs) are released by most cell types and can be classified into different subtypes, including large and small extracellular vesicles (respectively, lEVs and sEVs), exomeres, supermeres, oncosomes, and apoptotic bodies ( El Andaloussi et al, 2013 ; Brites, 2020 ; Zhang et al, 2021 ). These EVs are different in size, density, biochemical and biophysical properties, as well as in secretion pathways, which may depend on the donor cells that produce them ( Figure 1 ).…”

Section: Introductionmentioning

confidence: 99%

“…Nucleic acids and lipids are also reported as part of exomeres’ cargo. Lately, supermeres, nanoparticles smaller than sEVs and exomeres, and morphologically distinct from exomeres, were described to be easily ingested and enriched with cargo involved in several cancers, as well as Alzheimer’s and cardiovascular diseases ( Zhang et al, 2021 ). They are enriched in proteins and miRNAs, as well as miRNA-processing proteins such as Argonaute RISC Catalytic Component 2 (AGO2), and are functional agents of intercellular communication, also constituting candidate biomarkers and therapeutic targets ( Clancy et al, 2021 ).…”

Section: Introductionmentioning

confidence: 99%

Challenges in the Development of Drug Delivery Systems Based on Small Extracellular Vesicles for Therapy of Brain Diseases

et al. 2022

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Small extracellular vesicles (sEVs) have ∼30–200 nm diameter size and may act as carriers of different cargoes, depending on the cell of origin or on the physiological/pathological condition. As endogenous nanovesicles, sEVs are important in intercellular communication and have many of the desirable features of an ideal drug delivery system. sEVs are naturally biocompatible, with superior targeting capability, safety profile, nanometric size, and can be loaded with both lipophilic and hydrophilic agents. Because of their biochemical and physical properties, sEVs are considered a promising strategy over other delivery vehicles in the central nervous system (CNS) since they freely cross the blood-brain barrier and they can be directed to specific nerve cells, potentiating a more precise targeting of their cargo. In addition, sEVs remain stable in the peripheral circulation, making them attractive nanocarrier systems to promote neuroregeneration. This review focuses on the recent progress in methods for manufacturing, isolating, and engineering sEVs that can be used as a therapeutic strategy to overcome neurodegeneration associated with pathologies of the CNS, with particular emphasis on Alzheimer’s, Parkinson’s, and amyotrophic lateral sclerosis diseases, as well as on brain tumors.

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Supermeres are functional extracellular nanoparticles replete with disease biomarkers and therapeutic targets

Cited by 201 publications

References 61 publications

Exploration of Extracellular Vesicle miRNAs, Targeted mRNAs and Pathways in Prostate Cancer: Relation to Disease Status and Progression

Exploration of Extracellular Vesicle miRNAs, Targeted mRNAs and Pathways in Prostate Cancer: Relation to Disease Status and Progression

Electrodeposited Magnetic Nanoporous Membrane (MNM) with a Multi-Edge Superparamagnetic Heterogeneous Wedge Junction for High-Yield and High-Throughput Immunocapture of Specific Extracellular Vesicles and Lipoproteins

Challenges in the Development of Drug Delivery Systems Based on Small Extracellular Vesicles for Therapy of Brain Diseases

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