Clinical Prospect of Mesenchymal Stromal/Stem Cell-Derived Extracellular Vesicles in Kidney Disease: Challenges and the Way Forward
Abstract
:1. Introduction
2. Kidney Disease: Definition and Classification
3. Extracellular Vesicles—A New Paradigm Shift in the MSC Therapy
4. Demonstrable Renoprotective Effects of MSC-EVs in Preclinical Studies of Kidney Disease
EV Source | In Vivo Model | Type of Kidney Disease | Administration | Reference |
---|---|---|---|---|
BM-MSCs | Glycerol | AKI | Intravenous | [27] |
I/R | AKI | Intravenous | [54] | |
I/R | AKI | Intravenous | [55] | |
Cisplatin | AKI | Intravenous | [58] | |
Gentamicin | AKI | Intravenous | [59] | |
Glycerol | AKI | Intravenous | [60] | |
I/R | AKI | Intravenous | [56] | |
UUO | CKD | Intravenous | [61] | |
I/R | CKD | Intrarenal | [57] | |
AAN | CKD | Intravenous | [65] | |
UUO | CKD | Intravenous | [62] | |
UUO | CKD | Intravenous | [63] | |
STZ-DN | CKD | Intravenous | [66] | |
UUO | CKD | Intravenous | [64] | |
AD-MSCs | I/R | AKI | Intravenous | [67] |
Sepsis | AKI | Intravenous | [68] | |
MS+AS | CKD | Intrarenal | [69,70] | |
I/R | CKD | Intravenous | [71] | |
UUO | CKD | Intravenous | [72] | |
Glycerol | AKI | Intravenous | [73] | |
L-MSCs | STZ-DN | CKD | Intravenous | [66] |
AAN | CKD | Intravenous | [74] | |
K-MSCs | I/R | AKI | Intravenous | [75] |
I/R | AKI | Intravenous | [76] | |
UUO | CKD | Intravenous | [77] | |
UC-MSCs | Cisplatin | AKI | Kidney capsule | [78] |
I/R | AKI | Intravenous | [79] | |
I/R | AKI | Intravenous | [80] | |
I/R | AKI | Intravenous | [81] | |
I/R | AKI | Intravenous | [82] | |
I/R | AKI | Intravenous | [83] | |
I/R | AKI | Intravenous | [84] | |
Cisplatin | AKI | Kidney capsule | [85] | |
I/R | AKI | Intravenous | [86] | |
Sepsis | AKI | Intravenous | [87] | |
I/R | AKI | Intravenous | [88] | |
UUO | CKD | Intravenous | [89] | |
I/R | CKD | Intravenous | [86] | |
I/R | CKD | Intravenous | [79] | |
I/R | CKD | Intravenous | [84] | |
P-MSCs | I/R | AKI | Intrarenal | [90] |
I/R | AKI | Intrarenal | [91] |
5. Utilization of MSC-EVs in Clinical Trials
5.1. MSC-EVs in Clinical Trials of Kidney Disease
5.2. What Can We Learn from MSC´s Clinical Trials?
5.2.1. Characterization of Product for Clinical Trials
5.2.2. Dosing and Safety
5.2.3. Efficacy
5.2.4. Heterogeneity of MSC-Derived EVs
5.3. MSC-EVs—Proposed Mechanisms of Action
5.3.1. Proposed MSC-EV’s Mechanisms of Action in Kidney Diseases
MSCs Origin | MSCs Manipulation | MSCs Medium before EVs Isolation | EVs Isolation Method | Disease Model | Effects | Target Cells | Mechanisms (Molecule(s) or Signaling Pathways Identified) | Confirmation Method | Ref. No. |
---|---|---|---|---|---|---|---|---|---|
hUC | / | serum-free DMEM | UC | rat UUO model of RF | Amelioration of RF | / | EVs transfer CK1δ and E3 ubiquitin ligase β-TRCP promoting YAP ubiquitination and degradation | knockdown of CK1δ and β-TRCP in MSCs | [89] |
hAT | transfection of GDNF in MSCs | FCS-free RPMI supplemented with 0.5% BSA | UC | mouse UUO model of RF | Amelioration of RF and peritubular capillary loss | HUVEC cells | Sirtuin 1 (SIRT1) pathway | SIRT1 knockdown | [72] |
hUC | / | low glucose DMEM | UC | rat cisplatin-induced AKI | Improved renal function, morphology, and renal cell proliferation; decreased tubular apoptosis and oxidative stress | NRK-52E | p-p38 and caspase 3; PCNA and p-ERK | Inhibition of MEK1 and MEK2 with U0126 | [78] |
mBM | / | medium containing EVs-free serum | UC | mouse kidney IRI | Reduction of renal injury | / | CCR2 on MSC-exo binds to CCL2 lowering the recruitment of macrophages | CCR2 knockdown | [55] |
BM | / | FCS-deprived RPMI with 0.5% BSA | UC | glycerol- induced AKI in severe combined IDM | Morphologic and functional recovery in AKI | / | microRNAs | Depletion of Drosha to alter miRNA expression | [60] |
hBM | overexpression of miRNA-let7c | Alpha-MEM with EVs-free FBS | “ExoQuick” | mouse UUO model of RF | Attenuation of kidney injury | NRK-52E | miR-let7c attenuates TGF-β1-driven TGF-βR1 gene expression | Labeling pre-miRNA; inhibition of EVs released by GW4869 | [61] |
mBM | Erythropoietin treatment | RPMI with 10% FBS | UC or “PureExo exosome isolation kit” | mouse UUO model of RF | Decrease of tBM disruption | NRK-49F | miR-144 targets the tPA 3′-untranslated region and suppresses tPA and MMP9 level and activity | Depletion of miR-144 | [63] |
hBM | miR-199a-3p overexpression | DMEM/F12 with 10% EVs-free FBS | UC | hypoxia/reoxygenation (H/R) injury of HK-2 | Alleviation of IRI, functional recovery, and histologic protection; antiapoptotic effect | HK-2 | miR-199a-3p decrease Sema3A, activate protein kinase B (AKT) and extracellular-signal-regulated kinase (ERK) pathways | miR-199a-3p knockdown; Sema3A knockdown | [56] |
hUC | / | FBS-depleted DMEM with 0.5% BSA | UC | rat IRI | Amelioration of acute kidney IRI; reduction of cell apoptosis | rat RTECs | miR-30b/c/d inhibits mitochondrial fission through Dynamin-related protein 1 (DRP1) | miR-30 antagomirs | [81] |
hUC | / | DMEM with 10% EVs-depleted FBS | Sucrose /D2O cushion UC | sepsis— associated AKI | Alleviation of AKI and kidney tubular cells apoptosis; increased survival | HK-2 | miR-146b inhibits NF-κB activity and translocation of NFκB p-P65; decrease of IRAK1 | miR-146b mimics and inhibitors | [87] |
hUC | / | FBS-free mix of MSCM and DMEM/F12 | UC | murine IRI | Alleviation of ischemic AKI and decrease of renal tubular injury; attenuation of cell cycle arrest and apoptosis | HK-2 | Homing of EVs by VLA-4 and LFA-1; miR-125b-5p suppresses p53 in TECs leading to rescue G2/M arrest through up-regulation of CDK1 and Cyclin B1; apoptosis inhibition via Bcl-2 and Bax | miR-125b-5p Ox and inhibition; Ox of p53; transfection with siICAM-1 and siVCAM-1 | [88] |
hBM | / | FCS-free RPMI supplemented with 0.5% of BSA | UC | rat IRI model | Reduction of renal function impairment | / | RNA cargo | RNase treatment | [54] |
hUC | / | FBS-deprived DMEM, with 0.5% BSA | UC | rat model of unilateral AKI | Reversal of abnormal kidney structure and function; tubular cell dedifferentiation and growth; inhibition of apoptosis | tubular cells | Expression of HGF in tubar cells via its mRNA transfer; tubular cells media promote tubular cell dedifferentiation and migration via HGF/c-Met and Erk1/2 signaling pathways | RNase treatment; c-Met inhibitor or MEK inhibitor | [80] |
hUC | / | FBS-free medium | UC | rat IRI model of AKI; hypoxia injury of RTECs | Reduction of RF and cell apoptosis; increase of proliferation, renal function, and capillary vessel density | / | VEGF delivery to rat RTECs; RNA | Anti-human VEGF antibody; RNase treatment | [84] |
5.3.2. Mechanism of MSC-EVs Actions Related to Immunomodulation
5.3.3. Mechanism of MSC-EVs Actions Related to the Regeneration
5.4. Potency Testing
6. Perspectives of MSC-EV Use in the Treatment of Kidney Disease
Supplementary Materials
Author Contributions
Funding
Institutional Review Board Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Kosanović, M.; Milutinović, B.; Kutzner, T.J.; Mouloud, Y.; Bozic, M. Clinical Prospect of Mesenchymal Stromal/Stem Cell-Derived Extracellular Vesicles in Kidney Disease: Challenges and the Way Forward. Pharmaceutics 2023, 15, 1911. https://doi.org/10.3390/pharmaceutics15071911
Kosanović M, Milutinović B, Kutzner TJ, Mouloud Y, Bozic M. Clinical Prospect of Mesenchymal Stromal/Stem Cell-Derived Extracellular Vesicles in Kidney Disease: Challenges and the Way Forward. Pharmaceutics. 2023; 15(7):1911. https://doi.org/10.3390/pharmaceutics15071911
Chicago/Turabian StyleKosanović, Maja, Bojana Milutinović, Tanja J. Kutzner, Yanis Mouloud, and Milica Bozic. 2023. "Clinical Prospect of Mesenchymal Stromal/Stem Cell-Derived Extracellular Vesicles in Kidney Disease: Challenges and the Way Forward" Pharmaceutics 15, no. 7: 1911. https://doi.org/10.3390/pharmaceutics15071911
APA StyleKosanović, M., Milutinović, B., Kutzner, T. J., Mouloud, Y., & Bozic, M. (2023). Clinical Prospect of Mesenchymal Stromal/Stem Cell-Derived Extracellular Vesicles in Kidney Disease: Challenges and the Way Forward. Pharmaceutics, 15(7), 1911. https://doi.org/10.3390/pharmaceutics15071911