Megakaryocytes transfer mitochondria to bone marrow mesenchymal stromal cells to lower platelet activation
Chengjie Gao, … , Karina Yazdanbakhsh, Avital Mendelson
Chengjie Gao, … , Karina Yazdanbakhsh, Avital Mendelson
Published February 27, 2025
Citation Information: J Clin Invest. 2025;135(8):e189801. https://doi.org/10.1172/JCI189801.
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Research Article Hematology Article has an altmetric score of 11

Megakaryocytes transfer mitochondria to bone marrow mesenchymal stromal cells to lower platelet activation

Abstract

Newly produced platelets acquire a low activation state, but whether the megakaryocyte plays a role in this outcome has not been fully uncovered. Mesenchymal stem cells (MSCs) were previously shown to promote platelet production and lower platelet activation. We found that healthy megakaryocytes transfer mitochondria to MSCs, which is mediated by connexin 43 (Cx43) gap junctions on MSCs and leads to platelets at a low energetic state with increased LYN activation, characteristic of resting platelets with increased LYN activation, characteristic of resting platelets. On the contrary, MSCs have a limited ability to transfer mitochondria to megakaryocytes. Sickle cell disease (SCD) is characterized by hemolytic anemia and results in heightened platelet activation, contributing to numerous disease complications. Platelets in SCD mice and human samples had a heightened energetic state with increased glycolysis. MSC exposure to heme in SCD led to decreased Cx43 expression and a reduced ability to uptake mitochondria from megakaryocytes. This prevented LYN activation in platelets and contributed to increased platelet activation at steady state. Altogether, our findings demonstrate an effect of hemolysis in the microenvironment leading to increased platelet activation in SCD. These findings have the potential to inspire new therapeutic targets to relieve thrombosis-related complications of SCD and other hemolytic conditions.

Authors

Chengjie Gao, Yitian Dai, Paul A. Spezza, Paul Boasiako, Alice Tang, Giselle Rasquinha, Hui Zhong, Bojing Shao, Yunfeng Liu, Patricia A. Shi, Cheryl A. Lobo, Xiuli An, Anqi Guo, William B. Mitchell, Deepa Manwani, Karina Yazdanbakhsh, Avital Mendelson

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Figure 7

MSCs contribute to increased platelet activation in SCD.

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MSCs contribute to increased platelet activation in SCD. SA murine MKs w...
SA murine MKs were cultured together with MSCs from SS or SA mice. Platelets from cocultures were analyzed by flow cytometry for expression of (A) CD62P (n = 6) and (B) JonA (n = 6). SA or SS MSCs were analyzed by RT-PCR for expression of (C) Cx43 (encoded by Gja1) relative to Gapdh (n = 3). (D) Cx43 (encoded by Gja1) relative to Gapdh in 20 μM hemin-treated MSCs or vehicle control-treated MSCs (n = 3–4). PhAM-floxed;E2a-cre murine MKs were cultured together with hemin-treated MSCs or vehicle-treated MSCs. Following coculture, flow cytometry assessment of (E) mean fluorescence intensity (MFI) of PhAM signal in MSCs (n = 4–5). (F) Percentage of CD62P+ platelets from hemin-treated MSC MK cocultures normalized to the MK + MSC group (n = 4). C57BL/6 murine MKs cultured alone or together with vehicle-treated MSCs or hemin-treated MSCs. (G) Mitotracker green signal in MKs (n = 5) and (H) mitotracker green signal in platelets (n = 3-6). (I) Mitotracker green signal in peripheral blood platelets from patients with SCD or healthy donors (n = 7). (J) Flow cytometry analysis of P-LYN expression in murine platelets from cocultures of MKs only, MKs + MSCs, and MKs + hemin-pretreated MSCs (n = 4–5). *P ≤ 0.05, **P ≤ 0.01, ***P ≤ 0.001, ****P ≤ 0.0001. Data in AF and I were analyzed with 2-tailed, unpaired Student’s t test. Data in G, H, and J were analyzed by 1-way ANOVA with Tukey’s multiple comparison test. Data are presented as mean ± SEM.