Mesenchymal stromal cells lower platelet activation and assist in platelet formation in vitro
Avital Mendelson, … , Xiuli An, Karina Yazdanbakhsh
Avital Mendelson, … , Xiuli An, Karina Yazdanbakhsh
Published August 22, 2019
Citation Information: JCI Insight. 2019;4(16):e126982. https://doi.org/10.1172/jci.insight.126982.
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Research Article Hematology Stem cells

Mesenchymal stromal cells lower platelet activation and assist in platelet formation in vitro

Abstract

The complex process of platelet formation originates with the hematopoietic stem cell, which differentiates through the myeloid lineage, matures, and releases proplatelets into the BM sinusoids. How formed platelets maintain a low basal activation state in the circulation remains unknown. We identify Lepr+ stromal cells lining the BM sinusoids as important contributors to sustaining low platelet activation. Ablation of murine Lepr+ cells led to a decreased number of platelets in the circulation with an increased activation state. We developed a potentially novel culture system for supporting platelet formation in vitro using a unique population of CD51+PDGFRα+ perivascular cells, derived from human umbilical cord tissue, which display numerous mesenchymal stem cell (MSC) properties. Megakaryocytes cocultured with MSCs had altered LAT and Rap1b gene expression, yielding platelets that are functional with low basal activation levels, a critical consideration for developing a transfusion product. Identification of a regulatory cell that maintains low baseline platelet activation during thrombopoiesis opens up new avenues for improving blood product production ex vivo.

Authors

Avital Mendelson, Ana Nicolle Strat, Weili Bao, Peter Rosston, Georgia Fallon, Sophie Ohrn, Hui Zhong, Cheryl Lobo, Xiuli An, Karina Yazdanbakhsh

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Figure 5

Functional platelet characterization, showing activation in response to ADP stimulation.

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Functional platelet characterization, showing activation in response to ...
(A–D) Flow cytometry plots of PAC-1 expression in (A) unstimulated platelets from the control group and (B) unstimulated platelets from the cMSC group compared with (C) stimulated platelets from the control group and (D) stimulated platelets from the cMSC coculture group. (E) Quantification of the fold change in PAC-1 expression among the various groups (n = 3). A quantitative flow cytometry assay was performed, measuring the ability of platelets from the cMSC coculture group to adhere to matrix proteins bound to beads. (F) Platelets stimulated with ADP were able to bind efficiently to matrix-coated beads (n = 3–4). (G) Bound stimulated platelets were activated and expressed CD62P to a greater extent than unstimulated bound platelets (n = 3–4). (H) Fold change of stimulated CD62P+ platelets bound to matrix-coated beads relative to unstimulated platelets (n = 3–4). *P ≤ 0.05; **P ≤ 0.01; ****P ≤ 0.0001. E was analyzed by 1-way ANOVA with Tukey post hoc test. F–H was analyzed by 2-tailed t tests.