Long-lived lung megakaryocytes contribute to platelet recovery in thrombocytopenia models
Alison C. Livada, … , James Palis, Craig N. Morrell
Alison C. Livada, … , James Palis, Craig N. Morrell
Published September 20, 2024
Citation Information: J Clin Invest. 2024;134(22):e181111. https://doi.org/10.1172/JCI181111.
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Research Article Hematology

Long-lived lung megakaryocytes contribute to platelet recovery in thrombocytopenia models

Abstract

Lung megakaryocytes (Mks) are largely extravascular with an immune phenotype (1). Because bone marrow (BM) Mks are short lived, it has been assumed that extravascular lung Mks are constantly “seeded” from the BM. To investigate lung Mk origins and how origin affects their functions, we developed methods to specifically label lung Mks using CFSE dye and biotin delivered via the oropharyngeal route. Labeled lung Mks were present for up to 4 months, while BM Mks had a lifespan of less than 1 week. In a parabiosis model, lung Mks were partially replaced over 1 month from a circulating source. Unlike tissue-resident macrophages, using MDS1-Cre-ERT2 TdTomato mice, we found that lung Mks arose from hematopoietic stem cells. However, studies with FlkSwitch mTmG mice showed that lung Mks were derived from a Flt3-independent lineage that did not go through a multipotent progenitor. CFSE labeling to track lung Mk–derived platelets showed that approximately 10% of circulating platelets were derived from lung-resident Mks at steady state, but in sterile thrombocytopenia this was doubled (~20%). Lung-derived platelets were similarly increased in a malaria infection model (Plasmodium yoelii) typified by thrombocytopenia. These studies indicate that lung Mks arise from a Flt3– BM source, are long-lived, and contribute more platelets during thrombocytopenia.

Authors

Alison C. Livada, Kathleen E. McGrath, Michael W. Malloy, Chen Li, Sara K. Ture, Paul D. Kingsley, Anne D. Koniski, Leah A. Vit, Katherine E. Nolan, Deanne Mickelsen, Grace E. Monette, Preeti Maurya, James Palis, Craig N. Morrell

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Figure 6

Mks migrate to the lung to respond to increased platelet demand.

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Mks migrate to the lung to respond to increased platelet demand. (A) Mic...
(A) Mice were given CFSE o.p. and infected with PYnL, and on day 14, total Mks and CFSE+ and CFSE intravascular (CD42d i.v. -positive) and extravascular (CD42d i.v. –negative) Mks were quantified. The increase in total intravascular Mks was driven by CFSE extrapulmonary Mks. On day 14, there was a decrease in CFSE+ extra- and intravascular Mks (n = 5 per group, representative shown from 2 independent experiments). (B and C) With PYnL infection, there was an increase in higher ploidy CFSE+ Mks in (B) BM and spleen as well as in (C) lung, including CFSE+ Mks (n = 5 per group, representative shown from 2 independent experiments). (D) FlkSwitch mice infected with PYnL had no significant change in Tomato+Flt3 platelets on day 14 after infection, but (E) the percentage of lung Mks that were Tomato+Flt3 slightly declined and that of GFP+Flt3+ Mks increased slightly compared with uninfected controls. There was no change in MkPs, indicating an influx of mature Mks from the BM that was largely Tomato+Flt3 (n = 6–8 per group from 2 independent experiments). Data indicate the mean ± SEM. *P < 0.05, **P < 0.01, and ***P < 0.001, by unpaired, 2-tailed t test (A, D, and E) and multiple t tests with Holm-Šidák correction (B and C).