Rasa3 deficiency minimally affects thrombopoiesis but promotes severe thrombocytopenia due to integrin-dependent platelet clearance
Robert H. Lee, … , Anita Eckly, Wolfgang Bergmeier
Robert H. Lee, … , Anita Eckly, Wolfgang Bergmeier
Published March 15, 2022
Citation Information: JCI Insight. 2022;7(8):e155676. https://doi.org/10.1172/jci.insight.155676.
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Research Article Cell biology Hematology

Rasa3 deficiency minimally affects thrombopoiesis but promotes severe thrombocytopenia due to integrin-dependent platelet clearance

Abstract

Platelet homeostasis is dependent on a tight regulation of both platelet production and clearance. The small GTPase Rap1 mediates platelet adhesion and hemostatic plug formation. However, Rap1 signaling is also critical for platelet homeostasis as both Rap1 deficiency and uninhibited Rap1 signaling lead to marked thrombocytopenia in mice. Here, we investigated the mechanism by which deficiency in Rasa3, a critical negative regulator of Rap1, causes macrothrombocytopenia in mice. Despite marked morphological and ultrastructural abnormalities, megakaryocytes in hypomorphic Rasa3hlb/hlb (R3hlb/hlb) or Rasa3–/– mice demonstrated robust proplatelet formation in vivo, suggesting that defective thrombopoiesis is not the main cause of thrombocytopenia. Rather, we observed that R3hlb/hlb platelets became trapped in the spleen marginal zone/red pulp interface, with evidence of platelet phagocytosis by macrophages. Clearance of mutant platelets was also observed in the liver, especially in splenectomized mice. Platelet count and platelet life span in Rasa3-mutant mice were restored by genetic or pharmacological approaches to inhibit the Rap1/talin1/αIIbβ3 integrin axis. A similar pattern of splenic clearance was observed in mice injected with anti-αIIbβ3 but not anti–glycoprotein Ibα platelet-depleting antibodies. In summary, we describe a potentially novel, integrin-based mechanism of platelet clearance that could be critical for our understanding of select inherited and acquired thrombocytopenias.

Authors

Robert H. Lee, Dorsaf Ghalloussi, Gabriel L. Harousseau, Joseph P. Kenny, Patrick A. Kramer, Fabienne Proamer, Bernhard Nieswandt, Matthew J. Flick, Christian Gachet, Caterina Casari, Anita Eckly, Wolfgang Bergmeier

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Figure 1

R3hlb/hlb MKs show abnormal morphology and ultrastructure in situ.

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R3hlb/hlb MKs show abnormal morphology and ultrastructure in situ. (A) ...
(A) BM cryosections from control (R3+/+) and R3hlb/hlb mice were immunostained for MKs/platelets with anti–GPIX-AF488 (green), sinusoids with anti–CD105-AF647 (red), and nuclei with Hoechst (blue), and imaged by confocal microscopy. Boxes indicate localization of enlarged images (original magnification, ×200) shown in the middle panel. Scale bars: 10 μm. (B) Quantification of MKs in direct contact with sinusoids in the BM of R3+/+ and R3hlb/hlb mice (n = 26–30 fields from a total of 5 mice per group). (C) Representative transmission electron microscopy (TEM) images of R3hlb/hlb MKs forming protrusions (green outline) and forming clusters of multiple MKs (yellow outline). Scale bars: 5 μm (left), 10 μm (right). (D) Representative TEM images of MKs from R3+/+ (top panels) and R3hlb/hlb mice (bottom panels) showing structure of DMS and PZ; overview (left panels; scale bar: 10 μm) and detail (right panels; scale bar: 1–2 μm). (E) Maturation stage distribution (I–III; see Methods) of differentiated BM MKs (n = 5–6). Data shown as mean ± SEM. Statistical significance was determined using unpaired 2-tailed Student’s t test.