RESUMEN
Blood platelets are produced by megakaryocytes (MKs), their parent cells, which are in the bone marrow. Once mature, MK pierces through the sinusoid vessel, and the initial protrusion further elongates as proplatelet or buds to release platelets. The mechanisms controlling the decision to initiate proplatelet and platelet formation are unknown. Here, we show that the mechanical properties of the microenvironment prevent proplatelet and platelet release in the marrow stroma while allowing this process in the bloodstream. Loss of marrow confinement following myelosuppression led to inappropriate proplatelet and platelet release into the extravascular space. We further used an inert viscoelastic hydrogel to evaluate the impact of compressive stress. Transcriptional analysis showed that culture in three-dimensional gel induced upregulation of genes related to the Rho-GTPase pathway. We found higher Rho-GTPase activation, myosin light chain phosphorylation and F-actin under mechanical constraints while proplatelet formation was inhibited. The use of latrunculin-A to decrease F-actin promoted microtubule-dependent budding and proplatelet extension inside the gel. Additionally, ex vivo exposure of intact bone marrow to latrunculin-A triggered proplatelet extensions in the interstitial space. In vivo, this confinement-mediated high intracellular tension is responsible for the formation of the peripheral zone, a unique actin-rich structure. Cytoskeleton reorganization induces the disappearance of the peripheral zone upon reaching a liquid milieu to facilitate proplatelet and platelet formation. Hence, our data provide insight into the mechanisms preventing ectopic platelet release in the marrow stroma. Identifying such pathways is especially important for understanding pathologies altering marrow mechanics such as chemotherapy or myelofibrosis.
Asunto(s)
Plaquetas , Megacariocitos , Plaquetas/metabolismo , Plaquetas/efectos de los fármacos , Megacariocitos/metabolismo , Megacariocitos/efectos de los fármacos , Megacariocitos/citología , Animales , Ratones , Actinas/metabolismo , Proteínas de Unión al GTP rho/metabolismo , Cadenas Ligeras de Miosina/metabolismo , Ratones Endogámicos C57BL , Compuestos Bicíclicos Heterocíclicos con Puentes , TiazolidinasRESUMEN
Megakaryocytes (MKs) are the precursor cells of platelets, located in the bone marrow (BM). Once mature, they extend elongated projections named proplatelets through sinusoid vessels, emerging from the marrow stroma into the circulating blood. Not all signals from the microenvironment that regulate proplatelet formation are understood, particularly those from the BM biomechanics. We sought to investigate how MKs perceive and adapt to modifications of the stiffness of their environment. Although the BM is one of the softest tissue of the body, its rigidification results from excess fibronectin (FN), and other matrix protein deposition occur upon myelofibrosis. Here, we have shown that mouse MKs are able to detect the stiffness of a FN-coated substrate and adapt their morphology accordingly. Using a polydimethylsiloxane substrate with stiffness varying from physiological to pathological marrow, we found that a stiff matrix favors spreading, intracellular contractility, and FN fibrils assembly at the expense of proplatelet formation. Itgb3, but not Itgb1, is required for stiffness sensing, whereas both integrins are involved in fibrils assembly. In contrast, soft substrates promote proplatelet formation in an Itgb3-dependent manner, consistent with the ex vivo decrease in proplatelet formation and the in vivo decrease in platelet number in Itgb3-deficient mice. Our findings demonstrate the importance of environmental stiffness for MK functions with potential pathophysiological implications during pathologies that deregulate FN deposition and modulate stiffness in the marrow.
Asunto(s)
Fibronectinas , Megacariocitos , Animales , Ratones , Plaquetas/metabolismo , Médula Ósea , Fibronectinas/metabolismo , Megacariocitos/metabolismo , Recuento de PlaquetasRESUMEN
Alloimmunization against platelets remains a potentially serious adverse transfusion event. Alloantibodies produced by the recipient, mainly directed against human leukocyte antigen class I donor antigens, can compromise the therapeutic efficacy of subsequent transfusions, and may lead to refractoriness. Because the mechanism of anti-HLA alloantibody formation is poorly understood, this study aimed to identify the cells involved in the platelet immune response by focusing on the spleen, the main organ that orchestrates this alloimmune response. In the spleen, transfused allogeneic platelets are located in the marginal zone and interact with marginal zone B (MZB) cells, a specialized B-cell population implicated in the capture and follicular delivery of blood-borne antigens. To study the involvement of MZB cells in alloantibody production, we used a murine model reproducing major histocompatibility complex incompatibility between a donor (H2b) and recipient (H2d) that occurs during platelet transfusion. Following weekly H2b platelet transfusions, recipient H2d mice produced anti-H2b immunoglobulin G, which induced a refractory state upon subsequent transfusions. Specific immunodepletion of MZB cells or their displacement from the marginal zone to the B-cell follicles by treatment with an S1P1 antagonist before each transfusion prevented significant alloantibody formation. Under these conditions, transfused platelets were still circulating after 24 hours, whereas they were rapidly removed from circulation in alloimmunized mice. The identification of MZB cells as key players in the platelet alloimmune response opens up new perspectives for minimizing platelet alloimmunization and avoiding the associated refractory state in frequently transfused patients.