CCL5 Derived from Platelets Increases Megakaryocyte Proplatelet Formation

Overview

Journal Blood

Publisher Elsevier

Specialty Hematology

Date 2015 Dec 10

PMID 26647394

Citations 52

Authors

Kellie R Machlus

Kelly E Johnson

Rajesh Kulenthirarajan

Jodi A Forward

Mason D Tippy

Thomas S Soussou

Saleh H El-Husayni

Stephen K Wu

Suming Wang

Randolph S Watnick

Joseph E Italiano Jr

Elisabeth M Battinelli

Affiliations

Soon will be listed here.

Abstract

In times of physiological stress, platelet count can transiently rise. What initiates this reactive thrombocytosis is poorly understood. Intriguingly, we found that treating megakaryocytes (MKs) with the releasate from activated platelets increased proplatelet production by 47%. Platelets store inflammatory cytokines, including the chemokine ligand 5 (CCL5, RANTES); after TRAP activation, platelets release over 25 ng/mL CCL5. We hypothesized that CCL5 could regulate platelet production by binding to its receptor, CCR5, on MKs. Maraviroc (CCR5 antagonist) or CCL5 immunodepletion diminished 95% and 70% of the effect of platelet releasate, respectively, suggesting CCL5 derived from platelets is sufficient to drive increased platelet production through MK CCR5. MKs cultured with recombinant CCL5 increased proplatelet production by 50% and had significantly higher ploidy. Pretreating the MK cultures with maraviroc prior to exposure to CCL5 reversed the augmented proplatelet formation and ploidy, suggesting that CCL5 increases MK ploidy and proplatelet formation in a CCR5-dependent manner. Interrogation of the Akt signaling pathway suggested that CCL5/CCR5 may influence proplatelet production by suppressing apoptosis. In an in vivo murine acute colitis model, platelet count significantly correlated with inflammation whereas maraviroc treatment abolished this correlation. We propose that CCL5 signaling through CCR5 may increase platelet counts during physiological stress.

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