Non-muscle Myosin II Drives Vesicle Loss During Human Reticulocyte Maturation

Overview

Journal Haematologica

Specialty Hematology

Date 2018 Aug 5

PMID 30076174

Citations 24

Authors

Pedro L Moura

Bethan R Hawley

Tosti J Mankelow

Rebecca E Griffiths

Johannes G G Dobbe

Geert J Streekstra

David J Anstee

Timothy J Satchwell

Ashley M Toye

Affiliations

Soon will be listed here.

Abstract

The process of maturation of reticulocytes into fully mature erythrocytes that occurs in the circulation is known to be characterized by a complex interplay between loss of cell surface area and volume, removal of remnant cell organelles and redundant proteins, and highly selective membrane and cytoskeletal remodeling. However, the mechanisms that underlie and drive these maturational processes are currently poorly understood and, at present, reticulocytes derived through culture fail to undergo the final transition to erythrocytes. Here, we used high-throughput proteomic methods to highlight differences between erythrocytes, cultured reticulocytes and endogenous reticulocytes. We identify a cytoskeletal protein, non-muscle myosin IIA (NMIIA) whose abundance and phosphorylation status differs between reticulocytes and erythrocytes and localized it in the proximity of autophagosomal vesicles. An circulation system was developed to simulate the mechanical shear component of circulation and demonstrated that mechanical stimulus is necessary, but insufficient for reticulocyte maturation. Using this system in concurrence with non-muscle myosin II inhibition, we demonstrate the involvement of non-muscle myosin IIA in reticulocyte remodeling and propose a previously undescribed mechanism of shear stress-responsive vesicle clearance that is crucial for reticulocyte maturation.

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