Non-muscle myosin II drives vesicle loss during human reticulocyte maturation

Moura, Pedro L.; Hawley, Bethan R.; Mankelow, Tosti J.; Griffiths, Rebecca E.; Dobbe, Johannes G. G.; Streekstra, Geert J.; Anstee, David J.; Satchwell, Timothy J.; Toye, Ashley M.

doi:10.3324/haematol.2018.199083

Cited by 32 publications

(33 citation statements)

References 50 publications

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“…Upregulation of myosin levels may account for these phenomenally paradoxical findings. As a probable result of different reticulocyte maturation in beta thalassemia [ 21 ], it has been considered a cellular volume regulator in the microcytic βThal + RBCs [ 22 ]. βThal + membrane enrichment in several non-muscle myosin proteoforms might contribute to structural integrity, deformability, and resistance to stress [ 23 ], including storage-induced stress, since the expression of structural proteins did not reduce with storage time, as opposed to control RBCs.…”

Section: Discussionmentioning

confidence: 99%

Proteome of Stored RBC Membrane and Vesicles from Heterozygous Beta Thalassemia Donors

Tzounakas

Anastasiadi

Dzieciątkowska

et al. 2021

IJMS

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Genetic characteristics of blood donors may impact the storability of blood products. Despite higher basal stress, red blood cells (RBCs) from eligible donors that are heterozygous for beta-thalassemia traits (βThal+) possess a differential nitrogen-related metabolism, and cope better with storage stress compared to the control. Nevertheless, not much is known about how storage impacts the proteome of membrane and extracellular vesicles (EVs) in βThal+. For this purpose, RBC units from twelve βThal+ donors were studied through proteomics, immunoblotting, electron microscopy, and functional ELISA assays, versus units from sex- and aged-matched controls. βThal+ RBCs exhibited less irreversible shape modifications. Their membrane proteome was characterized by different levels of structural, lipid raft, transport, chaperoning, redox, and enzyme components. The most prominent findings include the upregulation of myosin proteoforms, arginase-1, heat shock proteins, and protein kinases, but the downregulation of nitrogen-related transporters. The unique membrane proteome was also mirrored, in part, to that of βThal+ EVs. Network analysis revealed interesting connections of membrane vesiculation with storage and stress hemolysis, along with proteome control modulators of the RBC membrane. Our findings, which are in line with the mild but consistent oxidative stress these cells experience in vivo, provide insight into the physiology and aging of stored βThal+ RBCs.

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Section: Discussionmentioning

confidence: 99%

Proteome of Stored RBC Membrane and Vesicles from Heterozygous Beta Thalassemia Donors

Tzounakas

Anastasiadi

Dzieciątkowska

et al. 2021

IJMS

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“…Cytoskeleton reorganization is primordial for erythroid differentiation, prompting major morphological changes such as cell shrinking and nuclear extrusion. During reticulocyte maturation, myosin‐II‐mediated cytoskeleton reorganization leads to a 20% loss of membrane and a decreased cell volume required to obtain a mature and functional red blood cell 47,48 . Additionally, it has recently been described that red blood cells' curvature is maintained through the contractility of myosin‐II 49 .…”

Section: Discussionmentioning

confidence: 99%

Myotonic dystrophy kinase‐related CDC42‐binding kinase α, a new transferrin receptor type 2‐binding partner, is a regulator of erythropoiesis

et al. 2021

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Efficient erythropoiesis relies on the expression of the transferrin receptor type 2 (TFR2). In erythroid precursors, TFR2 facilitates the export of the erythropoietin receptor (EPOR) to cell surface, which ensures the survival and proliferation of erythroblasts. Although TFR2 has a crucial role in erythropoiesis regulation, its mechanism of action remains to be clarified. To understand its role better, we aimed at identifying its protein partners by mass‐spectrometry after immunoprecipitation in erythroid cells. Here we report the kinase MRCKα (myotonic dystrophy kinase‐related CDC42‐binding kinase α) as a new partner of both TFR2 and EPOR in erythroblasts. We show that MRCKα is co‐expressed with TFR2, and TFR1 during terminal differentiation and regulates the internalization of the two types of transferrin receptors. The knockdown of MRCKα by shRNA in human primary erythroblasts leads to a decreased cell surface expression of both TFR1 and TFR2, an increased cell‐surface expression of EPOR, and a delayed differentiation. Additionally, knockout of Mrckα in the murine MEDEP cells also leads to a striking delay in erythropoiesis, showcasing the importance of this kinase in both species. Our data highlight the importance of MRCKα in the regulation of erythropoiesis.

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“…MYH9 ‐RD may affect low numbers of RBCs because changes in NMIIA contractility may have different effects on RBC membrane properties at different stages in RBC lifetimes. Previous studies suggest a role for NMII in erythroblast cell division prior to enucleation and in reticulocyte maturation . Future studies using mouse models of MYH9 ‐RD could test whether MYH9 ‐RD affects erythroblast terminal differentiation.…”

Section: Discussionmentioning

confidence: 96%

MYH9‐related disease mutations cause abnormal red blood cell morphology through increased myosin‐actin binding at the membrane

et al. 2019

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MYH9‐related disease (MYH9‐RD) is a rare, autosomal dominant disorder caused by mutations in MYH9, the gene encoding the actin‐activated motor protein non‐muscle myosin IIA (NMIIA). MYH9‐RD patients suffer from bleeding syndromes, progressive kidney disease, deafness, and/or cataracts, but the impact of MYH9 mutations on other NMIIA‐expressing tissues remains unknown. In human red blood cells (RBCs), NMIIA assembles into bipolar filaments and binds to actin filaments (F‐actin) in the spectrin‐F‐actin membrane skeleton to control RBC biconcave disk shape and deformability. Here, we tested the effects of MYH9 mutations in different NMIIA domains (motor, coiled‐coil rod, or non‐helical tail) on RBC NMIIA function. We found that MYH9‐RD does not cause clinically significant anemia and that patient RBCs have normal osmotic deformability as well as normal membrane skeleton composition and micron‐scale distribution. However, analysis of complete blood count data and peripheral blood smears revealed reduced hemoglobin content and elongated shapes, respectively, of MYH9‐RD RBCs. Patients with mutations in the NMIIA motor domain had the highest numbers of elongated RBCs. Patients with mutations in the motor domain also had elevated association of NMIIA with F‐actin at the RBC membrane. Our findings support a central role for motor domain activity in NMIIA regulation of RBC shape and define a new sub‐clinical phenotype of MYH9‐RD.

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Non-muscle myosin II drives vesicle loss during human reticulocyte maturation

Cited by 32 publications

References 50 publications

Proteome of Stored RBC Membrane and Vesicles from Heterozygous Beta Thalassemia Donors

Proteome of Stored RBC Membrane and Vesicles from Heterozygous Beta Thalassemia Donors

Myotonic dystrophy kinase‐related CDC42‐binding kinase α, a new transferrin receptor type 2‐binding partner, is a regulator of erythropoiesis

MYH9‐related disease mutations cause abnormal red blood cell morphology through increased myosin‐actin binding at the membrane

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