Megakaryocytes assemble podosomes that degrade matrix and protrude through basement membrane

Schachtner, Hannah; Calaminus, Simon D. J.; Sinclair, Amy; Monypenny, James; Blundell, Michael P.; Léon, Catherine; Holyoake, Tessa L.; Thrasher, Adrian J.; Michie, Alison M.; Vukovic, Milica; Gachet, Christian; Jones, Gareth E.; Thomas, Steven G.; Watson, Steve P.; Machesky, Laura M.

doi:10.1182/blood-2012-07-443457

Cited by 93 publications

(144 citation statements)

References 49 publications

(76 reference statements)

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“…In MKs, the Arp2/3 complex has previously been shown to play a role in both DMS formation and podosome formation. 49,50 However, to our knowledge, the direct role of Arp2/3 phosphorylation in proplatelet formation has not been studied. Interestingly, podosome formation by MKs has recently been proposed as a mechanism by which MKs degrade matrix and, in turn, cross basement membranes and release proplatelets into the bloodstream.…”

Section: Discussionmentioning

confidence: 99%

Synthesis and dephosphorylation of MARCKS in the late stages of megakaryocyte maturation drive proplatelet formation

Machlus

Stumpo

et al. 2016

Blood

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Key Points• Proteomic analyses and polysome profiling of developing MKs identified a striking increase in the levels of a novel protein, MARCKS, during proplatelet formation.• MARCKS deletion, inhibition, or phosphorylation inhibits proplatelet formation associated with activation of the actin-binding protein Arp2/3.Platelets are essential for hemostasis, and thrombocytopenia is a major clinical problem. Megakaryocytes (MKs) generate platelets by extending long processes, proplatelets, into sinusoidal blood vessels. However, very little is known about what regulates proplatelet formation. To uncover which proteins were dynamically changing during this process, we compared the proteome and transcriptome of round vs proplatelet-producing MKs by 2D difference gel electrophoresis (DIGE) and polysome profiling, respectively. Our data revealed a significant increase in a poorly-characterized MK protein, myristoylated alanine-rich C-kinase substrate (MARCKS), which was upregulated 3.4-and 5.7-fold in proplatelet-producing MKs in 2D DIGE and polysome profiling analyses, respectively. MARCKS is a protein kinase C (PKC) substrate that binds PIP 2 . In MKs, it localized to both the plasma and demarcation membranes. MARCKS inhibition by peptide significantly decreased proplatelet formation 53%. To examine the role of MARCKS in the PKC pathway, we treated MKs with polymethacrylate (PMA), which markedly increased MARCKS phosphorylation while significantly inhibiting proplatelet formation 84%, suggesting that MARCKS phosphorylation reduces proplatelet formation. We hypothesized that MARCKS phosphorylation promotes Arp2/3 phosphorylation, which subsequently downregulates proplatelet formation; both MARCKS and Arp2 were dephosphorylated in MKs making proplatelets, and Arp2 inhibition enhanced proplatelet formation. Finally, we used MARCKS knockout (KO) mice to probe the direct role of MARCKS in proplatelet formation; MARCKS KO MKs displayed significantly decreased proplatelet levels. MARCKS expression and signaling in primary MKs is a novel finding. We propose that MARCKS acts as a "molecular switch," binding to and regulating PIP 2 signaling to regulate processes like proplatelet extension (microtubule-driven) vs proplatelet branching (Arp2/3 and actin polymerization-driven).

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Section: Discussionmentioning

confidence: 99%

Synthesis and dephosphorylation of MARCKS in the late stages of megakaryocyte maturation drive proplatelet formation

Machlus

Stumpo

et al. 2016

Blood

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“…1D). These linear invadosomes are formed along type I collagen fibrils and are found in both normal and transformed cells (Di Martino et al, 2015;Juin et al, 2012;Juin et al, 2014;Schachtner et al, 2013). Linear invadosomes present markers that are common to all invadosomes, such as the actin-binding proteins N-WASP and cortactin (Artym et al, 2006), the scaffold protein tyrosine kinase substrate 5 (Tks5, also known as SH3PXD2A) (Blouw et al, 2015) and the Rho GTPase Cdc42 (Di .…”

Section: Induction Of Invadosome Formationmentioning

confidence: 99%

“…For instance, a recent study has demonstrated that cells from the metastatic breast cancer line MDA-MB 231 preferentially form integrin-dependent actin dots on a high density of fibrillar collagen, which corresponds to compressed and fixed collagen I (Artym et al, 2015). Several other studies have demonstrated that cells preferentially form linear actin structures on fibrillar collagen I (Monteiro et al, 2013;Schachtner et al, 2013). Based on these findings, we propose that the resulting invadosome architecture might depend less on the particular cell type than on the experimental setting used for their observation.…”

Section: Invadosome Plasticitymentioning

confidence: 99%

The microenvironment controls invadosome plasticity

Martino

Henriet

Ezzoukhry

et al. 2016

Journal of Cell Science

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Invadosomes are actin-based structures involved in extracellular matrix degradation. Invadosomes is a term that includes podosomes and invadopodia, which decorate normal and tumour cells, respectively. They are mainly organised into dots or rosettes, and podosomes and invadopodia are often compared and contrasted. Various internal or external stimuli have been shown to induce their formation and/or activity. In this Commentary, we address the impact of the microenvironment and the role of matrix receptors on the formation, and dynamic and degradative activities of invadosomes. In particular, we highlight recent findings regarding the role of type I collagen fibrils in inducing the formation of a new linear organisation of invadosomes. We will also discuss invadosome plasticity more generally and emphasise its physio-pathological relevance.

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“…Stage V and VI account for cells displaying proplatelet extensions. In stage V, during the initial stages of proplatelet extension the MK starts to spread and its cytoplasm unravels into cytoplasmic extensions, called podosomes [23]. As the cytoplasmic erosion continues, the extensions elongate and are remodeled into thinner strands with a pearl-on-a-string morphology, which will eventually shed into platelets [24].…”

Section: In Vitro Label Free Evaluation Of Megakaryocytic Developmentmentioning

confidence: 99%

Label free monitoring of megakaryocytic development and proplatelet formation in vitro

Pouli

Tozzi

Alonzo

et al. 2017

Biomed. Opt. Express

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Megakaryopoiesis and platelet production are complex biological processes that require tight regulation of successive lineage commitment steps and are ultimately responsible for maintaining and renewing the pool of circulating platelets in the blood. Despite major advancements in the understanding of megakaryocytic biology, the detailed mechanisms driving megakaryocytic differentiation have yet to be elucidated. Here we show that automated image analysis algorithms applied to two-photon excited fluorescence (TPEF) images can non-invasively monitor structural and metabolic megakaryocyte behavior changes occurring during differentiation and platelet formation in vitro. Our results demonstrate that high-contrast, label-free two photon imaging holds great potential in studying the underlying physiological processes controlling the intricate process of platelet production. Münger, and I. Georgakoudi, "Endogenous two-photon fluorescence imaging elucidates metabolic changes related to enhanced glycolysis and glutamine consumption in precancerous epithelial tissues," Cancer Res.

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Megakaryocytes assemble podosomes that degrade matrix and protrude through basement membrane

Cited by 93 publications

References 49 publications

Synthesis and dephosphorylation of MARCKS in the late stages of megakaryocyte maturation drive proplatelet formation

Synthesis and dephosphorylation of MARCKS in the late stages of megakaryocyte maturation drive proplatelet formation

The microenvironment controls invadosome plasticity

Label free monitoring of megakaryocytic development and proplatelet formation in vitro

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