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Abstract

The development of culture processes for hematopoietic progenitors could lead to the development of a complementary source of platelets for therapeutic purposes. However, functional characterization of culture-derived platelets remains limited, which raises some uncertainties about the quality of platelets produced in vitro. The aim of this study was to define the proportion of functional platelets produced in cord blood CD34+ cell cultures. Toward this, the morphological and functional properties of culture-derived platelet-like particles (PLPs) were critically compared to that of blood platelets. Flow cytometry combined with transmission electron microscopy analyses revealed that PLPs formed a more heterogeneous population of platelets at a different stage of maturation than blood platelets. The majority of PLPs harbored the fibrinogen receptor αIIbβ3, but a significant proportion failed to maintain glycoprotein (GP)Ibα surface expression, a component of the vWF receptor essential for platelet functions. Importantly, GPIbα extracellular expression correlated closely with platelet function, as the GPIIb+ GPIbα+ PLP subfraction responded normally to agonist stimulation as evidenced by α-granule release, adhesion, spreading, and aggregation. In contrast, the GPIIb+ GPIbα− subfraction was unresponsive in most functional assays and appeared to be metabolically inactive. The present study confirms that functional platelets can be generated in cord blood CD34+ cell cultures, though these are highly susceptible to ectodomain shedding of receptors associated with loss of function. Optimization of culture conditions to prevent these deleterious effects and to homogenize PLPs is necessary to improve the quality and yields of culture-derived platelets before they can be recognized as a suitable complementary source for therapeutic purposes.

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References

Gandhi

MJ.

, Drachman

JG.

, Reems

JA.

, Thorning

, Lannutti

. 2005. A novel strategy for generating platelet-like fragments from megakaryocytic cell lines and human progenitor cells. Blood Cells Mol Dis, 35:70–73.

Fujimoto

TT.

, Kohata

, Suzuki

, Miyazaki

, Fujimura

. 2003. Production of functional platelets by differentiated embryonic stem (ES) cells in vitro. Blood, 102:4044–4051.

Nishikii

, Eto

, Tamura

, Hattori

, Heissig

, Kanaji

, Sawaguchi

, Goto

, Ware

, Nakauchi

. 2008. Metalloproteinase regulation improves in vitro generation of efficacious platelets from mouse embryonic stem cells. J Exp Med, 205:1917–1927.

Choi

ES.

, Nichol

JL.

, Hokom

MM.

, Hornkohl

AC.

, Hunt

. 1995. Platelets generated in vitro from proplatelet-displaying human megakaryocytes are functional. Blood, 85:402–413.

Ungerer

, Peluso

, Gillitzer

, Massberg

, Heinzmann

, Schulz

, Munch

, Gawaz

. 2004. Generation of functional culture-derived platelets from CD34+ progenitor cells to study transgenes in the platelet environment. Circ Res, 95:e36–e44.

Matsunaga

, Tanaka

, Kobune

, Kawano

, Tanaka

, Kuribayashi

, Iyama

, Sato

, Takimoto

, Takayama

, Kato

, Ninomiya

, Hamada

, Niitsu

. 2006. Ex vivo large-scale generation of human platelets from cord blood CD34+ cells. Stem Cells, 24:2877–2887.

Boyer

, Robert

, Proulx

, Pineault

. 2008. Increased production of megakaryocytes near purity from cord blood CD34+ cells using a short two-phase culture system. J Immunol Methods, 332:82–91.

Sullenbarger

, Bahng

JH.

, Gruner

, Kotov

, Lasky

. 2009. Prolonged continuous in vitro human platelet production using three-dimensional scaffolds. Exp Hematol, 37:101–110.

Proulx

, Dupuis

, St-Amour

, Boyer

, Lemieux

. 2004. Increased megakaryopoiesis in cultures of CD34-enriched cord blood cells maintained at 39 degrees C. Biotechnol Bioeng, 88:675–680.

10.

Reems

JA.

, Pineault

, Sun

. 2010. In vitro megakaryocyte production and platelet biogenesis: state of the art. Transfus Med Rev, 24:33–43.

11.

Bergmeier

, Piffath

CL.

, Goerge

, Cifuni

SM.

, Ruggeri

ZM.

, Ware

, Wagner

. 2006. The role of platelet adhesion receptor GPIbalpha far exceeds that of its main ligand, von Willebrand factor, in arterial thrombosis. Proc Natl Acad Sci USA, 103:16900–16905.

12.

Gardiner

EE.

, Arthur

JF.

, Kahn

ML.

, Berndt

MC.

, Andrews

. 2004. Regulation of platelet membrane levels of glycoprotein VI by a platelet-derived metalloproteinase. Blood, 104:3611–3617.

13.

Bergmeier

, Piffath

CL.

, Cheng

, Dole

VS.

, Zhang

, von Andrian

UH.

, Wagner

. 2004. Tumor necrosis factor-alpha-converting enzyme (ADAM17) mediates GPIbalpha shedding from platelets in vitro and in vivo. Circ Res, 95:677–683.

14.

Stephens

, Yan

, Jandrot-Perrus

, Villeval

JL.

, Clemetson

KJ.

, Phillips

. 2005. Platelet activation induces metalloproteinase-dependent GP VI cleavage to down-regulate platelet reactivity to collagen. Blood, 105:186–191.

15.

Rabie

, Strehl

, Ludwig

, Nieswandt

. 2005. Evidence for a role of ADAM17 (TACE) in the regulation of platelet glycoprotein V. J Biol Chem, 280:14462–14468.

16.

Proulx

, Boyer

, Hurnanen

DR.

, Lemieux

. 2003. Preferential ex vivo expansion of megakaryocytes from human cord blood CD34+-enriched cells in the presence of thrombopoietin and limiting amounts of stem cell factor and Flt-3 ligand. J Hematother Stem Cell Res, 12:179–188.

17.

Cortin

, Garnier

, Pineault

, Lemieux

, Boyer

, Proulx

. 2005. Efficient in vitro megakaryocyte maturation using cytokine cocktails optimized by statistical experimental design. Exp Hematol, 33:1182–1191.

18.

Pineault

, Boucher

JF.

, Cayer

MP.

, Palmqvist

, Boyer

, Lemieux

, Proulx

. 2008. Characterization of the effects and potential mechanisms leading to increased megakaryocytic differentiation under mild hyperthermia. Stem Cells Dev, 17:483–493.

19.

McCabe White

, Jennings

. 1999. Platelet Protocols Research and Clinical Laboratory Procedures. Academic Press: San Diego.

20.

Bergmeier

, Rackebrandt

, Schroder

, Zirngibl

, Nieswandt

. 2000. Structural and functional characterization of the mouse von Willebrand factor receptor GPIb-IX with novel monoclonal antibodies. Blood, 95:886–893.

21.

O'Brien

JJ.

, Spinelli

SL.

, Tober

, Blumberg

, Francis

CW.

, Taubman

MB.

, Palis

, Seweryniak

KE.

, Gertz

JM.

, Phipps

. 2008. 15-deoxy-delta12,14-PGJ2 enhances platelet production from megakaryocytes. Blood, 112:4051–4060.

22.

McGowan

EB.

, Yeo

KT.

, Detwiler

. 1983. The action of calcium-dependent protease on platelet surface glycoproteins. Arch Biochem Biophys, 227:287–301.

23.

Bergmeier

, Burger

PC.

, Piffath

CL.

, Hoffmeister

KM.

, Hartwig

JH.

, Nieswandt

, Wagner

. 2003. Metalloproteinase inhibitors improve the recovery and hemostatic function of in vitro-aged or -injured mouse platelets. Blood, 102:4229–4235.

24.

Shrivastava

2009. The platelet storage lesion. Transfus Apher Sci, 41:105–113.

25.

Chernoff

, Snyder

. 1992. The cellular and molecular basis of the platelet storage lesion: a symposium summary. Transfusion, 32:386–390.

26.

Skripchenko

, Myrup

, Thompson-Montgomery

, Awatefe

, Moroff

, Wagner

. 2010. Periods without agitation diminish platelet mitochondrial function during storage. Transfusion, 50:390–399.

27.

Mitchell

SG.

, Hawker

RJ.

, Turner

VS.

, Hesslewood

SR.

, Harding

. 1994. Effect of agitation on the quality of platelet concentrates. Vox Sang, 67:160–165.

28.

Brill

, Chauhan

AK.

, Canault

, Walsh

MT.

, Bergmeier

, Wagner

. 2009. Oxidative stress activates ADAM17/TACE and induces its target receptor shedding in platelets in a p38-dependent fashion. Cardiovasc Res, 84:137–144.

29.

Canault

, Duerschmied

, Brill

, Stefanini

, Schatzberg

, Cifuni

SM.

, Bergmeier

, Wagner

. 2010. p38 mitogen-activated protein kinase activation during platelet storage: consequences for platelet recovery and hemostatic function in vivo. Blood, 115:1835–1842.

30.

Cramer

EM.

, Norol

, Guichard

, Breton-Gorius

, Vainchenker

, Masse

JM.

, Debili

. 1997. Ultrastructure of platelet formation by human megakaryocytes cultured with the Mpl ligand. Blood, 89:2336–2346.

31.

Junt

, Schulze

, Chen

, Massberg

, Goerge

, Krueger

, Wagner

DD.

, Graf

, Italiano

JE.

Jr. , Shivdasani

RA.

, von Andrian

. 2007. Dynamic visualization of thrombopoiesis within bone marrow. Science, 317:1767–1770.

32.

Dunois-Larde

, Capron

, Fichelson

, Bauer

, Cramer-Borde

, Baruch

. 2009. Exposure of human megakaryocytes to high shear rates accelerates platelet production. Blood, 114:1875–1883.

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Glycoprotein Ibα Receptor Instability Is Associated with Loss of Quality in Platelets Produced in Culture

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