Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways

Denis Noubouossie; Michael W Henderson; Micah J Mooberry; Anton Ilich; Patrick Ellsworth; Mark Piegore; Sarah C Skinner; Rafal Pawlinski; Ian Welsby; Thomas Renné; Maureane Hoffman; Dougald M Monroe; Nigel S Key

doi:10.1182/blood.2019001643

Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways

Standard

Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways. / Noubouossie, Denis; Henderson, Michael W; Mooberry, Micah J; Ilich, Anton; Ellsworth, Patrick; Piegore, Mark; Skinner, Sarah C; Pawlinski, Rafal; Welsby, Ian; Renné, Thomas; Hoffman, Maureane; Monroe, Dougald M; Key, Nigel S.

In: BLOOD, Vol. 135, No. 10, 05.03.2020, p. 755-765.

Research output: SCORING: Contribution to journal › SCORING: Journal article › Research › peer-review

Harvard

Noubouossie, D, Henderson, MW, Mooberry, MJ, Ilich, A, Ellsworth, P, Piegore, M, Skinner, SC, Pawlinski, R, Welsby, I, Renné, T, Hoffman, M, Monroe, DM & Key, NS 2020, 'Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways', BLOOD, vol. 135, no. 10, pp. 755-765. https://doi.org/10.1182/blood.2019001643

APA

Noubouossie, D., Henderson, M. W., Mooberry, M. J., Ilich, A., Ellsworth, P., Piegore, M., Skinner, S. C., Pawlinski, R., Welsby, I., Renné, T., Hoffman, M., Monroe, D. M., & Key, N. S. (2020). Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways. BLOOD, 135(10), 755-765. https://doi.org/10.1182/blood.2019001643

Vancouver

Noubouossie D, Henderson MW, Mooberry MJ, Ilich A, Ellsworth P, Piegore M et al. Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways. BLOOD. 2020 Mar 5;135(10):755-765. https://doi.org/10.1182/blood.2019001643

Bibtex

@article{396db1e3823d4ca7a15ce9527eaffbd4,

title = "Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways",

abstract = "Storage lesion-induced, red cell-derived microvesicles (RBC-MVs) propagate coagulation by supporting the assembly of the prothrombinase complex. It has also been reported that RBC-MVs initiate coagulation via the intrinsic pathway. To elucidate the mechanism(s) of RBC-MV-induced coagulation activation, the ability of storage lesion-induced RBC-MVs to activate each zymogen of the intrinsic pathway was assessed in a buffer system. Simultaneously, the thrombin generation (TG) assay was used to assess their ability to initiate coagulation in plasma. RBC-MVs directly activated factor XII (FXII) or prekallikrein, but not FXI or FIX. RBC-MVs initiated TG in normal pooled plasma and in FXII- or FXI-deficient plasma, but not in FIX-deficient plasma, suggesting an alternate pathway that bypasses both FXII and FXI. Interestingly, RBC-MVs generated FIXa in a prekallikrein-dependent manner. Similarly, purified kallikrein activated FIX in buffer and initiated TG in normal pooled plasma, as well as FXII- or FXI-deficient plasma, but not FIX-deficient plasma. Dual inhibition of FXIIa by corn trypsin inhibitor and kallikrein by soybean trypsin inhibitor was necessary for abolishing RBC-MV-induced TG in normal pooled plasma, whereas kallikrein inhibition alone was sufficient to abolish TG in FXII- or FXI-deficient plasma. Heating RBC-MVs at 60°C for 15 minutes or pretreatment with trypsin abolished TG, suggesting the presence of MV-associated proteins that are essential for contact activation. In summary, RBC-MVs activate both FXII and prekallikrein, leading to FIX activation by 2 independent pathways: the classic FXIIa-FXI-FIX pathway and direct kallikrein activation of FIX. These data suggest novel mechanisms by which RBC transfusion mediates inflammatory and/or thrombotic outcomes.",

author = "Denis Noubouossie and Henderson, {Michael W} and Mooberry, {Micah J} and Anton Ilich and Patrick Ellsworth and Mark Piegore and Skinner, {Sarah C} and Rafal Pawlinski and Ian Welsby and Thomas Renn{\'e} and Maureane Hoffman and Monroe, {Dougald M} and Key, {Nigel S}",

note = "Copyright {\textcopyright} 2020 American Society of Hematology.",

year = "2020",

month = mar,

day = "5",

doi = "10.1182/blood.2019001643",

language = "English",

volume = "135",

pages = "755--765",

journal = "BLOOD",

issn = "0006-4971",

publisher = "American Society of Hematology",

number = "10",

}

RIS

TY - JOUR

T1 - Red blood cell microvesicles activate the contact system, leading to factor IX activation via 2 independent pathways

AU - Noubouossie, Denis

AU - Henderson, Michael W

AU - Mooberry, Micah J

AU - Ilich, Anton

AU - Ellsworth, Patrick

AU - Piegore, Mark

AU - Skinner, Sarah C

AU - Pawlinski, Rafal

AU - Welsby, Ian

AU - Renné, Thomas

AU - Hoffman, Maureane

AU - Monroe, Dougald M

AU - Key, Nigel S

PY - 2020/3/5

Y1 - 2020/3/5

N2 - Storage lesion-induced, red cell-derived microvesicles (RBC-MVs) propagate coagulation by supporting the assembly of the prothrombinase complex. It has also been reported that RBC-MVs initiate coagulation via the intrinsic pathway. To elucidate the mechanism(s) of RBC-MV-induced coagulation activation, the ability of storage lesion-induced RBC-MVs to activate each zymogen of the intrinsic pathway was assessed in a buffer system. Simultaneously, the thrombin generation (TG) assay was used to assess their ability to initiate coagulation in plasma. RBC-MVs directly activated factor XII (FXII) or prekallikrein, but not FXI or FIX. RBC-MVs initiated TG in normal pooled plasma and in FXII- or FXI-deficient plasma, but not in FIX-deficient plasma, suggesting an alternate pathway that bypasses both FXII and FXI. Interestingly, RBC-MVs generated FIXa in a prekallikrein-dependent manner. Similarly, purified kallikrein activated FIX in buffer and initiated TG in normal pooled plasma, as well as FXII- or FXI-deficient plasma, but not FIX-deficient plasma. Dual inhibition of FXIIa by corn trypsin inhibitor and kallikrein by soybean trypsin inhibitor was necessary for abolishing RBC-MV-induced TG in normal pooled plasma, whereas kallikrein inhibition alone was sufficient to abolish TG in FXII- or FXI-deficient plasma. Heating RBC-MVs at 60°C for 15 minutes or pretreatment with trypsin abolished TG, suggesting the presence of MV-associated proteins that are essential for contact activation. In summary, RBC-MVs activate both FXII and prekallikrein, leading to FIX activation by 2 independent pathways: the classic FXIIa-FXI-FIX pathway and direct kallikrein activation of FIX. These data suggest novel mechanisms by which RBC transfusion mediates inflammatory and/or thrombotic outcomes.

AB - Storage lesion-induced, red cell-derived microvesicles (RBC-MVs) propagate coagulation by supporting the assembly of the prothrombinase complex. It has also been reported that RBC-MVs initiate coagulation via the intrinsic pathway. To elucidate the mechanism(s) of RBC-MV-induced coagulation activation, the ability of storage lesion-induced RBC-MVs to activate each zymogen of the intrinsic pathway was assessed in a buffer system. Simultaneously, the thrombin generation (TG) assay was used to assess their ability to initiate coagulation in plasma. RBC-MVs directly activated factor XII (FXII) or prekallikrein, but not FXI or FIX. RBC-MVs initiated TG in normal pooled plasma and in FXII- or FXI-deficient plasma, but not in FIX-deficient plasma, suggesting an alternate pathway that bypasses both FXII and FXI. Interestingly, RBC-MVs generated FIXa in a prekallikrein-dependent manner. Similarly, purified kallikrein activated FIX in buffer and initiated TG in normal pooled plasma, as well as FXII- or FXI-deficient plasma, but not FIX-deficient plasma. Dual inhibition of FXIIa by corn trypsin inhibitor and kallikrein by soybean trypsin inhibitor was necessary for abolishing RBC-MV-induced TG in normal pooled plasma, whereas kallikrein inhibition alone was sufficient to abolish TG in FXII- or FXI-deficient plasma. Heating RBC-MVs at 60°C for 15 minutes or pretreatment with trypsin abolished TG, suggesting the presence of MV-associated proteins that are essential for contact activation. In summary, RBC-MVs activate both FXII and prekallikrein, leading to FIX activation by 2 independent pathways: the classic FXIIa-FXI-FIX pathway and direct kallikrein activation of FIX. These data suggest novel mechanisms by which RBC transfusion mediates inflammatory and/or thrombotic outcomes.

U2 - 10.1182/blood.2019001643

DO - 10.1182/blood.2019001643

M3 - SCORING: Journal article

C2 - 31971571

VL - 135

SP - 755

EP - 765

JO - BLOOD

JF - BLOOD

SN - 0006-4971

IS - 10

ER -