Factor VIII is produced in the liver's sinusoidal cells and endothelial cells outside the liver throughout the body. This protein circulates in the bloodstream in an inactive form, bound to another molecule called von Willebrand factor, until an injury that damages blood vessels occurs.[8] In response to injury, coagulation factor VIII is activated and separates from von Willebrand factor. The active protein (sometimes written as coagulation factor VIIIa) interacts with another coagulation factor called factor IX. This interaction sets off a chain of additional chemical reactions that form a blood clot.[8]
Factor VIII participates in blood coagulation; it is a cofactor for factor IXa, which, in the presence of Ca2+ and phospholipids, forms a complex that converts factor X to the activated form Xa. The factor VIII gene produces two alternatively spliced transcripts. Transcript variant 1 encodes a large glycoprotein, isoform a, which circulates in plasma and associates with von Willebrand factor in a noncovalent complex. This protein undergoes multiple cleavage events. Transcript variant 2 encodes a putative small protein, isoform b, which consists primarily of the phospholipid binding domain of factor VIIIc. This binding domain is essential for coagulant activity.[9]
People with high levels of factor VIII are at increased risk for deep vein thrombosis and pulmonary embolism.[10] Copper is a required cofactor for factor VIII and copper deficiency is known to increase the activity of factor VIII.[11]
Factor VIII was first characterized in 1984 by scientists at Genentech.[13] The gene for factor VIII is located on the X chromosome (Xq28). The gene for factor VIII presents an interesting primary structure, as another gene (F8A1) is embedded in one of its introns.[14]
Activation of factor VIII to factor VIIIa is done by cleavage and release of the B domain. The protein is now divided to a heavy chain, consisting of the A1-A2 domains, and a light chain, consisting of the A3-C1-C2 domains. Both form non-covalently a complex in a calcium-dependent manner. This complex is the pro-coagulant factor VIIIa.[17]
No longer protected by vWF, activated FVIII is proteolytically inactivated in the process (most prominently by activated protein C and factor IXa) and quickly cleared from the blood stream.
Factor VIII is not affected by liver disease. In fact, levels usually are elevated in such instances.[21][22]
FVIII concentrated from donated blood plasma, or recombinant FVIII can be given to hemophiliacs to restore hemostasis. Bypassing agents such as recombinant FVIIa can be used in acquired hemophilia.
Antibody formation to factor VIII can also be a major concern for patients receiving therapy against bleeding; the incidence of these inhibitors is dependent of various factors, including the factor VIII product itself.[23]
Factor VIII related antigen is used as a target for immunohistochemistry, where endothelial cells, megakaryocytes, platelets and mast cells normally stain positive.[24]
In the 1980s, some pharmaceutical companies such as Baxter International and Bayer sparked controversy by continuing to sell contaminated factor VIII after new heat-treated versions were available.[25] Under FDA pressure, unheated product was pulled from US markets, but was sold to Asian, Latin American, and some European countries. The product was tainted with HIV, a concern that had been discussed by Bayer and the U.S. Food and Drug Administration (FDA).[25]
In the early 1990s, pharmaceutical companies began to produce recombinant synthesized factor products, which now prevent nearly all forms of disease transmission during replacement therapy.
Factor VIII was first discovered in 1937, but it was not until 1979 that its purification by Edward Tuddenham, Frances Rotblat and coworkers led to the molecular identification of the protein.[26][27]
^Truett MA, Blacher R, Burke RL, Caput D, Chu C, Dina D, et al. (October 1985). "Characterization of the polypeptide composition of human factor VIII:C and the nucleotide sequence and expression of the human kidney cDNA". DNA. 4 (5): 333–349. doi:10.1089/dna.1985.4.333. PMID3935400.
^Antonarakis SE (July 1995). "Molecular genetics of coagulation factor VIII gene and hemophilia A". Thrombosis and Haemostasis. 74 (1): 322–328. doi:10.1055/s-0038-1642697. PMID8578479. S2CID23435953.
^Levinson B, Kenwrick S, Lakich D, Hammonds G, Gitschier J (May 1990). "A transcribed gene in an intron of the human factor VIII gene". Genomics. 7 (1): 1–11. doi:10.1016/0888-7543(90)90512-S. PMID2110545.
^Hollestelle MJ, Geertzen HG, Straatsburg IH, van Gulik TM, van Mourik JA (February 2004). "Factor VIII expression in liver disease". Thrombosis and Haemostasis. 91 (2): 267–275. doi:10.1160/th03-05-0310. PMID14961153. S2CID20091477.
^Rubin R, Leopold L (1998). Hematologic Pathophysiology. Madison, Conn: Fence Creek Publishing. ISBN1-889325-04-X.
^Tuddenham EG, Trabold NC, Collins JA, Hoyer LW (January 1979). "The properties of factor VIII coagulant activity prepared by immunoadsorbent chromatography". The Journal of Laboratory and Clinical Medicine. 93 (1): 40–53. PMID366050.
Lenting PJ, van Mourik JA, Mertens K (December 1998). "The life cycle of coagulation factor VIII in view of its structure and function". Blood. 92 (11): 3983–3996. doi:10.1182/blood.V92.11.3983. PMID9834200.