Comment on Sun et al, page
VKORC1, the recently identified protein of the vitamin K cycle, catalyzes vitamin K epoxide to vitamin K and further to vitamin K hydroquinone, thus representing the rate-limiting enzyme for the carboxylation of vitamin K–dependent proteins.
The key gene of the vitamin K cycle encoding the molecular target of coumarin-type anticoagulants, vitamin K epoxide reductase (VKORC1; Online Mendelian Inheritance in Man [OMIM]*608547; 16p11.2), has recently been identified by our group and Sun and colleagues.1,2 VKORC1 recycles vitamin K 2,3 epoxide to vitamin K hydroquinone, which functions as the essential cofactor for γ-carboxylation of Gla-domain proteins such as coagulation factors II, VII, IX, and X; proteins C, S, and Z; osteocalcin; matrix Gla protein (MGP); and Gas6. This gene extended over 5126 base pairs and comprised 3 exons encoding a small protein of 163 amino acids with a calculated relative molecular mass of about 18 kDa.1,2 Mutations in VKORC1 cause 2 distinctive phenotypes: a homozygous missense mutation in the VKORC1 gene leads to combined deficiency of vitamin K–dependent coagulation factors type 2 (VKCFD2),1 and heterozygous missense mutations are responsible for hereditary warfarin resistance in humans, rats, and mice.1
In this issue of Blood, Sun and colleagues report further key information about VKORC1. Using a HEK 293 cell line overproducing factor X, they found that the fraction of carboxylated factor X increases dramatically from 52% to 92% by coexpressing VKORC1 (see figure). The explanation for this observation is that most likely VKORC1 is responsible for both the conversion of vitamin K epoxide to vitamin K and vitamin K to vitamin K hydroquinone. Thus, although γ-glutamyl carboxylase (GGCX) is the enzyme that accomplishes the carboxylation reaction, VKORC1 represents the rate-limiting step in the reaction. This conclusion is consistent with another very recent report of Wajih et al.3 FIG1
Separation of γ-carboxylated and uncarboxylated FX by hydroxylapatite chromatography. See the complete figure in the article beginning on page .
Separation of γ-carboxylated and uncarboxylated FX by hydroxylapatite chromatography. See the complete figure in the article beginning on page .
The finding of Sun et al has important practical implications. Some vitamin K–dependent coagulation factors are of commercial interest as factor IX and rFVIIa for the treatment of hereditary or acquired bleeding disorders and as activated protein C for the treatment of sepsis. The yield of carboxylated and accordingly functional active protein in cell lines coexpressing VKORC1 will be much higher than in currently used cell lines.
The role of VKORC1 as a main regulator of the carboxylation reaction has gained particular attention in view of its function as the molecular target of coumarin derivatives (eg, warfarin), the most prescribed drug for therapy of thromboembolic events. Recently, frequent VKORC1 gene variants have been reported that significantly alter the level of VKORC1 activity and consequently affect the therapeutic dose of the drug.4,5 In fact, these observations suggest VKORC1 as the principal genetic modulator of the interindividual and interethnic differences in warfarin response. Moreover, we are tempted to speculate that these naturally occurring VKORC1 gene variants may also have an important influence on downstream function of vitamin K–dependent proteins, including matrix Gla protein and osteocalcin, which have been suggested to play a role in the pathogenesis of atherosclerosis, myocardial infarction, and stroke.
The work of Sun et al demonstrates VKORC1 as a main regulator of the carboxylation reaction, which, in view of the multiple downstream pathways affected by this protein, suggests further exciting studies in the near future. ▪
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