The inhibitory effect of calumenin on the vitamin K-dependent gamma-carboxylation system. Characterization of the system in normal and warfarin-resistant rats

The vitamin K-dependent gamma-carboxylation system is responsible for post-translational modification of vitamin K-dependent proteins, converting them to Gla-containing proteins. The system consists of integral membrane proteins located in the endoplasmic reticulum membrane and includes the gamma-carboxylase and the warfarin-sensitive enzyme vitamin K(1) 2,3-epoxide reductase (VKOR), which provides gamma-carboxylase with reduced vitamin K(1) cofactor. In this work, an in vitro gamma-carboxylation system was designed and used to understand how VKOR and gamma-carboxylase work together as a system and to identify factors that can regulate the activity of the system. Results are presented that demonstrate that the endoplasmic reticulum chaperone protein calumenin is associated with gamma-carboxylase and inhibits its activity. Silencing of the calumenin gene with siRNA resulted in a 5-fold increase in gamma-carboxylase activity. The results provide the first identification of a protein that can regulate the activity of the gamma-carboxylation system. The propeptides of vitamin K-dependent proteins stimulate gamma-carboxylase activity. Here we show that the factor X and prothrombin propeptides do not increase reduced vitamin K(1) cofactor production by VKOR in the system where VKOR is the rate-limiting step for gamma-carboxylation. These findings put calumenin in a central position concerning regulation of gamma-carboxylation of vitamin K-dependent proteins. Reduced vitamin K(1) cofactor transfer between VKOR and gamma-carboxylase is shown to be significantly impaired in the in vitro gamma-carboxylation system prepared from warfarin-resistant rats. Furthermore, the sequence of the 18-kDa subunit 1 of the VKOR enzyme complex was found to be identical in the two rat strains. This finding supports the notion that different forms of genetic warfarin resistance exist.

Identification of the gene for vitamin K epoxide reductase

Vitamin K epoxide reductase (VKOR) is the target of warfarin, the most widely prescribed anticoagulant for thromboembolic disorders. Although estimated to prevent twenty strokes per induced bleeding episode, warfarin is under-used because of the difficulty of controlling dosage and the fear of inducing bleeding. Although identified in 1974 (ref. 2), the enzyme has yet to be purified or its gene identified. A positional cloning approach has become possible after the mapping of warfarin resistance to rat chromosome 1 (ref. 3) and of vitamin K-dependent protein deficiencies to the syntenic region of human chromosome 16 (ref. 4). Localization of VKOR to 190 genes within human chromosome 16p12-q21 narrowed the search to 13 genes encoding candidate transmembrane proteins, and we used short interfering RNA (siRNA) pools against individual genes to test their ability to inhibit VKOR activity in human cells. Here, we report the identification of the gene for VKOR based on specific inhibition of VKOR activity by a single siRNA pool. We confirmed that MGC11276 messenger RNA encodes VKOR through its expression in insect cells and sensitivity to warfarin. The expressed enzyme is 163 amino acids long, with at least one transmembrane domain. Identification of the VKOR gene extends our understanding of blood clotting, and should facilitate development of new anticoagulant drugs.

Mutations in VKORC1 cause warfarin resistance and multiple coagulation factor deficiency type 2

Coumarin derivatives such as warfarin represent the therapy of choice for the long-term treatment and prevention of thromboembolic events. Coumarins target blood coagulation by inhibiting the vitamin K epoxide reductase multiprotein complex (VKOR). This complex recycles vitamin K 2,3-epoxide to vitamin K hydroquinone, a cofactor that is essential for the post-translational gamma-carboxylation of several blood coagulation factors. Despite extensive efforts, the components of the VKOR complex have not been identified. The complex has been proposed to be involved in two heritable human diseases: combined deficiency of vitamin-K-dependent clotting factors type 2 (VKCFD2; Online Mendelian Inheritance in Man (OMIM) 607473), and resistance to coumarin-type anticoagulant drugs (warfarin resistance, WR; OMIM 122700). Here we identify, by using linkage information from three species, the gene vitamin K epoxide reductase complex subunit 1 (VKORC1), which encodes a small transmembrane protein of the endoplasmic reticulum. VKORC1 contains missense mutations in both human disorders and in a warfarin-resistant rat strain. Overexpression of wild-type VKORC1, but not VKORC1 carrying the VKCFD2 mutation, leads to a marked increase in VKOR activity, which is sensitive to warfarin inhibition.

Species comparison of vitamin K1 2,3-epoxide reductase activity in vitro: kinetics and warfarin inhibition

A comparative study of vitamin K(1) 2,3-epoxide reductase (VKOR) activity in vitro was conducted across species. The apparent kinetic constants K(m app), V(max), and Cl(int app) were determined in bovine, canine, equine, human, murine, ovine, porcine, and rat hepatic microsomes. In addition to these enzyme kinetic constants, the IC(50) of warfarin for VKOR was determined in human, murine, porcine, and rat hepatic microsomes. Interspecies differences were observed when comparing the K(m app) (range, 2.41-6.46 microM), V(max) (range, 19.5-85.7 nmol/mg/min), and Cl(int app) (range, 8.2-18.4 ml/mg/min) values. Comparison of the IC(50) values of warfarin, across the four species tested, revealed a significant species difference between murine microsomes (0.17 microM) and rat microsomes (0.07 microM). Overall, this study indicates that there are interspecies differences regarding the in vitro reduction of vitamin K(1) 2,3-epoxide by the warfarin-sensitive enzyme vitamin K(1) 2,3-epoxide reductase. Significant differences between the IC(50) values of murine and rat microsomes suggest differences in the susceptibility of these species to warfarin.

Locus-specific genetic differentiation at Rw among warfarin-resistant rat (Rattus norvegicus) populations

Populations may diverge at fitness-related genes as a result of adaptation to local conditions. The ability to detect this divergence by marker-based genomic scans depends on the relative magnitudes of selection, recombination, and migration. We survey rat (Rattus norvegicus) populations to assess the effect that local selection with anticoagulant rodenticides has had on microsatellite marker variation and differentiation at the warfarin resistance gene (Rw) relative to the effect on the genomic background. Initially, using a small sample of 16 rats, we demonstrate tight linkage of microsatellite D1Rat219 to Rw by association mapping of genotypes expressing an anticoagulant-rodenticide-insensitive vitamin K 2,3-epoxide reductase (VKOR). Then, using allele frequencies at D1Rat219, we show that predicted and observed resistance levels in 27 populations correspond, suggesting intense and recent selection for resistance. A contrast of F(ST) values between D1Rat219 and the genomic background revealed that rodenticide selection has overwhelmed drift-mediated population structure only at Rw. A case-controlled design distinguished these locus-specific effects of selection at Rw from background levels of differentiation more effectively than a population-controlled approach. Our results support the notion that an analysis of locus-specific population genetic structure may assist the discovery and mapping of novel candidate loci that are the object of selection or may provide supporting evidence for previously identified loci.

Vitamin K 2,3-epoxide reductase and the vitamin K-dependent gamma-carboxylation system

Vitamin K is an essential cofactor for post translational gamma-carboxylation of vitamin K-dependent coagulation factors. The modification is carried out by a system of integral proteins of the endoplasmic reticulum (ER) membrane where the warfarin sensitive vitamin K 2,3-epoxide reductase (VKOR) produces the reduced hydroquinone form of vitamin K (vit.KH(2)) needed by the gamma-carboxylase as the active cofactor. Currently, we have only limited knowledge about how the system functions at the molecular level. VKOR harbors a thiol red/ox center that is essential for electron transfer leading to vitamin K reduction. Reduction of this center with hydrophilic and hydrophobic trialkylphosphines shows that it is located in a hydrophobic environment which must be accessible by an as yet unidentified in vivo reductant of the center. Furthermore, we have addressed the question of whether VKOR or the gamma-carboxylase is the rate-limiting step in the vitamin K-dependent gamma-caboxylation system. A detailed kinetic analysis of an in vitro preparation of the system was undertaken in which gamma-carboxylation of the carboxylase peptide substrate FLEEL was measured as the gamma-carboxylation capacity of the system. Adding VKOR to the test system increased the gamma-carboxylation capacity of the system suggesting that VKOR is the rate-limiting step in the system. This finding puts VKOR in a central position to regulate biosynthesis of biologically active vitamin K-dependent proteins.

Homozygosity mapping of a second gene locus for hereditary combined deficiency of vitamin K-dependent clotting factors to the centromeric region of chromosome 16

Familial multiple coagulation factor deficiency (FMFD) of factors II, VII, IX, X, protein C, and protein S is a very rare bleeding disorder with autosomal recessive inheritance. The phenotypic presentation is variable with respect to the residual activities of the affected proteins, its response to oral administration of vitamin K, and to the involvement of skeletal abnormalities. The disease may result either from a defective resorption/transport of vitamin K to the liver, or from a mutation in one of the genes encoding gamma-carboxylase or other proteins of the vitamin K cycle. We have recently presented clinical details of a Lebanese family and a German family with 10 and 4 individuals, respectively, where we proposed autosomal recessive inheritance of the FMFD phenotype. Biochemical investigations of vitamin K components in patients' serum showed a significantly increased level of vitamin K epoxide, thus suggesting a defect in one of the subunits of the vitamin K 2,3-epoxide reductase (VKOR) complex. We now have performed a genome-wide linkage analysis and found significant linkage of FMFD to chromosome 16. A total maximum 2-point LOD score of 3.4 at theta = 0 was obtained in the interval between markers D16S3131 on 16p12 and D16S419 on 16q21. In both families, patients were autozygous for 26 and 28 markers, respectively, in an interval of 3 centimorgans (cM). Assuming that FMFD and warfarin resistance are allelic, conserved synteny between human and mouse linkage groups would restrict the candidate gene interval to the centromeric region of the short arm of chromosome 16.

A molecular mechanism for genetic warfarin resistance in the rat

Warfarin targets vitamin K 2,3-epoxide reductase (VKOR), the enzyme that produces reduced vitamin K, a required cofactor for g-carboxylation of vitamin K-dependent proteins. To identify VKOR, we used 4'-azido-warfarin-3H-alcohol as an affinity label. When added to a partially purified preparation of VKOR, two proteins were identified by mass spectrometry as calumenin and cytochrome B5. Rat calumenin was cloned and sequenced and the recombinant protein was produced. When added to an in vitro test system, the 47 kDa recombinant protein was found to inhibit VKOR activity and to protect the enzyme from warfarin inhibition. Calumenin was also shown to inhibit the overall activity of the complete vitamin K-dependent g-carboxylation system. The results were repeated in COS-1 cells overexpressing recombinant calumenin. By comparing calumenin mRNA levels in various tissues from normal rats and warfarin-resistant rats, only the livers from resistant rats were different from normal rats by showing increased levels. Partially purified VKOR from resistant and normal rat livers showed no differences in Km-values, specific activity, and sensitivity to warfarin. A novel model for genetic warfarin resistance in the rat is proposed, whereby the concentration of calumenin in liver determines resistance.

Genetic mechanisms for hypersensitivity and resistance to the anticoagulant Warfarin

Warfarin is the therapeutic of choice for maintenance anticoagualtion therapy. A principle caveat of this medication is that the dosage required to achieve the desired therapeutic effect varies up to 120-fold between individuals. Currently, there are no reliable means of prospectively identifying which patients will require either unusually high or low dosages. This dilemma puts patients at risk of therapeutic failure or potentially life-threatening overdosage during a prolonged trial-and-error period of establishing an individualized medication strategy. Pharmacogenetic research has revealed that extreme differences in the drug dose required to achieve the desired therapeutic response can be attributed to genetic variation in the genes encoding drug metabolizing enzymes, and cellular receptor proteins. The anticoagulant Warfarin represents a model system where there is evidence to suggest that both pharmacokinetic and pharmacodynamic mechanisms contribute to the overall variability in patient response. Here the current understanding concerning the influence of genetic variation in Warfarin pharmacokinetics is reviewed and the potential for similar genetic mechanism impacting on the pharmacodynamic response in man is explored. Diagnostic testing to identify subjects requiring low-dose Warfarin therapy is discussed in light of potential confounding or coexisting resistance to the drug effects.

Characterization and purification of the vitamin K1 2,3 epoxide reductases system from rat liver

The enzyme vitamin K1 2,3 epoxide reductase is responsible for converting vitamin K1 2,3 epoxide to vitamin K1 quinone thus completing the vitamin K cycle. The enzyme is also the target of inhibition by the oral anticoagulant, R,S-warfarin. Purification of this protein would enable the interaction of the inhibitor with its target to be elucidated. To date a single protein possessing vitamin K1 2,3 epoxide reductase activity and binding R,S-warfarin has yet to be purified to homogeneity, but recent studies have indicated that the enzyme is in fact at least two interacting proteins. We report on the attempted purification of the vitamin K1 2,3 epoxide reductase complex from rat liver microsomes by ion exchange and size exclusion chromatography techniques. The intact system consisted of a warfarin-binding factor, which possessed no vitamin K1 2,3 epoxide reductase activity and a catalytic protein. This catalytic protein was purified 327-fold and was insensitive to R,S-warfarin inhibition at concentrations up to 5 mM. The addition of the S-200 size exclusion chromatography fraction containing the inhibitor-binding factor resulted in the return of R,S-warfarin inhibition. Thus, to function normally, the rat liver endoplasmic reticulum vitamin K1 2,3 epoxide reductase system requires the association of two components, one with catalytic activity for the conversion of the epoxide to the quinone and the second, the inhibitor binding factor. This latter enzyme forms the thiol-disulphide redox centre that in the oxidized form binds R,S-warfarin.

1,25-Dihydroxyvitamin D3 promotes vitamin K2 metabolism in human osteoblasts

It has been reported that vitamin K2 (menaquinone-4) promoted 1,25-dihydroxyvitamin D3 (1,25(OH)2D3)-induced mineralization and enhanced gamma-carboxyglutamic acid (Gla)-containing osteocalcin accumulation in cultured human osteoblasts. In the present study, we investigated whether menaquinone-4 (MK-4) was metabolized in human osteoblasts to act as a cofactor of gamma-glutamyl carboxylase. Both conversions of MK-4 to MK-4 2,3-epoxide (epoxide) and epoxide to MK-4 were observed in cell extracts of cultured human osteoblasts. The effect of 1,25(OH)2D3 and warfarin on the vitamin K cycle to cultured osteoblasts were examined. With the addition of 1 nM 1,25(OH)2D3 or 25 microM warfarin in cultured osteoblasts, the yield of epoxide from MK-4 increased. However, the conversion of epoxide to MK-4 was strongly inhibited by the addition of warfarin (2.5-25 microM), whereas it was almost not inhibited by 1,25(OH)2D3 (0.1-10 nM). To clarify the mechanism for this phenomenon, a cell-free assay system was studied. Osteoblast microsomes were incubated with 10 microM epoxide in the presence or absence of warfarin and 1,25(OH)2D3. Epoxide reductase, one of the enzymes in the vitamin K cycle was strongly inhibited by warfarin (2.5-25 microM), whereas it was not affected by 1,25(OH)2D3 (0.1-1 nM). Moreover, there was no effect of pretreatment of osteoblasts with 1 nM 1,25(OH)2D3 on the activity of epoxide reductase. However, the activity of epoxidase, that is the gamma-glutamyl carboxylase was induced by the pretreatment of osteoblasts with 1 nM 1,25(OH)2D3. In the present study, it was demonstrated that the vitamin K metabolic cycle functions in human osteoblasts as well as in the liver, the post-translational mechanism, by which 1,25(OH)2D3 caused mineralization in cooperation with vitamin K2 was clarified.

Congenital deficiency of vitamin K dependent coagulation factors in two families presents as a genetic defect of the vitamin K-epoxide-reductase-complex

Hereditary combined deficiency of the vitamin K dependent coagulation factors is a rare bleeding disorder. To date, only eleven families have been reported in the literature. The phenotype varies considerably with respect to bleeding tendency, response to vitamin K substitution and the presence of skeletal abnormalities, suggesting genetic heterogeneity. In only two of the reported families the cause of the disease has been elucidated as either a defect in the gamma-carboxylase enzyme (1) or in a protein of the vitamin K 2,3-epoxide reductase (VKOR) complex (2). Here we present a detailed phenotypic description of two new families with an autosomal recessive deficiency of all vitamin K dependent coagulation factors. In both families offspring had experienced severe or even fatal perinatal intracerebral haemorrhage. The affected children exhibit a mild deficiency of the vitamin K dependent coagulation factors that could be completely corrected by oral substitution of vitamin K. Sequencing and haplotype analysis excluded a defect within the gamma-carboxylase gene. The finding of highly increased amounts of vitamin K epoxide in all affected members of both families indicated a defect in a protein of the VKOR-multienzyme-complex. Further genetic analysis of such families will provide the basis for a more detailed understanding of the structure-function relation of the enzymes involved in vitamin K metabolism.

Developmental changes of vitamin K epoxidase and reductase activities involved in the vitamin K cycle in human liver

We examined the developmental changes in activities of vitamin K epoxidase, and vitamin K-2,3-epoxide reductase and vitamin K reductase in the human autopsied liver. The activity of epoxidase, which converts vitamin K hydroquinone to its epoxide, showed a high value in the early prenatal period of 10-30 gestational weeks but decreased rather rapidly in contrast with the reductase activities. After birth, a significant decrease of the epoxidase activity was observed but no such change was seen during the postnatal period. On the other hand, the activities of vitamin K-2,3-epoxide reductase and vitamin K reductase, which convert vitamin K-2,3-epoxide to its hydroquinone, showed a significantly low value in the early prenatal period. The highest activity of vitamin K epoxidase in the early prenatal period may be essential to the production of vitamin K dependent ligands for growth factors expressed in the embryo.

Warfarin resistance is associated with a protein component of the vitamin K 2,3-epoxide reductase enzyme complex in rat liver

Warfarin, the most used drug in the world in long-term anticoagulation prophylaxis, targets the vitamin K 2,3-epoxide reductase (VKOR) of the vitamin K cycle in liver. Recently, the enzyme has been identified as a multicomponent lipid-protein enzyme system in the endoplasmic reticulum (ER) membrane (17). As the first step towards understanding genetic resistance to warfarin, we present in this paper data on VKOR from normal and a strain of warfarin resistant laboratory rats maintained in the United States. Metal induced in vitro assembly of the enzyme complex demonstrates that the glutathione-S-transferase (GST) enzyme component of the complex loses its GST activity upon formation of VKOR. Less VKOR activity is measured upon assembly of the complex from warfarin resistant rats. The GST activity measured in warfarin resistant rats, before assembly of the complex, is 10-fold less sensitive to warfarin inhibition than the GST activity measured in normal rats. Microsomal epoxide hydrolase (mEH) is the second component of VKOR. When incubated with the components of VKOR before assembly of the complex, antibodies raised against mEH prevented formation of the enzyme complex. Sequencing of mEH cDNAs from normal and warfarin resistant rats revealed identical sequences. The data suggest that the mutation responsible for genetic warfarin resistance is associated with the GST component of VKOR.

Co-purification of microsomal epoxide hydrolase with the warfarin-sensitive vitamin K1 oxide reductase of the vitamin K cycle

Vitamin K1 oxide reductase activity has been partially purified from rat liver microsomes. A three-step procedure produced a preparation in which warfarin-sensitive vitamin K1 oxide reductase activity was 118-fold enriched over the activity in intact rat liver microsomes. A major component of the multi-protein mixture was identified as a 50 kDa protein that strongly cross-reacts with antiserum prepared against homogeneous rat liver microsomal epoxide hydrolase. The reductase preparation also had a high level or epoxide hydrolase activity against two xenobiotic epoxide substrates. The K(m) values for hydrolysis by the reductase preparation were similar to those for homogeneous microsomal epoxide hydrolase itself, and the specific hydrolase activities of the reductase preparation were 25-35% of the specific activities measured for the homogeneous hydrolase preparation. Antibodies prepared against homogeneous microsomal epoxide hydrolase inhibited up to 80% of reductase activity of the reductase preparation. Homogeneous microsomal epoxide hydrolase had no vitamin K1 oxide reductase activity. This evidence suggests that microsomal epoxide hydrolase, or a protein that is very similar to it, is a major functional component of a multi-protein complex that is responsible for vitamin K1 oxide reduction in rat liver microsomes.

Assembly of the warfarin-sensitive vitamin K 2,3-epoxide reductase enzyme complex in the endoplasmic reticulum membrane

gamma-Carboxylation of vitamin K-dependent proteins requires a functional vitamin K cycle to produce the active vitamin K cofactor for the gamma-carboxylase which posttranslationally modifies precursors of these proteins to contain gamma-carboxyglutamic acid residues. The warfarin-sensitive enzyme vitamin K epoxide reductase (VKOR) of the cycle reduces vitamin K 2,3-epoxide to the active vitamin K hydroquinone cofactor. Because of the importance of warfarin as an anticoagulant in prophylactic medicine and as a poison in rodent pest control, numerous attempts have been made to understand the molecular mechanism underlying warfarin-sensitive vitamin K 2,3-epoxide reduction. In search for protein components that could be involved in this reaction we designed an in vitro gamma-carboxylation test system where the warfarin-sensitive VKOR produces the cofactor for the gamma-carboxylase. Dissection of this system by chromatographic techniques has identified a member(s) of the glutathione S-transferase gene family as one component of the VKOR enzyme complex in the endoplasmic reticulum membrane. The affinity-purified glutathione S-transferase(s) was sensitive to warfarin but lost its warfarin sensitivity and glutathione S-transferase activity upon association with lipids in the presence of Mn2+ or Ca2+. In the gamma-carboxylation test system, loss of warfarin-sensitive glutathione S-transferase activity coincided with formation of the VKOR enzyme complex. It is proposed that formation of VKOR in the endoplasmic reticulum membrane resembles formation of the lipoxygenase enzyme complex where the glutathione S-transferase-related FLAP protein binds cytosolic lipoxygenase to form a membrane enzyme complex.

The characterization of potent novel warfarin analogs

Racemic sodium warfarin, Coumadin, is widely used in the prevention of thromboembolic disease. The present study was undertaken to characterize three novel classes of warfarin analogs, and to compare them with the warfarin enantiomers. All three classes of compounds inhibit vitamin K epoxide reductase, the enzyme inhibited by racemic warfarin. The alcohol and the ester analogs have reduced protein binding compared with R-(+)-warfarin. The ester and the fluoro-derivatives have similar in vivo anticoagulant activity in the rat to that of S-(-)-warfarin. Thus, it is possible to synthesize novel warfarin analogs that differ from racemic warfarin or its enantiomers in certain selected properties.

The potent antioxidant activity of the vitamin K cycle in microsomal lipid peroxidation

In the vitamin K cycle, vitamin K-hydroquinone, the active cofactor for gamma-glutamylcarboxylase, is continuously regenerated. The successive pathways contain oxidation of the hydroquinone to the epoxide, followed by reduction to the quinone and reduction to the hydroquinone. Vitamin K-hydroquinone is a potent radical scavenging species (Mukai et al., J Biol Chem 267: 22277-22281, 1992). We tested the potential antioxidant activity of the vitamin K cycle in lipid peroxidation reactions (thiobarbituric acid reactive substances, TBARS) in rat liver microsomes. As prooxidant we used Fe2+/ascorbate, NADPH-Fe3+/ATP, and NADPH/CCl4. Vitamin K (< or = 50 microM) on its own did not influence the formation of TBARS. In combination with 1 mM dithiothreitol (DTT), the reductive cofactor for the microsomal enzyme vitamin K epoxide reductase, vitamin K suppressed lipid peroxidation with a concentration that blocked the maximal response by 50% (IC50) of ca. 0.2 microM. Vitamin K1 (phylloquinone) and vitamin K2 (menaquinone-4) were equally active. Warfarin (5 microM) and chloro-vitamin K (50 microM), inhibitors of vitamin K epoxide reductase and gamma-glutamylcarboxylase, respectively, were able to completely abolish the antioxidant effect. Lipid peroxidation was inversely related to the amount of vitamin K hydroquinone in the reaction. Vitamin K epoxide reductase seemed sensitive to lipid peroxidation, with half of the activity being lost within 10 min during oxidation with NADPH/CCl4. The inactivation could be attenuated by antioxidants such as vitamin E, reduced glutathione, and menadione and also by a K vitamin in combination with DTT, but not by superoxide dismutase and catalase. The results show that the vitamin K cycle could act as a potent antioxidant, that the active species in all probability is vitamin K-hydroquinone, and that the primary reaction product is the semiquinone. The results also show that the reaction product is processed in the vitamin K cycle to regenerate vitamin K-hydroquinone.

Natural prenylquinones inhibit the enzymes of the vitamin K cycle in vitro

Vitamin K belongs to a class of compounds commonly known as prenylquinones. Three other prenylquinones which are abundantly found in food are plastoquinone-9, ubiquinone-9 and ubiquinone-10. Using in vitro assay systems, it was recently found that synthetic derivatives of prenylquinones inhibit the vitamin K-dependent enzyme gamma-glutamylcarboxylase and, to a lesser extent, the vitamin K-epoxide reductase. In this paper we describe how natural prenylquinones affect the vitamin K-dependent enzymes in vitro. All three prenylquinones were found to inhibit both the vitamin K-dependent carboxylase and the K-epoxide reductase in a rat as well as in a cow liver system; 50% inhibition was obtained at concentrations in the micromolar range. On the basis of their respective standard redox potentials, a possible mechanism for the inhibitory effect of prenylquinones on the carboxylase enzyme is put forward. It is concluded that natural prenylquinones are potential antagonists of vitamin K and may interfere with vitamin K-dependent reactions in vivo.

Profactor IX propeptide and glutamate substrate binding sites on the vitamin K-dependent carboxylase identified by site-directed mutagenesis

The vitamin K-dependent carboxylase, a constituent of the endoplasmic reticulum membrane, catalyzes the conversion of reduced vitamin K to vitamin K epoxide and the concomitant conversion of glutamic acid to gamma-carboxyglutamic acid. To study structure-function relationships in the enzyme, seventeen clusters of charged residues of the bovine gamma-glutamyl carboxylase were substituted with alanines using site-specific mutagenesis. Wild-type and mutant carboxylase species were expressed in Chinese hamster ovary cells with an immunodetectable octapeptide inserted at their amino-terminal ends. Out of 17 mutant carboxylase species that contain a total of 41 charged residue to alanine substitutions, K217A/K218A (CBX217/218), R234A/H235A (CBX234/235), R359A/H360A/K361A (CBX359/360/361), R406A/H408A (CBX406/408), and R513A/K515A (CBX513/515) had impaired carboxylase activity compared with the wild-type enzyme. The vitamin K epoxidase activities of these mutants were reduced in parallel with the carboxylase activities. CBX217/218 appears to be inactive. High propeptide concentrations were required for stimulation of carboxylation of FLEEL by CBX234/235, CBX406/408, and CBX513/515, suggesting defects in the propeptide binding site. CBX359/360/361 showed normal affinity for the propeptide, FLEEL, proPT28, and vitamin K hydroquinone but exhibited a low catalytic rate for carboxylation. These results suggest that residue 217, residue 218, or both are either critical for catalysis or for maintaining the structure of a catalytically active enzyme. Regions around residues 234, 406, and 513 define in part the propeptide binding site, while the regions around residue 359 are involved in catalysis.

Target-based warfarin pharmacokinetics in the rat: the link with the anticoagulant effect

Warfarin and congeners bind tightly to the target enzyme vitamin K epoxide reductase. In this study the impact of the target binding on the warfarin pharmacokinetics in plasma and liver of the rat was estimated. Furthermore, the effect of warfarin pharmacokinetics on the time course of inhibition of vitamin K epoxide reductase was followed to find a link with the effect in time on the vitamin K-dependent clotting factor synthesis. Biochemical parameters, drug tissue levels and plasma coagulation activity prothrombin time were followed in normal and phenobarbitone (PB)-treated rats for 12 days after a single dose of S-warfarin (0.5 mg/kg). Warfarin accumulated to saturation (40-50 pmol/mg of protein) in liver microsomes to remain prolongedly bound and the half-life of elimination exceeded 7 days. PB-treated rats were not found to differ in this respect. In parallel with the steady increase of microsomal-free warfarin binding sites the ex vivo vitamin K epoxide reductase activity recovered, from 10% control activity at t = 3 hr to 70% at t = 12 days. PB-treated rats showed a 1.8-fold higher recovery rate in free enzyme. Blood coagulation was affected during the time in which the ex vivo vitamin K epoxide reductase activity was less than 20% of normal activity. The ex vivo reductase inhibition showed a sigmoidal effect relationship for plasma S-warfarin. Emax appeared to be significantly less than 100% (95% confidence intervals; 83-91%).(ABSTRACT TRUNCATED AT 250 WORDS)

Biochemical basis of warfarin and bromadiolone resistance in the house mouse, Mus musculus domesticus

Danish mice (Mus musculus domesticus) genetically resistant to the anticoagulant action of two 4-hydroxycoumarins, warfarin and bromadiolone, were examined to determine their mechanism of resistance. The hepatic vitamin K epoxide reductase in the bromadiolone-resistant mice and in one phenotype of warfarin-resistant mice was highly insensitive to in vitro inhibition by warfarin and bromadiolone. The kinetic constants for the epoxide reductase from bromadiolone-resistant mice were also altered. The Vmax for this enzyme was decreased by 40%, and the Km for the reaction reductant, dithiothreitol, was 70% lower than that of normal mice. This phenotype of Danish resistant mice appears to have a resistance mechanism that is similar to that reported for a Welsh strain of warfarin-resistant rats. The other phenotype of Danish resistant mice had a hepatic epoxide reductase that was only slightly less sensitive to warfarin inhibition than normal. The mechanism of warfarin resistance in these mice is not apparent from the available data.

Vitamin K-antagonistic effect of plastoquinone and ubiquinone derivatives in vitro

Decyl-ubiquinone and decyl-plastoquinone were used as model compounds to test the potential effect of quinone derivatives on two enzymes of the vitamin K cycle in vitro. Substantial inhibition of gamma-glutamate carboxylase was found, whereas vitamin K-epoxide reductase was inhibited to a much lesser extent. The inhibitory effect of both decylquinones was eliminated in a time-dependent way by solubilized microsomes, but not by purified carboxylase. Since a wide variety of prenylquinones occur as micronutrients, these results are of potential relevance for the effects of natural quinones in the human diet.

Microsomal lipoamide reductase provides vitamin K epoxide reductase with reducing equivalents

This study was undertaken to search for the endogenous dithiol cofactor of the reductases of the vitamin K cycle. As a starting point, the redox-active lipophilic endogenous compounds lipoic acid and lipoamide were looked at. The study shows that microsomes contain NADH-dependent lipoamide reductase activity. Reduced lipoamide stimulates microsomal vitamin K epoxide reduction with kinetics comparable with those for the synthetic dithiol dithiothreitol (DTT). Reduced lipoic acid shows higher (4-fold) Km values. No reductase activity with lipoic acid was found to be present in microsomes or cytosol. The reduced-lipoamide-stimulated vitamin K epoxide reductase is as sensitive to warfarin and salicylate inhibition as is the DTT-stimulated one. Both vitamin K epoxide reductase and lipoamide reductase activity are recovered in the rough microsomes. NADH/lipoamide-stimulated vitamin K epoxide reduction is uncoupled by traces of Triton X-100, suggesting that microsomal lipoamide reductase and vitamin K epoxide reductase are associated. The results suggest that the vitamin K cycle obtains reducing equivalents from NADH through microsomal lipoamide reductase.

Vitamin K metabolism and vitamin K1 status in human liver samples: a search for inter-individual differences in warfarin sensitivity

Vitamin K-dependent parameters in human liver samples were investigated to find a clue to the inter-individual differences in sensitivity for oral anticoagulants. Vitamin K epoxide reductase and vitamin K-dependent carboxylase activity differed 2-3-fold between the samples. Microsomal warfarin binding correlated significantly with the reductase activity. Microsomal vitamin K epoxide reductase of the different samples showed equal sensitivity for warfarin inhibition, I50 about 0.1 microM. Vitamin K epoxide reductase activity stimulated by NADH/lipoamide and microsomal lipoamide dehydrogenase activity showed higher inter-subject variability than the reductase activity by itself. Liver vitamin K1 levels varied 4-5-fold. Total and liver microsomal vitamin K1 levels were correlated. One of the liver samples was obtained from a donor anticoagulated with phenprocoumon and additionally treated with vitamin K1. High levels of the vitamin and its epoxide were present. Phenprocoumon was essentially irreversibly bound to the microsomes. In general the results confirm inter-individual differences in the hepatic vitamin K-dependent systems; the differences as such were found to be small. However, as the various parameters can work synergistically in the same direction, they may well account for the wide dose range observed in oral anticoagulant therapy.

Characterization of the purified vitamin K-dependent gamma-glutamyl carboxylase

Vitamin K-dependent carboxylase, purified from bovine liver, has properties similar to those reported for the carboxylase activity present in crude, solubilized microsomes. The purified carboxylase was found to possess the vitamin K epoxidase activity, believed to be essential for vitamin K-dependent carboxylation, but did not contain vitamin K epoxide reductase activity. Kinetic studies of the carboxylase done under defined conditions were complicated by the non-Michaelis-Menten kinetic behavior observed for reactions with two of the enzymes substrates, FLEEL and vitamin K1 hydroquinone. Initial rate experiments with the substrate FLEEL demonstrated behavior consistent with substrate inhibition and gave half-maximal activity at 1 mM FLEEL. Experiments with the substrate vitamin K1 hydroquinone also displayed non-Michaelis-Menten kinetics, as maximal activity was reached prematurely in relation to behavior at lower concentrations. Half-maximal activity was observed at 35 microM vitamin K1 hydroquinone. Initial rate experiments with varying NaH14CO3 concentration displayed Michaelis-Menten kinetics and gave a Km(app) of 0.29 mM. At cosubstrate concentrations chosen to obtain near-maximal activity, initial rate studies with varying NaH14CO3 concentration indicated a kcat near 1.0 s-1. Removal of the fourth substrate, oxygen, resulted in the loss of more than 99% of carboxylase activity. The sulfhydryl reagent N-ethylmaleimide inhibited carboxylase irreversibly, as did the anticoagulant warfarin.

Is thioredoxin the physiological vitamin K epoxide reducing agent?

E. coli thioredoxin plus thioredoxin reductase have previously been shown to replace dithiothreitol as the electron donor for mammalian liver microsomal vitamin K epoxide reduction in vitro. Such activity is dependent on detergent disruption of the microsomal membrane integrity. A previously characterized salicylate-inhibitable pathway for electron transfer from endogenous cytosolic reducing agents to the microsomal epoxide reducing warfarin-inhibitable enzyme is not inhibited by known alternate substrates and inhibitors of the thioredoxin system nor by antibodies against thioredoxin.

The relationship between the vitamin K cycle inhibition and the plasma anticoagulant response at steady-state S-warfarin conditions in the rat

The relationship between the inhibition of the vitamin K cycle and the inhibition of the vitamin K-dependent clotting factor synthesis was studied in the rat under a controlled rate of S-warfarin administration. Steady state of drug disposition was achieved from beyond day 2 and stable anticoagulation was achieved from beyond days 3 to 4. Doses up to 0.5 micrograms/kg/h were without effect, whereas 3 micrograms/kg/h reduced prothrombin complex activity to about 10%. Factor II and factor VII activity were equally suppressed as prothrombin complex activity. The concentration-effect relationship for steady-state S-warfarin plasma concentration and the inhibition of clotting factor synthesis revealed a steep sigmoidal response relationship (IC50 = 0.21 +/- 0.01 micrograms/ml, Hill slope = 2.07 +/- 0.3). Contrary to this, the target enzyme vitamin K1 2,3-epoxide reductase showed a dose-dependent response for the entire dose range. The sigmoidal effect relationship for plasma S-warfarin and enzyme inhibition showed a slope of 0.81 +/- 0.07 with IC50 = 16 +/- 1 ng/ml. The results demonstrate a reserve capacity for the coumarin-sensitive reductase; at least 70% of the hepatic vitamin K1 2,3-epoxide reductase activity has to be eliminated before the vitamin K-dependent carboxylation of the clotting factors objectively becomes compromised. In the study, the microsomal warfarin binding sites were compared with the vitamin K1 2,3-epoxide reductase activity, and a strict 1 to 1 relationship was found supporting the relationship between both.(ABSTRACT TRUNCATED AT 250 WORDS)

Tissue distribution of selective warfarin binding sites in the rat

Liver microsomes contain a specific warfarin binding site that is related to the target enzyme vitamin KO reductase [Thijssen HHW and Baars LGM, Biochem Pharmacol 38: 1115-1120, 1989]. In this study the distribution of the warfarin binder in the rat was investigated. Rats were given tracer doses of [14C]warfarin and tissue distribution was estimated after a time period. The selectivity of the distribution was verified by the ability of unlabeled warfarin to displace in vivo the tissue accumulated [14C]warfarin. The relation to the target enzyme vitamin KO reductase was verified by comparing the results with distribution behavior in the Scottish warfarin-resistant rat strain. The results show that in addition to liver various non-hepatic tissues accumulate warfarin. Among the tissues having a high accumulation ratio and a high rate of exchange by unlabeled warfarin are liver, pancreas, kidney, and salivary gland. Also arteria (aorta), bone, lung and spleen show exchangable [14C]warfarin accumulation. In HS rats the [14C]warfarin distribution was affected similarly for all tissues; lower levels of accumulation and higher rates of exchange by unlabeled warfarin. The tissue-bound warfarin was recovered predominantly in the microsomal fraction. Its release could only be accomplished in the presence of dithiothreitol and appeared to be stereoselective. The in vivo distribution pattern correlated with the number of warfarin binding sites in the tissue microsomes. The microsomal vitamin KO reductase activity did not always correlate to the binding capacity. The distribution was not affected by vitamin K deficiency. Warfarin-treated rats showed vitamin K epoxide accumulation in most of the organs having the warfarin binder.

The long-term effects of the rodenticide, brodifacoum, on blood coagulation and vitamin K metabolism in rats

1. The long-term (30 days) effects of a single dose of brodifacoum (0.2 mg kg-1, orally) on blood clotting activity and on liver parameters of the vitamin K cycle were investigated in rats. Maximal effect on blood clotting activity was seen on day one. On day seven blood clotting activity had returned to normal. 2. Liver microsomal vitamin KO reductase activity was maximally suppressed (10% of control activity) on day one, steadily recovered to about 40% on day 15 to remain at that level. The same time course was seen for the number of microsomal warfarin binding sites. 3. The persistent inhibition of the vitamin K cycle was also verified in vivo; following vitamin K administration (10 mg kg-1, i.v.) on day 30, the brodifacoum-treated rats accumulated vitamin KO in the liver. 4. Although clotting factor synthesis was normal, brodifacoum-treated rats were highly sensitive to warfarin. 5. Brodifacoum rapidly accumulated in the liver until the saturation of the microsomal binding site. Brodifacoum binding to the target prevented its elimination from the liver; liver content on day 30 was not different from day 7. 6. The results show (1) an over capacity for the hepatocellular vitamin K cycle, (2) a dissociation of the vitamin K epoxidation and the vitamin K-dependent carboxylation, (3) the 'superwarfarin' rodenticides to be extremely persistent due to their binding to the target.

A fibroblast cell culture model to study vitamin K metabolism and the inhibition of vitamin K epoxide reductase by known and suspected antagonists

The metabolism and antagonism of vitamin K has been studied in cultured fibroblasts. Monolayers of 3T3 mouse fibroblasts (grown in the absence or presence of warfarin or other putative antagonists) were incubated for 24 h with [1',2'-3H2]phylloquinone (K1) or [1',2'-3H2]phylloquinone epoxide (K1O), the cells harvested and lipid extracts fractionated by high performance liquid chromatography. [3H]K1 was converted to [3H]K1O (about 20% of [3H] lipids) and to unidentified polar metabolites (30%). [3H]K1O was converted to [3H]K1 (3%) and to polar metabolites (50%). Cells grown with warfarin showed a marked increase in the [3H]K1O:K1 ratio and in the proportion of polar metabolites. The metabolic interconversion of K1 and K1O and inhibitory response to warfarin provide evidence for a fibroblast pathway analogous to the vitamin K-epoxide cycle in the liver. From the K1O:K1 ratios it was possible to grade the antagonism of vitamin K epoxide reductase activity by known and suspected inhibitors. Inhibitory ratios were seen for racemic warfarin down to 10(-8) M. S-warfarin was a more potent antagonist than the R-enantiomer. Consistently low K1O:K1 ratios were observed for N-methyl-thiotetrazole and antibiotics with (moxalactam) or without (cefotaxime) this side chain suggesting that none of these compounds are direct inhibitors of vitamin K epoxide reductase. Fibroblasts grown in cell culture provide a useful model to study the extrahepatic role of vitamin K and the mode of action of vitamin K antagonists.

Warfarin resistance in a Chicago strain of rats

A warfarin-resistant strain of rats trapped in Chicago was studied to determine the mechanism of the warfarin resistance. The Chicago-resistant rats (CR) differ from a Welsh-resistant strain (WR) which has a vitamin K epoxide reductase that is insensitive to warfarin. The epoxide and dithiol-dependent quinone reductases of the CR rats were as sensitive to warfarin as the normal enzyme. Unlike the irreversible warfarin inhibition seen in normal rats, the warfarin inhibition of the epoxide reductase from the CR strain was partially reversible in vitro. In this respect, the CR rats appeared similar to a Scottish warfarin-resistant strain. The same steady-state level of warfarin (40 ng/mg protein) in liver microsomes could be achieved in normal and CR strain rats following a few days ingestion of a diet containing 50 ppm warfarin, but clearance of warfarin (1 mg/kg) from the liver microsomes was more rapid in the CR strain than in normal rats, and the recovery of epoxide reductase activity and prothrombin levels was more rapid. The mechanism of warfarin resistance in the CR strain differed from the warfarin resistance mechanisms of both the Scottish- and Welsh-resistant rat strains. The combination of an increased rate of warfarin clearance and the partially reversible inhibition of the epoxide reductase would be sufficient to allow the rats to survive a limited exposure to warfarin.

Substituted vitamin K epoxide analogues. New competitive inhibitors and substrates of vitamin K1 epoxide reductase

2- and 3-substituted vitamin K 2,3-epoxide analogues were synthesized and tested as inactivators, inhibitors, and substrates for beef liver microsomal vitamin K1 epoxide reductase. 2-(X)-3-phytyl-1,4-naphthoquinone 2,3-epoxides, where X is hydroxymethyl, chloromethyl, fluoromethyl, difluoromethyl, and formyl were all competitive inhibitors, but none was an inactivator. Only the 2-hydroxymethyl analogue was reduced to a quinone that was stable enough under the conditions of the experiment to be detected. Vitamin K1 epoxide analogues with modified phytyl chains (1'-hydroxy, 3'-fluoro with isomerized double bond, 1'-hydroxy and 1'-fluoro with saturated double bond, and the corresponding unsubstituted chains) were synthesized. All of the analogues were competitive inhibitors of vitamin K1 epoxide reductase. The nonfluorinated analogues also were shown to be substrates, being reduced to the corresponding quinone without enzyme inactivation. At least one other enzyme besides vitamin K1 epoxide reductase in beef liver microsomes also metabolizes all of these analogues.

Effect of warfarin on plasma and liver vitamin K levels and vitamin K epoxide reductase activity in relation to plasma clotting factor levels in rats

Changes in plasma and liver vitamin K1 and vitamin K1 epoxide levels, liver microsomal vitamin K epoxide reductase activity, and plasma clotting factor II and VII levels were determined in rats after a single injection of warfarin (2.5 mg/kg, s.c.). The plasma and liver vitamin K1 levels gradually decreased after warfarin injection, attaining the lowest values at 2-3 hrs and remaining low for 48 hrs. They then returned to the control levels at 72 hrs. The changes in vitamin K1 epoxide levels were opposite, with an increase being seen soon after the warfarin injection, the highest values at 3 hrs and a gradual decrease to the initial levels occurring subsequently. The combined levels of vitamin K1 plus vitamin K1 epoxide, however, remained almost constant in both plasma and liver after the warfarin injection. The liver vitamin K epoxide reductase activity decreased to its lowest level soon after the injection and then gradually increased after 12 hrs, but the activity at 72 hrs was only about 30% of the initial activity. The plasma clotting factor levels gradually decreased after the injection, bottomed at 24 hrs and then began to increase, recovering almost to the initial levels at 72 hrs. A positive correlation was found between plasma and liver levels for both vitamin K1 and vitamin K1 epoxide, and the slope of the vitamin K1 epoxide curve was steeper than that for vitamin K1 in the warfarin-treated rats. A similar positive correlation was found for both vitamin K1 and vitamin K1 epoxide after vitamin K1 injection in normal untreated rats, but the slope of the vitamin K1 epoxide curve was much shallower. These results suggest that warfarin inhibits vitamin K epoxide reductase and decreases blood clotting factor synthesis, thus increasing plasma and liver vitamin K1 epoxide levels. A vitamin K epoxide reductase activity one third of that in normal rats is sufficient to maintain normal reduction of vitamin K1 epoxide and synthesis of blood clotting factors.

Effect of N-ethylmaleimide on beef and rat liver vitamin K1 epoxide reductase

There is little difference in the extent of inactivation of beef liver microsomal vitamin K1 epoxide reductase by N-ethylmaleimide (NEM) whether or not the microsomes are pre-treated with dithiothreitol (DTT). The rat liver microsomal enzyme, however, is inactivated by NEM to a much greater extent if the microsomes are pre-treated with DTT. The beef liver enzyme activity is protected from NEM inactivation by the substrate, vitamin K1 epoxide. Ping-pong kinetics are exhibited by the beef liver enzyme. These results support a mechanism for vitamin K1 epoxide reductase in which the function of the required dithiol is to reduce an active site disulfide bond; however, the geometry of the active sites of the enzyme from rat and beef may be different.

Temporal variation in the effects of warfarin on the vitamin K cycle

In this in vivo study, the time-dependent effect of oral sodium warfarin was studied in male rats synchronized under a 12-hr light-dark cycle (light 0600-1800). Groups of 5 animals received an oral dose of 500 micrograms/kg of warfarin or saline at 0600 or 1800 and 1 mg/kg of vitamin K 8 hr later and the rats were sacrificed 240 min after vitamin K administration. The activities of the vitamin K reductase and vitamin K epoxide reductase were measured indirectly by determining the content of vitamin K1 and vitamin K epoxide reductase in the plasma and liver. The data obtained in control rats indicated that vitamin K and vitamin K 2,3 epoxide concentrations in plasma and liver were higher (P less than 0.05) at 1800 than at 0600. Warfarin had a greater (P less than 0.05) inhibitory effect on the vitamin K and vitamin K-epoxide reductases at 0600 compared to 1800; plasma levels of S- and R-warfarin did not vary with time of administration. The findings suggest that the activity of both reductases under control conditions, and the warfarin-induced inhibition of these enzymes varied depending on the time of drug administration.

Vitamin K-dependent carboxylase: partial purification of the enzyme by antibody affinity techniques

The vitamin K-dependent carboxylase activity of bovine liver microsomes has been purified 500-fold by adsorption to an antiprothrombin column and elution with a dodeca peptide which competes with a prothrombin precursor enzyme recognition site. The purified enzyme is devoid of bound precursors, and has the same ratio of vitamin K epoxidase activity to carboxylase activity as the crude microsomal preparation.

2-(Fluoromethyl)-3-phytyl-1,4-naphthoquinone and its 2,3-epoxide. Inhibition of vitamin K epoxide reductase

2-(Fluoromethyl)-3-phytyl-1,4-naphthoquinone (7) was synthesized from the known compound 2-bromo-3-methyl-1,4-dimethoxynaphthalene by N-bromosuccinimide bromination of the 3-methyl group, conversion to the corresponding 3-fluoromethyl compound with silver fluoride, attachment of the 3-phytyl substitutent via the lithium diaryl cuprate and phytyl bromide, and then silver oxide oxidation to 7. Epoxidation with basic hydrogen peroxide gave the corresponding 2,3-oxide (1) in a very low yield. Compound 1 was not a time-dependent inhibitor of beef liver microsomal vitamin K epoxide reductase, but it was a competitive, reversible inhibitor. It was not possible to determine if 1 was a substrate for the enzyme because the expected product of reduction, namely 7, rapidly decomposed under the assay conditions.

Depression of liver microsomal vitamin K epoxide reductase activity associated with antibiotic-induced coagulopathy

Hypoprothrombinemic changes in blood coagulation parameters, such as prolongation of prothrombin time, increase in the level of plasma protein induced by vitamin K absence, and decrease in plasma prothrombin level, were detected in rats fed a vitamin K-deficient diet. These changes were enhanced by the administration of beta-lactam antibiotics containing N-methyltetrazolethiol, thiadiazolethiol or methyl-thiadiazolethiol. Microsomal vitamin K epoxide reductase activity was suppressed with the maximum effect at 1-2 days after the treatment and with recovery, thereafter, gradually to the normal level after 5-7 days. Hypoprothrombinemic alterations in blood coagulation parameters following a single administration of antibiotic to vitamin K-deficient rats were somewhat delayed compared with the change in the epoxide reductase activity, but the effects of the antibiotic on both blood coagulation parameters and the enzyme activity disappeared completely 7 days after the antibiotic treatment. Antibiotic-induced depression of the epoxide reductase activity was observed even in the vitamin K sufficient rats, although the hypoprothrombinemic changes in the blood coagulation parameters did not develop. Vitamin K administration could normalize the blood coagulation parameters in the hypoprothrombinemic rats caused by treatment with the antibiotics but without recovery of the decreased epoxide reductase activity. These results suggest that some antibiotics inhibit liver microsomal vitamin K epoxide reductase, which causes hypoprothrombinemia to develop under vitamin K-deficient conditions.

Male infant with ichthyosis, Kallmann syndrome, chondrodysplasia punctata, and an Xp chromosome deletion

We report on a male infant with X-linked ichthyosis, X-linked Kallmann syndrome, and X-linked recessive chondrodysplasia punctata (CPXR). Chromosome analysis showed a terminal deletion with a breakpoint at Xp22.31, inherited maternally. This patient confirms the localization of XLI, XLK, and CPXR to this region of the X chromosome and represents an example of a "contiguous gene syndrome." A comparison of the manifestations of patients with CPXR, warfarin embryopathy, and vitamin K epoxide reductase deficiency shows a remarkable similarity. However, vitamin K epoxide reductase deficiency does not appear to be the cause of CPXR. We propose that CPXR may be due to a defect in a vitamin K-dependent bone protein such as vitamin K-dependent bone carboxylase, osteocalcin, or matrix Gla protein.

Microsomal warfarin binding and vitamin K 2,3-epoxide reductase

Rat liver microsomal 4-hydroxycoumarin binding was studied by assaying specific [14C]warfarin binding. Microsomes of warfarin-sensitive rats contained about 40 pmole of specific binding sites per mg of microsomal protein. There was no difference for R- or S-[14C]warfarin. Neither was there any difference between the enantiomers of acenocoumarol and phenprocoumon to prevent the in vitro racemic [14C]warfarin binding. Pretreatment of the microsomes with dithiothreitol, the in vitro reductor for microsomal vitamin K epoxide reductase activity, reduced the warfarin binding. Vitamin K epoxide nor vitamin K affected the warfarin binding. Microsomes of the Welsh warfarin resistant genotype showed weak warfarin binding properties. The Scottish resistant variant, on the other hand, did not differ from sensitive microsomes. Warfarin binding was reduced in microsomes of rats to which S-warfarin was administered. The reduction in warfarin binding was linear with the inhibition of microsomal vitamin K epoxide reductase activity and was linear with the amount of S-warfarin present in the microsomes. The results show the microsomal 4-hydroxycoumarin binding to be related to the target enzyme vitamin K epoxide reductase.

Sulfaquinoxaline inhibition of vitamin K epoxide and quinone reductase

Sulfaquinoxaline (N1-(2-quinoxalinyl)sulfanilamide) has been shown to be a potent (Ki = 1 microM) freely reversible inhibitor of the dithiothreitol-dependent reduction of both vitamin K epoxide and vitamin K quinone by rat liver microsomes in vitro. This observation provides an explanation for the hemorrhagic syndrome occasionally seen in poultry on medicated feed and the efficacy of sulfaquinoxaline in anticoagulant based rodenticides. Sulfaquinoxaline inhibition resembled inhibition by coumarin anticoagulants (e.g., warfarin) and hydroxynaphthoquinones (e.g., lapachol). Inhibition was observed in assays using microsomes from control strain rats, but the enzyme was resistant to sulfaquinoxaline in microsomes from warfarin-resistant rats. Steady-state kinetics inhibition patterns were nearly competitive versus dithiothreitol and nearly uncompetitive versus vitamin K epoxide as is observed for warfarin and lapachol. These results suggest that this inhibitor binds to the oxidized form of vitamin K epoxide reductase in the same way as suggested for the coumarins and hydroxyquinones. Of 10 other sulfa drugs tested, none were inhibitors, and of fragments and related compounds tested, only 2-aminoquinoxaline benzenesulfonamide was active. These results provide a probably orientation in the binding site in relation to that for warfarin and lapachol.