VKORC1 and CYP2C9 polymorphisms are used to predict the safe dose of oral anticoagulant therapy. A new variant of CYP4F2 (V433M) has recently been related to the required warfarin dose. We evaluated its influence in earliest response to acenocoumarol in 100 selected men who started anticoagulation (3 mg for 3 consecutive days). V433M genotype exerted a gene dosage-dependent effect on the decrease of factors II, VII, IX, and X in the earliest response to acenocoumarol, with homozygous 433V subjects being the most sensitive. Similarly, after the initiation of therapy, international normalized ratio also experienced a gene dosage-dependent effect (P = .015), and 433V subjects needed 4 mg/week less than 433M carriers to achieve a steady anticoagulation (P = .043). Multivariate linear regression analysis revealed a significant contribution of V433M polymorphism to variability of both early international normalized ratio value (R2 = 0.14) and dose requirements (R2 = 0.19). Our data underline the relevant role of CYP4F2 V433M polymorphism in the pharmacogenetics of coumarin anticoagulants.

The initiation of oral anticoagulation therapy is associated with one of the highest adverse event rates for any single drug.1  Up to one-half of patients with atrial fibrillation and no contraindication to warfarin therapy, who are at high risk of stroke, are currently not receiving anticoagulant therapy because physicians are often reluctant to initiate it in elderly patients or patients with risk of bleeding.2  In addition, the initiation of this therapy is always critical and the stabilization is difficult during the first weeks and the risk higher.3  Moreover, the broad variability in patient response also modulates the initial risk. It is now well known that common genetic polymorphisms have a strong influence on the interindividual coumarinics response. In extensively studied white populations, CYP2C9 genotype predicts approximately 10% of the interpatient variability in warfarin dose. Similarly, in white and Asian populations, VKORC1 genotype predicts 25% of such variability, with similar results for acenocoumarol.4  The importance of these strong genetic effects was recognized by recent relabeling of warfarin by the Food and Drug Administration to raise awareness in the clinical community.5  However, it is important to note that patient demographics, clinical factors, and (known) genetic variants combined only explain 45% to 55% of the total dose variant.6  From the recently published studies using genome-wide scan strategy for common genetic variants with influence of warfarin response, it could be concluded that none of the other candidate genes (besides VKORC1 and CYP2C9) will exert such a deep influence in response.6,7  These data do not discard, however, the fact that single nucleotide polymorphisms (SNPs) in new genes could also be involved in intermediate phenotypes, so explaining the modest percentages in interpersonal variability and hence be involved in the risk of therapy. In this vein, Caldwell et al8  used the Affymetrix (Santa Clara, CA) drug-metabolizing enzymes and transporters panel recently to describe that a variant in cytochrome P450 4F2 (CYP4F2) (rs2108622, V433M) influences warfarin requirements in long-term treatment patients. We have evaluated the role of CYP4F2 V433M polymorphism on acenocoumarol by analyzing the earliest response in a well-defined sample of patients starting therapy

We have analyzed the CYP4F2 V433M SNP on a previously selected sample9  of 100 white men younger than 75 years (62.2 ± 6.5 years; ± SD), of similar weight (body surface area [BSA], 1.81 ± 0.15 m2; ± SD), with nonvalvular atrial fibrillation, who were not taking any medication known to interfere with acenocoumarol and who started anticoagulation therapy with 3 mg acenocoumarol for 3 consecutive days. We evaluated the initial response over 3 consecutive days by analyzing the reduction in vitamin K-dependent hemostatic proteins and by considering its overall anticoagulant effect (international normalized ratio [INR]) according to V433M genotype. The dose needed to achieve a steady anticoagulation (INR = 2-3) recorded after 3 months was also evaluated. Plasma levels of clotting factors were determined using human immunodepleted plasma, based on the prothrombin time (factors II, VII, and X [FII, FVII, and FX, respectively]) or on the partial activated thromboplastin time (factor IX [FIX]; ACL 3000 with HemosIL reagents [Instrumentation Laboratory, Lexington, MA]).

Genotyping of other candidate SNPs has recently been published.9,10  Genotyping of V433M was performed by a validated TaqMan Drug Metabolism Genotyping Assay C_16179493_40 (Applied Biosystems, Foster City, CA). The frequency observed for V433M SNP (Table 1) was similar to that described for other white populations8,11  and to that previously described in the HapMap.

Table 1

Coagulation factors after 3 days of acenocoumarol treatment and response to anticoagulant therapy according to CYP4F2 V433M and VKORC1 C1173T genotypes

CYP4F2 V433M
VKORC1 C1173T
VVVMMMPβ coefficient (P)*CCCTTTPβ coefficient (P)*
41 42 17 NA NA 37 67 NA NA 
FII 60 ± 12 66 ± 17 70 ± 11 .005 0.263 (.013) 66 ± 11 64 ± 15 61 ± 12 .445 0.009 (.930) 
FVII 12 (7-24) 25 (13-44) 38 (22-47) .001 0.274 (.010) 27 (14-38) 20 (10-45) 8.5 (6-14) .044 −0.013 (.904) 
FIX 45 ± 21 59 ± 25 60 ± 15 .016 0.307 (.003) 52 ± 15 54 ± 26 32 ± 14 .002 −0.062 (.546) 
FX 52 ± 14 57 ± 21 63 ± 15 .082 0.203 (.055) 43 ± 12 56 ± 19 58 ± 18 .920 0.035 (.743) 
INR 2.32 (1.72-3.20) 1.84 (1.50-2.27) 1.56 (1.34-2.04) .015 −0.277 (.007) 1.74 (1.30-2.09) 2.03 (1.69-2.79) 2.96 (2.18-3.92) .023 0.236 (.020) 
Dose, mg/week§ 15.3 ± 5.7 18.6 ± 6.0 18.8 ± 5.6 .043 0.265 (.006) 19.6 ± 5.9 16.0 ± 5.66 13.7 ± 4.7 .018 −0.321 (.001) 
CYP4F2 V433M
VKORC1 C1173T
VVVMMMPβ coefficient (P)*CCCTTTPβ coefficient (P)*
41 42 17 NA NA 37 67 NA NA 
FII 60 ± 12 66 ± 17 70 ± 11 .005 0.263 (.013) 66 ± 11 64 ± 15 61 ± 12 .445 0.009 (.930) 
FVII 12 (7-24) 25 (13-44) 38 (22-47) .001 0.274 (.010) 27 (14-38) 20 (10-45) 8.5 (6-14) .044 −0.013 (.904) 
FIX 45 ± 21 59 ± 25 60 ± 15 .016 0.307 (.003) 52 ± 15 54 ± 26 32 ± 14 .002 −0.062 (.546) 
FX 52 ± 14 57 ± 21 63 ± 15 .082 0.203 (.055) 43 ± 12 56 ± 19 58 ± 18 .920 0.035 (.743) 
INR 2.32 (1.72-3.20) 1.84 (1.50-2.27) 1.56 (1.34-2.04) .015 −0.277 (.007) 1.74 (1.30-2.09) 2.03 (1.69-2.79) 2.96 (2.18-3.92) .023 0.236 (.020) 
Dose, mg/week§ 15.3 ± 5.7 18.6 ± 6.0 18.8 ± 5.6 .043 0.265 (.006) 19.6 ± 5.9 16.0 ± 5.66 13.7 ± 4.7 .018 −0.321 (.001) 

Normally distributed values are expressed as mean ± SD, and not normally distributed values are expressed as median (interquartile range).

VV indicates homozygous V433 carriers; VM, heterozygous V433 M carriers; MM, homozygous M433 carriers; CC, homozygous C1173 carriers; CT, heterozygous C1173T carriers; TT, homozygous T1173 carriers; and NA, not applicable.

*

Multivariate linear regression analysis, including the effects of VKORC C1173T, CYP2C9, and CYP4F2 as predictors. Results from CYP2C9 genotypes were not significant and thus not shown.

Three days after starting therapy. All factors are IU/mL.

International normalized ratio (INR) 3 days after starting therapy as median (p25-p75).

§

After 3 months of therapy.

Kruskal-Wallis test. The other P values used analysis of variance test.

Comparisons between 2 groups were performed by the analysis of variance test and Kruskal-Wallis test. A multivariate stepwise linear regression model was performed to evaluate the potential contribution of VKORC1, CYP450, and CYP4F2 polymorphisms to interindividual variability in therapeutic acenocoumarol doses and INR value at third day. All analyses were carried out using SPSS version 15.0 software (SPSS, Chicago, IL). Approval for this study was acquired from the Ethic Committee of Morales Meseguer Hospital (Murcia, Spain), and patient informed consent was obtained in accordance with the Declaration of Helsinki.

We evaluated the influence of V433M genotype in the initial response to 3 mg acenocoumarol over 3 consecutive days. To define the weight of CYP4F2 polymorphism more accurately, our experimental design took into account the influence of factors, such as age, BSA, sex, disease, and other drugs.9 

This is the first study to show that V433M polymorphism correlates with the decrease of FII, FVII, FIX, or FX in the earliest response to acenocoumarol, and these effects are gene dosage-dependent. Thus, whereas carriers of the V433V genotype experienced the biggest reduction in all vitamin K–dependent proteins analyzed, heterozygous subjects gave an intermediate response (Table 1). FVII reached the lower levels (12 IU/mL in V433V vs 38 IU/mL in M433M; P = .001), according to the shorter half-life of this factor, which also makes it the most sensitive to anticoagulants.12  The effect of this polymorphism on FX levels showed the same tendency, although differences did not reach statistical significance (Table 1). Such decreases were not related to CYP2C9 genotype.9  Linear regression analysis, including the effects of CYP2C9, VKORC1, and CYP4F2 genotypes, confirmed that only CYP4F2 V433M exerts an independent effect on clotting factors (Table 1).

We consistently observed a deep impact of the V433M genotype on INR after 3 days, which also had a gene dose-dependent effect (Table 1). As shown, V433V patients displayed the highest INR values. Worthy of note was that 6 of 9 patients with INR more than 3.5 after 3 days had V433V genotype.

The dose required to achieve a steady INR was also influenced by CYP4F2 genotype (Table 1), similar to data reported for warfarin therapy8 : 433M carriers needed approximately 4 mg/week more (∼26% increase in dose) than V433V subjects (P = .043; Table 1). However, we did not observe a clear gene dosage-dependent effect in this parameter, as described by Caldwell et al.8  This minor discrepancy may be explained by differences between warfarin and acenocoumarol or the size of our sample. Finally, combined genotypes of VKORC1 and CYP4F2 exacerbated the response. Thus, double homozygous VKORC1 1173T CYP4F2 433V (n = 5) showed the highest INR (3.1; 2.0-4.7) and required the lowest dose (11 ± 3 mg/week).

Results from multivariate linear regression models discarded the overall influence of CYP450 2C9 genotypes (P = .201), BSA (P = .145), and age (P = .071) in our study. The predictor contributions of VKORC1 and CYP4F2 to variability of both early INR and dose are shown in Table 2. Interestingly, the addition of V433M polymorphism to VKORC1 genotype raised the R2 from 8% to 14% for INR and from 12% to 19% for dose requirements.

Table 2

Summary of the additive regression models (stepwise method): predictor contribution to therapeutic dose of acenocoumarol and INR value at third day

R2Pβ coefficient (P)
Acenocoumarol dose    
    VKORC1 0.12 .001 −0.349 (.001) 
    VKORC1 plus CYP4F2 0.19 < .001 −0.334 (.001); 0.229 (.018) 
INR at day 3    
    VKORC1 0.08 .007 0.286 (.007) 
    VKORC1 plus CYP4F2 0.14 .001 0.271 (.007); −0.283 (.005) 
R2Pβ coefficient (P)
Acenocoumarol dose    
    VKORC1 0.12 .001 −0.349 (.001) 
    VKORC1 plus CYP4F2 0.19 < .001 −0.334 (.001); 0.229 (.018) 
INR at day 3    
    VKORC1 0.08 .007 0.286 (.007) 
    VKORC1 plus CYP4F2 0.14 .001 0.271 (.007); −0.283 (.005) 

INR indicates international normalized ratio.

CYP4F2 participates in the inactivation pathway of vitamin E.13  The V433M polymorphism has an effect on the cytochrome function because the 433M variant has decreased activity.14  The role of CYP4F2 in γ-carboxylation or vitamin K cycle is unknown, but it might have a functional effect on warfarin8  and acenocoumarol requirements. Relying on the similarity of the vitamins E and K, CYP4F2 might hydroxylate the vitamin K phytyl side chain, hence interfering in the vitamin K recycling.8  An alternative hypothesis is that CYP4F2 could be involved in the metabolism of acenocoumarol because the V433M polymorphism is associated with significantly different levels of FII, FVII, FIX, and FX only after acenocoumarol, not before therapy.

In conclusion, our data provide new information about the pharmacogenetics of acenocoumarol, as we confirm that the CYP4F2 V433M polymorphism plays a relevant role in the earliest response to acenocoumarol and the required dose. CYP4F2 V433M and VKORC1 genotyping may help to recommend safe doses in patients with a genetic profile associated with poor outcomes when treated by traditional trial-and-error dosing. The answer to the recent controversial question of whether genotyping before dosing would be clinically useful15,17  will require further randomized prospective and large trials that evaluate adverse effect of empiric versus genotype adjustment of doses, but obviously any new genetic element involved in adjustment of therapeutic dose will increase the reliability of pharmacogenetic tests.

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734.

This work was supported by Ministerio de Ciencia y Tecnología (Madrid, Spain), Fondo Europeode Desarrollo Regional (European Union), Red Temática de Investigación Cooperativa en Enfermadades Cardiovasculares (Madrid), Instituto de Salud Carlos III (Madrid) Grant SAF 2006-06212, and Fundación Séneca (Murcia, Spain) Grant 05759/PI/07.

Contribution: V.P.-A. collected patients, was responsible for their management, and analyzed clotting factors; V.R. collected patients, was responsible for their management, analyzed clotting factors, contributed to the design of the research, and performed the statistical analysis; A.I.A. and N.G.-B. were responsible for genetic analysis; J.C. and V.V. contributed to the design of the research; and R.G.-C. contributed to the design of the research and was responsible for genetic analysis. All authors contributed to the writing of the paper. Fundación Séneca (Murcia, Spain) Grant 05759/PI/07.

Conflict-of-interest disclosure: The authors declare no competing financial interests.

Correspondence: Rocio González-Conejero, Centro Regional de Hemodonación, Ronda de Garay s/n, 30003, Murcia, Spain; e-mail: rocio.gonzalez@carm.es.

1
Petty
 
GW
Brown
 
RD
Whisnant
 
JP
Sicks
 
JD
O'Fallon
 
WM
Wiebers
 
DO
Frequency of major complications of aspirin, warfarin, and intravenous heparin for secondary stroke prevention: a population-based study.
Ann Intern Med
1999
5:130
14
22
2
Evans
 
A
Davis
 
S
Kilpatrick
 
C
Gerraty
 
R
Campbell
 
D
Greenberg
 
P
The morbidity related to atrial fibrillation at a tertiary centre in one year: 9.0% of all strokes are potentially preventable.
J Clin Neurosci
2002
9
268
272
3
Ansell
 
J
Hirsh
 
J
Hylek
 
E
Jacobson
 
A
Crowther
 
M
Palareti
 
G
Pharmacology and management of the vitamin K antagonists: American College of Chest Physicians Evidence-Based Clinical Practice Guidelines (8th edition).
Chest
2008
133
suppl 6
160S
198S
4
Rettie
 
AE
Farin
 
FM
Beri
 
NG
Srinouanprachanh
 
SL
Rieder
 
MJ
Thijssen
 
HH
A case study of acenocoumarol sensitivity and genotype-phenotype discordancy explained by combinations of polymorphisms in VKORC1 and CYP2C9.
Br J Clin Pharmacol
2006
62
617
620
5
Gage
 
B
Eby
 
C
Johnson
 
J
et al
Use of pharmacogenetic and clinical factors to predict the therapeutic dose of warfarin.
Clin Pharmacol Ther
2008
84
326
331
6
Cooper
 
GM
Johnson
 
JA
Langaee
 
TY
et al
A genome-wide scan for common genetic variants with a large influence on warfarin maintenance dose.
Blood
2008
112
1022
1027
7
Wadelius
 
M
Chen
 
LY
Lindh
 
JD
et al
The largest prospective warfarin-treated cohort supports genetic forecasting.
Blood
2009
113
784
792
8
Caldwell
 
MD
Awad
 
T
Johnson
 
JA
et al
CYP4F2 genetic variant alters required warfarin dose.
Blood
2008
15:111
4106
4112
9
González-Conejero
 
R
Corral
 
J
Roldán
 
V
et al
The genetic interaction between VKORC1 c1173t and calumenin a29809g modulates the anticoagulant response of acenocoumarol.
J Thromb Haemost
2007
5
1701
1706
10
González-Conejero
 
R
Corral
 
J
Roldán
 
V
Vicente
 
V
Gamma-glutamyl carboxylase R325Q polymorphism on the response of acenocoumarol.
Thromb Res
2008
122
429
431
11
Fava
 
C
Montagnana
 
M
Almgren
 
P
et al
The V433M variant of the CYP4F2 is associated with ischemic stroke in male Swedes beyond its effect on blood pressure.
Hypertension
2008
52
373
380
12
Bernardi
 
F
Arcieri
 
P
Bertina
 
RM
et al
Contribution of factor VII genotype to activated FVII levels: differences in genotype frequencies between northern and southern European populations.
Arterioscler Thromb Vasc Biol
1997
17
2548
2553
13
Sontag
 
TJ
Parker
 
RS
Cytochrome P450 omega-hydroxylase pathway of tocopherol catabolism: novel mechanism of regulation of vitamin E status.
J Biol Chem
2002
12:277
25290
25296
14
Ward
 
NC
Tsai
 
IJ
Barden
 
A
et al
A single nucleotide polymorphism in the CYP4F2 but not CYP4A11 gene is associated with increased 20-HETE excretion and blood pressure.
Hypertension
2008
51
1393
1398
15
Thacker
 
SM
Grice
 
GR
Milligan
 
PE
Gage
 
BF
Dosing anticoagulant therapy with coumarin drugs: is genotyping clinically useful? Yes.
J Thromb Haemost
2008
6
1445
1449
16
Mannucci
 
PM
Spreafico
 
M
Peyvandi
 
F
Dosing anticoagulant therapy with coumarin drugs: is genotyping clinically useful? No.
J Thromb Haemost
2008
6
1450
1452
17
Li
 
C
Schwarz
 
UI
Ritchie
 
MD
Roden
 
DM
Stein
 
CM
Kurnik
 
D
Relative contribution of CYP2C9 and VKORC1 genotypes and early INR response to the prediction of warfarin sensitivity during initiation of therapy.
Blood
2008
12
12
[Epub ahead of print], doi 10.1182/blood-2008-09-176859
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