We have shown an association between a common mutation in the factor XIII a-subunit gene, coding for an amino acid change, 3 amino acids from the thrombin activation site (factor XIII Val34Leu) that may protect against myocardial infarction and predisposes to intracranial hemorrhage. To investigate the possible role of factor XIII Val34Leu in the pathogenesis of venous thromboembolism (VTE) and potential interactions with factor V Leiden (FV:Q506) and prothrombin G → A 20210, we studied 221 patients with a history of VTE and 254 healthy controls. Patients with VTE showed an increased frequency of the FXIII Val/Val genotype (63% v 49%) and a lower frequency of the Val/Leu genotype (31% v 42%) than controls (P = .007). FV:Q506 heterozygotes were more frequent in VTE patients (11%) than controls (5%; P = .04). The prothrombin G → A 20210 mutation was present in only 3 patients and no controls (P = .10). In a logistic regression model for a history of VTE, the odds ratio (95% confidence interval) for FXIII Val/Leu or Leu/Leu genotype was 0.63 (0.38 to 0.82) and for possession of FV:Q506 2.40 (1.17 to 4.90). There was no evidence for an interaction between factor XIII Val34Leu genotype and FV:Q506, prothrombin G → A 20210, sex, or age. It is concluded that possession of the Leu allele at factor XIII Val34Leu is protective against deep venous thrombosis.

GENETIC FACTORS may be implicated in the pathogenesis of at least 30% of cases of venous thrombosis. The most common inherited form of venous thrombosis is the result of resistance to activated protein C (APC). In the majority of cases, the molecular basis for APC resistance is a single point mutation arising in the factor V gene (FV:Q506, Factor V Leiden).1 

We have recently reported that a common point mutation (G → T) in exon 2 of the factor XIII a-subunit gene is protective against myocardial infarction2 and predisposes to intracerebral hemorrhage.3 This polymorphism codes for a valine (Val) to leucine (Leu) amino acid change 3 amino acids from the factor XIII thrombin activation site, and our results imply that this may interfere with fibrin cross-linking.

Fibrin formation is important in the development of venous thromboembolism (VTE), indicating that possession of the factor XIII 34Leu allele might interfere with this process. The aim of this study was to investigate an association of factor XIII Val34Leu with VTE and to evaluate possible interactions between FV:Q506 and prothrombin G → A 20210.

Study Population

Patients.

Two hundred twenty-six consecutive patients with a clinical diagnosis of VTE, attending the Leeds General Infirmary anticoagulation clinic between January 1, 1997 and October 31, 1997, which serves a population of approximately half a million, were recruited by one of the authors (A.J.C.). Patients with first ever as well as recurrent VTE were recruited. Five patients were excluded from the study (2 were not White North European, for 2 there was inadequate clinical information, and for 1 there was an insufficient sample for analysis), leaving a VTE study population of 221.

Controls.

Two hundred fifty-four White North European patients were drawn from the same geographical area as the patients and identified at random from age-stratified registers of general medical practitioners serving the Leeds Family Health Authority. These community control patients were invited to participate by postal questionnaire, with a response rate of 71%. There were no demographic differences between those patients who participated and those who did not. At the time of recruitment, control patients were free from a personal history and family history of VTE.

The study was approved by the United Leeds Teaching Hospitals Trust Research Ethics Committee.

Clinical Details

In the patient group, 122 (55%) patients had sustained a deep venous thrombosis (DVT), confirmed on Doppler ultrasound venogram examination of the calf, popliteal, femoral, and iliac veins. Ninety-nine patients (45%) had a clinical diagnosis of pulmonary embolism (PE), of which 82 had no evidence of DVT and 17 had evidence of both DVT and PE (the latter were classified as cases of PE for the purpose of the analysis). Confirmation of the clinical diagnosis of PE was based on the presence of either two or more areas of ventilation-perfusion mismatch on a Technicium99 lung scan or the presence of thrombus in the pulmonary vasculature confirmed by contrast-enhanced high-resolution spiral computed tomography (CT). CT examination was reserved for those patients with an intermediate probability of PE on lung scanning (n = 15).

DNA procedures.

Genomic DNA was extracted from peripheral leukocytes in citrated blood using the Nucleon kit (Nucleon Biosciences, Lanarkshire, UK). Using a polymerase chain reaction (PCR)-single-stranded confirmational polymorphism (SSCP) method the FXIII Val34Leu polymorphism was reported as Val/Val (G/G), Val/Leu (G/T), or Leu/Leu (T/T).2 A PCR method1 and Mnl I digest was used to type the FV:Q506 mutation. The prothrombin G → A 20210 mutation was characterized by a mutagenic primer sequence and HindIII digest.4 Heterozygous prothrombin mutants were confirmed by direct sequencing. Each genotype was analyzed without knowledge of case or control status.

Statistical methods.

Values for age were not normally distributed and are presented as median (range) and compared between groups using the Mann-Whitney test. The frequencies of dichotomous variables (sex, history of cancer, FV:Q506, and prothrombin genotypes) were compared between patients and controls using Fisher’s exact test. Frequencies of Factor XIII genotypes were compared using the chi-squared test. Logistic regression analysis was used to identify factors significantly and independently associated with a history of VTE.

As shown in Table 1, the 221 patients of VTE had a median age 2 years older than the 254 control patients, although there was a similar distribution of sexes in each group. Of the 221 patients, in 122 there was evidence of DVT only, whereas in the remaining 99 there was evidence of PE with or without clinically detectable DVT. A history of malignancy was more frequent in patients of VTE than in control patients.

Table 1.

Characteristics and Genotype Data in Cases of Venous Thromboembolism and Control Patients

VTE Patients Controls P
Number  221 254  
DVT only:PE  122:99  
Male:female  127:94 147:107  NS  
Age (yr)  62 (28-74)  60 (27-67) <.005  
History of malignancy  28 (13%)  9 (4%) <.005  
Factor XIII Val34Leu genotype    .007 
 Val/Val (G/G)  137 [63 (57-70)%] 123 [49 (43-55)%]  
 Val/Leu (G/T) 68 [31 (25-38)%]  107 [43 (36-49)%]  
 Leu/Leu (T/T)  12 [6 (3-7)%]  22 [9 (5-12)%]  
Factor V genotype    .03  
 Wild-type  191 [89 (85-93)%] 237 [94 (91-97)%]  
 FV:Q506 carriers 24 [11 (7-15)%]  15 [6 (3-9)%]  
Prothrombin 20210A genotype    .10  
 Wild-type  218  254  
 G-A 20210A mutation carriers  3  
VTE Patients Controls P
Number  221 254  
DVT only:PE  122:99  
Male:female  127:94 147:107  NS  
Age (yr)  62 (28-74)  60 (27-67) <.005  
History of malignancy  28 (13%)  9 (4%) <.005  
Factor XIII Val34Leu genotype    .007 
 Val/Val (G/G)  137 [63 (57-70)%] 123 [49 (43-55)%]  
 Val/Leu (G/T) 68 [31 (25-38)%]  107 [43 (36-49)%]  
 Leu/Leu (T/T)  12 [6 (3-7)%]  22 [9 (5-12)%]  
Factor V genotype    .03  
 Wild-type  191 [89 (85-93)%] 237 [94 (91-97)%]  
 FV:Q506 carriers 24 [11 (7-15)%]  15 [6 (3-9)%]  
Prothrombin 20210A genotype    .10  
 Wild-type  218  254  
 G-A 20210A mutation carriers  3  

Values for age are median (range). Square brackets enclose percentages and 95% confidence intervals.

Abbreviation: NS, not significant.

The distribution of genotypes at the Factor XIII Val34Leu polymorphism was different between patients and controls with fewer Val/Leu and Leu/Leu patients and more Val/Val patients among patients. At the factor V polymorphism there were more carriers of the FV:Q506 mutation in patients than in controls. The prothrombin G → A 20210 mutation was infrequent, being found in 3 patients and no controls. This difference was not significant.

In a logistic regression model factor XIII Val34Leu genotype, FV:Q506, age, and a history of malignancy were independently related to VTE (Table 2). The assumption that the more frequent Val allele was recessive in relation to VTE gave the best fitting model. When Factor XIII Val34Leu genotype was assumed to have a codominant influence of risk of VTE, the odds ratio (95% confidence interval) for possession of each additional Leu allele was 0.63 (0.47 to 0.87; P = .004). When factor XIII genotype was entered with the Val allele being dominant, there was no significant relationship to history of VTE. Sex showed no independent association with VTE. In view of the low frequency of the prothrombin gene mutation, prothrombin was not included in the regression model. There was no evidence of interaction between Factor XIII and FV:Q506 polymorphisms nor with age or history of malignancy.

Table 2.

Logistic Regression Model for History of Venous Thromboembolism

Odds Ratio P
Factor XIII Val/Leu or Leu/Leu genotype  0.56 (0.38-0.82)  .003  
Factor V:Q506mutation carrier  2.40 (1.17-4.90)  .017  
Age (for 10-yr increase)  1.17 (1.04-1.32)  .009  
History of malignancy 3.29 (1.47-7.35)  .004  
Male sex  1.09 (0.74-1.60) NS 
Odds Ratio P
Factor XIII Val/Leu or Leu/Leu genotype  0.56 (0.38-0.82)  .003  
Factor V:Q506mutation carrier  2.40 (1.17-4.90)  .017  
Age (for 10-yr increase)  1.17 (1.04-1.32)  .009  
History of malignancy 3.29 (1.47-7.35)  .004  
Male sex  1.09 (0.74-1.60) NS 

Values are shown for odds ratio with 95% confidence interval in brackets.

Abbreviation: NS, not significant.

The associations with genotype were reexamined in the patients divided into those with DVT only and cases of PE. Both Factor XIII Val34Leu (P = .025) and FV:Q506 (P = .026) were related to DVT, but there was no significant association with PE (Table 3).

Table 3.

Genotype Frequencies at the Factor V:Q506and Factor XIII Val34Leu Polymorphisms in Subjects With DVT and Pulmonary Embolism

DVT Only Pulmonary Embolism Control Patients
Number  122  99  254  
Factor V genotype 
 Wild-type  104  87  237  
 FV:Q506 16 8  15  
FXIII Val34Leu genotype  
 Val/Val (G/G)  76 61  123  
 Val/Leu (G/T)  36  32  107  
 Leu/Leu (T/T)  7  5  22 
DVT Only Pulmonary Embolism Control Patients
Number  122  99  254  
Factor V genotype 
 Wild-type  104  87  237  
 FV:Q506 16 8  15  
FXIII Val34Leu genotype  
 Val/Val (G/G)  76 61  123  
 Val/Leu (G/T)  36  32  107  
 Leu/Leu (T/T)  7  5  22 

DVT versus controls significant at P < .026 at both factor V and factor XIII polymorphisms. Other comparisons not significant.

This study shows an inverse association between possession of the Leu allele at factor XIII Val34Leu and the occurrence of DVT. These results are consistent with the hypothesis that the previously described protective effect of factor XIII 34Leu against myocardial infarction2 extends to venous thrombosis. However, the findings should be interpreted in the context of a case-control study design, and our findings require confirmation in a prospective study.

The formation of cross-linked fibrin from fibrin monomer is pivotal in the development of a stable thrombus. This process requires the action of thrombin on fibrinogen to produce soluble fibrin and the activation of Factor XIII, which cross-links fibrin, rendering it more resistant to fibrinolysis. Until recently, there has been no knowledge regarding the role of factor XIII in vascular disease. We have shown a lower prevalence of carriage of the Leu allele at factor XIII Val34Leu in patients with myocardial infarction than without (32% v50%).2 The odds ratio (OR) was 0.67 for a history of myocardial infarction in those carrying the Leu allele, which was similar to the OR of 0.56 in patients with VTE in the current study.

Further evidence for a biological effect of this polymorphism is derived from patients with primary intracerebral hemorrhage3 in whom we showed an excess of the factor XIII Leu allele. These findings support the hypothesis that factor XIII 34Leu is involved in the production of weaker fibrin structures, which might thereby protect against clot formation and predispose to hemorrhage.

Although we confirmed the expected association of FV:Q506with DVT, there was no interaction between FV:Q506 and factor XIII Val34Leu, although this might be accounted for by the smaller numbers bearing the FV:Q506 mutation and requires further investigation.

There was no significant association between factor XIII Val34Leu or FV:Q506 and risk of PE, which is consistent with a previous study of APC resistance and PE.5 However, this may simply reflect the reduced power to detect differences when data are subdivided, particularly as there was no evidence of heterogeneity in factor XIII or factor V genotype frequencies between patients of DVT and PE, respectively. If confirmed, a difference in the relationship of factor XIII Val34Leu genotype with DVT and PE would raise the possibility that differences in fibrin cross-linking may affect the clinical presentation in terms of embolization.

Although this study does not provide direct evidence for functional effects of factor XIII Val34Leu, preliminary experiments from our Unit have shown that using a pentylamino-incorporation assay (based on the method of Song6), factor XIII 34Leu shows an increased rate of activation by thrombin. Indeed, the rate of activation increases with increasing numbers of Leu alleles, and plasma from patients with the Leu/Leu genotype shows enhanced activation and degradation by α-thrombin compared with plasma from Val/Val patients, suggesting an alteration in FXIII function (unpublished observation, April 1998).

We have previously shown that in the small number of patients both carrying the factor XIII Leu allele and with acute myocardial infarction, PAI-1 levels were higher,2 suggesting that impairment of fibrinolysis negates the protective effect of factor XIII 34Leu. These findings indicate that the influence of factor XIII Val34Leu on myocardial infarction depends on complex interactions with other hemostatic factors. Although we have not shown this to be the case for factor V Leiden and prothrombin G → A 20210 in the present study, this is an area worthy of further investigation in relation to venous thrombosis.

In conclusion, these data suggest that possession of the Leu (T) allele at the factor XIII Val34Leu polymorphism is protective against VTE and provides further evidence for a role for factor XIII in thrombotic vascular disorders.

We thank our administrative officer, Christine Townsend, for her invaluable assistance with this study.

Supported by the Swiss Foundation for Medical-Biological grants (H.P.K.).

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked “advertisement” in accordance with 18 U.S.C. section 1734 solely to indicate this fact.

1
Bertina
RM
Koeleman
BPC
Koster
T
Rosendaal
FR
Dirven
RJ
de Ronde
H
van der Velden
PA
Reitsma
PH
Mutation in blood coagulation factor V associated with resistance to activated protein C.
Nature
369
1994
64
2
Kohler
HP
Stickland
MH
Ossei-Gerning
N
Carter
AM
Mikkola
H
Grant
PJ
Association of a common polymorphism in the factor XIII gene with myocardial infarction.
Thromb Haemost
79
1998
8
3
Catto
AJ
Kohler
HP
Bannan
S
Stickland
MH
Carter
AM
Grant
PJ
Factor XIII gene Val34Leu genotype: A novel association with primary intracerebral haemorrhage.
Stroke
29
1998
813
4
Poort
SR
Rosendaal
FR
Reitsma
PH
Bertina
RM
A common genetic variation in the 3′-untranslated region of the prothrombin gene is associated with elevated plasma prothrombin levels and an increase in venous thrombosis.
Blood
88
1996
3698
5
Desmarais
S
Moerloose
P
Reber
G
Minazio
P
Perrier
A
Bounameaux
H
Resistance to activated protein C in an unselected population of patients with pulmonary embolism.
Lancet
347
1996
1374
6
Song
YC
Sheng
DQ
Taubenfeld
SM
Matsueda
GR
A mictrotiter assay for factor XIII using fibrinogen and biotin cadaverine as substrate.
Anal Biochem
223
1994
88

Author notes

Address reprint requests to Andrew J. Catto, BSc MRCP, Unit of Molecular Vascular Medicine, G Floor, Martin Wing, Leeds General Infirmary, Leeds, LS1 3EX; e-mail: a.j.catto@leeds.ac.uk.

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