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DOI: 10.1055/s-0038-1656123
Positive Association of the β Fibrinogen H1/H2 Gene Variation to Basal Fibrinogen Levels and to the Increase in Fibrinogen Concentration during Acute Phase Reaction but not to Coronary Artery Disease and Myocardial Infarction
Publikationsverlauf
Received 23. September 1996
Accepted after revision 28. Februar 1997
Publikationsdatum:
12. Juli 2018 (online)
Summary
Background: Fibrinogen has been demonstrated to be an independent risk factor of cardiovascular disease. The absence of the Haelll cutting site (H2 allele) of an H1/H2 gene variation in the promoter region of the (β fibrinogen gene was associated with increased levels of fibrinogen. Methods and Results: In the present study, the effects of the H1/H2 gene variation not only on plasma fibrinogen concentrations but also on coronary artery disease (CAD) and myocardial infarction (MI) were investigated in 923 individuals who underwent coronary angiography for diagnostic purposes. Relation of the H1/H2 genotype to fibrinogen plasma levels: A strong association was observed between the H1/H2 gene variation and fibrinogen levels. The differences in fibrinogen plasma levels between H2H2 and H1H1 homozygotes were almost threefold more pronounced within subjects with clinical chemical signs of an acute phase reaction (CRP ≥ 7.5 mg/1) than within a subgroup of subjects without these signs (CRP < 7.5 mg/1) (median of CRP distribution: 7.5 mg/1). In 207 patients who underwent aortocoronary bypass surgery plasma fibrinogen levels were almost identical directly after surgery. Two days after operation fibrinogen increased to clearly higher levels in H2H2 homozygotes than in H1H2 and H1H1 genotypes, whereas almost the same maximal increases in fibrinogen concentrations were reached 3-4 days after surgery in all individuals. Relation of the H1/H2 genotype to CAD and MI. Whereas in the total population the plasma fibrinogen concentrations were strongly associated with smoking, CAD and MI, an association of the H1/H2 gene variation to CAD and MI was not detected. However, mean age at first MI of H2H2 individuals (62.9 years) was clearly higher than of H1H2 genotypes (56.9 years) and of H1H1 subjects (56.4 years). In addition, in a subgroup of individuals with a higher risk of MI by either high apoB and/or low apoAl plasma levels the portion of MI patients was clearly smaller within H2H2 homozygotes than within H1H2 or H1H1 genotypes, although – also in these high risk groups – mean age at first MI of H2H2 individuals were higher than of the other two genotypes.
Conclusions: Obviously, the H2 allele of the fibrinogen H1/H2 genotype does not only influence basal fibrinogen concentrations, but particularly also the extent of fibrinogen level increase during acute phase reaction. Whereas the fibrinogen plasma level is positively associated with coronary artery disease and myocardial infarction, the H2 allele - although exhibiting an association with elevated fibrinogen levels - was not positively associated with CAD and MI.
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