Association of Genetic Polymorphisms of Fibrinogen, Factor XIII A-Subunit and α2-Antiplasmin with Fibrinogen Levels in Pregnant Women

Schwedler, Christian; Heymann, Guido; Bukreeva, Larisa; Hoppe, Berthold

doi:10.3390/life11121340

Open AccessArticle

Association of Genetic Polymorphisms of Fibrinogen, Factor XIII A-Subunit and α₂-Antiplasmin with Fibrinogen Levels in Pregnant Women

¹

Institute of Laboratory Medicine and Pathobiochemistry, Charité—Universitätsmedizin Berlin, 13353 Berlin, Germany

²

Institute of Laboratory Medicine, Unfallkrankenhaus Berlin, 12683 Berlin, Germany

³

Medicover Berlin-Mitte MVZ, 10117 Berlin, Germany

^*

Author to whom correspondence should be addressed.

Life 2021, 11(12), 1340; https://doi.org/10.3390/life11121340

Submission received: 25 October 2021 / Revised: 26 November 2021 / Accepted: 1 December 2021 / Published: 3 December 2021

(This article belongs to the Section Reproductive and Developmental Biology)

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Abstract

:

Fibrinogen synthesis is stimulated by proinflammatory triggers and depends on α-, β- and γ-fibrinogen (FGA, FGB, FGG) genotypes. Constellations of fibrinogen, factor XIII A-subunit (F13A) and α₂-antiplasmin (A2AP) genotypes predisposing for dense fibrin gels with high antifibrinolytic capacity (e.g., FGB rs1800790 A-allele carriage in F13A 34Val/Val or A2AP 6Arg/Arg wildtypes) are related with reduced inflammation. As both relationships are likely to influence each other, we tested whether the association of fibrinogen genotypes with fibrinogen levels is influenced by F13A and A2AP genotypes in a population under proinflammatory stress. In total, 639 women were followed during pregnancy (2218 observations). The relationship between fibrinogen genotypes and levels was statistically assessed in univariate and multivariate analyses without and with stratification for F13A Val34Leu and A2AP Arg6Trp. Strong associations with fibrinogen levels could be found for FGB rs1800790G > A, FGA rs2070016T > C and FGG rs1049636T > C. For FGB rs1800790G > A and FGA rs2070016T > C, this relationship significantly depended on F13A Val34Leu and A2AP Arg6Trp genotypes. Specifically, in F13A 34Val/Val wildtypes, carriage of FGB rs1800790A was related to significantly lower fibrinogen levels compared with FGB rs1800790GG wildtypes (p < 0.01). For A2AP 6Arg/Arg wildtypes, a comparable relationship could be found (p < 0.04). As these genotype constellations related to lower fibrinogen levels have previously been shown to be associated with reduced inflammatory activity, these findings suggest that the influence of fibrinogen, F13A and A2AP genotypes on inflammation could affect the control of fibrinogen levels and vice versa.

Keywords:

fibrinogen; factor XIII; α₂-antiplasmin; genotype; fibrin crosslinking; inflammation; pregnancy

1. Introduction

Expression of fibrinogen depends on gene loci of α-, β- and γ-fibrinogen (FGA, FGB, FGG) and it is increased by acute-phase responses via interleukin 6 (IL6), glucocorticoids and others [1]. Genetic polymorphisms located at these gene loci influence fibrinogen levels [1], with FGB rs1800790G > A or a strongly linked genotype being consistently associated with higher fibrinogen levels [2]. An influence of this polymorphism on the transcription rate of the fibrinogen β-chain has been described [3,4]. Different studies confirm the relationship between FGB rs1800790G > A and fibrinogen levels in steady-state situations [5] as well as under weak proinflammatory triggers in individuals with unelevated levels of C-reactive protein (CRP) and IL6 [6].

Increasing fibrinogen concentrations are known to result in fibrin clots with increased density and high antifibrinolytic capacity [7]. For this correlation, the factor XIII A-subunit (F13A) 34Val/Val wildtype is a necessary precondition, and it is abrogated in carriers of the polymorphism F13A 34Leu allele [7]. For full antifibrinolytic capacity of these dense fibrin clot structures, strong incorporation of α₂-antiplasmin (A2AP) is necessary, which is highest in A2AP 6Arg/Arg wildtypes [8]. Recently, we described an interaction between fibrinogen, F13A and A2AP genotypes and inflammation, which could be detected in different cohorts under proinflammatory stimulation [9,10]. Carriage of fibrinogen genotypes known to be related to higher fibrinogen levels at steady-states (e.g., carriage of FGB rs1800790G > A minor allele(s)) were associated with reduced inflammatory activity if the presence of the F13A 34Val/Val wildtype gave the optimal background for highly crosslinked fibrin gels [7]. Similar results with respect to inflammatory activity could be found for these fibrinogen genotypes when the presence of A2AP 6Arg/Arg wildtype predisposed for a high antifibrinolytic capacity [8]. These relationships most likely could be explained with dense fibrin gels, with high antifibrinolytic capacity being more effective in controlling inflammatory processes [11,12].

As the association between fibrinogen genotypes and fibrinogen levels as well as the aforementioned influence of fibrinogen, F13A and A2AP genetics on inflammation are likely to influence each other, we tested in the present study the following hypothesis:

Fibrinogen genotypes known to be associated with higher fibrinogen levels at steady-state conditions (specifically FGB rs1800790G > A as well as polymorphisms of FGA and FGG) are related to reduced fibrinogen levels under proinflammatory stimulation, when F13A 34Val/Val wildtype and/or A2AP 6Arg/Arg wildtype is given.

We tested this hypothesis on a cohort of pregnant women, which was extensively characterized for fibrinogen and C-reactive protein (CRP) over the course of pregnancy. Pregnancy is known to be a proinflammatory condition with elevated biomarkers of inflammation [13,14]. Furthermore, pregnancy complications like pre-eclampsia or uteroplacental dysfunction have been described to be associated with increased inflammatory activity [13,14].

2. Materials and Methods

2.1. Patients

The influence of genotype constellations potentially predisposing for dense fibrin clot structures and inflammatory activity on fibrinogen levels under proinflammatory stimulation was assessed in a cohort of 639 patients (2218 observations), followed during pregnancy because of history of fetal loss (FL), placental dysfunction (PD), pregnancy complications or venous thromboembolism (VTE). CRP and fibrinogen levels were determined regularly with each presentation. Data were analyzed anonymously.

2.2. Laboratory Analytics and Parameter Definition

Genotypes of A2AP (Arg6Trp) rs2070863 (C > T), F13A Val34Leu (rs5985), FGA rs6050 (A > G), FGA rs2070016 (T > C), FGA rs2070006 (G > A), FGB −455G > A (rs1800790), FGB rs1800788 (C > T), and FGG rs1049636 (T > C) as well as CRP levels were characterized as described previously [9,10]. Quantification of fibrinogen levels was performed using Clauss’ method with routine diagnostics (Diagnostica Stago, Asnières sur Seine, France).

2.3. Statistical Analysis

For presentation of data distribution frequencies, mean standard deviation (SD), median and interquartile range (IQR) or cumulative probability plots were given, as indicated. For univariate analyses on fibrinogen levels, t-tests were performed and p-values were calculated. Multivariate analyses of fibrinogen levels were performed by logistic regression analysis adjusting for stage of pregnancy (trimester), age, primary diseases, and ethnicity. If indicated, these analyses were stratified for CRP elevation, F13A Val34Leu genotype or A2AP Arg6Trp genotype. To evaluate for potential interactive effects, corresponding interaction terms were included in logistic regression models (p for homogeneity) [15]. Statistical analyses were performed using Stata Statistical Software 10.1 (StataCorp, College Station, TX, USA).

3. Results

3.1. Patient Characteristics

The median age of patients included in the study was 32.1 years (IQR, 27.6–36.5), and the following primary diagnoses were reasons for presentation in our hemostasis out-patient unit: history of miscarriage (38%), actual or history of placental dysfunction (21%), history of deep vein thrombosis (DVT) (14%), history of pulmonary embolism (PE) (3.8%). Patients presented regularly during pregnancy as well as 12 weeks postpartum. Until the end of the first, second, and third trimester, 277 (12.5%), 864 (39.0%), and 894 (40.3%) observations were available, respectively. Additionally, 183 (8.3%) observations until 12 weeks postpartum were included in the study.

The distributions of clinical and laboratory data are summarized in Table 1.

3.2. Courses of Fibrinogen and CRP Levels during Pregnancy and Postpartum

Mean fibrinogen levels continuously increased with ongoing pregnancy (first trimester, 3.74 ± 0.94 mg/L, second trimester, 4.42 ± 0.96 mg/L, third trimester, 5.20 ± 1.06 mg/L). During the 12 weeks postpartum, a considerable decline in fibrinogen levels could be recognized (3.23 ± 0.81 mg/L). The frequency of CRP elevations ≥10 mg/L increased from 7.94% (first trimester) to 14.0% and 12.1% in the second and third trimesters, respectively. In the interval postpartum, only a small number of patients (2.7%) exhibited elevated CRP levels. For mean CRP levels, a comparable characteristic could be found (first trimester, 5.3 ± 8.12 mg/L, second trimester, 5.84 ± 5.21 mg/L, third trimester, 5.82 ± 7.39 mg/L, postpartum, 4.18 ± 3.53 mg/L).

3.3. Fibrinogen Levels in Dependence of Fibrinogen Genotypes with Consideration of CRP

We tested the association of fibrinogen genotypes as well as of F13A, F13B and A2AP with fibrinogen levels. The findings are given in Table 2.

While carriage of the FGB rs1800790 A allele exhibited only a very small effect on fibrinogen concentration, carriage of the minor alleles of FGA rs2070016T > C or FGG rs1049636T > C influenced fibrinogen levels significantly. Interestingly, in our cohort, carriage of the minor alleles of FGB rs1800790G > A and FGA rs2070016T > C was related to lower fibrinogen levels compared with the corresponding wildtypes, and for FGG rs1049636T > C higher fibrinogen levels could be detected. For F13A Val34Leu, F13B His95Arg and A2AP Arg6Trp fibrinogen levels were equal for wildtypes and minor allele carriers.

As expected, CRP elevation itself was very strongly associated with fibrinogen levels in the total study population (CRP <5 mg/L, 4.25 ± 1.06 mg/L, CRP ≥5 mg/L, 5.18 ± 1.14 mg/L, p < 0.0001; CRP <10 mg/L, 4.41 ± 1.10 mg/L, CRP ≥10 mg/L, 5.52 ± 1.23 mg/L, p < 0.0001). When considering inflammatory activity as measured by CRP elevation, a different behavior of the tested fibrinogen genotypes with respect to fibrinogen levels could be found (Table 3).

While for FGB rs1800790G > A in all CRP defined strata a significant association with fibrinogen levels was missing, a strong relationship was found for FGA rs2070016T > C in those patients with CRP levels ≥10 mg/L. In this case, minor allele carriers presented with significantly lower fibrinogen levels compared to the wildtypes. For FGG rs1049636T > C, minor allele carriers with low inflammatory activity exhibited higher fibrinogen levels than the corresponding wildtypes. With high inflammatory activity (CRP ≥10 mg/L), this genotype–phenotype relation tended to reverse. These findings could be confirmed in multivariate analyses adjusting for trimester, age, disease and ethnicity (data not shown).

3.4. Fibrinogen Levels and Dependence of Fibrinogen Genotypes with Consideration of F13A Val34Leu Genotype

As described previously, a strong correlation between fibrinogen level and fibrin clot density depends on the presence of the F13A 34Val/Val wildtype [7]. Furthermore, reduced inflammatory activity in FGB rs1800790 A-allele carriers could be found only in F13A 34Val/Val wildtypes, thus, F13A 34Val/Val wildtype seems to be a necessary precondition for this effect [9]. We therefore tested the relationship between fibrinogen genotypes and fibrinogen levels in F13A Val34Leu defined strata (Table 4).

Considering FGB rs1800790G > A, carriage of the minor allele was associated with significantly lower fibrinogen levels if the necessary background (F13A 34Val/Val) was given. In carriers of F13A 34Leu this relation vanished. Heterogeneity for this effect between both F13A Val34Leu defined strata was statistically significant in univariate as well as in multivariate analyses (p for homogeneity: 0.019 and 0.002, respectively). A similar tendency could be found for FGA rs2070016T > C. In F13A 34Val/Val wildtypes, carriage of the FGA rs2070016T > C minor allele was associated with lower fibrinogen levels compared with FGA rs2070016T > C wildtypes. In F13A 34Leu carriers, this effect of FGA rs2070016T > C genotype on fibrinogen levels was considerably diminished. Heterogeneity between both F13A Val34Leu strata was not statistically significant. For FGG rs1049636T > C, minor allele carriage was robustly associated with higher fibrinogen levels in both F13A Val34Leu strata.

We additionally evaluated whether F13A Val34Leu or A2AP Arg6Trp would have an influence on fibrinogen levels. Neither for F13A Val34Leu (fibrinogen levels: 34Val/Val, 4.54 ± 1.12 g/L, 34Leu, 4.53 ± 1.16 g/L, p = 0.56) nor for A2AP Arg6Trp (fibrinogen levels: 6Arg/Arg, 4.51 ± 1.17 g/L, 6Trp, 4.55 ± 1.15, p = 0.21) did fibrinogen levels differ significantly between wildtypes and minor allele carriers.

3.5. Fibrinogen Levels in Dependence of Fibrinogen Genotypes with Consideration of A2AP Arg6Trp Genotype

We finally tested whether the A2AP Arg6Trp genotype influenced the relationship between fibrinogen genotype and level. This assumption was based on the facts that fibrin clots of A2AP 6Arg/Arg wildtypes are known to have a higher antifibrinolytic capacity [8], and that this genotype influences the relationship between fibrinogen genotypes and inflammation [10]. The results of these analyses are given in Table 4. The findings resembled those for F13A Val34Leu. In individuals predisposed for a higher antifibrinolytic capacity (A2AP 6Arg/Arg wildtypes), carriage of the FGB rs1800790 A allele was related to lower fibrinogen levels. The same holds true for FGA rs2070016T > C. Here, the differences in fibrinogen levels were especially pronounced, and heterogeneity between both A2AP Arg6Trp defined strata was significant (p for homogeneity: 0.005). For FGG rs1049636T > C, again, carriage of the minor allele was robustly associated with higher fibrinogen levels in both A2AP Arg6Trp defined strata.

4. Discussion

The genetic background of fibrinogen synthesis is well-described, and different genetic polymorphisms of the fibrinogen gene loci have been shown to influence basal fibrinogen levels [1,16]. The most consistently reported polymorphisms identified to influence fibrinogen levels are located in the promotor region of FGB, which has many different regulatory elements [1]. Of them, FGB rs1800790G > A is a prominent example [17,18]. Electrophoretic mobility shift assays identified differences in the binding characteristics of various nuclear proteins, with FGB fragments carrying FGB rs1800790G > AG- and A alleles, respectively [3,4]. Furthermore, an increased basal rate of transcription could be detected for recombinant constructs with FGB rs1800790G > AA alleles compared to those with the corresponding G alleles [3,4]. Meanwhile, many different studies confirm increased basal fibrinogen levels in carriers of the FGB rs1800790G > A minor allele [5,6]. Regarding the behavior of fibrinogen levels under proinflammatory stimulation, the AIRGENE study added interesting details [6,19]. In this study, air pollution as measured by ambient particulate matter was used as a marker of proinflammatory stimulation, and the relationship between fibrinogen and the 5-day average of ambient particulate matter was analyzed considering the respective fibrinogen genotypes [19]. Of note, this proinflammatory stimulation did not result in recognizable elevations of CRP or IL6 in the study population [6]. This study revealed an up to 8-fold higher increase in fibrinogen levels under proinflammatory stimulation in FGB rs1800790G > A minor allele carriers when compared with FGB rs1800790G > A wildtypes [19]. Finally, for FGB rs4220G > A, which is in strong linkage disequilibrium with FGB rs1800790G > A, a significant interaction between inflammation, as measured by interleukin-6 levels and fibrinogen levels, has been described [20].

For FGA rs2070016T > C, which has been evaluated in this study in more detail, different studies identified carriage of the minor allele to be associated with higher fibrinogen levels [5,6,21,22,23]. In the case of FGG rs1049636T > C, data are more complex. Most investigations found lower fibrinogen levels in carriers of the corresponding minor allele [6,21,23]. However, in some studies, this relationship was found to be heterogenous between men and women, and only detectable in females [23]. In one study, carriage of the FGG rs1049636 C allele was associated with higher fibrinogen levels [24]. Moreover, this polymorphism was related to the levels of circulating γ’ fibrinogen, which is a splice polymorphism of fibrinogen with special functionalities [25,26].

Beside these polymorphisms located in fibrinogen gene loci, other loci were reported to be involved in genetic regulation of the strength of fibrinogen synthesis. These loci are involved in the regulation of inflammatory responses, with the loci of interleukin-6 receptor (IL6R) and interferon regulatory factor 1 (IRF1) being two examples [21,22].

Our analyses were performed on a cohort of pregnant women. Pregnancy is known to represent a proinflammatory trigger with elevated biomarkers of acute-phase response [13,14]. This proinflammatory stimulation is increased further in cases of pregnancy complications such as uteroplacental dysfunction [13,14]. Thus, in our view, a cohort of pregnant women is well-suited to test the hypothesis of our study, as a proinflammatory trigger is given. However, it is important to underscore that a generalization of our findings should only made with caution.

The results of the present study are seemingly in opposite to the findings reported earlier on genetic regulation of fibrinogen levels. However, they are in agreement with the hypothesis to be tested. In our population, FGB rs1800790 A-allele or FGA rs2070016 C-allele carriage was related to lower fibrinogen levels (Table 2). No obvious interaction with inflammatory activity as measured by CRP levels could be found (Table 3). Furthermore, in individuals with a genetic background predisposing for dense fibrin gels with higher antifibrinolytic capacity in situations, when fibrinogen levels are high (i.e., F13A 34Val/Val wildtypes and/or A2AP 6Arg/Arg wildtypes), FGB rs1800790G > A or FGA rs2070016T > C minor allele carriers exhibited significantly lower fibrinogen levels (Table 4) compared with the corresponding wildtypes. When comparing the relationship between FGB rs1800790G > A or FGA rs2070016T > C genotype and fibrinogen level in strata, defined by absence or presence of F13A 34Leu, a significant heterogeneity was detectable (Table 4). The same holds true for strata defined by A2AP 6Trp carriage (p = 0.09) (Table 4).

As reflected by the hypotheses of our study, we think the findings are plausible when considering the interactive effects of fibrinogen, F13A and A2AP genetics, described previously [9,10,11,27]. Carriage of FGB rs1800790 A allele(s) or FGA rs2070016 C allele(s) is associated with significantly lower inflammatory activity, if F13A 34Val/Val wildtypes and/or A2AP 6Arg/Arg wildtypes are considered. This effect can be demonstrated for CRP levels in patients suffering from rheumatoid arthritis (RA) as well as patients with non-autoimmune inflammations (non-RA). In RA patients, clinical disease activity scores (disease activity score of 28 joints) indicate lower inflammatory activity in these constellations, as well [10]. Thus, we assume that a “kinetic” view could help to clarify the putative discrepancies. Individuals carrying FGB rs1800790 A allele(s) or FGA rs2070016 C allele(s) exhibit higher basal fibrinogen levels [17,18]. In an early phase of proinflammatory stimulation, in these individuals, fibrinogen levels exhibit a steeper increase compared with the corresponding wildtypes [19]. If F13A 34Val/Val wildtype and/or A2AP 6Arg/Arg wildtype are also given, these situations with higher fibrinogen levels result in the generation of denser fibrin gels [7] with a higher antifibrinolytic capacity [8,28,29,30]. Hereby, a more effective confinement of inflammatory foci is achieved [12,31], which helps to shorten the duration of proinflammatory stimulation. Therefore, after an appropriate period, in individuals with these specific genetic backgrounds, inflammation as well as the trigger for fibrinogen synthesis are sufficiently suppressed to result in lower fibrinogen levels compared with individuals with a different genetic background.

In summary, we could demonstrate that genotype constellations of fibrinogen, F13A and A2AP, which predispose for reduced inflammatory activity [9,10,11] are related to lower fibrinogen levels in individuals under longstanding proinflammatory stimulation. The differences in fibrinogen levels for the different genotype constellations are rather small. Thus, it is tempting to assume that the findings of our study to have no direct medical implications. However, as previously shown by our group, seemingly small effects of these genotype constellations on CRP levels have a strong impact on a CRP-based predictive algorithm in respect of radiographic progression in spondylarthritis [32,33].

Thus, knowledge on the influence of fibrinogen, F13A and A2AP genotypes on fibrinogen expression could be of importance for future approaches on diagnostic algorithms based on fibrinogen levels.

5. Conclusions

Genetic polymorphisms of F13A and A2AP, which are known to influence the process of fibrin crosslinking as well as antifibrinolytic capacity of fibrin clots, influence genetic regulation of fibrinogen synthesis by genetic variability of the fibrinogen gene loci FGB, FGA and FGG. It could be assumed that this phenomenon is related to their influence on inflammation control. As our findings have been derived from a cohort of pregnant women, confirmatory studies in other patient groups under proinflammatory stimulation are needed.

Author Contributions

Conceptualization, B.H., C.S.; Data curation, B.H., G.H. and L.B.; Formal analysis, C.S., L.B. and B.H.; Investigation, C.S. and B.H.; Project administration, B.H.; Validation, B.H.; Writing—original draft, B.H.; Writing—Review & editing, C.S., G.H. and L.B. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the German Federal Ministry of Education and Research (Bundesministerium für Bildung und Forschung—BMBF) through ArthroMark (grants 01EC1009A and 01EC1401A).

Institutional Review Board Statement

The study was conducted according to the guidelines of the Declaration of Helsinki, and approved by the Ethics Committee of Charité—Universitätsmedizin Berlin (EK-CCM-1/2004 and EA2/020/08), dates: 22 January 2004 and 17 April 2008.

Informed Consent Statement

Informed consent was obtained from all subjects involved in the study.

Data Availability Statement

Data are available upon reasonable request.

Acknowledgments

We thank Peggy Thiele for genotyping, and to all patients who voluntarily participated in this cohort.

Conflicts of Interest

The authors declare no conflict of interest.

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Table 1. Clinical and laboratory characteristics of the study population.

Parameter	Characteristic
Age [years], median (IQR)	32.1 (27.6–36.5)
Miscarriage	38%
Placental dysfunction	21%
Deep vein thrombosis	14%
Pulmonary embolism	3.8%
Fibrinogen [g/L], mean ± SD	4.54 ± 1.17
CRP [mg/L], mean ± SD	5.54 ± 6.38
Frequency of minor allele carriers:
FGB rs1800790G > A	42%
FGB rs1800788C > T	38%
FGA rs6050A > G	49%
FGA rs2070016T > C	34%
FGA rs2070006G > A	63%
FGG rs1049636T > C	46%
F13A Val34Leu	46%
F13B His95Arg	18%
A2AP Arg6Trp	39%

IQR, interquartile range, CRP, C-reactive protein, SD, standard deviation, FGB, β-fibrinogen, FGA, α-fibrinogen, FGG, γ-fibrinogen, F13A, factor XIII A-subunit, F13B, factor XIII, B-subunit, A2AP, α₂-antiplasmin.

Table 2. Association of genotypes of fibrinogen, F13A, F13B and A2AP polymorphisms with fibrinogen levels.

	Fibrinogen Level [g/L], Mean ± SD
Genotype	Wildtype	Minor Allele	p Value
FGB rs1800790G > A	4.56 ± 1.21	4.51 ± 1.11	0.15
FGB rs1800788C > T	4.53 ± 1.13	4.51 ± 1.21	0.41
FGA rs6050A > G	4.53 ± 1.15	4.54 ± 1.18	0.59
FGA rs2070016T > C	4.58 ± 1.21	4.42 ± 1.07	0.002
FGA rs2070006G > A	4.51 ± 1.15	4.53 ± 1.17	0.58
FGG rs1049636T > C	4.43 ± 1.16	4.63 ± 1.15	0.0002
F13A Val34Leu	4.54 ± 1.18	4.53 ± 1.16	0.42
F13B His95Arg	4.53 ± 1.15	4.53 ± 1.21	0.51
A2AP Arg6Trp	4.51 ± 1.17	4.55 ± 1.15	0.21

SD, standard deviation, FGB, β-fibrinogen, FGA, α-fibrinogen, FGG, γ-fibrinogen, F13A, factor XIII A-subunit, F13B, factor XIII B-subunit, A2AP, α₂-antiplasmin.

Table 3. Association of genotypes of fibrinogen polymorphisms with fibrinogen levels in dependence of inflammatory activity.

	Fibrinogen Level [g/L], Mean ± SD
Genotype	Wildtype	Minor Allele	p Value
FGB rs1800790G > A
CRP < 5 mg/L	4.24 ± 1.10	4.25 ± 1.00	0.56
CRP < 10 mg/L	4.43 ± 1.15	4.40 ± 1.04	0.29
CRP ≥ 10 mg/L	5.53 ± 1.19	5.51 ± 1.30	0.44
FGA rs2070016T > C
CRP < 5 mg/L	4.26 ± 1.11	4.18 ± 0.98	0.08
CRP < 10 mg/L	4.43 ± 1.14	4.34 ± 1.04	<0.05
CRP ≥ 10 mg/L	5.62 ± 1.20	5.21 ± 1.01	0.01
FGG rs1049636T > C
CRP < 5 mg/L	4.13 ± 1.03	4.35 ± 1.08	0.0001
CRP < 10 mg/L	4.31 ± 1.08	4.51 ± 1.12	0.0002
CRP ≥ 10 mg/L	5.64 ± 1.26	5.39 ± 1.08	0.07

SD, standard deviation, FGB, β-fibrinogen, FGA, α-fibrinogen, FGG, γ-fibrinogen, CRP, C-reactive protein.

Table 4. Association between fibrinogen genotypes and fibrinogen levels in dependence of F13A Val34Leu and A2AP Arg6Trp genotypes.

	Fibrinogen Level [g/L], Mean ± SD
Genotype	Wildtype	Minor Allele	p Value
FGB rs1800790G > A
F13A 34Val/Val	4.62 ± 1.23	4.45 ± 1.12	<0.01 *
F13A 34Leu	4.50 ± 1.18	4.58 ± 1.11	0.15 *
A2AP 6Arg/Arg	4.56 ± 1.25	4.44 ± 1.07	<0.04 ^#
A2AP 6Trp	4.52 ± 1.14	4.59 ± 1.17	0.22 ^#
FGA rs2070016T > C
F13A 34Val/Val	4.60 ± 1.26	4.38 ± 1.04	<0.004
F13A 34Leu	4.56 ± 1.16	4.46 ± 1.10	0.1
A2AP 6Arg/Arg	4.61 ± 1.24	4.33 ± 1.03	<0.0001 ^$
A2AP 6Trp	4.54 ± 1.17	4.59 ± 1.12	0.28 ^$
FGG rs1049636T > C
F13A 34Val/Val	4.44 ± 1.19	4.63 ± 1.19	0.006
F13A 34Leu	4.43 ± 1.14	4.62 ± 1.13	0.006
A2AP 6Arg/Arg	4.41 ± 1.17	4.61 ± 1.16	<0.002
A2AP 6Trp	4.47 ± 1.15	4.65 ± 1.15	0.02

SD, standard deviation, FGB, β-fibrinogen, FGA, α-fibrinogen, FGG, γ-fibrinogen, F13A, factor XIII A-subunit, A2AP, α₂-antiplasmin.* p for homogeneity (F13A 34 al/Val vs. F13A 34Leu): 0.019. ^# p for homogeneity (A2AP 6Arg/Arg vs. A2AP 6Trp): 0.09. ^$ p for homogeneity (A2AP 6Arg/Arg vs. A2AP 6Trp): 0.005.

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Schwedler, C.; Heymann, G.; Bukreeva, L.; Hoppe, B. Association of Genetic Polymorphisms of Fibrinogen, Factor XIII A-Subunit and α₂-Antiplasmin with Fibrinogen Levels in Pregnant Women. Life 2021, 11, 1340. https://doi.org/10.3390/life11121340

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Schwedler C, Heymann G, Bukreeva L, Hoppe B. Association of Genetic Polymorphisms of Fibrinogen, Factor XIII A-Subunit and α₂-Antiplasmin with Fibrinogen Levels in Pregnant Women. Life. 2021; 11(12):1340. https://doi.org/10.3390/life11121340

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Schwedler, Christian, Guido Heymann, Larisa Bukreeva, and Berthold Hoppe. 2021. "Association of Genetic Polymorphisms of Fibrinogen, Factor XIII A-Subunit and α₂-Antiplasmin with Fibrinogen Levels in Pregnant Women" Life 11, no. 12: 1340. https://doi.org/10.3390/life11121340

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