Ethics statement

The study protocols conformed to the Helsinki declaration. Both studies were approved by the Regional Research Ethics Committee in Medicine, Central Norway (reference 157-1997 dated 06/11/1997 and reference 2009/1852-2, dated 11/20/2009), and the case-control study was approved by the Data Inspectorate of Norway. The participants in the pilot study gave written informed consent. The HUNT2 participants had signed consent to participate in morbidity and mortality follow-up studies. No minors or children participated in the present study.

The pilot study was based on data from 236 adults (146 males and 90 females) in a study on circulating plasma markers of inflammation, admitted for first-time elective coronary angiography due to suspected coronary artery disease as detailed previously [13]. Later, data on other genetic markers in this population have also been published [14], [15]. Briefly, the patients with available samples for the present pilot study (n = 234 due to 2 lost samples) consisted of 131 patients with significant (>50%) artery stenosis in at least one main coronary artery branch and 103 patients without significant coronary artery stenosis, as demonstrated by quantitative coronary angiography. Information was also registered about classical cardiovascular risk factors (body mass index (BMI), smoking, hypertension, hypercholesterolemia, and diabetes). DNA was extracted from blood samples anticoagulated with ethylenediaminetetraacetic acid by a salting-out procedure and genotyping for MBL2 polymorphisms was performed as described in [16]. Plasma was kept at −70°C and later analyzed for MBL concentrations using an in-house enzyme-linked immunoassay [17].

The case-control study was generated by linkage of population data from the second wave of the Nord-Trøndelag Health Study (HUNT2) to validated information on incident acute MIs.

HUNT2 was carried out in 1995–1997 as a population-based study and information was collected through comprehensive questionnaires and a clinical examination. The county of Nord-Trøndelag is fairly representative for Norway as a whole, with only 3% non-Caucasians. All inhabitants 13 years of age and older were invited, and a venous blood sample was drawn from all persons 20 years of age and older. In total, about 75 000 (70%) of those invited attended the study. The inclusion process is described elsewhere [18].

There are two primary referral hospitals in the county of Nord-Trøndelag (Levanger Hospital and Namsos Hospital). Data on all acute MI hospitalizations from 1995 (corresponding to the commencement of HUNT2) to the end of 2000 were registered retrospectively, whereas from 2001 registration has been done prospectively. MI was diagnosed according to the European Society of Cardiology/American College of Cardiology consensus guidelines [19]. The criteria were elevated troponin T or troponin I at the same time course with at least one of the following criteria: 1) symptoms consistent with myocardial infarction and/or 2) ECG changes with development of significant Q wave and/or 3) ECG changes consistent with ischemia (ST-segment elevation or depression).

Among participants in HUNT2, the following criteria had to be met to be eligible for the present study: available DNA, and no previous self-reported MI, angina pectoris or stroke. In total, 57 133 individuals met these criteria. We linked these HUNT2 participants to the hospital registrations to ascertain incident cases of MI from baseline at HUNT2 until the end of 2008. During follow-up, 1689 individuals had experienced an MI. Among incident MI patients, the 370 youngest were selected as cases in the study. As controls, we randomly selected 370 participants who were matched to the cases by age (±2 years) and gender. All controls were at risk of MI at the time when the MI occurred in their respective matched case.

Clinical information

Measurements of blood pressure, height, weight, waist and hip circumference were done as previously described [18]. BMI and waist-hip ratio (WHR) were calculated. Concentrations of blood lipids, creatinine and glucose were analysed by standard methods at the Central Laboratory at Levanger Hospital. Hypertension was defined as systolic blood pressure ≥140 mmHg or as diastolic blood pressure ≥90 mmHg, or as current use of antihypertensive medication. Information on use of other medications, such as statins or anti-platelet therapy was not available. Hypercholesterolemia was defined as total cholesterol >6.2 mmol/L. Smoking was classified in three groups: never, former or current smokers. A report of MI before 60 years of age in first-degree relatives was considered as a positive family history. The Framingham risk score [20] was calculated based on the corresponding variables from the HUNT2 database (age, HDL-cholesterol, total cholesterol, systolic blood pressure, antihypertensive treatment, smoking and diabetes). To classify the metabolic syndrome, a modified set of criteria based on The International Diabetes Federation consensus [21] were used. The criteria were 1) central obesity, (men: waist circumference ≥94 cm; women: waist circumference ≥80 cm) plus two of the following four criteria 2a) low HDL cholesterol (men <1.03 mmol/L; women <1.29 mmol/L), 2b) hypertension (systolic blood pressure ≥130 mmHg or diastolic blood pressure ≥85 mm Hg, or treatment for hypertension), 2c) fasting plasma glucose ≥5.6 mmol/L or previously diagnosed type 2 diabetes, 2d) fasting triglycerides >1.7 mmol/L.

Genotyping

DNA was extracted from peripheral blood leukocytes at the HUNT biobank using a commercial kit (Puregene, Gentra Systems, Minneapolis, MN) or by a robotic method (Autopure LS, Gentra Systems). Genotyping was performed using a combination of polymerase chain reaction (PCR) and pyrosequencing. All of the single nucleotide polymorphisms (SNPs) are found in the online database http://www.ncbi.nlm.nih.gov/snp/. The sequences were based on ENSG00000165471 (MBL2), ENSG00000085265 (FCN1), ENSG00000160339 (FCN2), and ENSG00000142748 (FCN3) in Ensemble release 65.

Four different SNPs in MBL2 were investigated (Figure 1, Panel A). Three of them are in exon 1 and give rise to the structural alleles B (codon 54, rs1800450), C (codon 57, rs1800451) and D (codon 52, rs5030737). Wild type is denoted A. The fourth is considered the most important promoter polymorphism: X/Y (rs7096206). These SNPs are inherited in haplotypes. To simplify the interpretation, data are presented by pooling the structural alleles B–D to one allele denoted O [4]. The structural alleles are always found on a Y promoter background, thus we used the term YO to denote this defective haplotype. Combining the promoter variant with the A and O alleles results in 6 haplotypes, as shown in Figure 1, Panel B. These haplotypes were further combined into three haplotype groups: normal (YA/YA, YA/XA), intermediate (XA/XA, YA/YO) or deficient (XA/YO, YO/YO), which correspond to serum concentrations of functional MBL [5].

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Figure 1. MBL2 gene and haplotypes.

Panel A: Simplified figure of the investigated MBL2 polymorphisms. Wild type allele is A. Panel B: MBL2 haplotypes and corresponding concentrations of functional MBL.

https://doi.org/10.1371/journal.pone.0042113.g001

One common polymorphic site in the promoter of the ficolin-1 gene (FCN1 −542, rs10120023) was genotyped. In the ficolin-2 gene (FCN2), two amino acid substituting SNPs in exon 8 were included. They are known to cause increased (FCN2 +6424, rs7851696) and reduced (FCN2 +6359, rs17549193) binding capacity of the protein to N-acetylglucosamine, respectively [22]. The gene coding for ficolin-3 (FCN3) is less polymorphic, but a frame-shift variation in position +1637 (rs28357092) of FCN3 is known to cause a 50% reduction of serum ficolin-3 in heterozygotes, and total ficolin-3 deficiency in homozygotes [23]. Despite its low allele frequency, this SNP was also included.

Four different PCR reactions were set up: MBL2 exon 1, MBL2 promoter, both FCN2 SNPs, and FCN1 and FCN3 in the same reaction. The primers are available as supporting information (Table S1). One primer in each pair was biotinylated. Evaluation of the PCR products by agarose gel electrophoresis showed specific bands of the expected molecular weights. The PCR product was further used for pyrosequencing. We chose the pyrosequencing platform because it has been successfully used for MBL2 genotyping [24]. Pyrosequencing was performed with a standard protocol on Pyro sequencer PSQ 96MA (Pyrosequencing AB; Biotage, Uppsala, Sweden), using a commercially available kit (PyroMark Gold Q96 Reagents, Qiagen, Germany).

Statistical analyses

In the pilot study, the Chi-square test was employed to compare the distribution of MBL2 haplotype groups between patients with and without significant coronary artery stenosis. Logistic regression modelling was used to adjust for the classical cardiovascular risk factors. Plasma MBL concentrations were compared among patients with different MBL2 haplotypes using the Kruskal-Wallis test.

Based on an expected frequency of 0.08 of the MBL2 combined low expressing haplotype (YO/YO+XA/YO) in Caucasians, a power calculation was performed for the case-control study. To detect an odds ratio (OR) of 2.0, assuming a power of 80% and a 5% significance level, 320 persons were required in each group. In order to account for possible variations in the genotype distribution in small datasets, 370 persons were included in each group. The study population was too small for analyses stratified by gender.

McNemar's test was used to compare numbers of discordant pairs. Due to non-normal distribution of several variables, the Wilcoxon signed rank test was used to evaluate differences in continuous and ordinal variables between pairs. The Kruskal-Wallis test was used to compare serum total cholesterol, total cholesterol – HDL cholesterol ratio, and triglycerides within the MBL2 haplotype groups. The Chi-square test was used for comparison of allele frequencies and of frequencies of participants with hypercholesterolemia within the MBL2 haplotype groups. Deviation from the Hardy-Weinberg equilibrium was calculated by using the chi-square test.

Conditional logistic regression was performed to evaluate associations between the three inferred MBL2 haplotype groups and risk of MI. Further models were developed, where traditional risk factors (hypertension, hypercholesterolemia, smoking, diabetes and BMI (continuous)), the Framingham risk score or the metabolic syndrome were also included.

All tests were two-sided and the results are presented as means, ORs or HRs (with 95% confidence intervals (CI)). To avoid false positive conclusions, the alpha level of significance for the comparisons of haplotype frequencies between cases and controls were obtained by permutation testing, using 10,000 permutations. By this method, which is considered the gold standard, a result is significant if the observed p-value is lower than the empirical p-value found under permutation. For other tests, p-values below 0.05 were considered statistically significant. Pilot data was analysed with SPSS for Windows, version 19.0.0 (IBM, New York, USA). Permutation testing was performed using the R package, version 2.14.1 (http://www.r-project.org). All other analyses were performed with Stata/MP for Mac, version 11.2, (Stata Corp., College Station, Texas, USA).

Study Limitations

There are some limitations to our study. MBL2 haplotypes were not assessed in all MI patients from the HUNT2 study; hence it is not known whether the associations are present in older individuals. Serum was not available at the time of the genotyping. However, our pilot study and other previous studies have shown that serum concentrations of functional MBL correspond closely to the genotypes [5]. The risk for an early MI is also influenced by other genetic factors, which were not included in the present study. Non-linearity in the light response following incorporation of more than five nucleotides may play a role in the assessment of homopolymeric regions like the one in FCN3. All samples with uncertain results were therefore re-sequenced manually. The results were not replicated in a similar cohort, as they were partly confirmatory. Because the included polymorphisms are located closely together and are not covered in previously published genome-wide association studies on early MI, it was not possible to use such data for replication. Although the population in Norway is assumed to be generally representative for the Caucasian population, we cannot exclude the possibility that MBL may be more important in relation to cardiovascular disease in this population compared to others.

Conclusions

The MBL2 haplotypes corresponding to functional MBL deficiency were associated with a doubling of the risk for MI in individuals younger than 62 years of age, independent of conventional risk factors. The findings confirm our hypothesis and support that MBL deficiency may lead to increased atherosclerosis or development of vulnerable plaques.