Background
Dilated cardiomyopathy (DCM), characterized by left ventricular dilation and systolic dysfunction, is the most common form of heart muscle disease, comprising 60% of the cases of identified cardiomyopathy [
1]. This disorder is clinically heterogeneous, ranging from affected individuals with clinical presentations of severe symptoms, including heart failure and sudden death, and asymptomatic individuals. The clinical course of DCM, almost regardless of the underlying cause, may be progressive, with roughly 50% of individuals reported to die within 5 years of diagnosis without transplantation [
1,
2]. Although longer survival has been accomplished recently with improved medical therapies and interventions, early examinations are necessary to improve the DCM prognosis. The etiology of DCM is multifactorial and many different clinical conditions can lead to phenotype of DCM. It has become evident that genetic factors play an important role in the etiology and pathogenesis of DCM. To date, DCM-associated mutations in many different genes have been reported, but still these mutations explain only a minority of the etiology of DCM [
3]. Some susceptibility genes have been shown to be associated with an increased risk of developing a DCM. These include HLA-DQA1*0501, HLA-DRB1*1401, exon 8 C/T of Endothelin receptor A, Leu10Pro of TGF-beta1, G994T of PAF acetyl hydrolase, MMP-3 5A/6A, and so on [
4‐
6]. With more knowledge about susceptibility genes and pathways involved in DCM, strategies may emerge to reduce myocyte death, and diminish myocardial fibrosis, processes that ultimately cause the heart fail.
Clinical observations and experimental studies have demonstrated that left ventricular (LV) remodeling and dilation occurs with the progression of end-stage LV failure. It has been reported that in experimental and human heart failure, nuclear factor kappa B (NF-κB) is chronically activated in cardiac myocytes, suggesting an important involvement of NF-κB in the cardiac remodeling process [
7]. NF-κB is a redox-sensitive transcription factor regulating a battery of inflammatory genes and it has been implicated as important for initiation and progression of pathogenesis of many autoimmune and inflammatory diseases [
8‐
10]. Numerous lines of investigation suggest that NF-κB could promote tumorigenesis [
11]. Cardiac-specific expression of tumor necrosis factor (TNF) has previously been shown to produce DCM, presumably through intact TNF-related apoptosis [
12]. In endothelin-1 deficient hearts NF-κB activity decreased, resulting in diminution of downstream inhibitors of TNF signaling [
13]. It is apparent that the role of NF-κB in the regulation of cardiomyocyte viability is multidimensional and might contribute to the development of DCM.
A common insertion/deletion polymorphism (-94 insertion/deletion ATTG, rs28362491) located between two putative key promoter regulatory elements in the
NFKB1 gene was identified which seems to be the first potential functional
NFKB1 genetic variation. The presence of a 4 base pair (bp) deletion resulted in the loss of binding to nuclear proteins, leading to reduced promoter activity [
14]. A research has shown that the deletion was associated with an increased risk for an inflammatory intestinal disorder-ulcerative colitis (US), but subsequently other study failed to replicate this association [
14‐
19]. Furthermore significant associations of this polymorphism with other disease entities (type 1 diabetes, oral squamous cell carcinoma, colorectal cancer, and melanoma) have been reported [
20‐
23]. However, its association with DCM is still unclear. The main goal of the present investigation was to determine the possible susceptibility of
NFKB1 -94 insertion/deletion ATTG polymorphism on the occurrence of DCM.
Results
Genotype distributions had no deviation from Hardy-Weinberg equilibrium both in patients and controls. Differences in allelic and genotype distribution of
NFKB1 gene -94 insertion/deletion ATTG polymorphism were tested between DCM patients and controls, and observed differences are presented in Table
1.
Table 1
The allelic and genotype distributions of NFKB1 polymorphism among patients and controls
NFKB1-94 genotype | ATTG1/ATTG1
| 18(10.2) | 42(20.7) | - | 1 | - |
| ATTG1/ATTG2
| 95(53.7) | 90(44.3) |
0.004
|
2.463
|
1.321–4.592
|
| ATTG2/ATTG2
| 64(36.1) | 71(35.0) |
0.023
|
2.103
|
1.101–4.018
|
| ATTG1/ATTG2+ATTG2/ATTG2 versus ATTG1/ATTG1
|
0.005
|
2.304
|
1.272–4.174
|
| ATTG1/ATTG1+ATTG1/ATTG2 versus ATTG2/ATTG2
| 0.810 | 1.053 | 0.691–1.604 |
NFKB1-94 allele | ATTG1
| 132(37.3) | 174(42.9) | 0.118 | 1.261 | 0.942–1.688 |
| ATTG2
| 222(62.7) | 232(57.1) | | | |
The overall genotype frequency of DCM patients was significantly different from that of controls. The frequency for ATTG1/ATTG1 genotype was slightly overrepresented in controls (P = 0.004, OR = 2.463, 95%CI = 1.321–4.592 for ATTG1/ATTG1 vs. ATTG1/ATTG2 comparison, and P = 0.023, OR = 2.103, 95%CI = 1.101–4.018 for ATTG1/ATTG1 vs. ATTG2/ATTG2 comparison, respectively). Furthermore, the P value and OR were 0.005 and 2.304, respectively, ATTG1/ATTG2 + ATTG2/ATTG2 vs. ATTG1/ATTG1 comparison, indicating that ATTG2 carrier (ATTG1/ATTG2 + ATTG2/ATTG2) was susceptible to DCM. The frequency of allele ATTG2 in DCM patients was higher than that in control subjects (62.7% vs. 57.1%), but is not statistically significant (P = 0.118).
Discussion
Genetic factors are known to play an important role in the etiology of DCM. The first DCM-associated mutation, in the dystrophin gene, was described in 1993 [
24,
25]. The genetic of DCM have been under intensive investigation lately and the knowledge on the genetic basis of DCM has increased rapidly. To date, DCM-associated mutations in many different genes with subsequent alterations in protein structure have been reported, but these mutations explain only a minority of the etiology of DCM [
3]. Some susceptibility genes have also been shown to be associated with an increased risk of developing a DCM.
NF-κB was discovered by Baltimore and coworkers in 1986 as a
factor in the
nucleus of
B cells that binds to the enhancer of the
kappa light chain of immunoglobulin [
11,
26]. The transcription of many genes for immune response, cell adhesion, differentiation, proliferation, angiogenesis and apoptosis are regulated by NF-κB. It is just this characteristic that makes NF-κB the crucial point of convergence of a number of stimuli that can influence different aspects of cellular homeostasis [
27]. Inappropriate activation of NF-κB can mediate inflammation and tumorigenesis. How NF-κB activation mediates tumorigenesis and inflammation has been widely studied during the past decade. Most inflammatory agents mediate their effects through the activation of NF-κB and it is suppressed by anti-inflammatory agents. Most carcinogens and tumor promoters activated NF-κB, whereas chemopreventive agents suppress it [
11]. NF-κB is rarely found to be constitutively active in normal cells except for proliferating T cells, B cells, thymocytes, monocytes, and astrocytes, while it is constitutively active in most tumor cell lines [
11,
23,
27]. However, the proposal that NF-κB leads to the onset of cancer has been changed by the evidence that, for skin cancer, NF-κB activation has been postulated as a safeguard against cancer [
27,
28]. Further studies could help to figure out the molecular mechanisms that dictate the pro-oncogenic or anti-oncogenic activity of NF-κB.
The -94 insertion/deletion ATTG polymorphism was identified in a study sequenced the
NFKB1 promoter in 10 inflammatory bowel disease and 2 controls, and the ATTG
1 allele was more frequent in ulcerative colitis than that in controls in the following study. The in vitro promoter expression studies suggest that the ATTG
1 allele may result in relatively decreased
NFKB1 message and hence decreased p50/p105 NF-κB protein production [
14]. The association between -94 insertion/deletion ATTG polymorphism and susceptibility to ulcerative colitis was confirmed in another study, but data were inconsistent and this association could not be replicated in different population [
16,
17,
29].
Given the considerable important role of NF-κB pathway involved in initiation and progression of pathogenesis in disease, we investigated the association between -94 insertion/deletion ATTG polymorphism and susceptibility to DCM. The present study shows that the allelic frequency for NFKB1 gene -94 insertion/deletion ATTG polymorphism in DCM patients is not significantly different from that of controls. However, the genotype frequency distribution in DCM patients was significantly different from that of controls. The frequency of the ATTG1/ATTG1 genotype of NFKB1 gene -94 insertion/deletion ATTG polymorphism in controls was significantly higher that in DCM patients. We conducted comparison between ATTG1/ATTG1 and (ATTG1/ATTG2+ATTG2/ATTG2) in DCM patients and controls, and further significant difference was observed (p = 0.005). These results indicated that ATTG2 carrier (ATTG1/ATTG2 + ATTG2/ATTG2) was susceptible to DCM. The allelic distribution between DCM patients and controls was different, although not statistically significant (p = 0.118), and the frequency for ATTG2 allele in DCM patients is higher than that in controls, although not statistically significant, also indicating that ATTG2 allele might be a risk factor for the susceptibility to DCM.
The role of NF-κB in heart has been extensively studied by many authors [
10]. Its role in the regulation of cardiomyocyte viability is multidimensional, because it was believed to activate cell-death pathway and it can also protect cells from death. In hearts subjected to in vivo infarction, NF-κB-activation is biphasic, peaking after 15 min and 3 h reperfusion, respectively. NF-κB might play a detrimental role during reperfusion and inhibition of leukocyte adhesion, cytokines, and chemokines which are regulated by NF-κB during reperfusion protects the heart against reperfusion injury [
10,
30]. A detrimental role of NF-κB-activation in cardiac allograft rejection has been suggested, as pharmacological inhibition of NF-κB prolongs survival of heterotopic transplants [
31]. In atherosclerotic lesions the NF-κB-regulated inflammatory mediators such as cytokines, inducible NO synthase and leukocyte adhesion molecules have been detected, and mice deficient in NF-κB signaling exhibit reduced fatty-streak formation when fed a fatty diet [
32,
33]. Although the functional consequences are as yet undetermined, both systemic and cardiac activation of NF-κB have been found in unstable coronary syndromes. The present study shows that the genotype distribution of
NFKB1 gene -94 insertion/deletion ATTG polymorphism in DCM patients is significantly different from that in control subjects, and (ATTG
1/ATTG
2+ATTG
2/ATTG
2) genotype frequency is higher in DCM patients than that in control subjects. Considering that the ATTG
1 allele may result in decreased
NFKB1 message and p50/p105 NF-κB protein production, a detrimental role of NF-κB-activation in the initiation and progression of pathogenesis in DCM can be presumed and much further work will be needed for a complete understanding of its mechanism. The main limitation of the present study is the relatively small size of the study population and the lack of replication of the significant association in a second independent cohort of DCM patients.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
BZ, LR and LZ conceived of the study, participated in its design, carried out most of the experiments and drafted the manuscript. YL, LG and YW participated in design of study and helped to draft the manuscript. YC, HX and YS performed sample collection and DNA extraction. YP and ML participated in genotyping. All authors have read and approved the final manuscript.