Background
Recurrent pregnancy loss (RPL) is defined as three or more consecutive spontaneous abortions before the 20th week of gestation [
1,
2]. It is estimated that RPL affects approximately 3% of healthy women of reproductive age with undetermined causes [
2,
3]. Until now, a few known etiological factors have been considered as the cause of RPL including genetic defects such as parental chromosome abnormalities, endocrine and metabolic disorders such as hypothyroidism, luteal phase deficiency and diabetes mellitus, autoimmune abnormalities such as antiphospholipid syndrome [
4‐
6], although the mechanisms are largely unknown.
Some studies have led to the awareness that these unexplained RPL might be due to dysregulated immunologic factors [
7,
8]. Considerable evidence has accumulated indicating that cytokines play a major role in reproductive events [
9]. For instance, tumor necrosis factor-α (TNF-α) is a potent cytokine which produced by mononuclear phagocytes, natural killer (NK) cells, and antigen-stimulated T-cells [
10]. It has often been associated with increased risk for adverse pregnancy outcomes. Circulating levels of TNF-α are higher both in animals and humans with a miscarriage compared to those with a successful pregnancy, suggesting that this cytokine is exclusively harmful for pregnancy [
8,
11‐
13].
An increasing number of genetic association research are conducted to determine the genetic background of RPL [
14]. Research efforts have focused on single nucleotide polymorphisms (SNP) because cytokines have their important roles in implantation and gestation [
14]. The production of cytokines can be controlled by genetic polymorphisms, especially in the promoter regions. The TNF-α is located within the human leukocyte antigen class III region in chromosome 6p21.3and has several functional sites of polymorphisms [
15]. Variants in the TNF-α promoter region were previously implicated in the pathogenesis of RPL, hence, many studies have been directed towards the relationships between SNPs in the promoter region of TNF-α at -1031T/C, −863C/A, −857C/T, −376G/A, −308G/A, −238G/A, +488G/A and RPL [
16,
17]. Although many studies have associated RPL and TNF-α polymorphisms, their role in reproductive failure is still debated. Some studies demonstrated that the −308 G/A polymorphism is not associated with RPL [
18,
19], other studies gave significant evidence for an increased risk of RPL for the carriers of the TNF-α-308A allele [
17,
20].
As stated above, several original studies have reported the correlations between TNF-α polymorphism and RPL, but the results are unconvincing and unreliable, which may partly be due to the relatively small samples and different human populations. A previous meta-analysis was conducted in 2012 trying to investigate this relationship [
21]. In view of 12 eligible studies, the results indicate that TNF-α-308G/A, −238G/A polymorphisms are not significantly associated with the risk of RPL in the overall population. However, careful inspection of the data used in that study revealed a noteworthy inconsistency of diagnostic criteria and much stricter entry criteria was needed to clarify such inconsistencies that might confound the conclusions [
22]. In the past three years, several more replication researches performed to reevaluate the effect of TNF-α gene polymorphisms on RPL provided some new data and diverse conclusions [
17‐
20]. Accordingly, we performed a meta-analysis with much stricter entry criteria to investigate the association between TNF-α polymorphism and RPL risk.
Methods
Search strategy
Article searches were performed independently by two investigators and the final search strategies were performed with agreement. An extensive systematic literature search for relevant studies was conducted with PubMed, Embase, and The Cochrane Library from their earliest available date through May 12, 2015. For TNF-α polymorphisms and RPL risk, the search terms were as follows: (“tumor necrosis factor” OR “TNF”) AND (“recurrent pregnancy loss” OR “recurrent spontaneous miscarriage” OR “recurrent spontaneous abortion”) AND “polymorphism”. All the articles about three or more miscarriages associated with TNF-α polymorphism were included. Moreover, all articles were published in the primary literature to avoid duplicating analyses. All clearly irrelevant studies, editorials, case reports, and review articles were excluded. Furthermore, literatures cited in the reference sections of review articles and other relevant studies were searched manually for additional eligible studies.
Selection criteria
Eligible studies were selected according to the following explicit inclusion criteria:
(1) the original study was designed as an independent genotyped case–control study; (2) inclusion of both RPL cases and non-RPL controls; (3) investigation of the correlation between TNF-α genetic polymorphisms and RPL risk; (4) adequate data that could be used to calculate the numbers of genotype frequency had to be clearly described in the original study. In addition, the following exclusion criteria were also used: (1) no healthy control population and raw data; (2) genotype frequency unavailable; (3) non-conformity with the criteria for RPL; and (4) duplication of previous publications.
The bibliographic search and data extraction were conducted independently by two investigators from all eligible publications according to the above inclusion criteria. Any disagreement was subsequently resolved by consensus with a third author. The following characteristics was collected prospectively: the first author’s name, year of publication, source of publication, country of origin, genotype number in cases and controls, genotype method, and gene polymorphism (Table
1).
Table 1
Main characteristics of the studies included in the meta-analysis
-238G/A | Alkhuriji A.F | 2013 | Saudi | three or more | 57/8/0a
| 55/7/3a
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Gupta R. | 2012 | Indian | three or more | 121/63/16a
| 154/113/33a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: not stated |
| Finana R.R. | 2010 | Bahrain | three or more | 148/52/4a
| 200/48/0a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Zammiti W | 2009 | Tunisia | three or more | 264/88/20a
| 215/52/7a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
-308G/A | Alkhuriji A.F | 2013 | Saudi | three or more | 33/24/8a
| 47/14/4a
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Gupta R. | 2012 | Indian | three or more | 229/62/9a
| 425/70/5a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Kuar A. | 2011 | Indian | three or more | 39/6/5a
| 41/7/2a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Finana R.R. | 2010 | Bahrain | three or more | 164/32/8a
| 212/32/4a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: not stated |
| Zammiti W | 2009 | Tunisia | three or more | 319/39/14a
| 222/47/5a
| PCR–RFLP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: not stated |
| Kamali- Sarvestani E | 2005 | Iranian | three or more | 117/14b
| 122/21b
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: not stated |
| Prigoshin N | 2004 | Argentina | three or more | 35/6b
| 49/5b
| PCR-SSP | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Pietrowski D | 2004 | Germany | three or more | 133/33/2a
| 167/41/4a
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: not stated |
| Daher S | 2003 | Brazil | three or more | 36/12b
| 89/19b
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
| Babbage S.J. | 2001 | UK | three or more | 30/13b
| 56/17b
| PCR | 1: adequate; 2: not stated;3: adequate; |
4: adequate; 5: unequal |
Quality assessment
The quality of the included studies was assessed according to the following criteria from the previous report [
23].
1.
Description of the case and control subjects’ characteristics (adequate, inadequate);
2.
Assessment and validation of miscarriage in the patients (adequate, inadequate, not stated). Adequate validation would include confirmation by scan or pathological examination; inadequate validation would include recollection of the patient as the only evidence or a biochemical pregnancy without ultrasound evidence of pregnancy;
3.
Description of the laboratory procedures for the genotyping (adequate, inadequate);
4.
Elimination of confounding factors in patients (not described, inadequate, adequate). “Adequate” refers to the elimination of the proven causes of recurrent miscarriage (chromosomal abnormalities of the couples, antiphospholipid antibodies, uterine abnormalities, protein C/S/antithrombin-III deficiency);
5.
Equal assessment for confounding factors in the case and control groups (equal, unequal, not stated).
Statistical analysis
Data management and analysis were performed using the programs STATA version 12 (StataCorp LP, College Station, TX, USA). Crude odds ratios (ORs) with 95% confidence intervals (CIs) were used to assess the association between the TNF-α polymorphisms and the risk of RPL. Analysis of polymorphisms was conducted in at least three studies. The ORs was calculated for the allele model, homozygote comparison, heterozygote comparison, dominant model, and recessive model based on the genotype frequencies in cases and controls. Heterogeneity was evaluated with Cochran's Q test and I2 statistic. When P value of Q test was less than 0.05 and/or I2 more than 50%, it was considered there was significant heterogeneity and a random-effects model was used, otherwise, the fixed effects model was selected. Potential publication bias was diagnosed statistically via the funnel plots and Egger’s tests. Moreover, subgroup analyses were conducted to explore reasons for heterogeneity. In all analyses, two-sided P value <0.05 was considered to be statistically significant.
Discussion
RPL is a common disorder and represents a major concern for reproductive problem [
38] affecting 1% to 3% of healthy women and occurs in 10% to 20% of pregnant woman [
39]. Until now, various factors have been identified that influence miscarriage, however, the exact underlying etiology in up to 50% of RPL patients remains undetermined [
38].
As a pleiotropic cytokine, TNF-α has attracted attention because of its involvement in the promotion of inflammatory response, autoimmune, endocrine and neoplastic diseases. Furthermore, there is convincing evidence that TNF-α induces apoptosis of cytotrophoblasts, which suggested that aberrant expression of TNF-α may have harmful effects on placental development and function [
40]. Increasing evidence shows that TNF-α mediate a number of pregnancy complications including RPL [
28,
41]. Mechanistically, increased TNF-α secretion led to RPL through inducing trophoblast invasion and placentation [
42] and proapoptotic gene expression in human fetal membranes [
43], resulting in accelerated membrane degradation and increased infertile susceptibility [
44]. Moreover, regulated TNF-α expression in the developing placenta may interfere with pregnancy survival. Increased placental levels of TNF-α increases abortion rates [
45], and blockade of TNF-α has been shown to prevent stress-induced miscarriage in mice [
46]. Based on the above, TNF-α may be involved in the pathogenesis of RPL.
The incidence of RPL is controlled by genetic factors, and genetic polymorphisms have been associated with poor pregnancy outcome [
16]. In the TNF-α gene, several polymorphisms had been identified, which might have a role in the pathogenesis of RPL, however, recent evidence dealing with the association of RPL and TNF-α gene polymorphisms presented some contradictory results. Several studies have reevaluated the connection between RPL risk and TNF-α polymorphisms [
20,
34]. A recent meta-analysis by Alkhurijiet al. [
17] suggested that the TNF-α gene polymorphism at position -308G/A could be a genetic predisposing factor for unexplained RPL while they found no association between TNF-α-238G/A polymorphism and RRL. In addition, several studies failed to find the association between the common polymorphisms in the TNF-α gene and RPL risk [
19,
33]. Since the discrepant study designs and statistical methods, and the diversities in sample sizes, countries of origin might lead to unreliable results, this present meta-analysis aimed to provide a more comprehensive and reliable conclusion between TNF-α gene functional polymorphisms and RPL.
The present meta-analysis included 1430 cases and 1727 controls from 10 independent case–control studies. The results suggested that -308G/A polymorphisms related with an elevated risk of RPL, indicating that -308G/A may be risk factors for RPL. However, no statistically significant association was observed between -238G/A and RPL risk. One possible reason behind this pattern of results could be that -308G/A polymorphism were more impactful than -238G/A on TNF-α gene expression and protein production, thereby possibly contributing to RPL risk. Moreover, stratification by geographic position, the polymorphism of -308G/A was significantly associated with RPL risk for Asians rather than non-Asians. The reason for the discrepancy is unclear, but it might be explained in part by geographic variation in the frequency of the allele A, i.e., TNF-α-308G/A polymorphism in the Asian patients was higher than non-Asians (14.86 vs.9.63%). The difference could also be explained by the small sample sizes of several included studies, which may lead to substantial errors from estimation [
22]. Thus, TNF-α-308G/A polymorphism may contribute to RPL susceptibility, especially in Asian population by the subgroup analysis.
In addition, no correlation was observed between -238G/A polymorphism and susceptibility to RPL. Smaller studies are often characterized by larger effects in this meta-analyses of -238G/A polymorphism, which can be possibly explained by publication bias [
47]. It is possible that publication bias may pose a problem for meta-analyses [
48]. Thus, more convincing evidences are required to draw a solid conclusion on the correlation between -238G/A polymorphism and the risk of RPL.
Our meta-analysis of the relationship between the TNF-α polymorphisms and RPL risk differs from the results previously reported by Zhang [
21]. The previous data demonstrated that TNF-α-308G/A, −238G/A polymorphisms are not associate with the risk of RPL in the overall population. This may be because the present study included five more studies and removed studies where diagnostic criteria of RPL were at least two consecutive spontaneous abortions [
33‐
37]. Our meta-analysis revealed, however, that the TNF-α-308G/A polymorphism is associated with susceptibility to RPL, especially in Asian populations, suggesting that TNF-α may play a role in RPL susceptibility.
As with other meta-analyses, it was prudent to acknowledge that several potential limitations were apparent in this analysis. First, the number of studies and the sample sizes were relatively small for analysis of each gene polymorphism thereby having insufficient power to estimate the association between TNF-α genetic polymorphisms and RPL risk. Second, a meta-analysis is a retrospective study, the selection bias would lead to the heterogeneity of the results, and thereby possibly influencing the reliability of our conclusions. Even though the studies have similar inclusion criteria, there are also some differences such as different examinations of each group patients, potential confounders (i.e., age, race) might skew the results. Finally, our study only included articles published in English from the three selected databases, which might limit the results of the meta-analysis. It was critical that larger and well-designed studies should be performed to reevaluate the association precisely.
Competing interests
All authors have no conflicts of interest.
Authors’ contributions
All the authors contributed to the conception of the meta-analysis. H-HL and X-HX: study conception and design, literature search, analysis and interpretation of data, drafting and revising the manuscript. JT: statistical analysis, providing additional data and revising the article for intellectual content and language. K-YZ: resolving the discrepancies between the two reviewers (H-HL and X-HX) in the selection of the study of interest, analysis and interpretation of data, and revising the manuscript. CZ and Z-JC: revising the article for intellectual content and revising the manuscript. All authors read and approved the final manuscript.