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. 2017 Oct 27;37(5):BSR20170240. doi: 10.1042/BSR20170240

IL-10 -1082 A>G (rs1800896) polymorphism confers susceptibility to pulmonary tuberculosis in Caucasians but not in Asians and Africans: a meta-analysis

Mohammed Y Areeshi 1, Raju K Mandal 1, Sajad A Dar 1,2, Arshad Jawed 1, Mohd Wahid 1, Mohtashim Lohani 1, Aditya K Panda 3, Bhartendu N Mishra 4, Naseem Akhter 5, Shafiul Haque00 1,
PMCID: PMC5658633  PMID: 28951522

Abstract

Background: Earlier studies have shown that interlukin-10 (IL-10) -1082 A>G gene polymorphism is implicated in susceptibility to pulmonary tuberculosis (PTB), but their results are inconsistent and inconclusive. In the present study, a meta-analysis was performed to analyze the potential association between IL-10 -1082 A>G gene polymorphism and PTB susceptibility.

Methods: A quantitative synthesis was done using PubMed (Medline), EMBASE, and Google Scholar web databases search and meta-analysis was performed by calculating pooled odds ratios (ORs) and 95% confidence intervals (95% CIs) for all the genetic models.

Results: A total of 22 eligible studies comprising 4956 PTB cases and 6428 healthy controls were included in the analysis. We did not observe any increased or decreased risk of PTB in allelic contrast (G vs. A: P=0.985; OR = 1.001, 95% CI = 0.863–1.162), homozygous (GG vs. AA: P=0.889; OR = 1.029, 95% CI = 0.692–1.529), heterozygous (GA vs. AA: P=0.244; OR = 0.906, 95% CI = 0.767–1.070), dominant (GG + AG vs. AA: P=0.357; OR = 1.196, 95% CI = 0.817–1.752), and recessive (GG vs. AA + AG: P=0.364; OR = 0.921, 95% CI = 0.771–1.100) genetic models. Likewise, no association of IL-10 -1082 A>G polymorphism with PTB risk was observed in Asian and African population for all the genetic models. Interestingly, the dominant model (GG + AG vs. AA: P=0.004; OR = 1.694, 95% CI = 1.183–2.425) demonstrated increased risk of PTB in Caucasian population.

Conclusions: This meta-analysis concludes that IL-10 -1082 A>G gene polymorphism is not significantly associated with overall, Asian and African population. However, this polymorphism is associated with Caucasian population.

Keywords: Meta-analysis, IL-10, pulmonary tuberculosis, polymorphism, genetic models

Introduction

Tuberculosis (TB) caused by Mycobacterium tuberculosis (M. tuberculosis or M. tb) is mainly a disease of the lungs mostly of pulmonary type tuberculosis (PTB), which can easily be spread to others by coughing and breathing. Regardless of availability of various effective treatment strategies, which were assumed to eliminate this disease, recent epidemiological figures of the year 2016 shown that TB is once more on the upsurge [1]. Globally, there is a large burden of disease with 9.6 million new cases and 1.5 million people are reported to deaths in the year 2014 [1].

Approximately one-third of the world’s population is thought to be affected with M. tuberculosis but relatively large number of population remains with no clinical sign of the disease. However, remaining 5–15% of the infected individuals develop active disease later in life [2]. This suggests that besides Mycobacteria itself, the host genetic factors may regulate the differences in host susceptibility to TB [3]. The identification of host genes and genetic variations that are important in susceptibility and resistance to tuberculosis would lead to a better understanding of the pathogenesis of PTB and perhaps lead to new approaches of the disease treatment or prophylaxis.

Immune response to PTB is regulated by interactions between lymphocytes with antigen-presenting cells and the cytokines secreted by these cell types. Cytokines, their genes and receptors have been implicated in the protective immunity, pathophysiology and in the development of tuberculosis [4]. Manifestation of clinical PTB depends on balance between T helper 1 (Th1) cytokines associated with resistance to infection and Th2 cytokines with progressive disease [5].

IL-10 gene maps on the long arm of chromosome 1 (1q31-1q32) locus and produced by both myeloid cells and T cells. IL-10 signals through a receptor complex consisting of two subunits: IL-10R1, induced on stimulated hematopoietic cells, and the IL-10R2, constitutively expressed on most cells and tissues [6].

IL-10, an anti-inflammatory cytokine prevents the protective immune response to pathogens by blocking the production of proinflammatory cytokines, such as TNF-α and Th1-polarizing cytokine IL-12, by directly acting on antigen-presenting cells such as macrophages and dendritic cells [7]. IL-10 may also inhibit phagocytosis and microbial killing by limiting the production of reactive oxygen and nitrogen intermediates in response to IFN-γ and Th1 induced response to TB [8,9]. IL-10 was shown to be elevated in the lungs and serum of PTB patients [10].

The production of cytokines can be modulated both by the stimuli present in the local environment as well as by the genetic factors. Both, in vitro and in vivo studies have demonstrated that the presence of polymorphisms within the coding or noncoding sequences of cytokine genes can alter the efficiency of transcription of these genes and thus the production of cytokines. Interindividual variations in IL-10 production are genetically contributed by polymorphisms within the promoter region. The polymorphism -1082 A>G occurs within a putative Ets (E26 transformation-specific) transcription factor-binding site and may affect the binding of this transcriptional factor and therefore altered levels of this cytokine and may alter Th1/ Th2 balance with major implications in tuberculous infection [11,12].

A number of clinical and genetic studies have been performed to consider the effect of IL-10 -1082 A>G (rs1800896) gene polymorphism on the development of PTB [1334]. Results published from previous studies are either conflicting or contradictory in nature and still it is unclear whether this polymorphism is associated with increased or decreased risk of PTB infection [1334]. Inconsistency in the results across many of the studies could possibly be due to the ethnicity of the population, sample size, and individual studies that have low power to evaluate the overall effect. To overcome this situation, nowadays meta-analysis statistical tool is in use to explore the risk factors associated with the genetic diseases, because it employs a quantitative method of pooling the data collected from individual studies where sample sizes are small to provide reliable conclusions. Hence, in the present study, a meta-analysis was performed to evaluate the effect of IL-10 -1082 A>G gene polymorphism on the risk of overall PTB development and its ethnicity-wise distribution.

Materials and methods

Literature search strategy

We performed a PubMed, Medline, EMBASE, and Google Scholar web databases search covering all research articles published with a combination of the following key words, i.e. IL-10, Interleukin-10 gene (polymorphism OR mutation OR variant) AND tuberculosis susceptibility or TB or Pulmonary tuberculosis or PTB (last updated on June 2016). We examined potentially pertinent genetic association studies by examining their titles and abstracts, and procured the most relevant publication matching with the eligible criteria for a closer examination. Besides the online database search, the references given in the selected research articles were also screened for other potential articles that may have been missed in the primary search.

Inclusion and exclusion criteria

In order to minimize heterogeneity and facilitate the proper interpretation of this study, published articles included in the current meta-analysis had to meet all the following criteria, i.e.

  • they must have done case–control studies between IL-10-1082 A>G gene polymorphism and PTB risk,

  • clearly described confirmed PTB patients and PTB free controls

  • have available genotype frequency in the both cases and controls

  • published in the English language

  • data collection and analysis methodology should be statistically acceptable

  • additionally, when the case–control study was included in more than one research article using the same subject series, we selected the research study that incorporated the largest number of individuals.

The major reasons for study exclusion were:

  • duplicate or overlapping publication

  • study design based on only PTB cases

  • genotype frequency not reported

  • data of review or abstract

Data extraction and quality assessment

For each retrieved study, the methodological quality assessment and data extraction were independently abstracted in duplicate by two independent investigators (SAD & RKM) using a standard protocol. Data collection form was used to confirm the accuracy of the collected data by strictly following the inclusion/exclusion criteria as stated above. In case of disagreement between the above mentioned two investigators on any item related with the data collected from the selected studies, the issue was fully debated and deliberated with the investigators to attain a final consensus. Also, in case failure of reaching consensus between the two investigators, an agreement was achieved following an open discussion with the adjudicator (SH). The major characteristics abstracted from the retrieved publications included the name of first author, publication year, the country of origin, source of cases and controls, number of cases and controls, study type, genotype frequencies, and association with pulmonary TB.

Quality assessment of the included studies

Methodological quality evaluation of the selected studies was performed independently by two investigators (RKM & SAD) by following the Newcastle–Ottawa Scale (NOS) of quality assessment [35]. The NOS quality assessment criteria included three major aspects: (i) subject selection: 0–4 points, (ii) comparability of subject: 0–2 points, and (iii) clinical outcome: 0–3 points. Selected case–control studies that gained five or more stars were considered as of moderate to good quality [36].

Statistical analysis

In order to evaluate the association between the IL-10 -1082 A>G gene polymorphism and risk of developing PTB, pooled ORs and their corresponding 95% CIs were estimated. Heterogeneity assumption was examined by the chi-square-based Q-test [37]. Heterogeneity was considered significant at P-value < 0.05. The data from single comparison were combined using a fixed effects model [38], when no heterogeneity was obtained. Otherwise the random-effects model was used for the pooling of the data [39]. Moreover, I2 statistics was employed to quantify interstudy variability and larger values suggested an increasing degree of heterogeneity [40]. Hardy–Weinberg equilibrium (HWE) in the controls was calculated by chi-square test. Funnel plot asymmetry was measured by Egger’s regression test, which is a type of linear regression approach to measure the funnel plot asymmetry on the natural logarithm scale of the OR. The significance of the intercept was measured by the t-test (P-value < 0.05 was considered as a representation of statistically significant publication bias).

A comparative assessment of ‘meta-analysis’ based programs was done by using weblink http://www.meta-analysis.com/pages/comparisons.html. The Comprehensive Meta-Analysis (CMA) Version 2 software program (Biostat, U.S.A.) was utilized to perform all the statistical analysis involved in this meta-analysis.

Results

Characteristics of the published studies

A total of 22 articles were lastly selected after literature search from the PubMed (Medline), EMBASE, and Google Scholar web databases. All retrieved articles were inspected carefully by reading their titles and abstracts, and the full-texts for the potentially relevant publications were further checked for their aptness of inclusion in this meta-analysis (Figure 1: PRISMA 2009 Flow Diagram). All the included 22 studies follow the preset eligible criteria of the study inclusion and clearly stated about sample sizes, genotypes, inclusion criteria of PTB patients, and healthy controls. All the studies included in this meta-analysis had recruited HIV free subjects.

Figure 1. PRISMA flow-diagram.

Figure 1

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The selection process (inclusion/exclusion) of the studies dealing with IL10 -1082 A>G (rs1800871) gene polymorphism and PTB risk.

Research articles either showing IL-10 polymorphism to predict survival in PTB patients or considering IL-10 variants as indicators for response to therapy were excluded straightaway. Similarly, studies investigating the levels of IL-10 mRNA or protein expression or relevant review articles were also excluded from this meta-analysis. We included only case–control or cohort design studies stating the frequency of all three genotypes. Besides the database search, the supporting references available in the retrieved articles were also checked for other potential studies. After careful screening and following the inclusion and exclusion criteria, 22 eligible original published studies were finally considered for the present study (Table 1). Distribution of genotypes, HWE P-values in the controls, and susceptibility toward PTB have been shown in Table 2. All the selected studies (22 in number) were examined for the overall quality following the NOS and most of the studies (>80%) scored five stars or more, indicating a modest to good quality (Table 3).

Table 1. Main characteristics of all studies included in the present meta-analysis.

First author and year [Ref.] Country Ethnicity Controls Cases Study Genotyping technique
Hu et al., 2015 [13] China Asian 480 120 HB ARMS PCR
Feng et al., 2014 [14] China Asian 191 191 HB PCR-RFLP
García-Elorriaga et al., 2013 [15] Mexico Mixed 47 40 HB TaqMan
Akgunes et al., 2011 [16] India Asian 30 30 HB PCR Probe
Liang et al., 2011 [17] China Asian 78 112 HB SNaPshot assay
Ansari et al., 2011 [18] Pakistan Asian 166 102 HB,PB ARMS PCR
Ben-Selma et al., 2011 [19] Tunisia African 95 76 HB ARMS PCR
Taype et al., 2010 [20] Peru Caucasian 510 500 PB PCR-RFLP
Mosaad et al., 2010 [21] Egypt African 98 26 HB ARMS PCR
Thye et al., 2009 [22] Ghana African 1968 1541 HB FRET
Ansari et al., 2009 [23] Pakistan Asian 188 111 HB ARMS PCR
Trajkov et al., 2009 [24] Macedonia Caucasian 301 75 HB, PB PCR-SSP
Selvaraj et al., 2008 [25] India Asian 183 155 HB ARMS PCR
Wu et al., 2008 [26] China Asian 111 183 PB PCR RFLP
Anand et al., 2007 [27] India Asian 143 132 HB ARMS PCR
Oh et al., 2007 [28] Korea Asian 117 145 HB ARMS PCR
Amirzargar et al., 2006 [29] Iran Asian 123 41 HB PCR-SSP
Shin et al., 2005 [30] Korea Asian 871 459 HB MAPA
Scola et al., 2003 [31] Italy Caucasian 114 45 HB ARMS PCR
López-Maderuelo et al., 2003 [32] Spain Caucasian 100 113 HB ARMS PCR
Delgado et al., 2002 [33] Cambodia Asian 106 358 HB PCR-SSP
Bellamy et al., 1998 [34] Gambia African 408 401 HB Hybridization
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Abbreviations: ARMS PCR, amplification-refractory mutation system polymerase chain reaction; FRET, fluorescence resonance energy transfer; HB, hospital based; MAPA, multiplex automated primer extension analysis; PB, population based; PCR-SSP, polymerase chain reaction with a sequence specific primers.

Table 2. Genotypic distribution of IL-10 -1082 A>G (rs1800896) gene polymorphism included in the meta-analysis.

First author and year Controls Cases
Genotype Minor allele Genotype Minor allele HWE
AA GA GG MAF AA GA GG MAF P-value
Hu et al., 2015 262 196 22 0.250 82 34 4 0.175 0.35
Feng et al., 2014 171 18 2 0.057 164 24 3 0.078 0.08
Elorriaga et al., 2013 25 18 4 0.276 27 11 2 0.187 0.01
Akgunes et al., 2011 17 13 0 0.216 15 9 6 0.350 0.26
Liang et al., 2011 69 9 0 0.057 100 12 0 0.053 0.11
Ansari et al., 2011 31 118 17 0.457 23 64 15 0.460 0.04
Ben-Selma et al., 2011 60 26 9 0.231 30 33 13 0.388 0.01
Taype et al., 2010 347 153 10 0.169 333 147 20 0.187 0.28
Mosaad et al., 2010 8 88 2 0.469 0 16 10 0.692 0.13
Thye et al., 2009 1048 783 140 0.269 794 630 117 0.280 0.27
Ansari et al., 2009 32 136 20 0.468 21 71 19 0.490 0.03
Trajkov et al., 2009 70 212 17 0.411 17 48 10 0.453 0.04
Selvaraj et al., 2008 108 69 6 0.221 102 42 5 0.174 0.83
Wu et al., 2008 104 18 0 0.073 48 12 1 0.114 0.98
Anand et al., 2007 73 61 6 0.260 74 55 3 0.231 0.01
Oh et al., 2007 45 53 19 0.388 98 43 4 0.175 0.95
Amirzargar et al., 2006 18 79 5 0.436 7 31 2 0.437 0.04
Shin et al., 2005 718 124 9 0.083 394 53 2 0.063 0.47
Scola et al., 2003 13 77 24 0.548 6 22 17 0.622 0.05
Maderuelo et al., 2003 21 50 29 0.540 33 47 33 0.501 0.91
Delgado et al., 2002 39 64 3 0.330 86 259 11 0.394 0.06
Bellamy et al., 1998 179 184 45 0.335 165 185 11 0.286 0.07
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Abbreviations: HWE, Hardy–Weinberg equilibrium; MAF, minor allele frequency;.

Table 3. Quality assessment conducted according to the NOS for all the studies included in the meta-analysis.

First author and year [Ref.] Quality indicators
Selection Comparability Exposure
Hu et al., 2015 [13] *** * **
Feng et al., 2014 [14] *** * **
García-Elorriaga et al., 2013 [15] *** * **
Akgunes et al., 2011 [16] ** * **
Liang et al., 2011 [17] **** ** **
Ansari et al., 2011 [18] *** * **
Ben-Selma et al., 2011 [19] **** * **
Taype et al., 2010 [20] **** * **
Mosaad et al., 2010 [21] *** * **
Thye et al., 2009 [22] **** ** **
Ansari et al., 2009 [23] *** * **
Trajkov et al., 2009 [24] *** * **
Selvaraj et al., 2008 [25] **** * **
Wu et al., 2008 [26] *** * ***
Prabhu Anand et al., 2007 [27] *** * ***
Oh et al., 2007 [28] ** * **
Amirzargar et al., 2006 [29] ** * **
Shin et al., 2005 [30] **** * **
Scola et al., 2003 [31] ** * **
López-Maderuelo et al., 2003 [32] *** * **
Delgado et al., 2002 [33] *** ** **
Bellamy et al., 1998 [34] *** * **
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Publication bias

Begg’s funnel plot and Egger’s test were performed to examine the publication bias among the selected studies for the present meta-analysis. The funnel plots were almost symmetric for both the Begg’s test and Egger’s test (Figure 2). The findings showed lack of publication bias among all comparison models (Table 4).

Figure 2. Funnel plot: Begg’s Funnel plot for overall analysis.

Figure 2

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Table 4. Statistics to test publication bias and heterogeneity in meta-analysis: overall analysis.

Comparisons Egger’s regression analysis Heterogeneity analysis Model used for the meta-analysis
Intercept 95% confidence interval P-value Q-value Pheterogeneity I2 (%)
G vs. A 0.134 −1.53 to 1.80 0.868 78.171 0.001 73.13 Random
GG vs. AA 0.261 −1.12 to 1.64 0.696 60.855 0.001 67.135 Random
AG vs. AA −0.494 −1.68 to 0.69 0.396 48.356 0.001 56.572 Random
GG + AG vs. AA −0.293 −1.63 to 1.04 0.651 60.090 0.001 65.052 Random
GG vs. AA + AG 0.420 −1.10 to 1.94 0.570 69.612 0.001 71.270 Random
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Test of heterogeneity

In order to test heterogeneity among the selected studies, Q-test and I2 statistics were employed. Significant heterogeneity was detected in all models. Therefore, random effects model was applied to synthesize the data (Table 4).

Sensitivity analysis

Sensitivity analysis was performed to assess the influence of each individual study on the pooled OR by deleting one single study each time. The results showed that no individual affected the pooled OR significantly, suggesting stability of this meta-analysis (Figure 3).

Figure 3. Forest Plot: Sensitivity analysis for overall analysis.

Figure 3

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Quantitative synthesis

We pooled all the 22 studies together which resulted into 4956 confirmed PTB cases and 6428 controls, for the assessment of overall association between the IL-10 -1082 gene polymorphism and risk of developing PTB. The pooled ORs from the overall studies indicated no association with increased or decreased risk between IL-10 -1082 A>G gene polymorphism and PTB susceptibility in allelic contrast (G vs. A: P=0.985; OR = 1.001, 95% CI = 0.863–1.162), homozygous (GG vs. AA: P=0.889; OR = 1.029, 95% CI = 0.692–1.529), heterozygous (GA vs. AA: P=0.244; OR = 0.906, 95% CI = 0.767–1.070), dominant (GG + AG vs. AA: P=0.357; OR = 1.196, 95% CI = 0.817–1.752), and recessive (GG vs. AA + AG: P=0.364; OR = 0.921, 95% CI = 0.771–1.100) genetic models, respectively (Figures 3 and 4).

Figure 4. Forest plot: Overall analysis showing OR with 95% CI to evaluate the association of the IL10 -1082 A>G (rs1800871) gene polymorphism and PTB risk. Black squares represent the value of OR and the size of the square indicates the inverse proportion relative to its variance. Horizontal line is the 95% CI of OR.

Figure 4

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Subgroup analysis

We have performed subgroup analysis based on ethnicity to explore the effect of ethnicity (Asian, African, and Caucasian) in the risk between IL-10 -1082 A>G and PTB risk.

Asian population

In Asian population, 13 studies were included and heterogeneity was observed in all the genetic models (Table 5). We performed analyses using random effect models for all the genetic models and no significant association of PTB susceptibility in all genetic models was detected in allele model (G vs. A: P=0.466; OR = 0.917, 95% CI = 0.726–1.158), homozygous model (GG vs. AA: P=0.602; OR = 0.853, 95% CI = 0.4710–1.547), heterozygous model (GA vs. AA: P=0.170; OR = 0.839, 95% CI = 0.652–1.078), dominant model (GG + AG vs. AA: GG vs. AA + AG: P=0.836; OR = 0.945, 95% CI = 0.554–1.613), and recessive model (GG vs. AA + AG: P=0.282; OR = 0.858, 95% CI = 0.650– 1.134) (Figure 5).

Table 5. Statistics to test publication bias and heterogeneity in the present meta-analysis: Asian population.

Comparisons Egger’s regression analysis Heterogeneity analysis Model used for the meta-analysis
Intercept 95% confidence interval P-value Q-value Pheterogeneity I2 (%)
G vs. A 1.686 −2.38 to 5.75 0.380 44.674 0.001 73.139 Random
GG vs. AA 1.018 −1.08 to 3.88 0.446 24.674 0.010 55.419 Random
AG vs. AA 0.883 −2.29 to 4.06 0.552 28.851 0.004 58.409 Random
GG+AG vs. AA 1.672 −1.85 to 5.19 0.318 37.372 0.001 67.890 Random
GG vs. AA+AG 0.025 −2.42 to 2.47 0.981 22.603 0.020 51.334 Random
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Figure 5. Forest plot: Data from the Asian population showing OR with 95% CI to evaluate the association of the IL10 -1082 A>G (rs1800871) gene polymorphism and PTB risk. Black squares represent the value of OR and the size of the square indicates the inverse proportion relative to its variance. Horizontal line is the 95% CI of OR.

Figure 5

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African population

In African population four studies were found. Publication bias was not significant but heterogeneity was found significant and conducted analyses using random effect models for all the genetic models (Table 6). We found no association with PTB risk in allele model (G vs. A: P=0.165; OR = 1.300, 95% CI = 0.898–1.883), homozygous model (GG vs. AA: P=0.569; OR = 1.407, 95% CI = 0.434–4.562), heterozygous model (GA vs. AA: P=0.128; OR = 1.101, 95% CI = 0.973–1.246), dominant model (GG + AG vs. AA: P=0.438; OR = 1.614, 95% CI = 0.482–5.412), and recessive model (GG vs. AA + AG: P=0.244; OR = 1.240, 95% CI = 0.863–1.783) genetic models (Figure 6).

Table 6. Statistics to test publication bias and heterogeneity in the present meta-analysis: African population.

Comparisons Egger’s regression analysis Heterogeneity analysis Model used for the present meta-analysis
Intercept 95% confidence interval P-value Q-value Pheterogeneity I2 (%)
G vs. A 2.415 −7.48 to 12.31 0.403 21.824 0.001 86.254 Random
GG vs. AA 1.047 −11.12 to 13.21 0.746 26.345 0.001 88.613 Random
AG vs. AA 1.562 −2.28 to 5.40 0.222 6.646 0.084 54.862 Fixed
GG + AG vs. AA 1.610 −4.12 to 7.34 0.350 10.073 0.018 70.216 Random
GG vs. AA + AG 1.486 −13.42 to 16.40 0.709 35.484 0.001 91.545 Random
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Figure 6. Forest plot: Data from the African population showing OR with 95% CI to evaluate the association of the IL10 -1082 A>G (rs1800871) gene polymorphism and PTB risk. Black squares represent the value of OR and the size of the square indicates the inverse proportion relative to its variance. Horizontal line is the 95% CI of OR.

Figure 6

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Caucasian population

In Caucasian population four studies were included. Publication bias and heterogeneity were not significant, hence fixed effect models were applied for all the genetic models (Table 7). We potentially found association of PTB risk with dominant model (GG + AG vs. AA: P=0.004; OR = 1.694, 95% CI = 1.183– 2.425). Whereas, other genetic models, i.e. allele (G vs. A: P=0.236; OR = 1.103, 95% CI = 0.938–1.298), homozygous model (GG vs. AA: P=0.098; OR = 1.439, 95% CI = 0.935–2.215), heterozygous model (GA vs. AA: P=0.446; OR = 0.915, 95% CI = 0.729–1.150), and recessive model (GG vs. AA + AG: P=0.926; OR = 0.990, 95% CI = 0.794–1.233) did not show any increased or decreased risk of PTB with IL-10 -1082 A>G gene polymorphism (Figure 7).

Table 7. Statistics to test publication bias and heterogeneity in the present meta-analysis: Caucasian population.

Comparisons Egger’s regression analysis Heterogeneity analysis Model used for the present meta-analysis
Intercept 95% confidence interval P-value Q-value Pheterogeneity I2 (%)
G vs. A 0.158 −8.42 to 8.74 0.940 2.616 0.455 0.001 Fixed
GG vs. AA 2.859 −16.58 to 22.30 0.590 5.366 0.147 44.089 Fixed
AG vs. AA −1.361 −4.15 to 1.42 0.170 2.446 0.485 00.001 Fixed
GG + AG vs. AA −1.031 −4.68 to 2.62 0.348 2.235 2.235 0.5250 Fixed
GG vs. AA + AG 8.205 3.75 to 12.65 0.015 4.744 0.192 36.760 Fixed
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Figure 7. Forest plot: Data from the Caucasian population showing OR with 95% CI to evaluate the association of the IL10 -1082 A>G (rs1800871) gene polymorphism and PTB risk. Black squares represent the value of OR and the size of the square indicates the inverse proportion relative to its variance. Horizontal line is the 95% CI of OR.

Figure 7

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Discussion

Although various mechanisms have been described for the development of a protective immune response that restricts and controls the infection and thus prevents the progression of the active disease, the reasons underlying active disease progression remain poorly understood [41]. Candidate gene approach and association studies have identified various host genetic factors that affect the susceptibility to TB [41]. As an immune response modulator, IL-10 has a crucial role to suppress proinflammatory cytokine responses by the innate and adaptive immune systems [42]. IL-10 is also thought to play an important regulatory role in many bacterial infections [43,44]. Immunoregulatory genes are very important in modulating the host susceptibility to PTB because the first line of defense against M. tuberculosis involves the identification and uptake of the bacterium by macrophages and dendritic cells [45].

As we know that PTB is one of the most common infectious diseases with a high morbidity and mortality [1]. A well-established genetic marker surely would have a significant influence in screening and prevention of PTB. Cytokine polymorphism has been considered to be of important roles in host genetic factors. Among them, IL-10 is an essential pleiotropic cytokine which takes part in immunoregulatory activities. Lately, IL-10 gene has been widely studied and some studies suggested that the IL-10 -1082 A>G polymorphism is associated with PTB susceptibility, but the results are inconsistent. The results of studies generated could be having insufficient statistical power of individual studies with small sample sizes or variations that existed in different population. Therefore, we conducted this meta-analysis to provide more accurate statistical evidence of association between IL-10 -1082 A>G polymorphism and PTB susceptibility. Pooled ORs generated from large sample size and sufficient statistical power from various studies have the advantage of reducing random errors [46].

In the present study, we have included 22 studies with all the preset eligible criteria of sample size, genotype, inclusion criteria of PTB patients, and healthy controls. Most of the included studies scored five or more stars in NOS quality score assessment and suggested good to moderate quality by clearly stating about the sample size, genotype, inclusion criteria of PTB patients, and healthy controls.

Overall, we found that there was no association between IL-10 -1082 A>G polymorphism and PTB susceptibility under any genetic models in overall analysis.

These observations suggested that the IL-10 -1082 A allele leads to increased resistance to PTB. Studies carried out on mice observed that overexpression of IL-10 may not be important for susceptibility to initial infection with M. tb but may play a role in reactivation of the latent disease [47]. Other studies also reported no association between the said polymorphism and resistance to TB [48,49].

During the subgroup analysis, we found that IL-10 -1082 A>G polymorphism has no role of increasing or decreasing PTB susceptibility in Asian and African populations. Interestingly, significant association was found with dominant model. This result implied that among different ethnicities, the same gene polymorphism may act differently in PTB susceptibility. Tuberculosis report clarified racial differences of susceptibility to TB [50]. Thus, the current results of the present study might attribute the racial differences and reflect the existence of racial differences of TB.

However, the susceptibility toward PTB is polygenic and multiple candidate genes are likely to be involved in determining resistance or susceptibility to TB [51]. Due to multifactorial nature of TB infection and complex nature of the immune system, IL-10 -1082 A>G genetic polymorphism cannot be solely responsible for the predisposition of PTB.

In the present study, significant heterogeneity was found between the selected studies in the test of heterogeneity. This discordance may be related to the ethnic origin of the patients as ethnicity-specific genetic variations may influence the host immunity to PTB. Nevertheless, some limitations also need to be addressed. First, we only included studies published in the English language, abstracted and indexed by the selected electronic databases were included for data analysis; it is possible that some pertinent studies published in other languages and indexed in other electronic databases may have missed. Second, the abstracted data were not stratified by other factors, e.g. HIV status or severity of the TB infection, and our results were based on unadjusted parameters. Third, we did not test for gene–environment interactions because of inadequate data available in the published reports. Despite above limitations, there are some advantages of the present study. First, the present meta-analysis was comprised with more number of studies which increased the statistical power of the study and ultimately reached at robust conclusion. Second, no publication bias was observed and further sensitivity analysis also supported our results more reliably.

Also, all the included studies were of good to modest quality fulfilling the preset needful criteria as tested by NOS quality score evaluation scale.

Conclusions

In conclusion, this meta-analysis demonstrated that IL-10 -1082 A>G gene polymorphism is not associated with PTB risk in overall, Asian and African population. Our result provided evidence that G allele carrier is associated with PTB in Caucasian population. In the near future, because of significant public health impact of PTB, larger studies are warranted to identify the host genes with their functional allele controlling the response to mycobacterial infections. This will help in the identification of the host genetic factors for the susceptibility to PTB, and would greatly help in the global control of this infectious disease.

Acknowledgments

The authors are thankful to the Deanship of Scientific Research, Jazan University, Jazan, Saudi Arabia for providing the necessary facilities for this research study.

Abbreviations

CI

confidence interval

HWE

Hardy–Weinberg equilibrium

IFN-y

Interferon gamma

IL-10

interlukin-10

NOS

Newcastle–Ottawa Scale

OR

odds ratio

PTB

pulmonary tuberculosis

Th1

T helper 1

TNF-a

Tumor necrosis factor - alpha

Competing Interests

The authors declare that there are no competing interests associated with the manuscript.

Funding

The authors declare that there are no sources of funding to be acknowledged.

Author Contribution

M.Y.A., R.K.M., S.A.D., A.J., M.W., M.L., A.K.P., B.N.M., N.A., and S.H. conceived and designed the study. M.Y.A., R.K.M., S.A.D., A.J., and M.W. searched the literature for selection of relevant studies. M.L., A.K.P., B.N.M., N.A., and S.H. verified the selection and extracted the required data from the articles. R.K.M., S.A.D., A.J., A.K.P., and S.H. performed the analysis. R.K.M., S.A.D., and S.H. wrote the paper. All the authors reviewed and approved the final manuscript.

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