- About this Journal
- Abstracting and Indexing
- Aims and Scope
- Annual Issues
- Article Processing Charges
- Articles in Press
- Author Guidelines
- Bibliographic Information
- Citations to this Journal
- Contact Information
- Editorial Board
- Editorial Workflow
- Free eTOC Alerts
- Publication Ethics
- Reviewers Acknowledgment
- Submit a Manuscript
- Subscription Information
- Table of Contents
BioMed Research International
Volume 2013 (2013), Article ID 901740, 7 pages
No Association of IFNG+874T/A SNP and NOS2A-954G/C SNP Variants with Nitric Oxide Radical Serum Levels or Susceptibility to Tuberculosis in a Brazilian Population Subset
1Immunology and Immunogenetics Laboratory, Evandro Chagas Clinical Research Institute, Oswaldo Cruz Foundation, Avenida Brasil 4365, Manguinhos, 21045-900 Rio de Janeiro, RJ, Brazil
2Department of Genetics and Southwest National Primate Research Center, Texas Biomedical Research Institute, 7620 NW Loop 410, 78227-5301 San Antonio, TX, USA
3Tuberculosis Clinical Laboratory, Evandro Chagas Clinical Research Institute, Oswaldo Cruz Foundation, Avenida Brasil 4365, Manguinhos, 21045-900 Rio de Janeiro, RJ, Brazil
Received 1 April 2013; Revised 5 June 2013; Accepted 5 July 2013
Academic Editor: Helder I. Nakaya
Copyright © 2013 Ana Cristina C. S. Leandro et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Tuberculosis (TB) is one of the most common infectious diseases in the world. Mycobacterium tuberculosis infection leads to pulmonary active disease in approximately 5–10% of exposed individuals. Both bacteria- and host-related characteristics influence latent infection and disease. Host genetic predisposition to develop TB may involve multiple genes and their polymorphisms. It was reported previously that interferon gamma (IFN-γ) and nitric oxide synthase 2 (NOS2) are expressed on alveolar macrophages from TB patients and are responsible for bacilli control; thus, we aimed this study at genotyping single nucleotide polymorphisms IFNG+874T/A SNP and NOS2A-954G/C SNP to estimate their role on TB susceptibility and determine whether these polymorphisms influence serum nitrite and production. This case-control study enrolled 172 TB patients and 179 healthy controls. Neither polymorphism was associated with susceptibility to TB. NOS2A-954G/C SNP was not associated with serum levels of nitrite and . These results indicate that variants of IFNG+874T/A SNP and NOS2A-954G/C SNP do not influence TB susceptibility or the secretion of nitric oxide radicals in the study population.
Tuberculosis (TB) has been declared as a major global healthy threat by the World Health Organization since 1993. Pulmonary TB is highly prevalent in Brazil , mainly, in Rio de Janeiro, where 11,155 new cases were reported in 2011 . Host factors play a major role in determining risk for active TB. Among them, IFN-γ production is critical in the intracellular control of M. tuberculosis infection, as previously demonstrated in vitro [3, 4] in experimental infection [5, 6]. In addition, interferon gamma (IFN-γ) induces apoptosis in mycobacteria-infected macrophages in a nitric oxide (NO) dependent environment [7, 8]. Polymorphism in the first intron of human IFNG gene is associated with higher in vitro production of this cytokine and is correlated with a gene dosage effect in the presence of the IFNG+874T allele . This common polymorphism is associated with TB susceptibility in African, Turkish, Tunisian, and Central West Brazilian populations [10–13], but not in African-Americans, or people of Iranian, Hispanic, or Chinese origin [14–17].
NO is a free radical and second messenger that has been shown to be important in the development of several diseases, including TB. NO plays a major role in the pulmonary host-defense mechanism in response to infections and is implicated in bacteriostatic and bactericidal processes. NO is vital for macrophage function and granuloma formation in the immune response and kills M. tuberculosis in vitro . NO production and NOS2 expression in rat alveolar macrophages are upregulated in response to heat-killed M. tuberculosis . However, the role of NO in killing or limiting the growth of M. tuberculosis in humans is still unclear. It has been proposed that NO produced by TB-infected human macrophages and by epithelial cells exhibits antimycobacterial behavior against M. tuberculosis . It was previously reported that the alveolar macrophages from active TB patients express inducible nitric oxide synthase (iNOS/NOS2) and may control mycobacteria growth in vivo . Thus, the NOS2A-954G/C SNP may represent a pivotal protective locus against TB. Investigation of this possibility is hampered by difficulty in estimating the production of NO in vivo mainly in lung tissues, but genetic analysis provides a potential means of examining the relation between NOS2A expression and disease outcome. Given the biological and genetic validity of the role of NOS2 in the immune system, SNPs have been reported in many populations worldwide [22–24]. The NOS2A-954G/C SNP variant was originally reported in a malaria endemic area in Africa , suggesting that this mutation might have originated as a consequence of selective pressure of Plasmodium infection. In a Mexican admixed population, this functional SNP was not associated with TB  and no further reports have associated it with NO radical levels.
In this present case-control study, we investigated the influence of the IFNG+874T/A (rs2430561) and NOS2A-954G/C (rs1800482) SNPs on TB susceptibility in a highly exposed and admixed population of TB patients. We also conducted functional studies to determine whether the modulation of nitric oxide radical secretion varies according to NOS2A-954G/C or IFNG/NOS2A combined genotypes.
2. Materials and Methods
2.1. Study Population
Patients and control groups were recruited from Evandro Chagas Clinical Research Institute at Fiocruz and from Municipal Health Centers, Rio de Janeiro, Brazil. All volunteers included in this study lived in the metropolitan area of Rio de Janeiro City (RJ, Brazil), were older than 18 years, and provided written informed consent. Cases and control groups were matched by age, socioeconomic class and area of residence. Control groups individuals were excluded if they had a history of prior antituberculosis therapy, signs and symptoms of suggestive active TB. The diagnostic criteria for TB were defined as the presence of a positive smear for acid fast bacilli  and/or culture positivity for M. tuberculosis in a sample from sputum and/or bronchial lavage and/or other clinical specimens according to . HIV-infected people and those taking immunosuppressant drugs were excluded from participation in the study. The protocol was approved by the Research Ethics Committees in Brazil (IPEC REC ref. 0008.0.009.000-04) and Rio de Janeiro Municipal Health Centre (REC ref. S/CRH/DRH/DIC3). Ethnic background was determined for each case and control volunteers by self-identification. We recognize the inherent inaccuracy and potential bias in dichotomous self-assessment of ethnic origin, in an admixed population, but self-assessment might nevertheless lead to statistically significant differences between the two groups. All TB patients and control groups were negative for HIV 1/2 infection (following standard diagnosis from The Brazilian Ministry of Health). Tuberculin skin test (TST) response to 5UT RT-23 (Statens Serum Institute, Denmark) was performed, and the skin test response was measured at the diameter of induration 72 h after the injection. Positive results were obtained when induration was ≥10 mm. Control group was classified into those who were naturally infected with M. tuberculosis (latency) and those who were uninfected (TST < 10 mm). BCG vaccination status was determined by the presence of the scar tissue. Blood samples were taken after informed consent was obtained from each subject. Patients and controls from the same family were not enrolled in the study.
2.2. Genotyping of IFNG+874T/A and NOS2A-954G/C Gene Polymorphisms
Genomic DNA was extracted from fresh or frozen EDTA blood using a DNA purification kit (QIamp DNA mini Kit, Qiagen, USA) according to the manufacturer’s instructions. The IFNG+874T/A SNP was detected by amplification refractory mutational system (ARMS-PCR) . The NOS2A-954G/C SNP was detected by restriction fragment length polymorphism (RFLP) . Amplifications were performed in a 9700 Thermocycler (96-Well GeneAmp PCR System 9700, Applied Biosystems, USA) using 2.5 UI and 1.5 UI for IFNG and NOS2A of Taq DNA polymerase, respectively (GoTaq flexi DNA polymerase, Promega, USA). Cycling PCR conditions for IFNG+874T/A were 3 minutes at 95°C followed by 10 cycles at 95°C for 15 s, 65°C for 50 s, and 72°C for 40 s; 20 cycles at 95°C for 20 s, 55°C for 50 s, and 72°C for 50 s; 72°C for 7 minutes and 4°C until use. Cycling PCR conditions for NOS2A-954G/C were 3 minutes at 95°C followed by 30 cycles at 94°C for 10 s, 60°C for 30 s, and 72°C for 30 s; 72°C for 7 minutes and 4°C until use. The amplified products were evaluated by electrophoresis on a 1.5% (IFNG) and 2.5% (NOS2A) agarose gel containing ethidium bromide (0.5 μg/mL).
2.3. Detection of Serum Nitric Oxide Radicals Concentration in TB Patients
The two primary stable nonvolatile breakdown products of NO are nitrite () and nitrate (). First, the serum levels were determined using a commercial ready to use Griess reaction kit (Promega) according to the manufacturer’s instruction. Briefly, serum samples were mixed with sulfanilamide solution following incubation at room temperature. N-1-Naphthylethylenediamine dihydrochloride was added, and absorbance was measured in a plate reader with a filter of 420 nm. Values were plotted in accordance with a NaNO2 standard curve (0.8–100 mM). Further analysis was performed to determine the total levels of by reduced , in a Vanadium III reduction assay, following a protocol previously described by Miranda et al. . Vanadium III (Sigma, 400 mg in 50 mL of 0.1 N HCl) was added to each well, incubated for 90 minutes at 37°C, and read at 540 nm to determine the total amount of + (after reduction to ), which was named .
2.4. Statistical Analysis
Deviation from Hardy-Weinberg equilibrium for the genetic variants was assessed by the chi-square test (χ2) in both case and control groups. We used the χ2 test to compare the differences in each genotype, allele, and combined genotype of IFNG+874T/A SNP and NOS2A-954G/C SNP frequency. Additionally, unconditional univariate and multivariate logistic regression analyses were used to examine the associations between the selected SNPs and tuberculosis risk by estimating odds ratios (ORs) and 95% confidence intervals (CIs) with and without adjustment for gender, ethnicity, TST status, and previous BCG vaccination between TB and control groups. All statistical tests were two-sided, a value of ≤0.05 was considered significant, and analyses were performed using Epi Info 6 (Version 6.04, July 1996, CDC, Atlanta, GA, USA), SNPStats (http://bioinfo.iconcologia.net/SNPstats), and SPSS (Version 16, September 2007). Additionally, the distributions of IFNG+874T/A and NOS2A-954G/C SNPs were compared among patients and in whom TST was positive in the control group by the χ2 or Fisher’s exact test. Subgroup analyses for genotype, allele, and combined genotype associations to tuberculosis were also conducted among TST-positive individuals. The analysis of the skin test positive group was planned because it was thought that this would represent people with probable latent TB infection. ANOVA test was used to compare the nitrite and levels in association with NOS2A-954G/C SNP and combined IFNG+874T/A/NOS2A-954G/C SNPs genotypes with the level of significance set at .
3.1. Study Population
TB patients and control group were enrolled consecutively and included 105 males (61.0%) and 67 females (39.0%) with a mean age of 36.9 ± 12.7 years (mean ± standard deviation) in the TB group, and 63 males (35.2%) and 116 females (64.8%) with a mean age of 35.1 ± 11.5 years in the control group. Age was not significantly different between the groups. Each volunteer defined his or her own ethnic group as White (Caucasian) or non-White (Afro-descendants). No Indians or people with Asian background were identified in the included subjects. In the TB group, 136 of 172 (79.1%) individuals defined their ethnic group as White (52, 30.3%) or non-White (84, 48.8%), and among control group, 78 (43.6%) and 82 (45.8%) of 160 were White or non-White, respectively. TST ranged from 0 to 35 (14.9 ± 10.3) mm and from 0 to 57 (12.1 ± 12.2) mm in TB and control groups, respectively. TST-positive (≥10 mm) reaction was identified in 98 of 155 (54.7%) tested subjects from control group, confirming the highest M. tuberculosis exposure in Rio de Janeiro. No statistical significance in relation to TST positivity and ethnicity or gender was observed in either TB patients or control groups (Table 1).
3.2. IFNG+874T/A SNP Distribution Is Not Associated with Tuberculosis
The genotype distribution of IFNG+874T/A SNP was in Hardy-Weinberg equilibrium () in both TB and control groups. TB patients and control group had very similar genotype and allele distributions () (Table 2). No statistical difference in genotypes was observed between TB patients and control subgroup who were TST positive (Table 2). The ability to respond to TST did not correlate with IFNG+874T/A SNP genotypes in either TB patients or control group. There is no statistical difference in IFNG+874T/A SNP genotypes between TB patients and control groups from univariate or multivariate analysis regarding ethnicity, age, and BCG vaccination status.
3.3. NOS2-954G/C SNP Distribution Is Not Associated with Tuberculosis
The genotype distributions of NOS2A-954G/C SNP were in Hardy-Weinberg equilibrium () in both TB and control groups. No association was seen in the genotypes and alleles frequencies between TB patients and control groups and from those positives TST (control subgroup) (Table 2). When univariate analysis was performed by age, gender, ethnicity, and BCG vaccination, no statistical difference was observed () (Table 2).
3.4. Serum Nitrite and NOx− Levels Are Not Associated with NOS2-954G/C Polymorphism in Tuberculosis Patients
The Griess reaction was performed in 75 TB patients and 78 control group, in proportion to sample sizes of the two groups. The mean serum concentration of nitrite and exhibited no statistical difference between TB patients (23.68 ± 15.74 μM and 32.61 ± 16.97 μM) and control group (23.99 ± 17.29 μM and 34.71 ± 19.39 μM), respectively. It was investigated whether serum levels of nitrite and could vary according to NOS2A-954G/C SNP genotypes in TB patients and control group. No statistical association of serum nitrite (23.77 ± 15.59 versus 23.49 ± 17.39 and 23.13 ± 17.78 versus 27.40 ± 17.08, in TB patients and control group, resp.) or levels (32.40 ± 16.6 versus 34.22 ± 19.59 and 34.34 ± 20.99 versus 38.12 ± 18.67, in TB patients and control group, resp.) was observed with GG and GC genotypes of NOS2A-954G/C SNP (Figure 1) even in the TST-positive control subgroup (data not shown) was found. These results suggested that the low NOS2A-954G/G SNP or moderate NOS2A-954G/C SNP nitric oxide producers were not associated with the modulation of nitrite and radical production in either TB patients or control group. The frequency of higher nitric oxide radical producers NOS2A-954C/C SNP was rare in our population.
3.5. Combined Genotype of IFNG+874T/A and NOS2A-954C/G SNPs Is Not Associated with Either Tuberculosis or Nitrogen Radicals
To determine whether the combination of SNPs in these two genes was associated with susceptibility to TB, polymorphisms association was evaluated between pulmonary TB and control groups. The rare NOS2A-954C/C SNP was not taken into account in assessing the combined genotypes with the IFNG+874T/A SNP. No statistical significance was seen between TB and control groups in IFNG+874T/A and NOS2A-954G/C SNPs genotypic distributions (Table 3) when they were compared. In both groups, the most prevalent combined genotypes were AT/GG (40.7% and 44.7%) and AA/GG (36.0% and 31.3%) in TB and control groups, respectively, with no statistical difference. The secretion of reactive nitrogen radicals was not related with the combined genotypes when TB and control groups were compared. The most frequent combined genotype AT/GG in TB (23.63 ± 1.60 and 32.35 ± 1.63) and control groups (24.46 ± 1.90 and 34.83 ± 2.21) did not induce different serum levels of nitrite and . These results demonstrated in our population that the combined genotypes profiles of IFNG+874T/A SNP (low IFNG+874AA, moderate IFNG+874AT, or high IFNG+874TT producers) and NOS2A-954G/C SNP (low NOS2A-954GG or moderate NOS2A-954GC producers) are not associated with the modulation of the production of nitrite and radicals in both TB patients and control group or in TST-positive control subgroup.
IFN-γ mediated immune activation has an important role in immunity to intracellular pathogens. IFN-γ is critical to macrophage activation, and measurable levels are lower in patients with active TB than in control group [28, 29], but they are not correlated with protection . It has been more formally suggested that IFN-γ activity is a continuous, genetically controlled trait with genetic variability in both production and responsiveness to IFN-γ , although there is little evidence to support a role for variability in IFN-γ production. For the IFNG gene, there are two intronic SNPs that contribute to its expression phenotypes: +874T/A SNP and +2109G/A SNP . The AA genotype of IFNG+874T/A SNP is thought to confer a low-secretor phenotype of IFN-γ. Conversely, the TT genotype of IFNG+874T/A SNP is thought to confer a high-secretor phenotype [33, 34]. Some controversy exists concerning association of IFNG gene polymorphisms and susceptibility to pulmonary TB [14, 16, 35–37]. Our results showed no evidence of an association between IFNG gene polymorphism and susceptibility to TB. The AA genotype frequency of IFNG+874 in the control group (35.2%) was a little higher than that in the Sicilian (26%) , Spanish (28%) , and Indian populations (11%)  but was lower than that in South African (47%) , Hong Kong Chinese (46%) , and South Korean populations (74%) . Reports describing the T allele frequency (IFNG+874T/A SNP) revealed that there are ethnic differences at this allele distribution. It has been reported that the T allele frequency is significantly lower in a Japanese population (9%)  than in a South African population (32%)  and in an Italian Caucasian population (47%) . Rossouw et al.  reported a significantly lower T allele frequency of INFG+874T/A in patients with M. tuberculosis infection than that in control groups in a South African population with a high annual incidence of TB.
Lio et al.  and Vallinoto et al.  found that the TT genotype was relatively rare in TB patients from Sicilian and Brazilian populations. However, a study conducted in a Central West Brazilian population by Amim et al.  showed different results from our study; in that population, the AA genotype of IFNG+874T/A SNP was associated with TB susceptibility. Amim et al.  compared two different populations in their study: one from Rio de Janeiro (patients) and the other from Central West of Region Brazil (control group), which can be characterized as bias because Brazil was colonized by several ethnic groups that migrated from different countries into different regions of Brazil. During the last 500 years these populations became mixed with native Indians, and each Brazilian region has its own admixes ethnic group descendants. Our patients and control group were enrolled from Rio de Janeiro City, which is composed of migratory populations from all over the country. Thus, the population in this city has a genetic background that represents a mix of all regions of the country.
There is convincing evidence that NO and related reactive nitrogen intermediate (RNI) can kill and/or inhibit intracellular pathogens such as mycobacteria. IFN-γ knockout mice which are not capable of producing NO and RNI in response to the bacilli develop tuberculosis quickly, suggesting a role for NO and RNI in the defense mechanism against M. tuberculosis . In contrast to murine models of TB, there is greater controversy about the role of NO in killing or limiting the growth of M. tuberculosis in humans. Nevertheless, alveolar macrophages from TB patients express higher amounts of NOS2 compared to control group , demonstrating a possible role in affecting bacilli growth. Several SNPs have been described in this gene  given the importance of this gene in the immune response to TB. Our study verified the influence of NOS2A-954G/C SNP on the risk of developing TB in a Brazilian population from a highly endemic area. We did not observe a statistical difference between the NOS2A-954G/C SNP genotype in our TB patients and control group. The frequency of NOS2A-954G/C SNP may differ among populations. The C allele of NOS2A-954G/C SNP has been shown to be absent from Caucasian populations  and in Peruvian population  and in low frequency in Asia . However, the C allele has high frequency in African populations . A single description of NOS2A-954G/C SNP genotype study in Brazilian population, studying gastric cancer, showed different frequencies for GG, GC, and CC genotypes in NOS2A-954G/C SNP (64.77%, 28.69%, and 6.54%, resp.)  compared with our study. In Mexicans, this SNP was not associated with TB and C allele frequency was 5% .
The involvement of NOS2A SNPs has been studied in different pathologies and still has controversy results. In order to assess the nitric oxide radical levels and to compare them with NOS2A-954G/C SNP and combined genotypes of IFNG+874T/A SNP/NOS2A-954G/C SNP in TB patients and control groups, the secretions of nitrite and radicals were analyzed. No association was identified between TB and control groups or between different genotype profiles or combined genotypes regarding nitrite and production. Our results indicate that in our admixed population the association between disease development and IFNG+874T/A and NOS2A-954G/C SNPs does not exert selective pressure on M. tuberculosis via immune response surveillance, as shown by the absence of correlation of active TB with these SNPs profiles but can lead to different approaches to evaluate the tuberculosis immunopathology genetics background in the near future. Tuberculosis is a multifactorial disease and the pulmonary milieu involving the immune response and bacilli interaction in different genetic background and environment factors should be addressed to answer the question whether M. tuberculosis growth is controlled by other interaction candidate genes and/or several risk factors.
This work was supported by funds provided by the PAPES V-Fiocruz/CNPq and IPEC/Fiocruz. A. C. C. S. Leandro and M. A. Rocha received fellowships from CAPES/Brazil.
- WHO, “Global tuberculosis report 2012,” World Health Organization, Geneva, Switzerland, 2010 (WHO/HTM/TB/2012. 6), http://www.who.int/tb/publications/global_report/en/index.html.
- Sistema Nacional de Vigilância em Saúde, Relatório de Situação, Rio de Janeiro, Brazil, 2nd edition, 2011, http://bvsms.saude.gov.br/bvs/publicacoes/sistema_nacional_vigilancia_saude_rj_5ed.pdf.
- M. G. Bonecini-Almeida, S. Chitale, I. Boutsikakis et al., “Induction of in vitro human macrophage anti-Mycobacterium tuberculosis activity: requirement for IFN-γ and primed lymphocytes,” Journal of Immunology, vol. 160, no. 9, pp. 4490–4499, 1998.
- S. C. Cowley and K. L. Elkins, “CD4+ T cells mediate IFN-γ-independent control of Mycobacterium tuberculosis infection both in vitro and in vivo,” Journal of Immunology, vol. 171, no. 9, pp. 4689–4699, 2003.
- A. M. Cooper, D. K. Dalton, T. A. Stewart, J. P. Griffin, D. G. Russell, and I. M. Orme, “Disseminated tuberculosis in interferon γ gene-disrupted mice,” Journal of Experimental Medicine, vol. 178, no. 6, pp. 2243–2247, 1993.
- A. M. Green, R. Difazio, and J. L. Flynn, “IFN-γ from CD4 T cells is essential for host survival and enhances CD8 T cell function during Mycobacterium tuberculosis infection,” Journal of Immunology, vol. 190, no. 1, pp. 270–277, 2013.
- O. J. Kwon, “The role of nitric oxide in the immune response of tuberculosis,” Journal of Korean Medical Science, vol. 12, no. 6, pp. 481–487, 1997.
- B. M. Saunders, S. L. Fernando, R. Sluyter, W. J. Britton, and J. S. Wiley, “A loss-of-function polymorphism in the human P2X7 receptor abolishes ATP-mediated killing of mycobacteria,” Journal of Immunology, vol. 171, no. 10, pp. 5442–5446, 2003.
- V. Pravica, C. Perrey, A. Stevens, J. H. Lee, and I. V. Hutchinson, “A single nucleotide polymorphism in the first intron of the human IFN-γ gene: absolute correlation with a polymorphic CA microsatellite marker of high IFN-γ production,” Human Immunology, vol. 61, no. 9, pp. 863–866, 2000.
- G. S. Cooke, S. J. Campbell, J. Sillah et al., “Polymorphism within the interferon-γ/receptor complex is associated with pulmonary tuberculosis,” The American Journal of Respiratory and Critical Care Medicine, vol. 174, no. 3, pp. 339–343, 2006.
- N. Sallakci, M. Coskun, Z. Berber et al., “Interferon-γ gene+874T-A polymorphism is associated with tuberculosis and gamma interferon response,” Tuberculosis, vol. 87, no. 3, pp. 225–230, 2007.
- L. H. L. V. Amim, A. G. Pacheco, J. Fonseca-Costa et al., “Role of IFN-γ +874 T/A single nucleotide polymorphism in the tuberculosis outcome among Brazilians subjects,” Molecular Biology Reports, vol. 35, no. 4, pp. 563–566, 2008.
- W. B. Selma, H. Harizi, I. Bougmiza et al., “Interferon gamma +874T/a polymorphism is associated with susceptibility to active pulmonary tuberculosis development in Tunisian patients,” DNA and Cell Biology, vol. 30, no. 6, pp. 379–387, 2011.
- S. M. Mirsaeidi, M. Houshmand, P. Tabarsi et al., “Lack of association between interferon-gamma receptor-1 polymorphism and pulmonary TB in Iranian population sample,” Journal of Infection, vol. 52, no. 5, pp. 374–377, 2006.
- A. Moran, X. Ma, R. A. Reich, and E. A. Graviss, “No association between the +874T/A single nucleotide polymorphism in the IFN-γ gene and susceptibility to TB,” International Journal of Tuberculosis and Lung Disease, vol. 11, no. 1, pp. 113–115, 2007.
- J. H. Hwang, E. J. Kim, W. J. Koh et al., “Polymorphisms of interferon-γ and interferon-γ receptor 1 genes and non-tuberculous mycobacterial lung diseases,” Tuberculosis, vol. 87, no. 2, pp. 166–171, 2007.
- F. Wu, Y. Qu, Y. Tang, D. Cao, P. Sun, and Z. Xia, “Lack of association between cytokine gene polymorphisms and silicosis and pulmonary tuberculosis in Chinese iron miners,” Journal of Occupational Health, vol. 50, no. 6, pp. 445–454, 2008.
- L. M. Gómez, J. Anaya, J. R. Vilchez et al., “A polymorphism in the inducible nitric oxide synthase gene is associated with tuberculosis,” Tuberculosis, vol. 87, no. 4, pp. 288–294, 2007.
- S. S. Greenberg, J. Xie, J. Kolls, C. Mason, and P. Didier, “Rapid induction of mRNA for nitric oxide synthase II in rat alveolar macrophages by intratracheal administration of Mycobacterium tuberculosis and Mycobacterium avium,” Proceedings of the Society for Experimental Biology and Medicine, vol. 209, no. 1, pp. 46–53, 1995.
- K. A. Rockett, R. Brookes, I. Udalova, V. Vidal, A. V. S. Hill, and D. Kwiatkowski, “1,25-Dihydroxyvitamin D3 induces nitric oxide synthase and suppresses growth of Mycobacterium tuberculosis in a human macrophage-like cell line,” Infection and Immunity, vol. 66, no. 11, pp. 5314–5321, 1998.
- S. Nicholson, M. D. G. Bonecini-Almeida, J. R. L. e Silva et al., “Inducible nitric oxide synthase in pulmonary alveolar macrophages from patients with tuberculosis,” Journal of Experimental Medicine, vol. 183, no. 5, pp. 2293–2302, 1996.
- M. C. Levesque, M. R. Hobbs, N. M. Anstey et al., “Nitric oxide synthase type 2 promoter polymorphisms, nitric oxide production, and disease severity in Tanzanian children with malaria,” Journal of Infectious Diseases, vol. 180, no. 6, pp. 1994–2002, 1999.
- J. F. Kun, B. Mordmüller, D. J. Perkins et al., “Nitric oxide synthase 2Lambaréné (G-954C), increased nitric oxide production, and protection against malaria,” Journal of Infectious Diseases, vol. 184, no. 3, pp. 330–336, 2001.
- S. E. Jamieson, E. N. Miller, G. F. Black et al., “Evidence for a cluster of genes on chromosome 17q11-q21 controlling susceptibility to tubercolosis and leprosy in Brazilians,” Genes and Immunity, vol. 5, no. 1, pp. 46–57, 2004.
- P. O. Flores-Villanueva, J. A. Ruiz-Morales, C. H. Song et al., “A functional promoter polymorphism in monocyte chemoattractant protein-1 is associated with increased susceptibility to pulmonary tuberculosis,” Journal of Experimental Medicine, vol. 202, no. 12, pp. 1649–1658, 2005.
- Manual de recomendações para o controle da tuberculose no Brasil, Ministério da Saúde, Secretaria de Vigilãncia Sanitária, Programa Nacional de Controle da Tuberculose, 2010, http://portal.saude.gov.br/portal/arquivos/pdf/manual_tuberculose.pdf.
- K. M. Miranda, M. G. Espey, and D. A. Wink, “A rapid, simple spectrophotometric method for simultaneous detection of nitrate and nitrite,” Nitric Oxide—Biology and Chemistry, vol. 5, no. 1, pp. 62–71, 2001.
- F. O. Sanchez, J. I. Rodriguez, G. Agudelo, and L. F. Garcia, “Immune responsiveness and lymphokine production in patients with tuberculosis and healthy controls,” Infection and Immunity, vol. 62, no. 12, pp. 5673–5678, 1994.
- M. Zhang, Y. Lin, D. V. Iyer, J. Gong, J. S. Abrams, and P. F. Barnes, “T-cell cytokine responses in human infection with Mycobacterium tuberculosis,” Infection and Immunity, vol. 63, no. 8, pp. 3231–3234, 1995.
- D. López-Maderuelo, F. Arnalich, R. Serantes et al., “Interferon-γ and interleukin-10 gene polymorphisms in pulmonary tuberculosis,” The American Journal of Respiratory and Critical Care Medicine, vol. 167, no. 7, pp. 970–975, 2003.
- A. O'Garra, P. S. Redford, F. W. McNab, C. I. Bloom, R. J. Wilkinson, and M. P. Berry, “The immune response in tuberculosis,” Annual Review of Immunology, vol. 31, pp. 475–527, 2013.
- S. Dupuis, R. Döffinger, C. Picard et al., “Human interferon-γ-mediated immunity is a genetically controlled continuous trait that determines the outcome of mycobacterial invasion,” Immunological Reviews, vol. 178, pp. 129–137, 2000.
- V. Pravica, A. Asderakis, C. Perrey, A. Hajeer, P. J. Sinnott, and I. V. Hutchinson, “In vitro production of IFN-γ correlates with CA repeat polymorphism in the human IFN-γ gene,” European Journal of Immunogenetics, vol. 26, no. 1, pp. 1–3, 1999.
- S. Henri, F. Stefani, D. Parzy, C. Eboumbou, A. Dessein, and C. Chevillard, “Description of three new polymorphisms in the intronic and 3′ UTR regions of the human interferon gamma gene,” Genes and Immunity, vol. 3, no. 1, pp. 1–4, 2002.
- M. Rossouw, H. J. Nel, G. S. Cooke, P. D. van Helden, and E. G. Hoal, “Association between tuberculosis and a polymorphic NFκB binding site in the interferon γ gene,” The Lancet, vol. 361, no. 9372, pp. 1871–1872, 2003.
- H. W. Tso, W. K. Ip, W. P. Chong, C. M. Tam, A. K. S. Chiang, and Y. L. Lau, “Association of interferon gamma and interleukin 10 genes with tuberculosis in Hong Kong Chinese,” Genes and Immunity, vol. 6, no. 4, pp. 358–363, 2005.
- M. I. Henao, C. Montes, S. C. París, and L. F. García, “Cytokine gene polymorphisms in Colombian patients with different clinical presentations of tuberculosis,” Tuberculosis, vol. 86, no. 1, pp. 11–19, 2006.
- A. Abhimanyu, I. R. Mangangcha, P. Jha et al., “Differential serum cytokine levels are associated with cytokine gene polymorphisms in north Indians with active pulmonary tuberculosis,” Infection, Genetics and Evolution, vol. 11, no. 5, pp. 1015–1022, 2011.
- F. Poli, A. Nocco, S. Berra et al., “Allele frequencies of polymorphisms of TNFA, IL-6, IL-10 and IFNG in an Italian Caucasian population,” European Journal of Immunogenetics, vol. 29, no. 3, pp. 237–240, 2002.
- D. Lio, V. Marino, A. Serauto et al., “Genotype frequencies of the +874T→A single nucleotide polymorphism in the first intron of the interferon-γ gene in a sample of Sicilian patients affected by tuberculosis,” European Journal of Immunogenetics, vol. 29, no. 5, pp. 371–374, 2002.
- A. C. R. Vallinoto, E. S. Graça, M. S. Araújo et al., “IFNG +874T/A polymorphism and cytokine plasma levels are associated with susceptibility to Mycobacterium tuberculosis infection and clinical manifestation of tuberculosis,” Human Immunology, vol. 71, no. 7, pp. 692–696, 2010.
- D. K. Dalton, S. Pitts-Meek, S. Keshav, I. S. Figari, A. Bradley, and T. A. Stewart, “Multiple defects of immune cell function in mice with disrupted interferon-γ genes,” Science, vol. 259, no. 5102, pp. 1739–1742, 1993.
- J. F. J. Kun, B. Mordmüller, B. Lell, L. G. Lehman, D. Luckner, and P. G. Kremsner, “Polymorphism in promoter region of inducible nitric oxide synthase gene and protection against malaria,” The Lancet, vol. 351, no. 9098, pp. 265–266, 1998.
- J. Martín, J. E. Calzada, and A. Nieto, “Inducible nitric oxide synthase (NOS2) gene polymorphism and parasitic diseases,” The Lancet, vol. 353, no. 9146, p. 72, 1999.
- Y. C. Jorge, M. C. Duarte, and A. E. Silva, “Gastric cancer is associated with NOS2-954G/C polymorphism and environmental factors in a Brazilian population,” BMC Gastroenterology, vol. 10, article 64, 2010.