docPredisposition to idiopathic thrombocytopenic purpura maps
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Predisposition to idiopathic thrombocytopenic purpura maps
Human Immunology 70 (2009) 179-183 Contents lists available at ScienceDirect Predisposition to idiopathic thrombocytopenic purpura maps close to the major histocompatibility complex class I chain-related gene A Maria Helena Thomaz Maia a,*, Raquel de Lima Peixoto a, Clayton Pereira Silva de Lima a, Milena MagalhÄes a, Leonardo Sena b, PerpÊtua do Socorro Silva Costa a, FabÎola Brasil Barbosa a, Layanna Freitas de Oliveira a, Matilde Romero c, Christina Nogueira de Araujo Silva c, Eduardo JosÊ Melo dos Santos a a b c Laboratòrio de Genètica Humana e Mèdica, Instituto de Ciéncias Biològicas, Universidade Federal do Parà, Belèm, PA, Brasil Departamento de Patologia, Universidade do Estado do Parà, Belèm, PA, Brasil Laboratòrio de Imunogenètica, Instituto Nacional do Cáncer, Rio de Janeiro, RJ, Brasil A R T I C L E I N F O Article history: Received 26 May 2008 Accepted 16 January 2009 Available online 23 January 2009 Keywords: Idiopathic thrombocytopenic purpura MHC Microsatellites MICA A B S T R A C T Idiopathic thrombocytopenic purpura (ITP) is an autoimmune condition with poorly known etiology, characterized by platelet destruction. Genetic association studies of this disease are scarce, discrepant, and restricted to major histocompatibility complex (MHC) polymorphisms. Hence, a case– control study was conducted with an aim to map the MHC to IPT susceptibility using HLA-B and nine microsatellite loci encompassing MHC class I, II, and III regions. We compared the allelic frequencies in samples of unrelated healthy controls and ITP patients. After correction for multiple tests, only allele MICA*183, also known as A5.1, demonstrated an association, resulting in the identification of a major predisposing region close to STR-MICA. This result may highlight the putative functional role of MICA in the immune response to ITP. 䉷 2009 American Society for Histocompatibility and Immunogenetics. Published by Elsevier Inc. All rights reserved. 1. Introduction Autoimmune thrombocytopenia arises from the early destruction of platelets by antiplatelet autoantibodies in the activated endothelial reticulum system [1,2]. The resulting disease is characterized by a severe decrease in platelet numbers in the peripheral blood, followed by symptoms such as petechiae, purpura, conjunctional hemorrhage, or other types of mucocutaneous bleeding [3]. Autoantibodies found in autoimmune thrombocytopenia may have distinct origins, differentiating the condition into four broad groups: idiopathic thrombocytopenic purpura (ITP), secondary immune thrombocytopenia (e.g., secondary to systemic lupus erythematosus), drug-induced immune thrombocytopenia, and viral infection-related thrombocytopenia (e.g., HIV) [1]. Among those groups, ITP has a significant incidence of around 6:100,000 inhabitants per year [4], although the fundamental disturbances that lead to its autoimmune response are unknown. Genetic factors can influence the development of autoimmune diseases, especially immune-response genes, including the human leukocyte antigen (HLA) genes. Indeed, some association studies have indicated genetic polymorphisms on HLA genes as predisposing factors to ITP [5–10]. However, the associations reported were generally weak and varied among the studies. Possible reasons for the lack of * Corresponding author. E-mail address: [email protected] (M.H.T. Maia). reproducibility in previous studies include different diagnostic criteria for ITP, ethnic variability in the HLA allele distribution, and the use of serological typing methods, which are unable to identify HLA alleles at the amino acid level. In addition, HLA analysis may be further complicated by linkage disequilibrium with other genes of the major histocompatibility complex (MHC). The first stage of the present study aimed to map the MHC using microsatellite markers encompassing the most relevant class I, II, and III recombination blocks [11] to identify the primary ITP predisposing/protective regions. Because the region around major histocompatibility complex class I chain-related gene A (MICA), represented by the STR-MICA, exhibited the strongest association signal in our study and the HLA-B locus was reported to be associated with ITP in some studies [8,10], this locus was genotyped and analyzed to certify that the possible association of ITP with MICA polymorphisms was not secondary based on linkage disequilibrium with this locus. 2. Subjects and methods Of about 400 patients registered at the Foundation Center of Hemotherapy and Hematology of Par (a reference state hematology center in northern Brazil) as autoimmune thrombocytopenia carriers, only 51 (11 men and 40 women, mean age of 35 years old at examination) could be diagnosed as adult ITP carriers using the absence of background diseases and the presence of GPIIb/IIIa and/or GPIb/IX serum autoantibodies as criteria (PakAuto Kit, GTI, 0198-8859/09/$32.00 - see front matter 䉷 2009 American Society for Histocompatibility and Immunogenetics. Published by Elsevier Inc. All rights reserved. doi:10.1016/j.humimm.2009.01.011 180 M.H.T. Maia et al. / Human Immunology 70 (2009) 179-183 Brookfield, WI, USA). The control sample was composed of 145 unrelated individuals (65 men and 80 women, mean age of 31 years old) representative of the same population from which the ITP carriers were obtained. Men and women in control sample underwent allelic frequency comparison to determine whether their lower female/male ratio could bias the results. DNA samples were isolated according to Sambrook et al. [12]. The nine microsatellites used for genetic mapping (Table 1) were located in the following MHC recombination blocks: (D6S2749 locus) and ␦ (G51152 and D6S2883) blocks in the class II region; in-between ␥ and ␦ blocks (D6S273 and BAT2GT) and  block (TNFd) in the class III region; and  (STR-MICA and D6S2811) and ␣ (D6S510) blocks in the class I region (Figure 1) [11,13,14]. Polymerase chain reaction (PCR) conditions for each loci were 94⬚C for 10 minutes, followed by 30 cycles at 94⬚C for 30 seconds, primer-specific annealing temperature for 30 seconds, 72⬚C for 1 minute, and final extension at 72⬚C for 1 hour. BAT2GT and D6S2883 were multiplexed at an annealing temperature of 60⬚C, whereas D6S2749, G51152, D6S273, and D6S2811 were multiplexed at an annealing temperature of 57⬚C. Annealing temperatures for TNFd, STR-MICA, and D6S510, loci that could not be multiplexed, were 64, 57, and 65⬚C, respectively. The final volume of each reaction was 15 L, composed of reaction buffer (20 mM Tris–HCl, pH 8.4, 50 mM KCl), 3.3 mM MgCl2, 0.75 L DMSO, 0.08 mM dNTP, 1 U Platinum Taq DNA polymerase (Invitrogen, Carlsbad, CA, USA), and 50 ng of genomic DNA. Primer concentrations were 0.25 mM for D6S510, TNFd, G51152, and MICA, 0.35 mM for D6S2883, 0.15 mM for BAT2GT, 0.1 mM D6S2749, 0.2 mM for D6S273, and 0.3 mM for D6S2811. Forward primers (Table 1) were fluorescently tagged at the 5= ends, allowing genotyping using an ABI 377 automated sequence analyzer (Applied Biosystems, Foster City, CA, USA). HLA-B genotyping was performed using the INNO-LiPA HLA-B Update Plus probe assay (Innogenetics, Gent, Belgium) according to the manufacturer’s instructions. 3. Results Hardy–Weinberg genotypic deviations were calculated using GENEPOP software [16]. Genetic diversities (H) for each locus were estimated according to Nei [17] and compared using Wilcoxon’s test. The 2 test was applied for each allele and the p value was accessed by Monte Carlo simulations, using the CLUMP software [18]. Odds ratios (OR) and 95% confidence intervals (CI) were estimated for alleles that significantly differed in their frequencies between patients and controls. Multiple test correction was applied by multiplying allelic p values by the number of alleles at each Table 1 Characteristics of the nine selected MHC microsatellites Loci Primer 1 Primer 2 Core motif References D6S2749 GAGGTAATGTCACAGGATGGG TGCTTATAGGGAGACTACCG GGTAAAATTCCTGACTGGCC GACAGCTCTTCTTAACCTGC ACATTTGTATGCTTCAGATG TGGAATCTCATCAAGGTCAG ACCAAACTTCAAATTTTCGGC GGAGAAGTTGAGTATTTCTG CTCCAGCCTGGATAACAG ACAAGGGCTTTAGGAGGTCT CATAGTGGGACTCTGTCTCCAAAG AGATCCTTCCCTGTGAGTTCTGCT CCTTTTTTTCAGGGAAAGTGC CCTTACCATCTCCAGAAACTGC TGCCATTTGGCCCTAAATGC TGGGCAATGAGTCCTATGAC AATGGGCTACTACTTCACACC CAACACACTGATTTCCATAGC GT 13 GT 13 G51152 D6S2883 D6S273 BAT2GT TNFd STR-MICA D6S2811 D6S510 AC 13 GT 13 GT 13;14 AG 13 GCT 13;15 GT 13 AC 13 Fig. 1. Localization map of the microsatellites in the MHC. The nine microsatellites studied (gray boxes) are shown in their relative position to relevant MHC genes (black boxes). locus according to Bonferroni’s correction linkage disequilibrium and haplotypes were inferred using Pypop software [19]. All loci were in Hardy–Weinberg equilibrium, and male and female control subsamples did not differ in terms of their allelic frequencies (2 ⫽ 26.618; p ⫽ 0.1464). Microsatellite genetic diversity (H) and number of alleles (k) did not differ statistically between patients and controls (Wilcoxon’s test: Z ⫽ 1.481, p ⫽ 0.139, for H comparison; Z ⫽ 1.782, p ⫽ 0.075, for k; Table 2); in addition, the Table 2 Genetic variability estimates for each locus in controls and patients samples Loci D6S2749 G51152 D6S2883 D6S273 BAT2GT TNFd STR-MICA D6S2811 D6S510 HLA-B Average Control (2n ⫽ 288) Patients (2n ⫽ 102) H k H k 0.744 0.707 0.850 0.779 0.789 0.666 0.772 0.930 0.846 0.931 0.800 08 10 10 08 13 08 05 21 13 27 12.3 0.760 0.759 0.815 0.780 0.822 0.726 0.774 0.940 0.837 0.944 0.816 06 09 10 08 14 06 05 21 09 26 11.4 H ⫽ expected heterozygosity; k ⫽ number of alleles; 2n ⫽ number of chromosomes sampled. M.H.T. Maia et al. / Human Immunology 70 (2009) 179-183 181 Fig. 2. Allelic frequencies of all loci studied among patients and controls. (A) D6S2749; (B) G51152; (C) D6S2883; (D) D6S273; (E) BAT2GT; (F) TNFd; (G) STR-MICA; (H) D6S510; (I) D6S2811; and (J) HLA-B. Black bars ⫽ controls; empty bars ⫽ patients.*p ⬍ 0.05; **pc ⬍ 0.05. Y axis ⫽ allelic frequencies; X axis ⫽ allelic denomination. values of H and k were similar to those described for other populations, especially those of European origin, and all microsatellite allele sizes observed were within the allele size range described in previous studies [13,15,20,21]. The highest difference among patients and controls with regard to allelic frequencies was observed in the STR-MICA for allele 183 (15%), as shown in Figure 2. The OR and 95% CI for all alleles that significantly differed in their frequencies between patients and controls (Table 3) and the most significant OR were obtained for STR-MICA (183 allele, also known as A5.1 [15]). The most significant p values among all alleles for each locus were obtained for STR- MICA (p ⫽ 0.0032), TNFd (p ⫽ 0.0069), BAT2GT (p ⫽ 0.0244), and D6S2883 (p ⫽ 0.034) loci (Table 3); however, after multiple test corrections, only STR-MICA, located in the  recombination block, remained significant (pc ⫽ 0.016). Hence, we believe that the trend represents an important clue to mapping ITP predisposing genes. Because HLA-B is a key locus near MICA, which is associated with several autoimmune conditions, including ITP itself, it constitutes a predisposing candidate gene. Hence, genotyping of this locus was performed and its allele frequencies are given in Figure 2. A total of 28 different HLA-B alleles were observed in both samples, 26 in patients and 27 HLA-B alleles in controls (Table 2). HLA-B*08 allelic 182 M.H.T. Maia et al. / Human Immunology 70 (2009) 179-183 Table 3 p values and odds ratio estimates for all loci Locus Allele OR p values pc values D6S2749 G51152 D6S2883 D6S273 BAT2GT TNFd STR-MICA D6S2811 D6S510 HLA-B 231 216 244 153 139 126 186 110 178 8 1.8843 1.7729 1.7679 1.4323 2.2174 3.1648 2.1877 1.6667 1.3995 3.5476 0.1217 0.1852 0.0342 0.1804 0.0244 0.0069 0.0032 0.2119 0.2122 0.0238 0.9735 1.8518 0.3762 1.6234 0.3172 0.0552 0.016 4.6613 2.7583 0.6663 OR ⫽ odds ratio; pc values ⫽ p corrected for multiple tests. frequency was the most discrepant between the two samples (7%). However, this low statistic difference (OR ⫽ 3.55; 95% CI ⫽ 1.17– 10.72; p ⫽ 0.0238) was not maintained after multiple test correction (Table 3). STR-MICA locus was in strong linkage disequilibrium with HLA-B in both control (D’ ⫽ 0.7665; p ⬍ 0.00009) and patient (D’ ⫽ 0.7942; p ⬍ 0.00009) samples. HLA-B*08 was associated with STR-MICA*183 in both samples (p ⬍ 0.002). Maximum likelihood haplotype frequencies estimates indicate that the haplotype HLA-B*08:STRMICA*183 was the most frequent among patients (9%), but although also observed among controls (4%), it only ranked ninth in frequency. 4. Discussion The present study is a comprehensive mapping of the MHC predisposing regions for ITP using microsatellite markers encompassing the three MHC regions and their main recombination blocks. The ITP susceptibility region seemed to be located in the surroundings of the STR-MICA locus, indicating class I centromeric region, at the end of the  block, as a primary predisposing region. Previous studies have indicated STR-MICA associated with rheumatoid arthritis (weak association with MICA*04, secondary to HLADRB1*0405 association, and weak protective effect associated with MICA*09 in Koreans [22]), psoriatic arthritis (disease development associated with MICA*09, the same MICA*002 allele), and BehÈet’s disease (associated with STR-MICA*06 in the absence of HLA-B*51 [15]). Those results indicate that the MICA gene may be involved in autoimmune diseases etiology, including ITP. However, MICA maps close to the HLA-B locus, which demonstrated an allele association with ITP in previous studies [8,10]. Indeed, MICA and HLA-B loci were in linkage disequilibrium in several populations studies [23– 27]. Moreover, some authors detected a strong association between the STR-MICA A5.1 allele (STR-MICA*183 allele in our study), which is associated with the MICA*008 extracellular allele [23], and the HLA-B*08 allele [15,28,29]. However, the association of ITP with HLA-B was weak and not retained after multiple test correction in our study. This fact indicates that the primary association remains with MICA, whereas HLA-B association seems to be secondary to MICA, as supported by our linkage disequilibrium analysis. Accordingly, some reported MHC class I and II associations with ITP might be circumstantial as a result of linkage disequilibrium, which partially explains the discrepancies found in previous studies. Indeed, single associations of HLA-B8, -B12 [8], and -A28 [9] with ITP have been described; moreover, HLA-A3/B7/DR2 and HLA-A26/ B38/DR2 haplotypes, which are discrepant in their class I components, were also found to be associated with ITP [10]. On the other hand, further studies have not confirmed any class I association with ITP [30 –33], and different MHC class II alleles, HLADRB1*0410 and HLADRB1*0101, were associated with the disease in distinct studies [5,6]. Because the association observed was restricted to STR-MICA, it could not be explained by population stratification; otherwise, the remaining microsatellites markers would have shown differences in their allelic frequencies when comparing control and patient samples. It is also important to highlight that the 51 ITP patients studied, which seems to be a statistically small number, are an appropriate sample because ITP is a fairly rare disease, as indicated by sample sizes in other studies [5–7]. The prevalence rate of about 60 cases per million implies that our sample constitutes at least one third of the predicted cases in the population surveyed in the present study. In addition, highly stringent criteria were used to select adult ITP carriers, preventing false-negative identification of patients for autoantibodies. Because disease association with microsatellite markers is possibly indirect, the MHC region close to STR-MICA could be the major source of ITP susceptibility factors (i.e., the neighboring loci in this region would be the best candidate genes for the disease). However, polymorphisms on STR-MICA may be immunologically relevant, because they have been associated with autoimmune dysfunctions like BehÈet’s disease and psoriatic arthritis [15,34]. In the context of its immunological function, the MICA gene itself was described as a ligand for the NKG2D/DAP10 stimulatory receptor complex [35], expressed on natural killer cells, gd T cells and CD8⫹ ab T cells, triggering cytolysis mediated by NKG2D-bearing cells [36] and also costimulating CD8⫹ ab T lymphocytes [37]. Although MICA seems to be primarily involved with the cellular immune response, it may be also implicated in the humoral response through complex association between these two immune branches. For instance, once stimulated, NKG2D-bearing cells produce cytokines related to growth, proliferation, and differentiation of B cells into plasmocytes, which play a central role in the production of antiplatelet IgM autoantibodies, characteristic of ITP etiopathogeny [3]. In short, the main conclusion of the present study indicates a putative primary enrollment of genes very close to the MICA gene, or even MICA itself, with ITP susceptibility. Acknowledgments This study was partially supported by the Brazilian National Research Council (CNPq). We appreciate the collaboration of all patients and thank the logistic and technical support personnel provided by the Foundation Center of Hemotherapy and Hematology of Par and the Federal University of ParÂ. References [1] Chong BH, Ho SJ. Autoimmune thrombocytopenia. J Thromb Haemost 2005;3: 1763–72. [2] Hopkins LM, John MD, Rico B, Rodney SV, Kenneth AS, John AG. 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