Background
Asthma is a chronic inflammatory disease of the airways that is a major cause of morbidity in developed countries and has been increasing in prevalence [
1,
2]. Asthma is a common disease caused by interactions between multiple genes of small to modest effect and equally important environmental factors. Asthma susceptibility has been linked to several loci e.g. chromosomes 5, 6, 11, 12 and 14 [
3]. Among these linkages, chromosome 5q23-35 has been replicated in several genome-wide studies in different populations [
3].
McIntire
et al. identified a chromosomal region that regulated T
H2 cytokine production as well as airway hyperresponsiveness (AHR) using a congenic mouse model of asthma [
4]. This region was distinct from the IL4 cytokine gene cluster and other nearby cytokine genes [
4]. The region is homologous to human chromosome 5q33 and contains the
TIM (T cell immunoglobulin domain and mucin domain) gene family [
4]. There are two genes in this family (
TIM1 and
TIM3) that are biologically plausible atopy susceptibility genes.
TIM1 (also known as the hepatitis A virus cellular receptor,
HAVCR1) is expressed preferentially on T
H2 cells and
TIM3 (
HAVCR2) is expressed preferentially on T
H1 cells after activation of naive CD4
+ T-helper cells. T
H1 cells mediate immune responses to intracellular pathogens, delayed-type hypersensitivity reactions, and produce cytokines such as interferon-γ, IL2, tumour-necrosis factor-α and lymphotoxin. T
H2 cells mediate immune responses to extracellular pathogens and produce cytokines such as IL4, IL10 and IL13 which promote atopic and allergic diseases [
5]. TIM1 promotes T
H2 cytokine production and proliferation. In a murine model of asthma, stimulation of TIM1 in the presence of antigen prevented the development of respiratory tolerance and increased pulmonary inflammation [
6]. TIM3 inhibits T
H1-mediated auto- and alloimmune responses and acts via its ligand, galectin-9, to induce cell death in T
H1 but not T
H2 cells [
7‐
9]. Considering their immunological function and chromosomal location both
TIM1 and
TIM3 are good candidate genes for asthma.
Recent association studies suggested that polymorphisms in the
TIM3 promoter region may be associated with asthma-related phenotypes in both Caucasian and Asian population samples [
10‐
12]. Other studies have demonstrated associations of
TIM1 polymorphisms with asthma and related traits [
11,
13,
14]. In the present study, we performed an association study in three asthma/allergy population samples to investigate the role of polymorphisms in the
TIM3 promoter region and determined whether these polymorphisms affected
TIM3 transcriptional activity.
Methods
Study populations
We used three independent asthma/allergy population samples: the Canadian Asthma Primary Prevention Study (CAPPS) cohort, the Study of Asthma Genes and the Environment (SAGE) birth cohort and the Saguenay-Lac-St-Jean (SLSJ)/Québec City (QC) Familial Collection (Table
1). The study protocols were approved by ethical review boards at all participating institutions. Informed consent was obtained from each individual or his/her guardian.
Table 1
Sample sizes by study, phenotype and ethnic background
Families | 545 | 723 | 306 | 1573 |
Genotyped | 1316 | 1466 | 1234 | 4016 |
Caucasian Samples (complete trios)
|
Phenotype |
Asthma | 51 | 109 | 379 | 539 |
Atopy | 105 | 145 | 362 | 612 |
AHR | 142 | 96 | 278 | 516 |
Atopic Asthma | 37 | 71 | 305 | 413 |
Non Caucasian Samples
a
(complete trios)
|
Asthma | 3 | 28 | na | 31 |
Atopy | 18 | 44 | na | 62 |
AHR | 14 | 22 | na | 36 |
Atopic Asthma | 3 | 20 | na | 23 |
Combined Analysis
b
(complete trios)
|
Asthma | 57 | 139 | 379 | 575 |
Atopy | 135 | 190 | 362 | 687 |
AHR | 170 | 120 | 278 | 568 |
Atopic Asthma | 43 | 92 | 305 | 440 |
The CAPPS cohort was initiated in 1995 and recruited from two Canadian cites, Vancouver and Winnipeg [
15,
16]. Infants were recruited who were at high risk for the development of asthma, defined as those who had at least one first-degree relative with asthma or two first-degree relatives with other allergic diseases. In total, there were 545 families recruited into this study (549 infants, 4 sets of twins). At the 7-year time point loss to follow-up was minimal, with 86% of the families completing a questionnaire. Spirometry and methacholine challenge testing were performed at the 7-year time point. The diagnoses of asthma and other atopic disorders were made by a pediatric allergist based on a detailed history and physical examination. Atopy was defined as at least one positive skin prick test. Methacholine challenge testing was carried out according to Cockcroft et al. [
17]. The provocative concentration of methacholine that induced a 20% decrease in FEV
1 from post-saline value (PC
20) was determined. AHR for this cohort and the SAGE cohort was defined as a PC
20 of less than 3.2 mg/ml methacholine [
18,
19].
SAGE is a population-based sample of 16,320 children, born in the province of Manitoba, Canada in 1995 [
20]. In 2002, the families were sent a questionnaire to determine their health and home environment exposure. Children were classified according to the presence of asthma (n = 392), hay fever/food allergy (n = 192) or neither (n = 3002). All the children in the asthma and allergy groups were invited to participate in the study, together with a random sample (n = 200) of children with neither condition. A pediatric allergist assessed the presence of asthma based on a detailed history and physical examination, a methacholine challenge test was administered and skin prick tests for common allergens were performed. In total, 725 families were recruited into the study, including 247 with an asthmatic child and 328 with an atopic child.
The SLSJ/QC Familial Collection is comprised of 306 families from the Saguenay-Lac-Saint-Jean (n = 227) and Québec City (n = 79) regions of Québec, Canada [
21,
22]. There is at least one adult asthmatic proband in each family. Asthma was assessed using a respiratory health questionnaire and pulmonary function tests. AHR was defined as a PC
20 < 8 mg/ml at the time of recruitment. If PC
20 was not measurable, a 15% increase in FEV
1 after inhalation of a bronchodilator or a variation in PEF of at least 12% within a 2-week period was also considered diagnostic of AHR. Participants were defined as having asthma if they had a reported history of asthma that was validated by a physician, or they showed asthma-related symptoms and a positive PC
20 at the time of recruitment. Subjects were defined as atopic if they had at least one positive response to a skin prick test. Subjects with a PC
20 > 8 mg/ml were considered not to have AHR; non-asthmatics were those who had no history of physician-diagnosed asthma, no symptoms of asthma and a PC
20 greater than 8 mg/ml; non-atopics were those who had no positive response on skin prick test.
Expression of TIM3in tissues
The Human Multiple Tissue, Human Immune System cDNA Panels and Human Blood Fraction Panel (BD Biosciences/Clontech, Palo Alto, CA, USA) were used to analyze expression of
TIM3 in various tissues. The PCR primers for the gene expression study are listed in Table
2. Resting CD14+ (monocytes), CD4+ (T helper/inducer cells), CD8+ (T suppressor/cytotoxic cells) and CD19+ (B lymphocytes) cells were positively selected from mononuclear cells from healthy donors by immunomagnetic separation with Dynabeads M-450 (Dynal, Oslo, Norway). Cells were activated with pokeweed mitogen (Invitrogen, San Diego, CA, USA) and concanavalin A (ICN, Costa Mesa, CA, USA) by standard methods, and the degree of activation of lymphocytes was estimated on the basis of morphological criteria (blast morphology and mitoses) and expression of two activation markers, CD25 (interleukin-2 receptor) and CD71 (transferrin receptor). We used glycerol-3-phosphate dehydrogenase (
G3PDH) as an internal control for PCR. Amplification conditions were an initial denaturation step at 94°C for 10 min followed by 34, and 30 cycles of denaturation at 94°C for 30 s, annealing at 60°C for 30 s and extension at 72°C for 30 s for primer pairs amplifying
TIM3 and
G3PDH, respectively.
Table 2
Sequence of primers used in reverse transcriptase-polymerase chain reaction, 5' Rapid Amplification of cDNA ends (5'RACE) and (RT-PCR) and plasmid constructs
TIM3 RT-PCR primers | Forward | 5'-tgctgctgctgctactacttaca-3' |
| Reverse | 5'-aggttggccaaagagatgag-3' |
5'RACE | First round forward | 5'-gctggggtgtagaagcagggcagat-3' |
| First round reverse | 5'-ccatcctaatacgactcactatagggc-3' |
| Nested PCR forward | 5'-tgtctgtgtctctgctgggccatgt-3' |
| Nested PCR reverse | 5'-actcactatagggctcgagcggc-3' |
Plasmid constructs primers | Common reverse primer | 5'-attatctcgagtggactgggtacttcttccaa |
| Forward primer +63 bp | 5'-attatggtacctgactgtagacctggcagtgtt-3' |
| Forward primer -241 bp | 5'-attatggtaccggacatgctccatttcaggt-3' |
| Forward primer -452 bp | 5'-attatggtacctgaggcttatgctgggagtt-3' |
| Forward primer -914 bp | 5'-attatggtaccaaaccactcagcctgtgagc-3' |
| Forward primer -1702 bp | 5'-attatggtaccgccttgaccaagttcatgct-3' |
| Forward primer -2220 bp | 5'-attatggtaccccagctccctacacacacaa-3' |
5' Rapid Amplification of cDNA ends (5'RACE)
We performed 5' RACE experiments using commercially available RACE-ready human leukocyte and spleen cDNAs (Marathon Ready cDNA, BD Biosciences/Clontech) according to the manufacturer's instructions. Primers used for amplification for the first round PCR and for the nested PCR are shown in Table
2. The amplified RACE product was cloned into pCR2.1 TOPO-TA cloning vector (Invitrogen). Plasmids were purified by column chromatography (Invisorb Spin Plasmid Mini Kit, Invitek GmbH, Berlin) and subjected to direct sequencing with M13 primers.
Single nucleotide polymorphism (SNP) screening and genotyping
Approximately 2500 bp of the 5' flanking region upstream of the transcription initiation site of TIM3 was amplified by PCR from genomic DNA of 19 unrelated healthy Caucasians. Subsequently, the products were subjected to direct sequencing with a Big-Dye Terminator Kit (Applied Biosystems, Foster City, CA, USA). Genotyping of the two tag SNPs was done by TaqMan Assay-on-Demand™ SNP typing (Applied Biosystems).
Plasmid construction, transfection and luciferase assay
Genomic fragments of the 5' flanking region of exon 1 of TIM3 were amplified. PCR products were digested with XhoI and KpnI overnight at 37°C and then subcloned into the pGL3-Basic vector (Promega, Madison, WI, USA) digested with XhoI and KpnI. The clones were sequenced to confirm that the inserts were correct. The YT human T/NK cell line provided by Dr. Zacharie Brahmi as a gift was resuspended in RPMI 1640 (Sigma-Aldrich Co, St. Louis, MO, USA) with 20% FBS. Approximately 1 × 107 YT cells were cotransfected with 30 μg of test construct and 150 ng of pPL-TK (Promega) by electroporation with a Gene Pulsar II (Bio-Rad, Hercules, CA) set at 300 V and 975 μF. Transfected cells were harvested 24 h after transfection. Cells were lysed by the addition of 200 μl of lysis buffer (Promega). Twenty μl of each lysate was used for luciferase assay with the Dual-Luciferase Reporter Assay System (Promega). The firefly luciferase values were normalized to the Renilla luciferase values of pRL-TK, which were determined at the same time. The signal was read using a POLARstar OPTIMA (BMG, Alexandria, VA, USA) fluorimeter. Reporter activity is presented as the mean of at least five independent measurements.
Statistical analysis
Differences in transcriptional activity in the reporter gene assays were analyzed by ANOVA and unpaired t-tests. We tested for association with asthma, atopy, atopic asthma and airway hyper- responsiveness phenotypes using the Family based Association Test (FBAT) software [
23].
Discussion
In the present study, we determined the expression pattern of TIM3 in human cells. We investigated the genomic structure and transcriptional activity of TIM3 and investigated polymorphisms in the promoter region of TIM3 in multiple cohorts. We isolated the full-length genomic region of TIM3 and characterized its promoter region. We found six polymorphisms in TIM3, but none was associated with asthma or the transcriptional activity of the gene in vitro.
TIM3 was initially cloned as a T
H1-specific cell-surface marker. In our results,
TIM3 was expressed on activated CD4+ cells as well as resting CD8+ cells and CD14+ cells, consistent with previous reports. In the mouse,
TIM3 was expressed in both CD4+ and CD8+ cells [
24,
25] and in human peripheral blood mononuclear cells
TIM3 was expressed at a higher level on CD14+ cells and CD8+ cells than on CD4+ cells [
26].
TIM3 was also reported to be expressed in NK and NTK (NK-like T) cells [
26,
27]. In our results,
TIM3 was expressed at a higher level in activated CD4+ cells than in resting CD4+ cells but conversely expression was higher in resting CD8+ than in activated CD8+ cells. Our results demonstrate that the expression level of
TIM3 is not only differentially regulated in subsets of T cells but is also determined by the activation state of the cell.
TIM3 is expressed in human NK cells both at the mRNA and protein levels [
26,
27]. We found that
TIM3 was also expressed in one type of NK cell line, the YT cell line, which was used in the reporter gene assays. We identified
TIM3 promoter activity in the -241 bp and -1702 kb regions relative to the transcription initiation site. Conserved non-coding sequences may contain transcriptional regulatory elements participating in the temporal and tissue-specific expression patterns of genes [
28,
29]. In the UCSC website
http://genome.ucsc.edu/ there are three conserved regions in the
TIM3 promoter (Figure
3B) and the first conserved region contributes to the -241 bp promoter region and the last two regions contribute to the -1702 bp promoter region. There are five SNPs in the -1.7 kb region and the -1516 G/T, -1571delC and -1766G/T SNPs flank the conserved sequence. However, the haplotype formed by these SNPs did not affect the promoter activity (Figure
3C). We also stimulated the YT cell line with IL-2 at different concentrations but we found no difference in promoter activity among the different haplotypes after the stimulation (data not shown).
There are discrepant reports concerning the association between
TIM3 polymorphisms and allergic phenotypes [
10‐
14]. Graves
et al. [
11] studied a mixed Caucasian/Hispanic population. The two
TIM3 SNPs that showed association with eczema and atopy were rs1036199 and rs4704853. However, in our sample these two SNPs were in perfect LD and rs4704853 was not associated with any phenotype. This discrepancy may be due to the different ethnic group studied in the previous report [
11]. Two other studies reported associations in Asian samples [
10,
12]. The -574G > T (rs10515746) polymorphism was associated with asthma and rhinitis in a Korean population although the -574T allele was found in less than 2% of the patients [
10]. Therefore, our study may not have been adequately powered if this association is limited to the Asian population.
In Caucasian and African-American populations no association of
TIM3 polymorphisms was seen with asthma or related phenotypes [
13,
14]. The three cohorts used in this study were family-based and there were more than 1000 individuals in each cohort. There were non-Caucasian samples in both SAGE and CAPPS but we analyzed the data separately to avoid possible loss of power due to genetic heterogeneity. Correction for multiple comparisons was performed to avoid false positive results. Although a nominal association of rs13170556 was found in the CAPPS cohort it was not significant after correction for multiple comparisons. Moreover, the association was not replicated in the other two cohorts and in the combined analysis of all three cohorts. Therefore, the association was likely a statistical artifact rather than a true positive result.
We did not analyze other phenotypes such as total or specific serum IgE in this study. We did not analyze haplotypes in the patient cohorts as we believe that this would have been inappropriate since we used tag SNPs from HapMap and it has been suggested that in this scenario there is little benefit of exhaustive haplotype testing [
30]. In addition, we used the most powerful approach given our study design, there is high LD in the region, the marker coverage was not dense and our single SNP main effects were negative. All these factors made it unlikely that we would have benefited from haplotype tests.
The power to detect an association in this study varied with the phenotype, allele frequency and cohort considered. Power was calculated using the TDT Power Calculator [
31]. For a major allele 'A' and minor allele 'a', we assumed the penetrance of the three genotypes was AA = 0.1, Aa = 0.2 and aa = 0.5. For an allele frequency of 0.13 and the phenotype of allergic asthma in the CAPPS cohort (i.e. 37 trios) the power to detect an association was only 0.41. However, for a sample size of 96 trios (e.g. AHR in the SAGE cohort) the power was 0.80 and was >0.80 for all other phenotypes in all cohorts in the Caucasians.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
JZ participated in the genotyping, performed the remainder of the molecular analysis and produced the first draft of the manuscript, DD performed the analysis of the genetic epidemiological data and helped to draft the manuscript, LA participated in the genotyping, DS participated in the genotyping, MC-Y participated in the recruitment of the patient cohorts and helped to draft the manuscript, AB participated in the recruitment of the patient cohorts and helped to draft the manuscript, CL participated in the recruitment of the patient cohorts and helped to draft the manuscript, PDP participated in the recruitment of the patient cohorts, the design of the study and helped to draft the manuscript, AJS participated in the design of the study and helped to draft the manuscript. All authors read and approved the final manuscript.