Polymorphisms of IGFI contribute to the development of ischemic stroke
- Authors:
- Published online on: October 21, 2011 https://doi.org/10.3892/etm.2011.372
- Pages: 93-98
Abstract
Introduction
Stroke is a neurological disease which causes long-term disability and is the third leading cause of death in the United States. Ischemic stroke (IS) accounts for approximately 85% of all strokes. The other 9% are caused by intracerebral hemorrhage and 4–5% by subarachnoid hemorrhage (1,2). Environmental and genetic factors are related to the pathogenesis of IS. Several lines of genetic studies have reported the relationship between IS and single nucleotide polymorphisms (SNPs) of candidate genes, such as the transforming growth factor β1 (TGFB1), transforming growth factor β receptor II (70/80 kDa) (TGFBR2) and tumor necrosis factor (TNF) (3–5).
Insulin-like growth factor 1 (somatomedin C) (IGF1) is similar to insulin in function and plays a crucial role in mammalian growth and development. The IGF1 level declines during the normal aging process, and a low IGF1 level correlates with decreased cognitive abilities (6). In vitro studies have shown that IGF1 reduces neuronal cell death in various injury insults (7,8) and IGF1 has a protective effect in ischemic animal models (9,10). Several reports have reviewed the roles of IGF1 in stroke severity and outcome (11,12). They have suggested that IGF levels may be associated with neurological recovery and functional outcome, and have also proposed IGF1 as a predictor of stroke outcome.
In this study, we investigated the association between IGF1 SNPs and IS in a Korean population. We also assessed the relationship between IGF1 SNPs and the clinical phenotypes according to the scores of National Institutes of Health Stroke Survey (NIHSS) and the Modified Barthel Index (MBI).
Materials and methods
Study population and clinical phenotypes
IS patients were enrolled among participants visiting the Departments of Neurosurgery and Physical Medicine and Rehabilitation, Kyung Hee Medical Center (Seoul, Republic of Korea). Patients with transient ischemic attack, cerebrovascular malformation, congenital brain disorders and accidental or iatrogenic stroke, were excluded. Stroke patients were diagnosed by computed tomography, magnetic resonance imaging, angiography and duplex sonography. The control subjects were recruited among healthy volunteers to examine the general health check-up program. Patients with neurological diseases, ischemic heart diseases and other severe diseases, were excluded. All stroke patients were classified into clinical phenotypes according to the NIHSS and MBI scores. For the neurological functional level of IS patient, the severity of 13 neurological symptoms was assessed by the NIHSS score. For the daily living activity of IS patients, the quality of 10 general life activities was evaluated by the MBI score. This study was approved by the Ethics Review Committee of the Medical Research Institute, School of Medicine, Kyung Hee University. Written informed consent was obtained from all patients. If patients were incommunicative, it was obtained from a guardian or close relatives.
SNP selection and genotyping
We searched the coding SNPs (cSNPs) of the IFG1 gene in the SNP database of the National Center for Biotechnology Information (http://www.ncbi.nlm.nih.gov/SNP, BUILD 132). The cSNPs with a heterozygosity of <0.05 and/or a minor allele frequency (MAF) of <0.05, were excluded. Out of five missense and two synonymous SNPs, there were no cSNPs with a heterozygosity of >0.05 or a MAF of >0.05. Therefore, we searched the untranslational and intron SNPs of the IGF1 gene and previous studies (13–15). Finally, five SNPs [rs2162679 (intron), rs2195239 (intron), rs978458 (intron), rs1520220 (intron) and rs6214 (3′ untranslated region; 3′UTR)] were selected (Fig. 1). Genotypes of the five selected SNPs were analyzed by direct sequencing (Macrogen, Seoul, Republic of Korea). Polymerase chain reactions (PCRs) were conducted using the forward and reverse primers of each SNP (Table II). PCRs were performed under the following conditions: 35 cycles at 95°C for 30 sec, 58°C for 30 sec, 72°C for 30 sec, and 1 cycle at 72°C for 5 min for the final reaction. The PCR products were sequenced by an ABI PRISM 3730XL analyzer (PE Applied Biosystems, Foster City, CA, USA) and genotypes of each SNP were analyzed by SeqManII software (DNASTAR, Madison, WI, USA).
Statistical analysis
SNPStats (http://bioinfo.iconcologia.net/index.php?module=Snpstats), SNPAnalyzer Pro (ISTECH, Goyang, Republic of Korea), and Helixtree (Golden Helix, Bozeman, MT, USA) were used to obtain odds ratios (ORs), 95% confidence intervals (CIs) and p-values. Hardy-Weinberg equilibrium (HWE) was calculated using the Chi-square test. Multiple logistic regression models were conducted using the following models: codominant1 (major allele homozygotes vs. heterozygotes), codominant2 (major allele homozygotes vs. minor allele homozygotes), dominant (major allele homozygotes vs. heterozygotes and minor allele homozygotes), recessive (major allele homozygotes and heterozygotes vs. minor allele homozygotes) and log-additive (major allele homozygotes vs. heterozygotes vs. minor allele homozygotes) (16,17). Bonferroni correction was performed to obtain further statistical significance. Linkage disequilibrium (LD) blocks were estimated using Haploview version 4.2 (Daly Lab, Cambridge, MA, USA). The required case size in each SNP was estimated using the genetic power calculator (http://pngu.mgh.harvard.edu/~purcell/gpc/cc2.html) to obtain the statistical power. The statistical significant level was set at a value of p<0.05.
Results
Demographic and clinical features of study subjects
Table I shows the demographic and clinical features of the IS patients and the control subjects. The age of the IS patients and control subjects was 65.8±12.1 (mean ± SD) and 62.9±9.3 years, respectively. The number of IS patients and control subjects was 119 (66 male/53 female) and 289 (150 male/139 female), respectively. All IS patients were divided into two clinical subgroups according to the NIHSS (<6 and ≥6) and MBI scores (<60 and ≥60). The numbers of IS patients with a NIHSS score of <6 and ≥6 were 55 (49.1%) and 57 (50.9%), respectively. The numbers of IS patients with a MBI score of <60 and ≥60 were 71 (74.7%) and 24 (25.3%), respectively. In two clinical subgroups, patients with inappropriate or insufficient clinical data, were excluded (Table I).
Genetic analysis of IGF1 SNPs
Table III represents the genotype and allele frequencies of the five examined SNPs (rs2162679, rs2195239, rs978458, rs1520220 and rs6214) in the IS patients and the control subjects. The HWE of the five SNPs showed no difference in the control group (rs2162679, p=0.61; rs2195239, p=0.18; rs978458, p=0.91; rs1520220, p=1.00; rs6214, p=1.00). Multiple logistic regression analysis adjusting for age and gender was performed. An intron SNP (rs2162679) was associated with the development of IS [p=0.0050, OR = 0.27, 95% CI = 0.11–0.67 in the codominant2 model (A/A vs. G/G); p=0.0150, OR = 0.58, 95% CI = 0.37–0.90 in the dominant model (A/A vs. A/G and G/G); p=0.0059, OR = 0.32, 95% CI = 0.13–0.79 in the recessive model (A/A and A/G vs. G/G); and p=0.0020, OR = 0.59, 95% CI = 0.41–0.83 in the log-additive model (A/A vs. A/G vs. G/G)]. A 3′UTR SNP (rs6214) was also associated with the development of IS [p=0.0110, OR = 0.44, 95% CI = 0.23–0.83 in the codominant2 model (G/G vs. A/A); p=0.0250, OR = 0.59, 95% CI = 0.37–0.93 in the dominant model (G/G vs. A/G and A/A); p=0.0420, OR = 0.57, 95% CI = 0.32–1.00 in the recessive model (G/G and A/G vs. A/A); and p=0.0088, OR = 0.66, 95% CI = 0.49–0.90 in the log-additive model (G/G vs. A/G vs. A/A)]. The A allele frequency of rs2162679 was higher in the IS group (74.4%) than in the control group (63.8%) (p=0.004, OR = 1.64, 95% CI = 1.17–2.31). The G allele frequency of rs6214 was higher in the IS group (60.5%) than in the control group (50.2%) (p=0.007, OR = 1.52, 95% CI = 1.12–2.07). After Bonferroni correction (pc), the allele frequencies of rs2162679 and rs6214 showed significant differences between IS and the controls (rs2162679, pc=0.004; rs6214, pc=0.007). The other SNPs (rs2195239, rs978458 and rs1520220) had no differences between IS and the controls (Table III). The LD block was estimated using Haploview version 4.2. One LD block was strongly made between rs1520220 and rs978458 (D’=1.0 and r2=0.993 in the control group). However, the haplotypes of these two SNPs were not associated with the development of IS (data not shown). IS patients were classified into two clinical subgroups according to the NIHSS (<6 and ≥6) and MBI (<60 and ≥60) scores. As shown in Table IV, the five tested SNPs were not associated with the NIHSS and MBI scores.
 | Table III.Genotype and allele frequencies of IGF singe nucleotide polymorphisms in controls and IS patients. |
| Table IV.Genotype frequencies of IGF singe nucleotide polymorphisms in stroke subgroups according to the NIHSS and MBI scores. |
Sample power
We estimated the sample power using a genetic power calculator to obtain the required sample size. The sample powers (α=0.05, genotype relative risk 2-fold, number of case for 70% power) of each SNP in the IS group were 0.757 for rs2162679 (n=104), 0.800 for rs2195239 (n=93), 0.801 for rs978458 (n=93), 0.801 for rs1520220 (n=93) and 0.801 for rs6214 (n=93). Therefore, the results of the five examined SNPs in the IGF1 gene had statistical confidence.
Discussion
IGF1 is an endogenous survival factor for neurons, glial cells and endothelial cells. IGF1 plays an important role in tissue repair and cell proliferation. IGF1 induces the synthesis of elastin and prevents apoptosis of vascular smooth muscle cells. Therefore, low levels of IGF1 may be a risk factor of stroke. As shown in previous studies, the expression of IGF1 increased after hypoxic injury in regions with neuronal loss (18) and IGF1 reduced infarct volume and improved neurological function after ischemia in an animal study (19).
There are several reports that IGF1 polymorphisms are associated with certain diseases, such as adenocarcinoma (EAC) and colorectal cancer (15,20). McElholm et al observed that IGF1 SNP rs6214 was associated with Barrett’s esophagus (BE) in EAC (15). Using GG genotype as reference, OR for BE in AA (wild-type) was 0.43 (95% CI 0.24–0.75). Feik et al also suggested that rs6214 could have an impact on developing colorectal cancer and colorectal polyps with villous elements (20). Based on previous studies, we believed that the SNPs of IGF1 were associated with the development of IS and clinical features according to the NIHSS and MBI scores in Korean stroke patients. In the present study, we found a significant association between IGF1 SNPs and IS. The G allele frequency of rs6214 in the IGF1 gene was higher in the IS group (60.5%) than in the control group (50.2%). The A allele of rs2162679 was also higher in the IS group (74.4%) than in the control group (74.4%). Thus, our results suggest that IGF1 may be a risk factor of IS development. However, all five SNPs (rs2162679, rs2195239, rs978458, rs1520220 and rs6214) of IGF1 did not contribute to the NIHSS and MBI scores of IS. To our knowledge, this is the first study on whether IGF1 SNPs are associated with the development of IS in a Korean population. Additional studies with a larger number of cases or different populations are required in order to confirm our results.
In conclusion, we suggest that an intron SNP (rs2162679) and 3′UTR SNP (rs6214) of the IGF1 gene may be associated with the development of IS.
Acknowledgements
This work was supported by the Biogreen 21 Program (Code PJ007187), Rural Development Administration
