The G-403A polymorphism in RANTES gene may be involved in the development of coronary artery disease (CAD) through increasing RANTES-mediated leukocyte trafficking and activation. However, studies investigating the relationship between G-403A polymorphism and CAD yielded contradictory and inconclusive results. In order to shed some light on these inconsistent findings, a meta analysis was performed to clarify the role of G-403A polymorphism of RANTES gene in the susceptibility of CAD.
A systemic literature search of PubMed and EMBASE was conducted from their inception to March 23, 2012, to retrieve related studies. In addition, Conference Proceedings Citation Index-Science was searched, authors of relevant studies were contacted, and reference lists of the included studies and their related citations in PubMed were reviewed for additional pertinent studies.
A total of 8 eligible studies were identified, with a total of 4252 CAD cases and 2150 controls. There was no evidence of significant association between G-403A polymorphism and CAD risk in any genetic model or pairwise comparisons (additive model: OR = 1.046, 95% CI = 0.883–1.239, I2 = 65.9%; recessive model: OR = 1.140, 95% CI = 0.774–1.678, I2 = 53.1%; dominant model: OR = 1.000, 95% CI = 0.820–1.21), I2 = 62.6%; AA vs GG: OR = 1.141, 95% CI = 0.734–1.773, I2 = 61.2%; GA vs GG: OR = 0.993, 95% CI = 0.800–1.232, I2 = 64.6%). Subgroup analysis and meta regression indicated that ethnicity and genotyping method accounted for the significant heterogeneity among studies. In the stratified analysis by ethnic group, G-403A polymorphism was found to be associated with increased CAD risk in Caucasian population whereas its protective role was observed in Asian population in some but not all comparisons.
Data from the current meta-analysis do not support the existence of a relationship between G-403A polymorphism and the development of CAD, and large sample size study employing unified genotyping method is needed to further evaluate the influence of G-403A polymorphism on susceptibility of CAD.
Citation: Liu J, Jia Y-J, Li X-L, Xu R-X, Zhu C-G, et al. (2012) RANTES Gene G-403A Polymorphism and Coronary Artery Disease: A Meta Analysis of Observational Studies. PLoS ONE 7(10): e47211. doi:10.1371/journal.pone.0047211
Editor: Yi Zheng, University of Nevada School of Medicine, United States of America
Received: May 29, 2012; Accepted: September 10, 2012; Published: October 10, 2012
Copyright: © Liu et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: This work was partially supported by the National Science Foundation of China (NSFC 81070171 to Dr J-JL). The funder had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
It has been widely accepted that atherosclerosis is an inflammatory disease mediated by intense immunological activity, a process characterized with the accumulation and activation of the inflammatory and immune cells within the vessel wall . The extravasation of the circulating monocyte and lymphocyte from the peripheral blood to the intima is the most pronounced event in the early stages of atherogenesis . The recruitment of these cells to vascular wall is mainly guided by endothelial leukocyte adhesion molecules and chemoattractants . Given their fundamental role in the inception of atherosclerosis, chemokines and their receptors have been the focus of intensive researching during the past decades.
Regulated on activation, normal T cell expressed and secreted (RANTES), also known as CCL5, belongs to the CC chemokine family and has strong chemoattractant and activating properties for T-lymphocytes and macrophages . Several lines of evidence have indicated that RANTES involved in the formation , exacerbation  and instability of atherosclerotic lesions . Recently, a polymorphism in the RANTES promoter region (G-403A) has been shown to increase the promoter activity, result in increased expression of RANTES and affect the RANTES-mediated inflammatory disease , including atherosclerosis. Some clinic-based observational studies have reported that G-403A polymorphism was associated with the susceptibility of coronary artery disease (CAD) , . However, an observational study in Korea have inconsistently shown a decreased risk of CAD in individuals with G-403A polymorphism . Still other studies could not draw any firm conclusion about the existence of association between G-403A polymorphism and CAD because of the limitation in sample size –. We therefore performed a meta analysis of available studies with a case-control or cohort design to clarify the role of the G-403A polymorphism in RANTES gene in development of CAD.
Search Strategy and Selection Criteria
PubMed, and EMBASE (from their inception to March 23, 2012) were searched to identify potentially relevant studies. A search strategy combining both the Medical Subject Heading and text words was used. No language restriction was applied and non–English-language articles were translated before further analysis. The search strategy is listed in table 1. Reference lists of all the included articles, the related articles of each included study generated by PubMed and relevant reviews were also screened to avoid the omitting of any potentially relevant studies. Authors of abstracts were contacted to obtain missing data when necessary. In addition, conference proceedings were searched in Conference Proceedings Citation Index-Science (CPCI-S) and authors of relevant studies were contacted via email and asked for any other published or unpublished studies that might contribute to the meta-analysis.
Studies were included for the meta-analysis if they satisfied the following criteria: 1) they evaluate the association between G-403A polymorphism in RANTES gene and CAD; 2) they included individuals with CAD and those without CAD; 3) the baseline characteristics were comparable between the two distinct population; and 4) the size of sample, source of control, distribution of alleles, and frequency of genotype were all reported or can be calculated using the data provided in studies.
Data Extraction and Quality Assessment
Two investigators independently extracted data from each study with a predefined review form and discrepancies were resolved by consensus of all investigators. Information extracted included: author, year of publication, study design, country of origin, gender composition, mean age, diagnosis of CAD, selection of control (population-based or hospital-based), sample size, ethnicity, and genotyping method.
The overall odds ratio (OR) was estimated with DerSimonian-Laird random effects model. The ORs of individual studies are shown as squares, with the size proportional to the weight of each study in the overall estimate; 95% confidence intervals (CIs) are shown as horizontal lines. The pooled OR and its 95% CI are shown as a dashed vertical line and a diamond, respectively. A, Additive model. B, Recessive model. C, Dominant model. D, AA versus GG. E, GA versus GG.
The quality of each study was assessed independently by two investigators using the Newcastle-Ottawa quality assessment scale . The quality of case control studies were evaluated the in the following three major components: selection of case and controls, comparability of cases and controls, and ascertainment of exposure. For cohort studies, the items assessed included selection of cohorts, comparability of cohorts, and assessment of outcome.
The horizontal line in the funnel plot indicates the random effects summary estimate, while the sloping lines indicate the expected 95% confidence intervals for a given standard error, assuming no heterogeneity between studies. Each study is represented by a circle, the area of which represents the study’s precision. A, Additive model (Egger’s test P = 0.643). B, Recessive model (Egger’s test P = 0.020 ). C, Dominant model (Egger’s test P = 0.519). D, AA versus GG (Egger’s test P = 0.014). E, GA versus GG (Egger’s test P = 0.429).
Deviation from Hardy-Weinberg equilibrium (HWE) in the control group was examined using a two tailed chi-square test. Association between G-403A polymorphism and CAD were tested under the following three genetic models: additive, recessive, and dominant. In addition, contrast of genotype AA versus GG, and GA versus GG were also evaluated.
The statistical heterogeneity among studies was assessed with Q statistic, and I2 test was used to quantify inconsistency. A Q statistic P value <0.10 or an I2 value≥50% was considered to represent significant statistical heterogeneity. Data were combined using a Mantel-Haenszel fixed effect method in the absence of heterogeneity; otherwise, DerSimonian and Laird random effect method was used.
A sensitivity analysis was conducted, after excluding each of the studies in turn, to evaluate whether the results could have been affected significantly by a single study. To explore the potential source of heterogeneity among individual studies and test the effects of study characteristics and methodological quality on the overall effect estimates, subgroup analyses and meta regression were performed stratified by the following factors: source of controls (population or hospital based), ethnicity (Caucasians or Asians), definition of cases (coronary angiography (CA) or non-CA), violation of HWE (yes or no), and genotyping methods.
Potential publication bias was examined by the asymmetry linear regression of Egger's test and displayed as funnel plot of precision (standard error of log RR) against the treatment effect (displayed as RR on a logarithmic scale). Statistical analyses were undertaken using Stata version 12.0 (StataCorp, College Station, TX).
Literature Review and Description of Included Studies
A total of 220 potentially relevant studies were identified from the following databases in our initial literature search: 66 from PubMed, 154 from EMBASE. Our hand search of the relevant reviews identified an additional citation. Our retrieving in CPCI-S and contacting with authors identified no additional studies. After screening the titles or abstracts, 211 studies were excluded because of duplicate data, other types of publications (book chapter, comment, conference proceeding, editorial, letter, or review), or non-relevance research (non-human study or evaluating RANTES level not polymorphism) (figure 1). The full-length papers of the remaining 10 studies were retrieved and assessed for eligibility. Of the retrieved studies, a total of eight –, ,  met our inclusion criteria and were included in our systematic review. The remaining 2 studies were excluded because the disease was not limited to CAD , or because the frequency of genotype was not available .
All studies included in the present meta analysis used a case-control design, with a total of 4252 CAD cases and 2150 controls. Characteristics of the included studies are summarized in table 2. Six studies were conducted in Caucasian population, while two were conducted in Asian population. Diverse genotyping methods were used, including single-strand conformation polymorphism (SSCP), TaqMan, SNaPshot, restriction fragment length polymorphisms (RFLP), and polymerase chain reaction with sequence-specific primers (PCR-SSP). The definition of cases varied among studies, but most employed coronary angiography for diagnosis of CAD , –, . Five studies recruited population-based controls and three , ,  recruited patients without CAD as controls. The distribution of RANTES genotype and A allele frequencies among CAD cases and controls are given in table 3. Seven of the eight studies reported data enabling formal testing of whether genotype frequencies in the control group deviated from HWE. In two studies, the genotype distributions in control groups were not consistent with that expected under HWE.
Using the quality assessment instrument, case-control study was assigned a maximum of 4 points for selection of case and controls, a maximum of 2 points for comparability of cases and controls, and a maximum of 3 points for ascertainment of exposure. Consequently, the theoretical maximum sum score of 9 points could be obtained if a study fulfilled all of the aforementioned criteria in quality assessment. Based on the quality assessment scale for case control studies, two studies had the maximum score of 9 points, four scored 8 points, and two scored 7 points, with a mean score of 8 (table 2).
Data Synthesis and Subgroup Analyses
A DerSimonian and Laird random effect method was employed in the estimation of overall odds ratio (OR) because of the significant heterogeneity in our initial data synthesis with fixed effect model. Table 4 and table 5 presents the results of meta analysis for the association of G-403A polymorphism and the susceptibility of CAD under different genetic models and contrasts. When all studies were included in the quantitative analysis, the results did not support the existence of relation between G-403A polymorphism and CAD. The overall ORs for the additive, recessive, as well as dominant genetic model, AA versus GG, and GA versus GG were 1.046 (95%CI: 0.883–1.239), 1.140 (95%CI: 0.774–1.678), 1.000 (95%CI: 0.820–1.219), 1.141 (95%CI: 0.734–1.773), 0.993 (95%CI: 0.800–1.232), respectively (figure 2). In the subgroup analysis under additive model, G-403A polymorphism was found to be correlated with increased risk of CAD when the estimation of pooled OR was restricted to Caucasians ethnic group (OR = 1.173, 95%CI: 1.045–1.316), studies violating HWE (OR = 1.210, 95%CI: 1.034–1.416), or studies using RFLP as genotyping method (OR = 1.209, 95%CI: 1.063–1.376). However, the G-403A polymorphism was found to be associated with decreased risk of CAD in Asians ethnic group (OR = 0.798, 95%CI: 0.680–0.936). In the subgroup analysis under dominant model, statistically significant but contradictory results were found among Caucasians ethnic group (OR = 1.155, 95%CI: 1.007–1.324), Asians ethnic group (OR = 0.717, 95%CI: 0.572–0.900), studies using RFLP genotyping method (OR = 1.233, 95%CI: 1.059–1.435), and studies using Non-RFLP genotyping method (OR = 0.818, 95%CI: 0.672–0.996). The decreased risk of CAD was also found in the Asians ethnic group under both AA vs GG and GA vs GG contrasts (OR = 0.672, 95% CI: 0.480–0.940; OR = 0.737, 95% CI: 0.568–0.955, respectively). Besides, combined data from studies violating HWE suggested a positive association of G-403A polymorphism with risk of CAD under GA vs GG contrast (OR = 1.279, 95% CI: 1.054–1.552). The remaining pooled ORs from other subgroup analysis did not reach statistical significance.
Sensitivity and Publication Bias
The results of meta analysis remained non-significant when each study was sequentially omitted from the analysis, indicating that the results of the present meta analysis were stable. The shape of funnel plots was symmetrical in the additive and dominant genetic model, as well as in contrast of GA versus GG, and the Egger’s test P value was 0.643, 0.519, and 0.429 respectively, suggesting no evidence of publication bias (Figure 3). However, obvious funnel plot asymmetry was found in recessive genetic model and the contrast of AA versus GG, with a significant Egger’s test P value (P = 0.020, P = 0.014 respectively), implying the existence of publication bias.
Since there was significant heterogeneity among individual studies, a univariable regression was conducted to explore the predefined possible source of heterogeneity under additive model. The results of univariable regression suggested that ethnicity and genotyping method were the significant source of heterogeneity (P = 0.012, 0.019, respectively), while the heterogeneity in the overall ORs could not be accounted for by source of controls, difference in cases definition or deviation from HWE (table 6). Including ethnicity and genotyping method in a multivariable regression model showed that those two variables can explain all of the heterogeneity (F = 7.86, P = 0.0411, τ = 0, I2-residual = 0%, Adj R2 = 100%).
The present meta-analysis, which involved 4252 CAD cases and 2150 controls, showed no evidence of an association between the G-403A polymorphism and CAD. Of the five overall ORs estimated under different genetic models and genotype contrasts, three showed a trend toward increased risk for CAD (OR>1), one showed an opposite trend toward decreased risk for CAD (OR<1), and the remaining one was a null value (OR = 1). Therefore it was not possible to draw any firm conclutions from these contradictory and not statistically significant results.
Significant heterogeneity existed among studies in all five comparisons, and subgroup analysis as well as meta regression confirmed that ethnicity and genotyping method variation account for all of the heterogeneity. Besides, subgroup analysis stratified by ethnicity, genotyping method, and departure from HWE provided significant and contradictory results in some, but not all, comparisons. G-403A polymorphism seemed to be a risk factor for the development of CAD in Caucasians ethnic group (under additive and dominant model), whereas its protective role in CAD was shown in Asians ethnic group (in all comparisons except recessive model), indicating that the role of G-403A polymorphism in the development of CAD may be ethnicity dependent. However, given the limited studies in Asians ethnic group, such implication needs further scientific justification based on large sample. Similarly, opposite results were also obtained among studies employing different genotyping method. In studies using RFLP method, G-403A polymorphism was shown to be a risk factor (under additive and dominant model) while in studies using non-RFLP method, it was shown to be protective for the development of CAD (under dominant model). Although no heterogeneity (I2 = 0% for RFLP subgroup under both additive and dominant model) or only minor heterogeneity (I2 = 18.8% for no-RFLP subgroup under dominant model) was presented in these statistically significant results, due to the variation in sensitivity and accuracy of different genotyping method, choosing an appropriate one is critical in SNP analysis. RFLP was the most often used method for genotyping RATENT in the present meta analysis because of its relative simplicity. However, RFLP is not a direct method and its discriminatory power depends on the restriction enzymes’ success in achieving recognition and cleavage at restriction sites. Besides, the high reaction temperature needed for RFLP might decrease the sensitivity of assay. Other genotyping methods, such as SSCP, SNaPshot, Taqman and PCR-SSP, were also employed in the studies included in the present meta analysis. Although SSCP has been widely used for genotyping, it is only suitable for screening sequence variations because of its relative low sensitivity  and inability to localize those variations to particular nucleotides. It has been demonstrated that SNaPshot , Taqman  and PCR-SSP  could provide high sensitivity and accuracy in SNP genotyping under optimized conditions. Hence, SNaPshot, Taqman and PCR-SSP are more reliable and accurate genotyping method for SNP detection compared with RFLP and SSCP. To minimize assay variation and increase statistical power, further studies with identical and reliable genotyping method and large sample will be required to confirm the association between G-403A polymorphism and CAD risk. Under additive model and GA vs GG comparison, pooled ORs for studies departing from HWE achieved statistical significance and indicated an increased risk of CAD for individuals with G-403A polymorphism. Because departure from HWE could be attributed to some potential bias such as genotyping error, possible ethnic admixture in the population or selection bias in choosing subjects, these results may not valid and must be interpreted with caution.
The G-403A polymorphism is caused by the substitution of adenine for guanine in the promoter region of the RANTES gene. There has been evidence that the A-403 mutant can lead to increased transcription of RANTES  and was associated with high levels of serum RANTES . It has been proven that RANTES was delivered by activated platelets or platelet microparticles in initiation of the atherogenetic process , . Subsequently, RANTES released by platelets deposited on the surface of inflamed endothelium, promoting circulating monocytes recruitment onto endothelial cells . It is therefore reasonable to hypothesise that G-403A polymorphism is associated with the susceptibility of CAD. However, the present meta analysis suggested that there was a lack of association between G-403A polymorphism and the development of CAD. Given the complexity of the etiology of CAD and the interplay between genetic background and exposures to environmental factors, the following factors may contribute to the lack of an association between the G-403A polymorphism and susceptibility of CAD. First, the G-403A polymorphism is not the only mutants found in the promoter region of RANTES gene and another mutant, C-28G polymorphism, has also been found to exist and affect its transcription activity . Hence, merely considering the role of G-403A polymorphism without excluding the influence of C-28G polymorphism may mask the possible relationship between the former and CAD. Second, RANTES exerts its chemotactic function by binding to several receptors, including CCR1, CCR3, as well as CCR5  and other genes regulating the expression of these receptors may influence the association between G-403A polymorphism and susceptibility of CAD. Third, since CAD is a complex and multifactorial disease, the effect of single genetic factor on the risk of CAD may be more pronounced in the presence of conventional cardiovascular risk factors such as hypertension, diabetes, and hypercholesterolemia. Although these risk factors were all well comparable within each single study, it was not excluded that the variability in baseline characteristics may exist among studies and any imbalance in these risk factors would distort the association of G-403A polymorphism with CAD.
There are some limitations with this meta-analysis that should be considered when interpreting the clinical significance of the results. A notable limitation is that all analyses were conducted at the study level because of the unavailability of individual patient data from the original studies. Therefore, our analysis was based on unadjusted estimates and classic CAD risk factors, including smoking, hypertension, diabetes, and dyslipidemia, can not be adjusted to provide more precise overall risk estimates. Besides, environmental factors such as lifestyle, diet, alcohol consumption, and stress were also unavailable and limited the evaluation of gene-environment interactions. Additionally, unpublished studies were not included in this meta analysis and both the asymmetric funnel plot and Egger’s test indicated the existence of publication bias in two of the five comparisons. Finally, it was likely that the statistically significant results observed in certain subgroup might be due to chance or confounding because of the limited studies included in that subgroup.
In conclusion, there was no evidence in support of the hypothesis that the G-403A polymorphism had any influence on the susceptibility of CAD in the current meta-analysis. Although subgroup analysis and meta regression suggested possible different and statistically significant influence of this mutant on CAD in Caucasian and Asian population, further analysis with more homogeneous sample and unified genotyping method is warranted to clarify this potential impact.
Conceived and designed the experiments: JL J-JL. Performed the experiments: R-XX X-LL. Analyzed the data: JL N-QW J-JL. Contributed reagents/materials/analysis tools: Y-JJ X-LL C-GZ. Wrote the paper: JL Y-LG J-JL.
- 1. Li JJ (2011) Inflammation in coronary artery diseases. Chin Med J 124: 3568–3575.
- 2. Ley K, Miller YI, Hedrick CC (2011) Monocyte and Macrophage Dynamics During Atherogenesis. Arterioscler Thromb Vasc Biol 31: 1506–1516. doi: 10.1161/atvbaha.110.221127
- 3. Zernecke A, Weber C (2010) Chemokines in the vascular inflammatory response of atherosclerosis. Cardiovasc Res 86: 192–201. doi: 10.1093/cvr/cvp391
- 4. Pattison JM, Nelson PJ, Huie P, Sibley RK, Krensky AM (1996) RANTES chemokine expression in transplant-associated accelerated atherosclerosis. J Heart Lung Transplant 15: 1194–1199. doi: 10.1016/s0140-6736(94)90992-x
- 5. Schober A, Manka D, von Hundelshausen P, Huo Y, Hanrath P, et al. (2002) Deposition of Platelet RANTES Triggering Monocyte Recruitment Requires P-Selectin and Is Involved in Neointima Formation After Arterial Injury. Circulation 106: 1523–1529. doi: 10.1161/01.cir.0000028590.02477.6f
- 6. Huo Y, Schober A, Forlow SB, Smith DF, Hyman MC, et al. (2003) Circulating activated platelets exacerbate atherosclerosis in mice deficient in apolipoprotein E. Nat Med. 9: 61–67. doi: 10.1038/nm810
- 7. Potteaux S, Combadière C, Esposito B, Lecureuil C, Ait-Oufella H, et al. (2006) Role of Bone Marrow–Derived CC-Chemokine Receptor 5 in the Development of Atherosclerosis of Low-Density Lipoprotein Receptor Knockout Mice. Arterioscler Thromb Vasc Biol 26: 1858–1863. doi: 10.1161/01.atv.0000231527.22762.71
- 8. Nickel RG, Casolaro V, Wahn U, Beyer K, Barnes KC, et al. (2000) Atopic Dermatitis Is Associated with a Functional Mutation in the Promoter of the C-C Chemokine RANTES. J Immunol 164: 1612–1616.
- 9. Simeoni E, Winkelmann BR, Hoffmann MM, Fleury S, Ruiz J, et al. (2004) Association of RANTES G-403A gene polymorphism with increased risk of coronary arteriosclerosis. Eur Heart J 25: 1438–1446. doi: 10.1016/j.ehj.2004.05.005
- 10. Vogiatzi K, Voudris V, Apostolakis S, Kochiadakis GE, Thomopoulou S, et al. (2009) Genetic diversity of RANTES gene promoter and susceptibility to coronary artery disease and restenosis after percutaneous coronary intervention. Thromb Res 124: 84–89. doi: 10.1016/j.thromres.2008.12.043
- 11. Jang Y, Chae JS, Hyun YJ, Koh SJ, Kim JY, et al. (2007) The RANTES -403G>A promoter polymorphism in Korean men: association with serum RANTES concentration and coronary artery disease. Clin Sci (Lond) 113: 349–356. doi: 10.1042/cs20070014
- 12. Berg KK, Madsen HO, Garred P, Wiseth R, Gunnes S, et al. (2009) The Additive Contribution from Inflammatory Genetic Markers on the Severity of Cardiovascular Disease. Scand J Immunol 69: 36–42. doi: 10.1111/j.1365-3083.2008.02187.x
- 13. Tavakkoly-Bazzaz J, Amiri P, Tajmir-Riahi M, Javidi D, Khojasteh-Fard M, et al. (2011) RANTES gene mRNA expression and its −403 G/A promoter polymorphism in coronary artery disease. Gene 487: 103–106. doi: 10.1016/j.gene.2011.07.019
- 14. Tereshchenko IP, Petrkova J, Voevoda MI, Taborsky M, Navratilova Z, et al. (2011) CCL5/RANTES gene polymorphisms in Slavonic patients with myocardial infarction. Mediators Inflamm. 2011: 525691. doi: 10.1155/2011/525691
- 15. Wells GA, Shea B, O'Connell D, Petersen J, Welch V, et al. The Newcastle-Ottawa Scale (NOS) for assessing the quality of nonrandomized studies in meta-analyses. Available: http://www.ohri.ca/programs/clinical_epidemiology/oxford.htm. Accessed 2012 Mar 31.
- 16. Park S, Youn JC, Shin DJ, Park CM, Kim JS, et al.. (2007) Genetic polymorphism in the pregnancy-associated plasma protein-A associated with acute myocardial infarction. Coron Artery Dis 18: 417–422 410.
- 17. Szalai C, Duba J, Prohászka Z, Kalina Á, Szabó T, et al. (2001) Involvement of polymorphisms in the chemokine system in the susceptibility for coronary artery disease (CAD). Coincidence of elevated Lp(a) and MCP-1 −2518 G/G genotype in CAD patients. Atherosclerosis 158: 233–239. doi: 10.1016/s0021-9150(01)00423-3
- 18. Böger CA, Fischereder M, Deinzer M, Aslanidis C, Schmitz G, et al. (2005) RANTES gene polymorphisms predict all-cause and cardiac mortality in type 2 diabetes mellitus hemodialysis patients. Atherosclerosis 183: 121–129. doi: 10.1016/j.atherosclerosis.2005.03.006
- 19. Herder C, Peeters W, Illig T, Baumert J, de Kleijn DPV, et al. (2011) RANTES/CCL5 and Risk for Coronary Events: Results from the MONICA/KORA Augsburg Case-Cohort, Athero-Express and CARDIoGRAM Studies. PLoS ONE 6: e25734. doi: 10.1371/journal.pone.0025734
- 20. Parsons BL, Heflich RH (1997) Genotypic selection methods for the direct analysis of point mutations. Mutat Res 387: 97–121. doi: 10.1016/s1383-5742(97)00026-4
- 21. Li L, Li CJ, Zhang YJ, Zheng L, Jiang HX, et al. (2011) Simultaneous detection of CYP3A5 and MDR1 polymorphisms based on the SNaPshot assay. Clin Biochem 44: 418–422. doi: 10.1016/j.clinbiochem.2010.12.018
- 22. Zhou C, Ni J, Zhao YM, Su B (2006) Rapid detection of epidermal growth factor receptor mutations in non-small cell lung cancer using real-time polymerase chain reaction with TaqMan-MGB probes. Cancer J 12: 33–39. doi: 10.1097/00130404-200601000-00007
- 23. von Hundelshausen P, Weber KSC, Huo Y, Proudfoot AEI, Nelson PJ, et al. (2001) RANTES Deposition by Platelets Triggers Monocyte Arrest on Inflamed and Atherosclerotic Endothelium. Circulation 103: 1772–1777. doi: 10.1161/01.cir.103.13.1772
- 24. Mause SF, von Hundelshausen P, Zernecke A, Koenen RR, Weber C (2005) Platelet Microparticles. Arterioscler Thromb Vasc Biol 25: 1512–1518.
- 25. Liu H, Chao D, Nakayama EE, Taguchi H, Goto M, et al. (1999) Polymorphism in RANTES chemokine promoter affects HIV-1 disease progression. Proc Natl Acad Sci U S A. 96: 4581–4585. doi: 10.1073/pnas.96.8.4581
- 26. Apostolakis S, Papadakis EG, Krambovitis E, Spandidos DA (2006) Chemokines in vascular pathology. Int J Mol Med 17: 691–701. doi: 10.3892/ijmm.17.5.691