Abstract
Objective. To assess the potential association between CD40 rs1883832 polymorphism and biopsy-proven giant cell arteritis (GCA). We also studied the influence of the polymorphism on phenotypic expression of this vasculitis, in particular the development of visual ischemic manifestations.
Methods. Three hundred five Spanish patients with biopsy-proven GCA and 788 matched controls were assessed. DNA from patients and controls was obtained from peripheral blood. Samples were genotyped for the CD40 rs1883832 C/T polymorphism using a predesigned TaqMan allele discrimination assay and by polymerase chain reaction amplification.
Results. Patients with GCA showed a trend toward a higher frequency of the minor allele homozygote of rs1883832 (TT) compared to healthy controls (12.1% vs 8.3%, respectively; p = 0.05, OR 1.54, 95% CI 0.98–2.40). Also, a marginally significant increased frequency of the minor allele T was observed in patients with GCA who had visual ischemic manifestations (36.9%) compared to those without visual ischemic manifestations (27.7%; p = 0.04, OR 1.53, 95% CI 0.99–2.34). In this regard, patients with GCA carrying the minor allele T (either TT or TC) experienced visual ischemic manifestations more commonly than those carrying the CC genotype (58.5% vs 44.2%; p = 0.04, OR 1.78, 95% CI 0.99–3.22).
Conclusion. Our results suggest a potential implication of the CD40 rs1883832 C/T polymorphism in susceptibility to visual ischemic manifestations in individuals with biopsy-proven GCA.
- GIANT CELL ARTERITIS
- TEMPORAL ARTERY BIOPSY
- GENETICS
- CD40 GENE POLYMORPHISM
- RS1883832
- VISUAL ISCHEMIC MANIFESTATIONS
Giant cell arteritis (GCA) is the most common type of systemic vasculitis in Western countries in individuals over age 501,2. The immune attack, affecting medium-size and large arteries, leads to damage of the wall structures and to rapid concentric hyperplasia of the intima, followed by luminal occlusion3,4. Clinical manifestations reflect end-organ ischemia, including blindness, jaw claudication, or stroke. GCA is a complex polygenic disease5. Various gene polymorphisms have been associated with either disease susceptibility5,6,7 or a higher risk of severe ischemic complications8,9.
GCA inflammatory lesions infiltrate all layers of the arterial wall, and are composed of T cells, dendritic cells (DC), highly activated macrophages, and in some cases multinucleated giant cells10. However, B cell infiltration is rare11.
CD40 is a type I transmembrane protein receptor of the tumor necrosis factor (TNF) superfamily12. Activation of CD40 results in binding to TNF receptor-associated factors13 and upregulation of proinflammatory genes14,15. Various studies support an important role of this moiety in vascular wall inflammation: CD40 is constitutively expressed in vascular wall cells such as endothelial cells (EC) and smooth muscle cells (SMC)16, macrophages, DC, and fibroblasts. CD40/CD40L interactions on the EC result in endothelium and SMC activation and expression of adhesion molecules17, promoting leukocyte recruitment and migration into tunica media. CD40 upregulates expression of local vascular endothelial growth factor and basic fibroblast growth factor18, promoting in vivo angiogenesis (a major structural alteration in the inflamed tunica media is the formation of blood vessels)19. CD40/CD40L has a role in DC/T cell interactions inside the vascular wall20: CD40L on activated T cells interacts with CD40 on DC, enhancing several costimulatory ligands on the DC that interact with T cell costimulatory receptors, promoting a positive feedback loop that drives differentiation21. CD40 is a major mechanism involved in interleukin 12 (IL-12) production by DC22. In turn, IL-12 is dominant in directing the development of naive CD4 T cells into T helper (Th)1 cells that produce high amounts of interferon-γ (IFN-γ)23. IFN-γ tissue concentration correlates with the degree of intimal thickening, the extent of neovascularization, and the formation of multi-nucleated giant cells19.
There is a single-nucleotide polymorphism located in the 5’ untranslated region (Kozak sequence) of the CD40 gene (−1C/T, rs1883832). Its major allele has been associated to Graves’ disease24. Also, the major allele of another CD40 polymorphism (rs4810485), in almost complete linkage disequilibrium with rs1883832 (r2 = 0.95), has been associated with rheumatoid arthritis (RA)25.
The CD40 rs1883832 major allele has been associated with an increased translational efficiency of nascent CD40 mRNA transcripts26, resulting in an increase of CD40 expression at the cell surface27.
CD40 is known to be a regulator of retinal inflammation and neurovascular degeneration28. However, to our knowledge, no previous studies have linked the CD40 rs1883832 polymorphism with ophthalmological diseases. Taking into account this evidence, we aimed to assess the potential association between the rs1883832 CD40 polymorphism and biopsy-proven GCA. We also studied whether this polymorphism might influence the phenotypic expression of this vasculitis, in particular the development of visual ischemic manifestations.
MATERIAL AND METHODS
Patients
Three hundred five patients diagnosed with biopsy-proven GCA were recruited from departments of Rheumatology or Internal Medicine located in 5 Spanish cities: Lugo (Hospital Xeral-Calde), Madrid (Hospital Clínico San Carlos and Hospital de la Princesa), Barcelona (Hospital Universitario de Bellvitge), Sabadell (Hospital de Sabadell), and Granada (Hospital Clínico San Cecilio). A control population composed of 788 healthy controls from the corresponding cities matched by age and sex with patients with GCA was also assessed. All patients with GCA had a positive temporal artery biopsy showing disruption of the internal elastic laminae with infiltration of mononuclear cells into the arterial wall with or without giant cells29. Also, all of them met the 1990 American College of Rheumatology criteria for the classification of GCA30. Patients and controls all provided written informed consent. We obtained approval for the study from the local ethics committees.
Clinical ischemic manifestations were assessed that occurred in the time from the onset of GCA symptoms to 1 month after the onset of corticosteroid therapy31,32. The manifestations were considered to be present based on established definitions and consisted of the presence of visual ischemic manifestations33 and severe ischemic complications34,35. We also assessed the presence of polymyalgia rheumatica (PMR) based on reported definitions34,35.
Genotyping methods
DNA from patients and controls was obtained from peripheral blood, using standard methods. Samples were genotyped for the CD40 (−1C/T) rs1883832 polymorphism using a TaqMan 5’ allele discrimination assay (Applied Biosystems, Foster City, CA, USA). Allele-specific probes were labeled with the fluorescent dyes VIC and FAM. Polymerase chain reaction (PCR) was carried out in a total reaction volume of 4 μl with the following amplification protocol: denaturation at 95°C for 10 min, followed by 45 cycles of denaturation at 92°C for 15 s, and finished with annealing and extension at 60°C for 1 min. Post-PCR, the genotype of each sample was attributed automatically by measuring the allelic-specific fluorescence on ABI Prism 7900 Sequence Detection Systems using SDS 2.3 software for allelic discrimination (Applied Biosystems)36. Duplicate samples and negative controls were included to ensure accuracy of genotyping.
Statistical analysis
We used the chi-square test and Fisher’s exact test for Hardy-Weinberg equilibrium and statistical analysis to compare allelic and genotypic distributions. Odds ratios and 95% CI were calculated according to Woolf’s method using the Statcalc program (Epi-Info 2002, Centers for Disease Control and Prevention, Atlanta, GA, USA). P values < 0.05 were considered statistically significant.
RESULTS
The median age at the time of disease diagnosis in this series of 305 patients with biopsy-proven GCA was 75 years (interquartile range 70-79 yrs). Women (n = 209; 68.5%) outnumbered men. Headache was the most common feature (n = 243; 79.7%). An abnormal temporal artery on physical examination was observed in 168 (55.1%) patients. Also, 146 (47.9%) had PMR. Jaw claudication occurred in 127 (41.6%). Visual ischemic manifestations were observed in 65 (21.3%) patients. Fourteen (4.6%) experienced a stroke. Severe ischemic complications (defined if at least 1 of the following was observed: visual ischemic manifestations, cerebrovascular accidents, jaw claudication, or limb claudication of recent onset) were found in 163 (53.4%) patients.
No evidence of departure from Hardy-Weinberg equilibrium was observed in controls. The case:control ratio was 1:2.5. The power of this study for finding a difference between patients with GCA and healthy controls was between 69% and 98%, with an estimated OR between 1.5 and 2.0, a type I error rate of 0.05, a dominant inheritance mode and 0.0001% of population risk.
Influence of CD40 rs1883832 polymorphism in the susceptibility to GCA
Patients with GCA showed a trend toward a higher frequency of the minor allele homozygote of rs1883832 (TT) compared to controls (12.1% vs 8.3%, respectively; p = 0.05, OR 1.54, 95% CI 0.98–2.40; Table 1). In this regard, the frequency of the minor allele T was increased among patients with GCA compared to controls but the difference did not achieve statistical significance (29.7% vs 27.0%, respectively; p = 0.20).
Genotype and allele frequencies of CD40 rs1883832 polymorphism according to patients’ clinical manifestations
To further investigate the potential role of the CD40 rs1883832 polymorphism in the phenotypic expression of this vasculitis, patients with GCA were stratified according to the occurrence of PMR, visual ischemic complications, or severe ischemic manifestations, and then assessed for the allele and genotype distribution (Table 2). No significant differences were found in the allele or genotype frequencies between patients with GCA, either with or without PMR (Table 2). However, a marginally significant increased frequency of the minor allele T was observed in patients who had visual ischemic manifestations (36.9%) compared to patients who did not have visual ischemic manifestations (27.7%; p = 0.04, OR 1.53, 95% CI 0.99–2.34). However, the correction of p value for the number of alleles tested yielded a p value for the allele T association with visual ischemic manifestations slightly out of the range of significance (p = 0.08).
Also, patients with GCA carrying the minor allele T (either TT or TC) experienced visual ischemic manifestations more commonly than those carrying the CC genotype (58.5% vs 44.2%, respectively; p = 0.04, OR 1.78, 95% CI 0.99–3.22). Moreover, there was a nonsignificant trend toward a higher frequency of the minor allele T among patients with severe ischemic complications (32.5%) compared to those without these complications (26.4%; p = 0.10, OR 1.34, 95% CI 0.93–1.94). In this regard, the frequency of individuals carrying the minor allele T was increased among patients who had severe ischemic complications (52.1%) compared to those without severe ischemic complications (41.5%) but the difference remained slightly out of the range of significance (p = 0.065, OR 1.53, 95% CI 0.95–2.48).
Comparison of patients with GCA according to the presence or absence of other clinical manifestations did not yield statistically significant differences (data not shown).
DISCUSSION
We analyzed for the first time the potential implication of the CD40 rs1883832 C/T polymorphism in susceptibility to biopsy-proven GCA. We observed a nonsignificant trend for association between the genotype TT (homozygous for the minor allele T) and biopsy-proven GCA. However, differences in allelic frequencies between patients with GCA and healthy controls were smaller. Our data, assessing the largest series of GCA included in a genetic study, also disclosed a marginally significant increased frequency of the minor allele T of the CD40 rs1883832 polymorphism in the subgroup of patients with GCA who experienced visual ischemic manifestations. We also observed a higher frequency of the minor allele T among patients with severe ischemic complications, but the differences were smaller and did not reach statistical significance, probably because of an insufficient sample size, as GCA is a relatively uncommon disease.
The CD40 rs1883832 C/T polymorphism has previously been associated with Graves’ disease24,37 and multiple sclerosis38. Another CD40 polymorphism (rs4810485) in linkage disequilibrium with rs1883832 (r2 = 0.95) has been associated with an increased risk for RA25 and a higher rate of joint destruction in patients with this chronic inflammatory rheumatic disease39. In both Graves’ disease and RA the allele associated with a higher risk of disease susceptibility or with worse outcome was the major allele C. This major allele C has been associated with a higher expression of the CD40 moiety in cell surface of peripheral blood mononuclear cells, B cells, and platelets26,27,40. However, in keeping with data reported in patients with multiple sclerosis, in our series of GCA the allele that seems to be associated with a worse outcome (manifested by increased risk of visual ischemic complications) was the minor allele T.
As discussed, arterial wall inflammation leads to rapid concentric hyperplasia of the intima, followed by luminal occlusion in patients with GCA3,4. Because of the potential role played by CD40/CD40L interaction in the stimulus of IL-12 secretion by local DC, it is possible that the smaller number of CD40 moieties on the cell surface associated with the minor allele T of the rs1883832 polymorphism26 might predispose to a higher risk of visual ischemic manifestations in patients with GCA. IL-12 is dominant in directing the development of naive CD4 T cells into Th1 cells that produce high amounts of IFN-γ, a key cytokine in GCA, whose tissue concentration correlates with the degree of intimal thickening, the extent of neovascularization, and the formation of multinucleated giant cells19. Moreover, the source of IL-12 is highly restricted to DC that produce this cytokine after stimulation with either bacterial components such as lipopolysaccharide (LPS) or during the interaction with CD4+ T cells, because of the ligation of either CD4023 or MHC class II molecules on DC. LPS-induced IL-12 plays an important role in the activation of the effector mechanisms in the initial phase of immune response in infected tissues, initiating an innate resistance to the pathogen while ensuring induction of the correct class of adaptive host response22. However, the major mechanisms involved in IL-12 induction appear to be signaling through DC surface CD40 molecules or MHC class II molecules22. Considering that GCA has been proposed to be an antigen-driven disease41, we hypothesize that CD40 rs1883832 C/T polymorphism might contribute to an insufficient initial immune reaction against the antigen or antigens responsible for this vasculitis, leading to a situation in which the antigen cannot be completely eradicated, and chronically stimulates the immune system inside the arterial wall. This hypothesis agrees with previous observations in which patients with biopsy-proven GCA who suffered visual ischemic manifestations were associated with an initial lower inflammatory response31,42,43,44. The fact that subjects not carrying CD40 rs1883832 minor allele T develop this condition may be due to the intrinsic characteristics of the antigen responsible for the disease, that is, it is difficult to eradicate completely even with a normal amount of CD40 in the cell surface.
Based on our data, the presence of this genetic variant could help to identify patients with biopsy-proven GCA who have a higher risk of a worse visual outcome. Further studies in large series of patients with GCA are needed to confirm our observations.
Acknowledgment
We thank Sofia Vargas, Gema Robledo, and Sonia García Ruíz for processing the DNA samples. We also thank Sara Abel Liz, Maria Soledad Folgosa Rodriguez, and Ana Maria Ramos Gandoy, nurses from the Rheumatology Division, Hospital Xeral-Calde, Lugo, Spain, for help in collection of samples.
Footnotes
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Dr. González-Gay and Dr. Martín shared authorship in this study.
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Supported by 2 grants from Fondo de Investigaciones Sanitarias PI06-0024 and PS09/00748 (Spain); and partially supported by RETICS Program, RD08/0075 (RIER) from Instituto de Salud Carlos III.
- Accepted for publication May 4, 2010.