- About this Journal ·
- Abstracting and Indexing ·
- Aims and Scope ·
- Annual Issues ·
- Article Processing Charges ·
- Articles in Press ·
- Author Guidelines ·
- Bibliographic Information ·
- Citations to this Journal ·
- Contact Information ·
- Editorial Board ·
- Editorial Workflow ·
- Free eTOC Alerts ·
- Publication Ethics ·
- Reviewers Acknowledgment ·
- Submit a Manuscript ·
- Subscription Information ·
- Table of Contents
Mediators of Inflammation
Volume 2012 (2012), Article ID 320953, 10 pages
oxLDL Downregulates the Dendritic Cell Homing Factors CCR7 and CCL21
1Medizinische Klinik und Poliklinik I, Campus Grosshadern, Ludwig-Maximilians University, 81377 Munich, Germany
2Institute of Clinical Chemistry, Campus Grosshadern, Ludwig-Maximilians University, 81377 Munich, Germany
3Department of Surgery, Campus Grosshadern, Ludwig-Maximilians University, 81377 Munich, Germany
4Department of Cardiothoracic Surgery, J. W. Goethe University, 61590 Frankfurt, Germany
5Department of Cardiac Surgery, Campus Grosshadern, Ludwig-Maximilians University, 81377 Munich, Germany
Received 28 August 2011; Accepted 14 February 2012
Academic Editor: Carlos Henrique Serezani
Copyright © 2012 Thomas Nickel et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Introduction. Dendritic cells (DCs) and oxLDL play an important role in the atherosclerotic process with DCs accumulating in the plaques during plaque progression. Our aim was to investigate the role of oxLDL in the modulation of the DC homing-receptor CCR7 and endothelial-ligand CCL21. Methods and Results. The expression of the DC homing-receptor CCR7 and its endothelial-ligand CCL21 was examined on atherosclerotic carotic plaques of 47 patients via qRT-PCR and immunofluorescence. In vitro, we studied the expression of CCR7 on DCs and CCL21 on human microvascular endothelial cells (HMECs) in response to oxLDL. CCL21- and CCR7-mRNA levels were significantly downregulated in atherosclerotic plaques versus non-atherosclerotic controls [90% for CCL21 and 81% for CCR7 ()]. In vitro, oxLDL reduced CCR7 mRNA levels on DCs by 30% and protein levels by 46%. Furthermore, mRNA expression of CCL21 was significantly reduced by 50% () and protein expression by 24% in HMECs by oxLDL (). Conclusions. The accumulation of DCs in atherosclerotic plaques appears to be related to a downregulation of chemokines and their ligands, which are known to regulate DC migration. oxLDL induces an in vitro downregulation of CCR7 and CCL21, which may play a role in the reduction of DC migration from the plaques.
Atherosclerosis is a dynamic inflammatory disease [1, 2] in which autoantigenes, such as oxidized low-density protein (oxLDL), play an essential role. Dendritic cells (DCs) are key regulatory antigen-presenting cells (APCs) that induce inflammatory processes. DCs can be detected in the vascular inflammatory environment, from endothelial dysfunction to consecutive plaque formation and rupture [3–5]. DCs are the most potent APCs and are highly specialized to prime naive T-cells . Interestingly, mature DC-specific markers, for example, CD83, accumulate during plaque progression. It has been shown previously that the presence of CD83 is more than two fold, higher in symptomatic compared to asymptomatic patients .
DCs, after entering the vascular tissue, screen the environment for potential antibodies . After processing the antigens, a maturation process is initiated and immunomodulatory receptors, such as the CD83-receptor (important for T-cell-stimulation), are upregulated . In a previous study, we found a CD83 upregulation on DCs by proatherosclerotic stimuli like oxLDL and asymmetric dimethylarginine (ADMA) . Beside CD83, DC induces CCR7 expression during maturation, which acts as a receptor for constitutively expressed CCL21 and CCL19 [10, 11]. In analogy to DC accumulation and maturation, activated CCR7 expressing T-cells are trapped especially in the plaque shoulders [12, 13] where mature DCs are forming clusters with T cells .
Several studies have demonstrated the important link between DC/T-cell recruitment and CCR7 expression [12–14]. The increase in CCR7 receptors induces homing of mature DCs and T-cells to the lymph nodes through CCL21/CCL19 expressing lymph vessels [2, 11, 12].
High plasma concentrations of oxLDL and their appearance in atherosclerotic lesions are of utmost importance in the pathogenesis of atherosclerosis .
The present study focuses on the influence of oxLDL on the DC-related chemokine receptors CCR7, CCL19, and CCL21. We characterized the DC-specific chemokine-ligand expression in human atherosclerotic carotid artery plaques. Furthermore, we investigated the impact of oxLDL on the DC receptor CCR7 expression and its ligands CCL-21 on human microvascular endothelial cells (HMECs).
2. Materials and Methods
2.1. In Vivo
2.1.1. Study Population
All investigations were approved by the institutional review board and the ethics committee of the Ludwig-Maximilians University of Munich. Informed consent was obtained from all patients. The investigation conforms to the principles outlined in the declaration of Helsinki. Between September 2006 and May 2008, carotid endarterectomy (CEA) was performed in 47 patients. The indications for CEA were based on carotid duplex sonography: stenosis of the internal carotid artery of more than 70% for symptomatic patients and more than 85% for asymptomatic patients. For comparison, we collected 10 blood samples from healthy age-matched men without clinically manifested atherosclerosis and 14 pieces of aortic tissue with no visible atherosclerotic lesions.
2.1.2. RNA Isolation from Atherosclerotic Plaque for Real-Time PCR
100 mg plaque tissue was homogenized in 1 mL QIAzol Lysis. 50 pg/tube RNA (PBMCs) was used. First-strand cDNA synthesis and PCR were performed using Omniscript from Qiagen (Hilden, Germany). The two-step quantitative real-time PCR (rt-PCR) system was applied according to the manufacturers’ instructions. The quantitative real-time PCR system provides optimal performance with SYBR Green primers (Qiagen: Hilden, Germany). Rt-PCR was performed in the ABI PRISMTM 7700 System (Applied Biosystems, Germany). Data analysis was performed using the delta-delta-Ct method as described previously . Primer sequences for the amplified fragments were GAPDH: 5′-CGG AGT CAA CGG ATT TGG TCG TAT-3′/5′-AGC CTT CTC CAT GGT GGT GAA GAC-3′; CCR7: 5′-TGG AGG CCT TTA TCA CCA TC-3′/5′-TGT AGG GCA GCT GGA AGA CT-3′; CCL19: 5′-CTG TGA CCC AGA AAC CCA TC-3′/5′-GCT TCA TCT TGG CTG AGG TC-3′; CCL21: 5′-CCC AGC TAT CCT GTT CTT GC-3′/5′-TCA GTC CTC TTG CAG CCT TT-3′; CD4: 5′-AGG AAG TGA ACC TGG TGG TG-3′/5′-CTC AGC AGA CAC TGC CAC AT-3′.
2.1.3. Immunofluorescence Analysis of CCL21 Expression in Human Plaque and Aortic Tissue
Frozen sections (10 μm) were prepared from human aorta and plaque material of the internal carotid artery. After fixation in methanol/ethanolic acid for 1.5 min at −20°C, the sections were washed immediately 3 times for 3 min in PBS. Unspecific binding was blocked with a 2% BSA/0.2% Tween 20 solution for 1 h and followed by 3 washing steps in PBS. To visualize nucleoli we used DAPI (4′, 6′Diamidino-2′phenylindole, Merck KGaA, Germany) in a final concentration of 1 μg/mL. After another washing step the sections were incubated with a fluorescent labelled anti-human CCL21/6Ckine antibody (5 μg/mL, R&D Systems, Inc., Germany).
To determine the localization of the CCL21 expressing structure (CCL21/6Ckine antibody 5 μg/mL, R&D Systems, Inc., Germany), the sections were also incubated with a Cy3-labeled anti-PECAM-1 antibody (5 μg/mL, AbD Serotec, Germany), which demarcates the endothelia cells in the vessel wall. Immunofluorescence analysis of CCL21 expression was investigated by confocal microscopy (LSM 510 META, Zeiss, Plan-Neofluar 40x/1.30 oil objective, Germany) and quantified by LSM Image Browser 4.2 (Zeiss, Germany).
2.1.4. Immunofluorescence Analysis of CCR-7/CD4- and CCR-7/CD83-Coexpression in Human Plaque and Aortic Tissue
The sections were incubated with an FITC-labelled anti-human CCR7 antibody (1 : 100 concentration, R&D Systems, Inc., Germany) for 1 h, followed by 3 washing steps in PBS.
The sections were incubated with an Atto594-labeled anti-CD4 antibody (10 μg/mL, AbD Serotec, Germany) or Atto594-labelled anti-CD83 (10 μg/mL, AbD Serotec, Germany) for 1 h, which represents the T-lymphocytes (CD4) or mature DC (CD83). The immunofluorescence analysis was investigated by confocal microscopy (LSM 510 META, Zeiss, Plan-Neofluar 40x/1.30 oil objective, Germany).
2.1.5. ELISA for oxLDL and CCL21
Plasma tubes were centrifuged and the plasma was fractionated and frozen at −80°C.
oxLDL levels were examined by using a cytokine-specific ELISA kit according to the manufacturers’ instructions (ImmunDiagnostik, Bensheim, Germany) . Before analysis, samples were treated as described above. In brief, after washing with wash buffer several times, standard samples and controls were added and incubated for 4 hours at room temperature on a horizontal mixer. Thereafter, a washing conjugate was added and incubated for 1 h as described before. The substrate was added and incubated for 25 minutes in the dark. Stop-solution was added and immediately analyzed by an ELISA-reader at 450 nm.
Detection of CCL21 in serum was also performed by a quantitative sandwich enzyme immunoassay technique, according to the manufacturers’ instructions (R&D Systems, Germany).
2.2. In Vitro
2.2.1. Generation of Monocyte-Derived Dendritic Cells (DCs)
Mononuclear cells were isolated from 100 mL of peripheral blood of a healthy human donor by a Ficoll density gradient according to the protocol by Boyum . The purity of the monocyte culture was enhanced up to 97% by adhesion on γ-globulin coated plates. DCs were obtained from the monocyte culture according to the modified protocol by Romani et al.  as described in detail in our recent publication [9, 17].
2.2.2. Endothelial Cells (ECs)
All experiments were performed with human microvascular endothelial cells (HMECs-1), generously provided by the Center for Disease Control and Prevention and the National Center for Infectious Disease (Atlanta, USA). Cells were cultured in MCDB-131 (without phenol red; cc pro, Neustadt/W., Germany) supplemented with 10% fetal calf serum (FCS; PAA, Pasching, Austria), 2 mM L-Glutamine (Biochrom AG, Berlin, Germany), 1 μg/mL hydrocortisone, and 10 ng/mL epidermal growth factor (Sigma, Taufkirchen, Germany). The cells were used at least 10 days after thawing and for no more than 20 passages .
2.2.3. LDL Oxidation
LDL (density = 1.019 to 1.063 g/mL) was isolated from human plasma of normolipidemic healthy volunteers by sequential ultracentrifugation as described and stored in PBS containing 2 mmol/L EDTA. Shortly before oxidation, the EDTA was removed from LDL by passing the lipoprotein through a PD 10 column (Pharmacia, Austria). LDL was oxidized in Ham’s F-10 medium by exposure to 5 μmol/L CuSO4 at 37°C for 30 h [11, 21]. All preparations were dialyzed before they were added to the cultured cells. This reflects oxLDL concentrations in the plaque and has been used in previous studies [5, 22, 23]. In addition, several other studies have shown that an oxLDL concentration of (10 μg/mL) is not toxic to the cultured cells [9, 24, 25]
2.2.4. Total RNA Isolation and Real-Time PCR
For isolation of mRNA from HMECs-1 and DCs, the total RNA isolation RNAeasy Mini Kit from Qiagen (Hilden, Germany) was used according to the instructions provided by the manufacturer. 50 pg/tube RNA (PBMC) was used. First-strand cDNA synthesis and PCR were performed using Omniscript from Qiagen (Hilden, Germany). The two-step quantitative RT-PCR system was applied according to the manufacturers’ instructions and as described above .
2.2.5. Flow-Cytometric Analysis of DCs
Cells were incubated with antibodies according to the manufacturers’ instructions. Fixed cells were analyzed on an FACS Calibur cytometer (Becton Dickinson). Antibodies were matched to iso-type-controls (Mouse-γ2a-(FITC)/-γ1(PE)-Fastimmune; BD; USA). To verify the purity of our DC-culture, we used CD3 (BD, USA) and CD20 (BD, USA) to rule out a T-cell and B-cell contamination (<5%). DCs were characterized by low CD14 expression (BD, USA) and high expression of CD80 (BD, USA), CD86 (BD, USA), and HLA-DR (BD, USA), as described previously .
At day five, we incubated the DCs with oxLDL (10 μg/mL) for 24 hours. Expression analysis of the chemokine receptor CCR7 (R&D, USA) and CD83 (BioLegend, USA) on human DCs were performed using flow-cytometer analysis [16, 17].
2.2.6. Immunofluorescence of CCL21 on HMECs-1
HMECs-1 were cultivated on chamber slides and stimulated with 10 μg/mL oxLDL for 48 h. The monoclonal antibody for CCL21/6Ckine (R&D, USA) was labeled with Alexa 488 using the Alexa Fluor Protein Labeling Kit (Invitrogen, life technologies, USA) according to the manufacturers’ instructions. HMECs-1 were incubated with the labeled antibody (concentration 1 : 20) for 30 minutes. Thereafter, Vybrant DiD (Invitrogen, life technologies, USA) was used as a marker of the plasma membrane. CCL21-labeled HMECs-1 were investigated by confocal microscopy (Zeiss LSM 510 Meta, Plan-Apochromat 63x/1.40 oil objective) and quantified by LSM Image Browser 4.2 (Zeiss, Germany).
2.2.7. Statistical Analysis
Data is presented as ± standard-deviation of the mean (SDM). The Kolmogorov-Smirnov test was used to determine whether or not the data was normally distributed. If the data was normally distributed, the unpaired t-test was used to compare the two groups. Data that was not normally distributed was compared using the Wilcoxon signed Rank Test. Differences between means were considered significant with and highly significant with . All in-vitro experiments were repeated at least eight times with different cells and lipoprotein preparations. SPSS (version 16, Leibniz Rechenzentrum Munich) was used for statistical analysis.
3. Results and Discussion
3.1. In Vivo
3.1.1. Study Population
Carotid plaque tissue and blood samples were collected from 47 patients undergoing CEA, of which 77% were male and, on average,years of age. 66% had asymptomatic disease, whereas and the rest showed cerebral ischemic complications. The different risk profiles and medication are summarized in Table 1.
Serum for the PBMCs in the control group was collected from 10 healthy age-matched patients. 60% were of male gender with an average age of years. None had cerebral ischemic complications or clinical manifest atherosclerosis. Concerning the risk-profile, 20% had insulin-dependent diabetes mellitus, 80% hypertension, and 10% were smokers. Concerning the medication, 10% took thrombocyte aggregation inhibitors, 80% statins, and 60% had a β-blocker (Table 1).
Aortic tissue in the control group was collected from 14 patients who underwent valve replacement and had no sign of aortic atherosclerosis. 71% were of male gender with an average age ofyears. 14% had a cerebral ischemic event. Concerning the risk profile, 28% had insulin-dependent diabetes mellitus, 85% hypertension, and 35% were smokers. With respect to medication, 43% took thrombocyte aggregation inhibitors, 78% statins, and 43% had a β-blocker.
3.1.2. CCL21/CCL19 and CD83/CCR7 and CD4 mRNA Analysis of the Atherosclerotic Plaque
In line with previous investigations, we detected that the median CD83 mRNA levels in plaque tissue from CEA-group were nearly twice as high as in healthy aortic tissue (), demonstrating the augmented presence of mature DCs in the atherosclerotic tissue [7, 27, 28]. In a subgroup analysis, we further found that CD83 levels in men were significantly higher (+120%; ) compared to women. CD4 mRNA levels were evenfold higher in healthy aortic tissue (; data not shown).
CCR7, normally coexpressed on mature DCs and T-cells, was 81% lower in the plaque compared to compared to healthy aortic tissue () without any gender specific differences.
Further analysis of CCL19 revealed that its transcripts were downregulated by 99% (). CCL21 was found 90% lower in the plaque () compared to healthy aortic tissue (Figure 1).
Furthermore CCL21 was also found lower in the symptomatic patients (58%; ) compared to asymptomatic patients from the CEA group.
3.1.3. Immunofluorescence Analysis of CCL21 Expression in Human Plaque and Aortic Tissue
To confirm the PCR results on the protein level, we performed a semiquantitative immunofluorescence analysis on histological slides of human aortic and plaque tissue.
To analyze the location of CCL21 expressing cells, we stained the endothelial cells (α-PECAM-1-Cy3) in the aortic tissue section. This revealed a colocalization of the CCL21 and the vascular wall of the vasa vasorum (Figure 2(a)).
In every single healthy aortic tissue slide (), we could detect higher CCL21 expression via an increased fluorescence signal signal from the binding fluorescent antibody than in the plaque tissue (). An example is shown (; in Figure 2(b)).
3.1.4. Immunofluorescence Analysis of CCR-7/CD4 and CCR-7/CD83 Coexpression in Human Plaque and Aortic Tissue
To further investigate differences of the CCR7 level on T-lymphocytes (CD4 positive) and mature DC (CD83 positive) in human tissue, immunofluorescence analysis was used. By double staining, we could detect a decreased signal of CCR7 on CD4-positive cells within the plaque tissue (Figure 2(c); lower panel) compared with control aortic tissue (Figure 2(c); upper panel). Also, CD83-expressing cells within the plaque show a decreased CCR7 signal (Figure 2(d); lower panel) compared to the aortic tissue which correlates with the PCR results.
3.1.5. Circulating oxLDL and CCL21 Concentrations
For oxLDL, we found a 52.1% () higher concentration in the plaque group compared to the control group (Table 1). oxLDL serum concentrations showed no correlation with CCL21/CCL19 or CCR7 expressions in plaques (Table 1).
For CCL21, we found a 28% () higher serum concentration in the CEA group compared to the controls (Table 1).
3.2. In Vitro Cell Experiments
3.2.1. CCR7 and CCL21/CCL19 Expression in DCs and HMECs-1
After stimulation with oxLDL, we found a reduction of the mRNA levels of CCR7 (DCs) by 30% using RT-PCR (; ). This correlated with a reduction in protein expression by 46% (; % versus control % positive cells; ; Figure 3). In contrast, protein expression of CD83 was significantly upregulated by 10 μg/mL oxLDL, as shown in Figure 3 (60%, versus control % positive cells; ; Figure 2) by 10 μg/mL oxLDL (Figure 3).
For HMECs-1, stimulation with oxLDL led to a significant reduction of CCL21 mRNA expression (50%; ΔΔct = 0.5; , Figure 4(a)). These results correspond with the results of the immunofluorescence analysis, where we found a 24% down-regulation of CCL21 receptor expression (; 34.00 ± 8.53 versus control 44.54 ± 6.23 intensity/mm2; ; Figures 4(b) and 4(c). oxLDL had no significant impact on protein or mRNA expression of CCL19 (Figure 4(a)).
The main findings obtained from our study are (1) The DC-chemokine receptor CCR7 and its ligands CCL21/CCL19 are significantly downregulated in atherosclerotic plaques; (2) Circulating CCL21 levels are upregulated in serum from atherosclerotic patients; (3) oxLDL impairs CCR7 expression in DCs and CCL21 expression in microvascular ECs.
Our data support the concept that modulation of chemokine receptors (mediated, e.g., by oxLDL) in the plaque may trigger retention of DCs, thereby impeding the vascular innate and adaptive immunity [29, 30]. Accordingly, Angeli et al. found that oxLDL and other lipid mediators are jointly responsible for trapping of DCs in the vascular wall . In our in vivo study, oxLDL serum concentrations showed no correlation with CCL21/CCL19 or CCR7 expression in plaques. However, CCR7 and CCL21/CCL19 were downregulated in atherosclerotic plaques compared to nonatherosclerotic aortic tissue. This discrepancy may be explained by the fact that oxLDL is unstable in serum but accumulates in the subintimal space over time. Hereby, it reaches much 70 fold higher subintimal concentrations as compared to serum levels . This fact especially appeases to monocytes rich plaques .
We found CCR7 expression to be downregulated after 24 hours of stimulation with oxLDL. Alongside, CCL21 was downregulated on HMECs-1 after incubation with oxLDL, in a concentration which predominates in atherosclerotic plaques. Trogan et al. previously demonstrated that phases of hyperlipidemia severely reduce CCR7 mRNA and the corresponding protein levels in an ApoE−/−-mice model. CCR7 increased in the presence of normolipidemia. In their work, CCR7 expression was found to be essential for the migration of DCs from atherosclerotic plaque. In atherosclerotic plaques of ApoE−/−-mice, CCR7 receptor expression was reduced. When transferred to wild-type mice, this process was accompanied by an upregulation of CCR7 itself .
Under a high-dose statin therapy, Damas et al. found a significant decrease in CCL19 and CCL21 levels in serum . Our data support this observation, showing reduced CCL21 serum protein expression in the control group, characterized by low oxLDL levels. The difference in controls was evident despite a low-dose statin therapy.
Our results suggest that DC maturation is triggered by increased oxLDL deposits in the subintimal space. At the same time DCs, and even T-cells do not seem to express enough CCR7 receptors in order to migrate. As a consequence, oxLDL, DCs and T-cells appear to accumulate, thereby enhancing plaque inflammation processes and possibly plaque rupture.
These results complement the former findings that oxLDL increased the adhesion and promotes the maturation and differentiation of DCs from monocytes [9, 26]. Furthermore, oxLDL supports the building of foam-cell accumulations and also directly induces chemotaxis of immune cells like T-cells via upregulation of endothelial adhesion molecules . Keeping in mind that DCs are responsible for priming naive T-cells to oxLDL-specific T-cells [9, 33], the interaction of oxLDL and DCs must be taken into account as a key factor for the induction and progression of atherosclerosis.
oxLDL not only seems to have an influence on the expression of CCR7, but also to induce downregulation of CCL21 on ECs in vitro as well as decreased expression of CCL21 and CCL19 in the plaque. Comparing CCL19 with CCL21, the latter appears to be affected more directly by local plaque homing factors. In plaque versus normal aortic tissue, we found a much higher response to CCL21 on ECs as opposed to CCL19. Typically, the expression of CCL21 on ECs is higher than CCL19 , since CCL21 has a C-terminus indicating a strong affinity to glycosaminoglycan. This is crucial for effective presentation of CCL21 on ECs [11, 34].
In contrast to our study, other investigators demonstrated an upregulation of CCL21/CCL19 in carotid plaques . In previous studies, 2–4 coronary or renal vessels from autopsy material were taken as controls. To overcome these limitations, we used 14 age-matched healthy aortic tissue samples taken from valve operations serving as controls, which were immediately frozen after their operative preparation, similar to the procedures of carotid tissue preparation. Autolysis and coincidence caused by the small number of controls were therefore ruled out in our experimental setting. A further aspect which points against the renal vessels as controls is the fact, that the vascular-associated lymphoid tissue (including DC and T-cells) has been characterized in human large arteries, including the aorta, carotid, and coronary arteries [35, 36] but not in renal vessels.
In summary, our results suggest that alterations in the vascular chemokine profile may be responsible for accumulation of mature DCs in plaque, which potentially enhance the risk for plaque rupture. It may be argued that inhibiting DC migration leads to a less robust immune response. Indeed, altered priming can be expected in the presence of impaired DC migration. However, if migration is blocked and maturation enabled, the consequence of trapping mature DCs in the direct atherogenic vicinity may induce plaque formation and progression or even rupture. Suppression of DC migration and maturation may, therefore, prove a promising future therapeutic target to prevent plaque instability and rupture.
The authors have no conflicts of interest to disclose. This work was supported in part by the Heinrich and Lotte Muehlfenzl Foundation, which provide educational grants for young scientists.
- R. Ross, “Atherosclerosis: an inflammatory disease,” New England Journal of Medicine, vol. 340, no. 2, pp. 115–126, 1999.
- J. K. Damas, C. Smith, E. Oie, et al., “Enhanced expression of the homeostatic chemokines CCL19 and CCL21 in clinical and experimental atherosclerosis: possible pathogenic role in plaque destabilization,” Arteriosclerosis, Thrombosis, and Vascular Biology, vol. 27, no. 3, pp. 614–620, 2007.
- G. Wick, H. Perschinka, and Q. Xu, “Autoimmunity and atherosclerosis,” American Heart Journal, vol. 138, no. 5, pp. 444–449, 1999.
- G. Wick, M. Romen, A. Amberger, B. Metzler, M. Mayr, G. Falkensammer, et al., “Atherosclerosis, autoimmunity, and vascular-associated lymphoid tissue,” The FASEB Journal, vol. 11, no. 13, pp. 1199–1207, 1997.
- Y. V. Bobryshev, “Dendritic cells in atherosclerosis: current status of the problem and clinical relevance,” European Heart Journal, vol. 26, no. 17, pp. 1700–1704, 2005.
- J. Banchereau, F. Briere, C. Caux, J. Davoust, S. Lebecque, Y. J. Liu, et al., “Immunobiology of dendritic cells,” Annual Review of Immunology, vol. 18, pp. 767–811, 2000.
- C. Erbel, K. Sato, F. B. Meyer, S. L. Kopecky, R. L. Frye, J. J. Goronzy, et al., “Functional profile of activated dendritic cells in unstable atherosclerotic plaque,” Basic Research in Cardiology, vol. 102, no. 2, pp. 123–132, 2007.
- M. Breloer, B. Kretschmer, K. Luthje, S. Ehrlich, U. Ritter, T. Bickert, et al., “CD83 is a regulator of murine B cell function in vivo,” European Journal of Immunology, vol. 37, no. 3, pp. 634–648, 2007.
- T. Nickel, D. Schmauss, H. Hanssen, Z. Sicic, B. Krebs, S. Jankl, et al., “OxLDL uptake by dendritic cells induces upregulation of scavenger-receptors, maturation and differentiation,” Atherosclerosis, vol. 205, no. 2, pp. 442–450, 2009.
- I. Van Brussel, E. A. Van Vre, G. R. De Meyer, C. J. Vrints, J. M. Bosmans, and H. Bult, “Decreased numbers of peripheral blood dendritic cells in patients with coronary artery disease are associated with diminished plasma Flt3 ligand levels and impaired plasmacytoid dendritic cell function,” Clinical Science, vol. 120, pp. 415–426, 2011.
- R. Forster, A. C. Davalos-Misslitz, and A. Rot, “CCR7 and its ligands: balancing immunity and tolerance,” Nature Reviews Immunology, vol. 8, no. 5, pp. 362–371, 2008.
- S. K. Bromley, S. Y. Thomas, and A. D. Luster, “Chemokine receptor CCR7 guides T cell exit from peripheral tissues and entry into afferent lymphatics,” Nature Immunology, vol. 6, no. 9, pp. 895–901, 2005.
- Y. V. Bobryshev, “Dendritic cells and their role in atherogenesis,” Laboratory Investigation, vol. 90, pp. 970–984, 2010.
- D. R. Greaves and T. J. Schall, “Chemokines and myeloid cell recruitment,” Microbes and Infection, vol. 2, no. 3, pp. 331–336, 2000.
- R. H. Boger, S. M. Bode-Boger, S. Kienke, A. C. Stan, R. Nafe, J. C. Frolich, et al., “Dietary l-arginine decreases myointimal cell proliferation and vascular monocyte accumulation in cholesterol-fed rabbits,” Atherosclerosis, vol. 136, no. 1, pp. 67–77, 1998.
- T. Nickel, H. Hanssen, I. Emslander, V. Drexel, G. Hertel, A. Schmidt-Trucksass, et al., “Immunomodulatory effects of aerobic training in obesity,” Mediators of Inflammation, vol. 2011, Article ID 308965, 10 pages, 2011.
- T. Nickel, H. Hanssen, Z. Sisic, S. Pfeiler, C. Summo, D. Schmauss, et al., “Immunoregulatory effects of the flavonol quercetin in vitro and in vivo,” European Journal of Nutrition, vol. 50, no. 3, pp. 163–172, 2010.
- A. Boyum, “Isolation of human blood monocytes with nycodenz, a new non-ionic iodinated gradient medium,” Scandinavian Journal of Immunology, vol. 17, no. 5, pp. 429–436, 1983.
- N. Romani, G. Ratzinger, K. Pfaller, W. Salvenmoser, H. Stossel, F. Koch, et al., “Migration of dendritic cells into lymphatics-the langerhans cell example: routes, regulation, and relevance,” International Review of Cytology, vol. 207, pp. 237–270, 2001.
- T. Nickel, A. Deutschmann, H. Hanssen, C. Summo, U. Wilbert-Lampen, et al., “Modification of endothelial biology by acute and chronic stress hormones,” Microvascular Research, vol. 78, no. 3, pp. 364–369, 2009.
- M. D. Gunn, K. Tangemann, C. Tam, J. G. Cyster, S. D. Rosen, L. T. Williams, et al., “A chemokine expressed in lymphoid high endothelial venules promotes the adhesion and chemotaxis of naive t lymphocytes,” National Academy of Sciences of the United States of America, vol. 95, no. 1, pp. 258–263, 1998.
- S. R. McColl, “Chemokines and dendritic cells: a crucial alliance,” Immunology and Cell Biology, vol. 80, no. 5, pp. 489–496, 2002.
- A. Surdacki, M. Nowicki, J. Sandmann, D. Tsikas, R. H. Boeger, S. M. Bode-Boeger, et al., “Reduced urinary excretion of nitric oxide metabolites and increased plasma levels of asymmetric dimethylarginine in men with essential hypertension,” Journal of Cardiovascular Pharmacology, vol. 33, no. 4, pp. 652–658, 1999.
- S. R. Meisel, X. P. Xu, T. S. Edgington, et al., “Dose-dependent modulation of tissue factor protein and procoagulant activity in human monocyte-derived macrophages by oxidized low density lipoprotein,” Journal of Atherosclerosis and Thrombosis, vol. 18, no. 7, pp. 596–603, 2011.
- R. Zaguri, I. Verbovetski, M. Atallah, et al., “Danger effect of low-density lipoprotein (LDL) and oxidized LDL on human immature dendritic cells,” Clinical and Experimental Immunology, vol. 149, no. 3, pp. 543–552, 2007.
- M. Weis, C. L. Schlichting, E. G. Engleman, and J. P. Cooke, “Endothelial determinants of dendritic cell adhesion and migration: new implications for vascular diseases,” Arteriosclerosis, Thrombosis, and Vascular Biology, vol. 22, no. 11, pp. 1817–1823, 2002.
- A. Yilmaz, B. Lipfert, I. Cicha, K. Schubert, M. Klein, D. Raithel, et al., “Accumulation of immune cells and high expression of chemokines/chemokine receptors in the upstream shoulder of atherosclerotic carotid plaques,” Experimental and Molecular Pathology, vol. 82, no. 3, pp. 245–255, 2007.
- A. Yilmaz, M. Lochno, F. Traeg, I. Cicha, C. Reiss, C. Stumpf, et al., “Emergence of dendritic cells in rupture-prone regions of vulnerable carotid plaques,” Atherosclerosis, vol. 176, no. 1, pp. 101–110, 2004.
- J. Llodra, V. Angeli, J. Liu, E. Trogan, E. A. Fisher, and G. J. Randolph, “Emigration of monocyte-derived cells from atherosclerotic lesions characterizes regressive, but not progressive, plaques,” National Academy of Sciences of the United States of America, vol. 101, no. 32, pp. 11779–11784, 2004.
- G. J. Randolph, V. Angeli, and M. A. Swartz, “Dendritic-cell trafficking to lymph nodes through lymphatic vessels,” Nature Reviews Immunology, vol. 5, no. 8, pp. 617–628, 2005.
- K. Nishi, H. Itabe, M. Uno, K. T. Kitazato, H. Horiguchi, K. Shinno, et al., “Oxidized LDL in carotid plaques and plasma associates with plaque instability,” Arteriosclerosis, Thrombosis, and Vascular Biology, vol. 22, no. 10, pp. 1649–1654, 2002.
- E. Trogan, J. E. Feig, S. Dogan, G. H. Rothblat, V. Angeli, F. Tacke, et al., “Gene expression changes in foam cells and the role of chemokine receptor CCR7 during atherosclerosis regression in apoe-deficient mice,” National Academy of Sciences of the United States of America, vol. 103, no. 10, pp. 3781–3786, 2006.
- G. K. Hansson, “Inflammation, atherosclerosis, and coronary artery disease,” The New England Journal of Medicine, vol. 352, no. 16, pp. 1685–1695, 2005.
- R. Yoshida, M. Nagira, M. Kitaura, N. Imagawa, T. Imai, and O. Yoshie, “Secondary lymphoid-tissue chemokine is a functional ligand for the CC chemokine receptor CCR7,” Journal of Biological Chemistry, vol. 273, no. 12, pp. 7118–7122, 1998.
- Y. V. Bobryshev and R. S. Lord, “Mapping of vascular dendritic cells in atherosclerotic arteries suggests their involvement in local immune-inflammatory reactions,” Cardiovascular Research, vol. 37, no. 3, pp. 799–810, 1998.
- G. Wick, M. Knoflach, and Q. Xu, “Autoimmune and inflammatory mechanisms in atherosclerosis,” Annual Review of Immunology, vol. 22, pp. 361–403, 2004.