Connective Tissue Growth Factor Is Overexpressed in Complicated Atherosclerotic Plaques and Induces Mononuclear Cell Chemotaxis In Vitro
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动脉硬化血栓血管生物学 2005年第5期
From the Medical Clinic II (I.C., A.Y., W.G.D., C.D.G.) and Medical Clinic IV (M.G.-S.), University of Erlangen-Nuremberg, Erlangen, Germany; Department of Vascular Surgery (M.K., D.R.), Clinic Nuremberg, Germany; and Center for Cell and Vascular Biology (D.R.B.), Children’s Research Institute, Columbus, Ohio.
Correspondence to Dr Iwona Cicha, Laboratory of Molecular Cardiology, Medical Clinic II, University of Erlangen-Nuremberg, Schwabachanlage 10, 91054 Erlangen, Germany. E-mail Iwona_Cicha@yahoo.com
Abstract
Objective— Atherosclerotic blood vessels overexpress connective tissue growth factor (CTGF) mRNA, but the role of CTGF in atherosclerosis remains controversial. To assess the hypothesis that CTGF is involved in atherosclerotic plaque progression, we investigated CTGF protein expression and distribution in the different types of plaque morphology.
Methods and Results— Serial cross-sections of 45 human carotid plaques were immunohistochemically analyzed for the presence of CTGF protein, neovascularization (von Willebrand factor), macrophages (CD68), and T cells (CD3). The lesions were categorized according to American Heart Association (AHA) classification as fibrous (type IV and V) or complicated plaques (type VI). The levels of CTGF were significantly higher in complicated compared with fibrous plaques (P=0.002). CTGF accumulated particularly in the rupture-prone plaque shoulder and in the areas of neovascularization or infiltration with inflammatory cells. Macrophage-like cells stained positive for CTGF protein in plaques. Subsequent in vitro studies showed that although monocyte-derived macrophages do not produce CTGF on stimulation with transforming growth factor-?, lipopolysaccharide, or thrombin, they take it up from culture medium. Furthermore, CTGF induces mononuclear cell chemotaxis in a dose-dependent manner.
Conclusion— CTGF protein is significantly increased in complicated compared with fibrous plaques and may enhance monocyte migration into atherosclerotic lesions, thus contributing to atherogenesis.
CTGF protein expression in carotid plaque development was investigated. CTGF levels were significantly increased in vulnerable complicated lesions compared with stable fibrous plaques. CTGF was also shown to act as chemoattractant for human mononuclear cells in vitro, suggesting its importance in atherosclerosis.
Key Words: connective tissue growth factor ? atherosclerosis ? plaque development ? chemotaxis
Introduction
Atherosclerosis is a chronic multifactorial disease characterized by the accumulation of lipids, fibrous tissue, and inflammatory cells in the large arteries. Whereas the earliest type of lesion consists mainly of lipid-laden foam cells and some T cells, the feature of advanced lesions is the accumulation of lipid-rich necrotic debris, encapsulated by a fibrous cap consisting of extracellular matrix produced by smooth muscle cells (SMCs). In the process of plaque development, complex cellular interactions between cells of the vessel wall and the immune system result in thinning of the fibrous cap, growing lipid core, increased inflammatory activity, and neovascularization. These processes lead to plaque instability and may result in plaque rupture, which is a common pathogenetic feature in a majority of acute manifestations of atherosclerosis, such as acute coronary syndrome and stroke.1
Connective tissue growth factor (CTGF), a potent angiogenic, chemotactic, and extracellular matrix–inducing growth factor, is produced by a wide variety of cells, including endothelial cells (ECs), SMCs, and fibroblasts. At low levels, CTGF supports wound healing by connective tissue formation after tissue injury and plays a role in angiogenesis and skeletal development.2 However, overexpression of CTGF gene was implicated in progression of many chronic inflammatory-fibroproliferative disorders, such as glomerulosclerosis, pulmonary fibrosis, and cirrhosis.3
As reported by Oemar et al,4 CTGF mRNA is expressed at very high levels in atherosclerotic but not in normal human blood vessels. CTGF-producing cells in plaques, mainly nonproliferating SMCs and ECs, were detected predominantly along the shoulders of the fibrous cap. However, CTGF protein expression in relation to plaque morphology has not been investigated, and the role of this growth factor in atherosclerosis remains controversial. CTGF may reduce the likelihood of plaque rupture through extracellular matrix–mediated stabilization of the fibrous cap. On the other hand, it may contribute to plaque destabilization by inducing SMCs to undergo apoptosis.5 It was also shown that CTGF acts as an adhesion factor for activated platelets and monocytes via integrins IIb/?3 and M/?2, respectively.6,7 These findings suggest that this protein may be involved in promoting platelet and monocyte adhesion to dysfunctional endothelium, and in the formation of platelet-rich thrombi at ruptured atherosclerotic lesions.
In this study, we investigated the occurrence and distribution of CTGF protein in atherosclerotic plaques and correlated it with different types of plaque morphology. Moreover, we associated the CTGF levels with known risk factors for atherosclerosis and with patients’ medication. We report here a significant increase in the mean number of CTGF-expressing cells in complicated (type VI) compared with fibrous (type IV and V) plaques. Furthermore, CTGF is shown to induce chemotaxis in human mononuclear cells in vitro, suggesting an active role of this protein in atherosclerosis.
Materials and Methods
The Materials and Methods section is available online at http://atvb.ahajournals.org.
Results
CTGF Protein Is Overexpressed in Advanced Atherosclerotic Plaques
According to their morphologies, the plaques were defined as fibrous (AHA type IV and V; n=21) or complicated plaques (type VI; n=24). To confirm the previous report of Oemar,4 the cross-sections of 5 of 45 carotid specimens from regions bordering with morphologically normal vessel were used to mimic initial stages of plaque development. These cross-sections of preatheroma morphology contained very few CTGF-positive cells in immunohistochemical analysis (24.2±5.1 versus 76.9±5.9 in plaques [type VI-VI]; P<0.01). In accordance with the study by Oemar,4 this finding was subsequently confirmed using in situ hybridization method, which detected increased CTGF mRNA expression mainly in SMCs and luminal ECs of advanced plaques, whereas in cross-sections of preatheroma morphology, CTGF expression was limited to scarce ECs at the lumen (Figure 1A). In advanced plaques, levels of CTGF protein were significantly higher in complicated (type VI) lesions (93.9±8.3; n=24) compared with fibrous plaques (57.5±6; n=21; P=0.002; Figure 1B and 1C).
Figure 1. CTGF expression in different types of atherosclerotic lesions. A, In situ hybridization; x150. B, Immunohistochemical staining; x20. C, Quantitative analysis of differences in CTGF-positive cell numbers in complicated (n=24) vs fibrous plaques (n=21). Graph shows the median, 10th, 25th 75th, and 90th percentiles. The statistical difference between the different plaque types was calculated using Mann–Whitney rank sum test.
The presence of CTGF protein was compared with clinical data and the current medication of the patients (Table). There were no significant correlations between mean CTGF-positive cell numbers and smoking, diabetes mellitus, hyperlipidemia, or hypertension. In plaques of patients with acute cerebral symptoms, there was a trend for increased levels of CTGF protein compared with asymptomatic patients (84.8±8.1, n=27 versus 66.8±8.5, n=18; P=0.13). Treatment with aspirin, angiotensin-converting enzyme (ACE) inhibitors, clopidogrel, or angiotensin II type 1 receptor antagonists had no effect on the CTGF expression in plaques. A reduction in the level of CTGF was observed in plaques from patients treated with statins (56.6±5.4, n=11 versus 85.9±7.7 in untreated patients, n=34; P=0.013). However, the prevalence of fibrous plaque morphology and of concomitant treatment with ACE inhibitors was much higher in this group and might contribute to the decreased CTGF level in these patients.
Patient Characteristics
Distribution of CTGF in Advanced Atherosclerotic Plaques
In the cross-sections of the vessel regions exhibiting preatheroma morphology, CTGF-positive cells localized mainly to lumen endothelium and thickened intima, whereas no CTGF was observed in media or in contralateral intima (data not shown). In advanced plaques, CTGF-positive staining was localized mainly to the plaque shoulders, fibrous cap, and the borders of the lipid core (Figure 2A). The plaque shoulder with the stronger degree of inflammation was defined as plaque shoulder-1, and the other as plaque shoulder-2. As shown in Figure 2B, significant increases in the numbers of CTGF-positive cells were observed between complicated and fibrous plaques in the following regions: fibrous cap (81.8±10.5 versus 43.4±10; P=0.005), plaque shoulder-1 (160.4±16.3 versus 104±13.8; P=0.03), border regions of the lipid core (117.9±16 versus 68.7±8.3; P=0.02). The trend for increased occurrence of CTGF-positive cells was also observed in the contralateral intima and the plaque shoulder-2 of complicated plaques; however, it was not statistically significant (P<0.07). There were no differences between the numbers of CTGF-positive cells in the media of complicated versus fibrous plaques.
Figure 2. Distribution of CTGF in advanced atherosclerotic plaques. A, Immunohistochemical staining: overview (x20); marked area of plaque shoulder shown in magnification (x150). B, Quantitative analysis of CTGF distribution in different regions of advanced plaques. FC indicates fibrous cap; PS1, plaque shoulder with the higher degree of inflammation; PS2, plaque shoulder with the lower degree of inflammation; LC, lipid core border; M, media; CI, contralateral intima. Open bars correspond to fibrous plaques and closed bars to complicated plaques. *P<0.05; **P<0.01 complicated vs fibrous plaques (Mann–Whitney rank sum test).
CTGF Presence Is Associated With Intimal Neovascularization and Inflammation
The numbers of CTGF-positive cells were greatly dependent on the plaque vulnerability, with CTGF-expressing cells localized particularly in the areas of complications (ie, intimal neovascularization [Figure 3A], endothelial erosion, mural thrombi, or the sites of heavy infiltration with inflammatory cells). In particular, average numbers of CTGF-positive cells were significantly higher in plaques undergoing neovascularization (88.4±8.5; n=25) compared with plaques without neovascularization (62.7±6.8; n=20; P=0.03).
Figure 3. Association of CTGF protein with neovascularization and inflammation. A, Neovascularization areas are abundant in CTGF, macrophages, and T cells; x150. For identification of cells, the following antibodies were used: anti–von Willebrand factor (vWF; ECs), anti-CD68 (macrophages), and anti-CD3 (T cells). B, Numbers of CTGF-positive cells correlate with macrophage numbers in plaques (Spearman rank order correlation test). C, Immunostaining of serial sections (2-μm thickness) shows CTGF protein expressed by macrophages and a subpopulation of SMC-like cells (x600). Top, arrows show CD68-positive cells expressing CTGF; arrowheads mark SMC-like cells (CD68-negative) positive for CTGF. Bottom, A subpopulation of SMCs identified by antibody directed against SM actin shows weak positive expression of CTGF (arrowheads).
In all analyzed plaques, macrophage and T-cell infiltration occurred coincidentally and was most pronounced in plaque shoulder-1 and in the areas bordering the lipid core. Macrophages always outnumbered lymphocytes, but both cell types were significantly more abundant in complicated (type VI) than in fibrous plaques (types IV and V). Mean macrophage cell numbers in complicated plaques were 86.3±5.6 versus 59.5±6.4 in fibrous plaques (P=0.005). A similar increase in T-cell number of complicated plaques was observed (21.2±1.6 versus 13.6±1.8; P<0.002). The mean numbers of T cells and macrophages correlated positively with CTGF expression in plaques (r=0.915, P<0.001 for macrophages [Figure 3B]; r=0.737, P<0.001 for T cells [data not shown]).
Immunohistochemical analysis showed that CTGF protein was often expressed by cells of macrophage-like morphology. Because the results of double-immunostaining of the same cell type are often unclear because of the color overlap, we performed the staining on serial 2-μm sections, which allows identification of single cells. The sections were stained either for anti-CD68 as macrophage/foam cell marker or for anti-SM actin as SMC marker. CTGF-positive cells were detected on the parallel sections. The results of the staining (Figure 3C, top) clearly demonstrate that the majority of CD68-positive cells are also positive for CTGF. On the other hand, a subpopulation of CD68-negative cells of SMC-like morphology from the same area also showed strong CTGF expression. These results were confirmed by staining with SMC marker, which showed that some but not all SMCs express CTGF (Figure 3C, bottom).
CTGF Is Taken Up by Macrophages In Vitro and Acts As Chemoattractant for Peripheral Blood Mononuclear Cells
Immunohistochemical analysis showed that the presence of CTGF protein in plaques was often associated with macrophages/foam cells (Figure 3C). However, macrophages did not express CTGF mRNA in Northern blot analysis4 or in situ hybridization4,12 (data not shown). Therefore, we investigated whether stimulated macrophages can produce CTGF in vitro. For this purpose, monocyte-derived macrophages were incubated with transforming growth factor-? (TGF-?) or thrombin, both known to induce CTGF in other cell types,13,14 or with lipopolysaccharide (LPS). The stimulation of macrophages with TGF-?, thrombin, or LPS had no inducing effect on CTGF expression (Figure 4A). However, macrophages cultured with medium containing CTGF could take up CTGF from the medium, as demonstrated by Western blotting (Figure 4B). After 2 hours of culture, Myc-tagged CTGF was observed in washed cell pellets, whereas in the negative control samples without added recombinant CTGF, no CTGF bands were detectable either in cell pellets or in culture media. Detected CTGF was clearly not a result of platelet contamination because its molecular weight corresponded to the size of the recombinant CTGF containing a tag (42 versus 38 kDa of endogenous CTGF). The exogenous origin of CTGF was further confirmed by Western blot analysis using anti-Myc tag antibody (Figure 4B, right).
Figure 4. CTGF interaction with monocytes/macrophages. A, Macrophages do not produce CTGF on stimulation with TGF-? (5 ng/mL; 24 hours), thrombin (5 U/mL; 24 hours [T24] or 6 hours [T6]), or LPS (0.1 μg/mL; 24 hours). Autologous CTGF released from platelet was used as a positive control (P); c indicates unstimulated cells. B, Western blot analysis of macrophages cultured in the presence or absence of CTGF (0.4 μg/mL) shows CTGF uptake from culture medium. Recombinant-purified CTGF at 0.4 μg/mL was used as a positive control (c); ? indicates macrophages; m, culture medium. Results are representative of 3 independent experiments. C, CTGF induces a dose-dependent chemotactic response in PBMCs. Values from control wells (no chemoattractant in the lower chamber) were set as a baseline. Monocyte chemoattractant protein-1 (MCP-1; 50 ng/mL; positive control) or CTGF at 10 to 100 ng/mL was placed in the lower chamber, and the cells were allowed to migrate for 1 hour at 37°C. Results are expressed as mean±SEM; number of experiments given in brackets. To compare the data from different groups, 1-way ANOVA was used; **P<0.001; *P<0.05 vs control wells; P<0.01 vs 100 ng/mL CTGF. D, CTGF-induced chemotaxis is inhibited by heparin. CTGF-induced chemotaxis values (CTGF; 100 ng/mL) were set as 100%. CTGF+heparin, 100 ng/mL CTGF+10 μg/mL heparin were added to lower wells; PBMCs+heparin, cells were preincubated with 10 μg/mL heparin for 20 minutes at 25°C and allowed to migrate toward 100 ng/mL CTGF. Results are expressed as mean±SEM of 3 independent experiments. Paired t test was used to compare the data between groups; *P=0.002.
To prove the physiological relevance of CTGF–monocyte/macrophage interactions we performed a chemotaxis assay. As shown in Figure 4C, CTGF (10 to 100 ng/mL) induced peripheral blood mononuclear cell (PBMC) migration in a dose-dependent manner. The mean number of migrated cells in the control wells without chemoattractant (56.1x103 cells) was set as a baseline. There was a statistically significant increase in the number of migrated nonadherent cells already at 10 ng/mL of CTGF (n=3; P<0.05 versus control wells). At 100 ng/mL CTGF, a >3-fold increase in migrated cell numbers was observed (n=5; P<0.001 versus control). To prove that the observed induction of PBMCs migration is CTGF specific, we performed further experiments adding to the lower wells heparin, which is known to bind CTGF.7 Because the highest chemoattractant activity was observed at 100 ng/mL of CTGF, this concentration was used in the subsequent assays. In the presence of heparin (10 μg/mL), the chemotactic response to CTGF was reduced by 41% (n=3; P=0.002 versus CTGF alone; Figure 4D). Furthermore, the preincubation of PBMCs with heparin (10 μg/mL; 20 minutes at 25°C) suppressed CTGF-induced chemotaxis by 47% (n=3; P=0.002 versus untreated cells; Figure 4D), implying that cell surface heparan sulfate proteoglycans are required for CTGF-mediated PBMC migration.
Discussion
The present study reports increased CTGF expression in complicated versus fibrous plaques, as well as colocalization of CTGF protein with inflammatory infiltrates and intimal neovascularization in advanced atherosclerotic lesions. Additionally, our study demonstrated the strong chemotactic effect of CTGF on PBMCs in vitro. These findings support the hypothesis that CTGF may play an active role in atherosclerosis by promoting monocyte migration into lesions and inducing intimal angiogenesis.
Chronic inflammatory responses in atherosclerosis lead to increased leukocyte accumulation and production of metalloproteinases, often resulting in degradation of the fibrous cap and plaque rupture. Clinically, in most patients, fatal coronary/cerebral events occur as a result of erosion or more often through uneven thinning and rupture of the fibrous cap.1 On the basis of post mortem analyses of culprit plaques, the following criteria for defining vulnerable plaques were listed: large lipid core, thin fibrous cap, remodeling, active plaque inflammation, and superficial platelet aggregation.15 Angiogenesis and superficial calcified nodules were also included as markers of vulnerability. The presence of 1 or a combination of these factors in the lesion may warrant higher risk of plaque complications. In light of these data, the finding that CTGF protein is overexpressed in complicated plaques and correlates positively with the numbers of inflammatory cells within the plaque may underscore the pathophysiologic importance of this growth factor in the progression of atherosclerosis. CTGF gene expression in ECs and SMCs is strongly upregulated by various cytokines (TGF-?, platelet-derived growth factor, and basic fibroblast growth factor16), it was also reported to be induced in ECs by hypoxia,17 lipid mediators,18 and nonuniform shear stress.19 In the inflammatory fibroproliferative conditions of atherosclerosis, all these factors may act in concert to enhance CTGF protein production by ECs and SMCs. Furthermore, in advanced atherosclerotic lesions, the levels of cAMP, which interfere with CTGF expression in fibroblasts13,20 and SMCs,21 are markedly decreased.22 The reduced CTGF-suppressive activity in plaque may thus contribute to CTGF overexpression.
CTGF protein in advanced plaques was observed particularly in the rupture-prone shoulder of the plaque, at the borders of the lipid core, and in areas of complications (ie, endothelial erosion and neovascularization). Intimal neovascularization is thought to relate to intraplaque hemorrhage, plaque rupture, and subsequent intravascular thrombosis.23 Newly formed blood vessels are often associated with chronic inflammatory infiltrates and the formation of granulation-like tissue. In this context, various cytokines were shown to induce ECs transformation into angiogenic phenotype, the most potent of them being vascular endothelial growth factor (VEGF), which is also overexpressed in advanced atherosclerotic lesions.24 Because the mechanisms of intimal angiogenesis are poorly understood, the possible interactions between CTGF and VEGF in the plaques remain unknown. However, the presence of increased numbers of CTGF-positive cells in neovascularization areas agrees with its proposed angiogenic activity. Apart from CTGF, cystein-rich 61 (CYR61), another member of CCN protein family (CYR61, CTGF, and nephroblastoma overexpressed [NOV] is overexpressed in human and mouse atherosclerotic lesions and colocalizes with angiotensin II in neovascularization areas.25 It is not known whether CTGF in atherosclerotic lesions is also upregulated by angiotensin II; however, recent evidence showed it is angiotensin II inducible in myocardium, renal artery,26 and aorta27 of hypertensive rats. CTGF and CYR61 can promote EC growth, migration, and proliferation,16 and production of metalloproteinases.17 Thus, the possible upregulation of CTGF by angiotensin II or by hypoxia in the deeper layers of atherosclerotic intima may act as additional angiogenic stimulus.
In agreement with previous studies by Oemar,4 we detected CTGF mRNA expression in SMCs and ECs of advanced lesions but not in plaque macrophages. Also, the Northern blot analyses of circulating and alveolar macrophages4 and RT-PCR of peripheral blood monocytes (M. Goppelt-Struebe, unpublished data, 2002) failed to detect the CTGF transcripts in these cells. In contrast, histochemical results of this and previous studies reported the presence of CTGF protein in macrophages of atherosclerotic plaque, developing granulation tissue during wound healing12 and human bone marrow (I. Cicha, unpublished data, 2003). Thus, we investigated whether the stimulation of monocyte-derived macrophages in vitro may induce CTGF production. TGF-?, thrombin, and LPS failed to induce CTGF synthesis by macrophages, pointing to endocytosis as a possible mechanism of CTGF uptake. As we reported previously,11 megakaryocytic endocytosis of CTGF from the extracellular fluid in the bone marrow is a likely mechanism of uptake of this protein into platelet -granules. In the present study, macrophages cultured in presence of CTGF were able to take up CTGF from the culture medium, as demonstrated by Western blot analysis. Wahab et al28 demonstrated that CTGF is internalized from the mesangial cell surface in endosomes; however, it is unclear whether macrophages take up CTGF by phagocytosis or via a specific receptor. Activated human monocytes were shown previously to adhere to CTGF via integrin M/?2,7 but it remains to be investigated whether CTGF is also internalized as a ligand of this integrin. Also, the functional meaning of CTGF uptake is unknown so far. Importantly, integrin outside-in signaling in monocytes/macrophages often involves upregulation of proinflammatory cytokines such as interleukin-1?.7 CTGF was shown to upregulate matrix metalloproteinase expression in ECs.17 It is thus possible that it can induce similar response in macrophages. Further detailed studies will be necessary to characterize the functional interactions between monocytes and CTGF and specific intracellular signal transduction pathways in these cells in response to CTGF.
In our study, we demonstrated that CTGF induces a dose-dependent chemotactic response in PBMCs. This effect may be physiologically relevant in chronic conditions of atherosclerosis. Platelet adhesion and mural aggregates of platelets are ubiquitous in the initiation and generation of atherosclerotic lesions.1 Platelets precede monocytes in adhesion to dysfunctional endothelium and, on activation, release their granules, which contain cytokines and growth factors, among them CTGF.11 CTGF acting in concert with other chemoattractants may thus lead to the enhanced adhesion and migration of monocytes across the endothelium. In this study, CTGF-dependent chemotaxis was inhibited by pretreatment of cells with heparin, pointing to the involvement of heparan sulfate proteoglycans in the mononuclear cell response to CTGF. These data should stimulate further studies to identify other receptor(s) and signaling pathways responsible for CTGF-mediated monocyte migration.
In conclusion, this study demonstrated that CTGF protein is increased in complicated versus fibrous atherosclerotic plaques. Furthermore, the in vitro results show that by stimulation of chemotaxis, CTGF could contribute to mononuclear cell recruitment in the artery wall. Further research will be required to elucidate the contribution of CTGF to plaque development and to investigate the mechanisms of CTGF–monocyte interactions in atherosclerosis.
Acknowledgments
This work was supported by Deutsche Forschungsgemeinschaft grant GRK 750. We thank Dr Oliver Pullig and Herbert Rohrmueller for help with in situ hybridization, and Dr Juliane Heusinger-Ribeiro for kindly providing CTGF. Technical assistance of Katja Schubert is gratefully acknowledged.
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Correspondence to Dr Iwona Cicha, Laboratory of Molecular Cardiology, Medical Clinic II, University of Erlangen-Nuremberg, Schwabachanlage 10, 91054 Erlangen, Germany. E-mail Iwona_Cicha@yahoo.com
Abstract
Objective— Atherosclerotic blood vessels overexpress connective tissue growth factor (CTGF) mRNA, but the role of CTGF in atherosclerosis remains controversial. To assess the hypothesis that CTGF is involved in atherosclerotic plaque progression, we investigated CTGF protein expression and distribution in the different types of plaque morphology.
Methods and Results— Serial cross-sections of 45 human carotid plaques were immunohistochemically analyzed for the presence of CTGF protein, neovascularization (von Willebrand factor), macrophages (CD68), and T cells (CD3). The lesions were categorized according to American Heart Association (AHA) classification as fibrous (type IV and V) or complicated plaques (type VI). The levels of CTGF were significantly higher in complicated compared with fibrous plaques (P=0.002). CTGF accumulated particularly in the rupture-prone plaque shoulder and in the areas of neovascularization or infiltration with inflammatory cells. Macrophage-like cells stained positive for CTGF protein in plaques. Subsequent in vitro studies showed that although monocyte-derived macrophages do not produce CTGF on stimulation with transforming growth factor-?, lipopolysaccharide, or thrombin, they take it up from culture medium. Furthermore, CTGF induces mononuclear cell chemotaxis in a dose-dependent manner.
Conclusion— CTGF protein is significantly increased in complicated compared with fibrous plaques and may enhance monocyte migration into atherosclerotic lesions, thus contributing to atherogenesis.
CTGF protein expression in carotid plaque development was investigated. CTGF levels were significantly increased in vulnerable complicated lesions compared with stable fibrous plaques. CTGF was also shown to act as chemoattractant for human mononuclear cells in vitro, suggesting its importance in atherosclerosis.
Key Words: connective tissue growth factor ? atherosclerosis ? plaque development ? chemotaxis
Introduction
Atherosclerosis is a chronic multifactorial disease characterized by the accumulation of lipids, fibrous tissue, and inflammatory cells in the large arteries. Whereas the earliest type of lesion consists mainly of lipid-laden foam cells and some T cells, the feature of advanced lesions is the accumulation of lipid-rich necrotic debris, encapsulated by a fibrous cap consisting of extracellular matrix produced by smooth muscle cells (SMCs). In the process of plaque development, complex cellular interactions between cells of the vessel wall and the immune system result in thinning of the fibrous cap, growing lipid core, increased inflammatory activity, and neovascularization. These processes lead to plaque instability and may result in plaque rupture, which is a common pathogenetic feature in a majority of acute manifestations of atherosclerosis, such as acute coronary syndrome and stroke.1
Connective tissue growth factor (CTGF), a potent angiogenic, chemotactic, and extracellular matrix–inducing growth factor, is produced by a wide variety of cells, including endothelial cells (ECs), SMCs, and fibroblasts. At low levels, CTGF supports wound healing by connective tissue formation after tissue injury and plays a role in angiogenesis and skeletal development.2 However, overexpression of CTGF gene was implicated in progression of many chronic inflammatory-fibroproliferative disorders, such as glomerulosclerosis, pulmonary fibrosis, and cirrhosis.3
As reported by Oemar et al,4 CTGF mRNA is expressed at very high levels in atherosclerotic but not in normal human blood vessels. CTGF-producing cells in plaques, mainly nonproliferating SMCs and ECs, were detected predominantly along the shoulders of the fibrous cap. However, CTGF protein expression in relation to plaque morphology has not been investigated, and the role of this growth factor in atherosclerosis remains controversial. CTGF may reduce the likelihood of plaque rupture through extracellular matrix–mediated stabilization of the fibrous cap. On the other hand, it may contribute to plaque destabilization by inducing SMCs to undergo apoptosis.5 It was also shown that CTGF acts as an adhesion factor for activated platelets and monocytes via integrins IIb/?3 and M/?2, respectively.6,7 These findings suggest that this protein may be involved in promoting platelet and monocyte adhesion to dysfunctional endothelium, and in the formation of platelet-rich thrombi at ruptured atherosclerotic lesions.
In this study, we investigated the occurrence and distribution of CTGF protein in atherosclerotic plaques and correlated it with different types of plaque morphology. Moreover, we associated the CTGF levels with known risk factors for atherosclerosis and with patients’ medication. We report here a significant increase in the mean number of CTGF-expressing cells in complicated (type VI) compared with fibrous (type IV and V) plaques. Furthermore, CTGF is shown to induce chemotaxis in human mononuclear cells in vitro, suggesting an active role of this protein in atherosclerosis.
Materials and Methods
The Materials and Methods section is available online at http://atvb.ahajournals.org.
Results
CTGF Protein Is Overexpressed in Advanced Atherosclerotic Plaques
According to their morphologies, the plaques were defined as fibrous (AHA type IV and V; n=21) or complicated plaques (type VI; n=24). To confirm the previous report of Oemar,4 the cross-sections of 5 of 45 carotid specimens from regions bordering with morphologically normal vessel were used to mimic initial stages of plaque development. These cross-sections of preatheroma morphology contained very few CTGF-positive cells in immunohistochemical analysis (24.2±5.1 versus 76.9±5.9 in plaques [type VI-VI]; P<0.01). In accordance with the study by Oemar,4 this finding was subsequently confirmed using in situ hybridization method, which detected increased CTGF mRNA expression mainly in SMCs and luminal ECs of advanced plaques, whereas in cross-sections of preatheroma morphology, CTGF expression was limited to scarce ECs at the lumen (Figure 1A). In advanced plaques, levels of CTGF protein were significantly higher in complicated (type VI) lesions (93.9±8.3; n=24) compared with fibrous plaques (57.5±6; n=21; P=0.002; Figure 1B and 1C).
Figure 1. CTGF expression in different types of atherosclerotic lesions. A, In situ hybridization; x150. B, Immunohistochemical staining; x20. C, Quantitative analysis of differences in CTGF-positive cell numbers in complicated (n=24) vs fibrous plaques (n=21). Graph shows the median, 10th, 25th 75th, and 90th percentiles. The statistical difference between the different plaque types was calculated using Mann–Whitney rank sum test.
The presence of CTGF protein was compared with clinical data and the current medication of the patients (Table). There were no significant correlations between mean CTGF-positive cell numbers and smoking, diabetes mellitus, hyperlipidemia, or hypertension. In plaques of patients with acute cerebral symptoms, there was a trend for increased levels of CTGF protein compared with asymptomatic patients (84.8±8.1, n=27 versus 66.8±8.5, n=18; P=0.13). Treatment with aspirin, angiotensin-converting enzyme (ACE) inhibitors, clopidogrel, or angiotensin II type 1 receptor antagonists had no effect on the CTGF expression in plaques. A reduction in the level of CTGF was observed in plaques from patients treated with statins (56.6±5.4, n=11 versus 85.9±7.7 in untreated patients, n=34; P=0.013). However, the prevalence of fibrous plaque morphology and of concomitant treatment with ACE inhibitors was much higher in this group and might contribute to the decreased CTGF level in these patients.
Patient Characteristics
Distribution of CTGF in Advanced Atherosclerotic Plaques
In the cross-sections of the vessel regions exhibiting preatheroma morphology, CTGF-positive cells localized mainly to lumen endothelium and thickened intima, whereas no CTGF was observed in media or in contralateral intima (data not shown). In advanced plaques, CTGF-positive staining was localized mainly to the plaque shoulders, fibrous cap, and the borders of the lipid core (Figure 2A). The plaque shoulder with the stronger degree of inflammation was defined as plaque shoulder-1, and the other as plaque shoulder-2. As shown in Figure 2B, significant increases in the numbers of CTGF-positive cells were observed between complicated and fibrous plaques in the following regions: fibrous cap (81.8±10.5 versus 43.4±10; P=0.005), plaque shoulder-1 (160.4±16.3 versus 104±13.8; P=0.03), border regions of the lipid core (117.9±16 versus 68.7±8.3; P=0.02). The trend for increased occurrence of CTGF-positive cells was also observed in the contralateral intima and the plaque shoulder-2 of complicated plaques; however, it was not statistically significant (P<0.07). There were no differences between the numbers of CTGF-positive cells in the media of complicated versus fibrous plaques.
Figure 2. Distribution of CTGF in advanced atherosclerotic plaques. A, Immunohistochemical staining: overview (x20); marked area of plaque shoulder shown in magnification (x150). B, Quantitative analysis of CTGF distribution in different regions of advanced plaques. FC indicates fibrous cap; PS1, plaque shoulder with the higher degree of inflammation; PS2, plaque shoulder with the lower degree of inflammation; LC, lipid core border; M, media; CI, contralateral intima. Open bars correspond to fibrous plaques and closed bars to complicated plaques. *P<0.05; **P<0.01 complicated vs fibrous plaques (Mann–Whitney rank sum test).
CTGF Presence Is Associated With Intimal Neovascularization and Inflammation
The numbers of CTGF-positive cells were greatly dependent on the plaque vulnerability, with CTGF-expressing cells localized particularly in the areas of complications (ie, intimal neovascularization [Figure 3A], endothelial erosion, mural thrombi, or the sites of heavy infiltration with inflammatory cells). In particular, average numbers of CTGF-positive cells were significantly higher in plaques undergoing neovascularization (88.4±8.5; n=25) compared with plaques without neovascularization (62.7±6.8; n=20; P=0.03).
Figure 3. Association of CTGF protein with neovascularization and inflammation. A, Neovascularization areas are abundant in CTGF, macrophages, and T cells; x150. For identification of cells, the following antibodies were used: anti–von Willebrand factor (vWF; ECs), anti-CD68 (macrophages), and anti-CD3 (T cells). B, Numbers of CTGF-positive cells correlate with macrophage numbers in plaques (Spearman rank order correlation test). C, Immunostaining of serial sections (2-μm thickness) shows CTGF protein expressed by macrophages and a subpopulation of SMC-like cells (x600). Top, arrows show CD68-positive cells expressing CTGF; arrowheads mark SMC-like cells (CD68-negative) positive for CTGF. Bottom, A subpopulation of SMCs identified by antibody directed against SM actin shows weak positive expression of CTGF (arrowheads).
In all analyzed plaques, macrophage and T-cell infiltration occurred coincidentally and was most pronounced in plaque shoulder-1 and in the areas bordering the lipid core. Macrophages always outnumbered lymphocytes, but both cell types were significantly more abundant in complicated (type VI) than in fibrous plaques (types IV and V). Mean macrophage cell numbers in complicated plaques were 86.3±5.6 versus 59.5±6.4 in fibrous plaques (P=0.005). A similar increase in T-cell number of complicated plaques was observed (21.2±1.6 versus 13.6±1.8; P<0.002). The mean numbers of T cells and macrophages correlated positively with CTGF expression in plaques (r=0.915, P<0.001 for macrophages [Figure 3B]; r=0.737, P<0.001 for T cells [data not shown]).
Immunohistochemical analysis showed that CTGF protein was often expressed by cells of macrophage-like morphology. Because the results of double-immunostaining of the same cell type are often unclear because of the color overlap, we performed the staining on serial 2-μm sections, which allows identification of single cells. The sections were stained either for anti-CD68 as macrophage/foam cell marker or for anti-SM actin as SMC marker. CTGF-positive cells were detected on the parallel sections. The results of the staining (Figure 3C, top) clearly demonstrate that the majority of CD68-positive cells are also positive for CTGF. On the other hand, a subpopulation of CD68-negative cells of SMC-like morphology from the same area also showed strong CTGF expression. These results were confirmed by staining with SMC marker, which showed that some but not all SMCs express CTGF (Figure 3C, bottom).
CTGF Is Taken Up by Macrophages In Vitro and Acts As Chemoattractant for Peripheral Blood Mononuclear Cells
Immunohistochemical analysis showed that the presence of CTGF protein in plaques was often associated with macrophages/foam cells (Figure 3C). However, macrophages did not express CTGF mRNA in Northern blot analysis4 or in situ hybridization4,12 (data not shown). Therefore, we investigated whether stimulated macrophages can produce CTGF in vitro. For this purpose, monocyte-derived macrophages were incubated with transforming growth factor-? (TGF-?) or thrombin, both known to induce CTGF in other cell types,13,14 or with lipopolysaccharide (LPS). The stimulation of macrophages with TGF-?, thrombin, or LPS had no inducing effect on CTGF expression (Figure 4A). However, macrophages cultured with medium containing CTGF could take up CTGF from the medium, as demonstrated by Western blotting (Figure 4B). After 2 hours of culture, Myc-tagged CTGF was observed in washed cell pellets, whereas in the negative control samples without added recombinant CTGF, no CTGF bands were detectable either in cell pellets or in culture media. Detected CTGF was clearly not a result of platelet contamination because its molecular weight corresponded to the size of the recombinant CTGF containing a tag (42 versus 38 kDa of endogenous CTGF). The exogenous origin of CTGF was further confirmed by Western blot analysis using anti-Myc tag antibody (Figure 4B, right).
Figure 4. CTGF interaction with monocytes/macrophages. A, Macrophages do not produce CTGF on stimulation with TGF-? (5 ng/mL; 24 hours), thrombin (5 U/mL; 24 hours [T24] or 6 hours [T6]), or LPS (0.1 μg/mL; 24 hours). Autologous CTGF released from platelet was used as a positive control (P); c indicates unstimulated cells. B, Western blot analysis of macrophages cultured in the presence or absence of CTGF (0.4 μg/mL) shows CTGF uptake from culture medium. Recombinant-purified CTGF at 0.4 μg/mL was used as a positive control (c); ? indicates macrophages; m, culture medium. Results are representative of 3 independent experiments. C, CTGF induces a dose-dependent chemotactic response in PBMCs. Values from control wells (no chemoattractant in the lower chamber) were set as a baseline. Monocyte chemoattractant protein-1 (MCP-1; 50 ng/mL; positive control) or CTGF at 10 to 100 ng/mL was placed in the lower chamber, and the cells were allowed to migrate for 1 hour at 37°C. Results are expressed as mean±SEM; number of experiments given in brackets. To compare the data from different groups, 1-way ANOVA was used; **P<0.001; *P<0.05 vs control wells; P<0.01 vs 100 ng/mL CTGF. D, CTGF-induced chemotaxis is inhibited by heparin. CTGF-induced chemotaxis values (CTGF; 100 ng/mL) were set as 100%. CTGF+heparin, 100 ng/mL CTGF+10 μg/mL heparin were added to lower wells; PBMCs+heparin, cells were preincubated with 10 μg/mL heparin for 20 minutes at 25°C and allowed to migrate toward 100 ng/mL CTGF. Results are expressed as mean±SEM of 3 independent experiments. Paired t test was used to compare the data between groups; *P=0.002.
To prove the physiological relevance of CTGF–monocyte/macrophage interactions we performed a chemotaxis assay. As shown in Figure 4C, CTGF (10 to 100 ng/mL) induced peripheral blood mononuclear cell (PBMC) migration in a dose-dependent manner. The mean number of migrated cells in the control wells without chemoattractant (56.1x103 cells) was set as a baseline. There was a statistically significant increase in the number of migrated nonadherent cells already at 10 ng/mL of CTGF (n=3; P<0.05 versus control wells). At 100 ng/mL CTGF, a >3-fold increase in migrated cell numbers was observed (n=5; P<0.001 versus control). To prove that the observed induction of PBMCs migration is CTGF specific, we performed further experiments adding to the lower wells heparin, which is known to bind CTGF.7 Because the highest chemoattractant activity was observed at 100 ng/mL of CTGF, this concentration was used in the subsequent assays. In the presence of heparin (10 μg/mL), the chemotactic response to CTGF was reduced by 41% (n=3; P=0.002 versus CTGF alone; Figure 4D). Furthermore, the preincubation of PBMCs with heparin (10 μg/mL; 20 minutes at 25°C) suppressed CTGF-induced chemotaxis by 47% (n=3; P=0.002 versus untreated cells; Figure 4D), implying that cell surface heparan sulfate proteoglycans are required for CTGF-mediated PBMC migration.
Discussion
The present study reports increased CTGF expression in complicated versus fibrous plaques, as well as colocalization of CTGF protein with inflammatory infiltrates and intimal neovascularization in advanced atherosclerotic lesions. Additionally, our study demonstrated the strong chemotactic effect of CTGF on PBMCs in vitro. These findings support the hypothesis that CTGF may play an active role in atherosclerosis by promoting monocyte migration into lesions and inducing intimal angiogenesis.
Chronic inflammatory responses in atherosclerosis lead to increased leukocyte accumulation and production of metalloproteinases, often resulting in degradation of the fibrous cap and plaque rupture. Clinically, in most patients, fatal coronary/cerebral events occur as a result of erosion or more often through uneven thinning and rupture of the fibrous cap.1 On the basis of post mortem analyses of culprit plaques, the following criteria for defining vulnerable plaques were listed: large lipid core, thin fibrous cap, remodeling, active plaque inflammation, and superficial platelet aggregation.15 Angiogenesis and superficial calcified nodules were also included as markers of vulnerability. The presence of 1 or a combination of these factors in the lesion may warrant higher risk of plaque complications. In light of these data, the finding that CTGF protein is overexpressed in complicated plaques and correlates positively with the numbers of inflammatory cells within the plaque may underscore the pathophysiologic importance of this growth factor in the progression of atherosclerosis. CTGF gene expression in ECs and SMCs is strongly upregulated by various cytokines (TGF-?, platelet-derived growth factor, and basic fibroblast growth factor16), it was also reported to be induced in ECs by hypoxia,17 lipid mediators,18 and nonuniform shear stress.19 In the inflammatory fibroproliferative conditions of atherosclerosis, all these factors may act in concert to enhance CTGF protein production by ECs and SMCs. Furthermore, in advanced atherosclerotic lesions, the levels of cAMP, which interfere with CTGF expression in fibroblasts13,20 and SMCs,21 are markedly decreased.22 The reduced CTGF-suppressive activity in plaque may thus contribute to CTGF overexpression.
CTGF protein in advanced plaques was observed particularly in the rupture-prone shoulder of the plaque, at the borders of the lipid core, and in areas of complications (ie, endothelial erosion and neovascularization). Intimal neovascularization is thought to relate to intraplaque hemorrhage, plaque rupture, and subsequent intravascular thrombosis.23 Newly formed blood vessels are often associated with chronic inflammatory infiltrates and the formation of granulation-like tissue. In this context, various cytokines were shown to induce ECs transformation into angiogenic phenotype, the most potent of them being vascular endothelial growth factor (VEGF), which is also overexpressed in advanced atherosclerotic lesions.24 Because the mechanisms of intimal angiogenesis are poorly understood, the possible interactions between CTGF and VEGF in the plaques remain unknown. However, the presence of increased numbers of CTGF-positive cells in neovascularization areas agrees with its proposed angiogenic activity. Apart from CTGF, cystein-rich 61 (CYR61), another member of CCN protein family (CYR61, CTGF, and nephroblastoma overexpressed [NOV] is overexpressed in human and mouse atherosclerotic lesions and colocalizes with angiotensin II in neovascularization areas.25 It is not known whether CTGF in atherosclerotic lesions is also upregulated by angiotensin II; however, recent evidence showed it is angiotensin II inducible in myocardium, renal artery,26 and aorta27 of hypertensive rats. CTGF and CYR61 can promote EC growth, migration, and proliferation,16 and production of metalloproteinases.17 Thus, the possible upregulation of CTGF by angiotensin II or by hypoxia in the deeper layers of atherosclerotic intima may act as additional angiogenic stimulus.
In agreement with previous studies by Oemar,4 we detected CTGF mRNA expression in SMCs and ECs of advanced lesions but not in plaque macrophages. Also, the Northern blot analyses of circulating and alveolar macrophages4 and RT-PCR of peripheral blood monocytes (M. Goppelt-Struebe, unpublished data, 2002) failed to detect the CTGF transcripts in these cells. In contrast, histochemical results of this and previous studies reported the presence of CTGF protein in macrophages of atherosclerotic plaque, developing granulation tissue during wound healing12 and human bone marrow (I. Cicha, unpublished data, 2003). Thus, we investigated whether the stimulation of monocyte-derived macrophages in vitro may induce CTGF production. TGF-?, thrombin, and LPS failed to induce CTGF synthesis by macrophages, pointing to endocytosis as a possible mechanism of CTGF uptake. As we reported previously,11 megakaryocytic endocytosis of CTGF from the extracellular fluid in the bone marrow is a likely mechanism of uptake of this protein into platelet -granules. In the present study, macrophages cultured in presence of CTGF were able to take up CTGF from the culture medium, as demonstrated by Western blot analysis. Wahab et al28 demonstrated that CTGF is internalized from the mesangial cell surface in endosomes; however, it is unclear whether macrophages take up CTGF by phagocytosis or via a specific receptor. Activated human monocytes were shown previously to adhere to CTGF via integrin M/?2,7 but it remains to be investigated whether CTGF is also internalized as a ligand of this integrin. Also, the functional meaning of CTGF uptake is unknown so far. Importantly, integrin outside-in signaling in monocytes/macrophages often involves upregulation of proinflammatory cytokines such as interleukin-1?.7 CTGF was shown to upregulate matrix metalloproteinase expression in ECs.17 It is thus possible that it can induce similar response in macrophages. Further detailed studies will be necessary to characterize the functional interactions between monocytes and CTGF and specific intracellular signal transduction pathways in these cells in response to CTGF.
In our study, we demonstrated that CTGF induces a dose-dependent chemotactic response in PBMCs. This effect may be physiologically relevant in chronic conditions of atherosclerosis. Platelet adhesion and mural aggregates of platelets are ubiquitous in the initiation and generation of atherosclerotic lesions.1 Platelets precede monocytes in adhesion to dysfunctional endothelium and, on activation, release their granules, which contain cytokines and growth factors, among them CTGF.11 CTGF acting in concert with other chemoattractants may thus lead to the enhanced adhesion and migration of monocytes across the endothelium. In this study, CTGF-dependent chemotaxis was inhibited by pretreatment of cells with heparin, pointing to the involvement of heparan sulfate proteoglycans in the mononuclear cell response to CTGF. These data should stimulate further studies to identify other receptor(s) and signaling pathways responsible for CTGF-mediated monocyte migration.
In conclusion, this study demonstrated that CTGF protein is increased in complicated versus fibrous atherosclerotic plaques. Furthermore, the in vitro results show that by stimulation of chemotaxis, CTGF could contribute to mononuclear cell recruitment in the artery wall. Further research will be required to elucidate the contribution of CTGF to plaque development and to investigate the mechanisms of CTGF–monocyte interactions in atherosclerosis.
Acknowledgments
This work was supported by Deutsche Forschungsgemeinschaft grant GRK 750. We thank Dr Oliver Pullig and Herbert Rohrmueller for help with in situ hybridization, and Dr Juliane Heusinger-Ribeiro for kindly providing CTGF. Technical assistance of Katja Schubert is gratefully acknowledged.
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