Elena Butoi

Contribution of Platelet CX 3 CR1 to Platelet–Monocyte Complex Formation and Vascular Recruitment During Hyperlipidemia

Objective—The chemokine receptor CX3CR1 is an inflammatory mediator in vascular diseases. On platelets, its ligation with fractalkine (CX3CL1) induces platelet activation followed by leukocyte recruitment to activated endothelium. Here, we evaluated the expression and role of platelet-CX3CR1 during hyperlipidemia and vascular injury. Methods and Results—The existence of CX3CR1 on platelets at mRNA and protein level was analyzed by RT-PCR, quantitative (q)PCR, FACS analysis, and Western blot. Elevated CX3CR1 expression was detected on human platelets after activation and, along with increased binding of CX3CL1, platelet CX3CR1 was also involved in the formation of platelet–monocyte complexes. Interestingly, the expression of CX3CR1 was elevated on platelets from hyperlipidemic mice. Accordingly, CX3CL1-binding and the number of circulating platelet–monocyte complexes were increased. In addition, CX3CR1 supported monocyte arrest on inflamed smooth muscle cells in vitro, whereas CX3CR1-deficient platelets showed decreased adhesion to the denuded vessel wall in vivo. Conclusion—Platelets in hyperlipidemic mice display increased CX3CR1-expression and assemble with circulating monocytes. The formation of platelet–monocyte complexes and the detection of platelet-bound CX3CL1 on inflamed smooth muscle cells suggest a significant involvement of the CX3CL1–CX3CR1 axis in platelet accumulation and monocyte recruitment at sites of arterial injury in atherosclerosis.

Cross talk between smooth muscle cells and monocytes/activated monocytes via CX3CL1/CX3CR1 axis augments expression of pro-atherogenic molecules.

OBJECTIVE In atherosclerotic lesions, fractalkine (CX3CL1) and its receptor (CX3CR1) expressed by smooth muscle cells (SMC) and monocytes/macrophages, mediate the heterotypic anchorage and chemotaxis of these cells. We questioned whether, during the close interaction of monocytes with SMC, the CX3CL1/CX3CR1 pair modulates the expression of pro-atherogenic molecules in these cells. METHODS AND RESULTS SMC were co-cultured with monocytes or LPS-activated monocytes (18h) and then the cells were separated and individually investigated for the gene and protein expression of TNFα, IL-1β, IL-6, CX3CR1 and metalloproteinases (MMP-2, MMP-9). We found that SMC-monocyte interaction induced, in each cell type, an increased mRNA and protein expression of TNFα, IL-1β, IL-6, CX3CR1, MMP-2 and MMP-9. Blocking the binding of fractalkine to CX3CR1 (by pre-incubation of monocytes with anti-CX3CR1 or by CX3CR1 siRNA transfection) before cell co-culture decreased the production of TNFα, CX3CR1 and MMP-9. Monocyte-SMC interaction induced the phosphorylation of p38MAPK and activation of AP-1 transcription factor. Silencing the p65 (NF-kB subunit) inhibited the IL-1β and IL-6 and silencing c-jun inhibited the TNFα, CX3CR1 and MMP-9 induced by SMC-monocyte interaction. CONCLUSIONS The cross-talk between SMC and monocytes augments the inflammatory response in both cell types as revealed by the increased expression of TNFα, IL-1β, IL-6, CX3CR1 and MMPs. Up-regulation of TNFα, CX3CR1 and MMP-9 is further increased upon interaction of SMC with activated monocytes and is dependent on fractalkine/CXRCR1 pair. These data imply that the fractalkine/CX3RCR1 axis may represent a therapeutic target to impede the inflammatory process associated with atherosclerosis.

A novel pro-inflammatory mechanism of action of resistin in human endothelial cells: Up-regulation of SOCS3 expression through STAT3 activation

Resistin is a significant local and systemic regulatory cytokine involved in inflammation. Suppressors of cytokine signaling (SOCS) proteins are intracellular regulators of receptor signal transduction induced by several cytokines in a cytokine and cell specific manner. Resistin up-regulates SOCS3 expression in mice adipocytes but it is not known whether this is a common occurrence in other cells. We questioned whether resistin-induces SOCS3 in human endothelial cells and if signal transducer and activator of transcription (STAT) proteins are involved in the process. The Real-Time PCR and Western blot analysis showed that in resistin-activated HEC the gene and protein expression of SOCS3 were significantly increased. Furthermore, resistin induced activation of STAT3 as characterized by increased tyrosine phosphorylation. Resistin-induced SOCS3 expression was blocked by specific inhibitors of STAT3 signaling and by the transfection of siRNA specific for STAT3. Silencing of SOCS3 gene expression by transfection with SOCS3 siRNA reduced the expression of resistin induced-P-selectin and fractalkine in HEC. Together, our results demonstrate that in HEC (1) resistin up-regulates SOCS3 expression and activates STAT3 transcription factor; (2) the increase in SOCS3 mRNA and protein expression as well as STAT3 activation have a long-lasting effect (up to 18h); (3) inhibition of SOCS3 function prevents resistin-induced expression of cell adhesion molecules P-selectin and fractalkine and thus activation of endothelial cells. The data uncover a new resistin-mediated mechanism in human endothelial cells and designate SOCS3 as a novel therapeutic target to modulate resistin-dependent inflammation in vessel wall diseases.

Curcumin and a Morus alba Extract Reduce Pro‐Inflammatory Effects of Resistin in Human Endothelial Cells

Resistin is a cytokine which plays an important role in cardiovascular disease by influencing systemic inflammation and endothelial activation. In human endothelial cells (HEC) it increases the expression of P‐selectin and fractalkine, and enhances monocyte adhesion by antioxidant mechanisms. This study investigated whether the natural antioxidants curcumin (CC) and an extract of Morus alba leaves (MA) have protective effects in resistin‐activated HEC. HEC were exposed to 100 ng/mL resistin for 6 and 18 h in the absence or presence of MA or CC and the expression of fractalkine and P‐selectin was determined by RT‐PCR and western blot. Intracellular accumulation of reactive oxygen species (ROS) was monitored by fluorimetry and NADPH oxidase activity by a lucigenin‐enhanced chemiluminescence assay. In addition, adhesion assays using the monocytic U937 cells were performed. The results showed that treatment of HEC exposed to resistin with MA and CC: (1) inhibited significantly P‐selectin and fractalkine expression, (2) inhibited the increase in the intracellular ROS level, (3) reduced NADPH activation and (4) reduced monocytes adhesion to HEC. The results indicate that MA and curcumin target resistin‐induced human endothelial activation partly via antioxidant mechanisms and suggest that they may represent therapeutic agents in vascular disease mediated by resistin. Copyright

Subendothelial resistin enhances monocyte transmigration in a co-culture of human endothelial and smooth muscle cells by mechanisms involving fractalkine, MCP-1 and activation of TLR4 and Gi/o proteins signaling

The cytokine resistin and the chemokine fractalkine (FKN) were found at increased levels in human atherosclerotic plaque, in the subendothelium, but their role in this location still needs to be characterized. Recently, high local resistin in the arterial vessel wall was shown to contribute to an enhanced accumulation of macrophages by mechanisms that need to be clarified. Our recent data showed that resistin activated smooth muscle cells (SMC) by up-regulating FKN and MCP-1 expression and monocyte chemotaxis by activating toll-like receptor 4 (TLR4) and Gi/o proteins. Since in the vessel wall both endothelial cells (EC) and SMC respond to cytokines and promote atherosclerosis, we questioned whether subendothelial resistin (sR) has a role in vascular cells cross-talk leading to enhanced monocyte transmigration and we investigated the mechanisms involved. To this purpose we used an in vitro system of co-cultured SMC and EC activated by sR and we analyzed monocyte transmigration. Our results indicated that: (1) sR enhanced monocyte transmigration in EC/SMC system compared to EC cultured alone; (2) sR activated TLR4 and Gi/o signaling in EC/SMC system and induced the secretion of more FKN and MCP-1 compared to EC cultured alone and used both chemokines to specifically recruit monocytes by CX3CR1 and CCR2 receptors. Moreover, FKN produced by resistin in EC/SMC system, by acting on CX3CR1 on EC/SMC specifically contributes to MCP-1 secretion in the system and to the enhanced monocyte transmigration. Our study indicates new possible targets for therapy to reduce resistin-dependent enhanced macrophage infiltration in the atherosclerotic arterial wall.

Cross-talk between macrophages and smooth muscle cells impairs collagen and metalloprotease synthesis and promotes angiogenesis.

Coronary atherosclerosis complicated by plaque disruption and thrombosis is a critical event in myocardial infarction and stroke, the major causes of cardiovascular death. In atherogenesis, macrophages (MAC) and smooth muscle cells (SMC) are key actors; they synthesize matrix components and numerous factors involved in the process. Here, we design experiments to investigate whether SMC-MAC communication induces changes in ECM protein composition and/or neo-angiogenesis. Cell to cell communication was achieved using trans-well chambers, where SMCs were grown in the upper chamber and differentiated MAC in the bottom chamber for 24 or 72h. We found that cross-talk between MAC and SMC during co-culture: (i) significantly decreased the expression of ECM proteins (collagen I, III, elastin) in SMC; (ii) increased the expression and activity of metalloprotease MMP-9 and expression of collagenase MMP-1, in both MAC and SMC; (iii) augmented the secretion of soluble VEGF in the conditioned media of cell co-culture and VEGF gene expression in both cell types, compared with control cells. Moreover, the conditioned media collected from MAC-SMC co-culture promoted endothelial cell tube formation in Matrigel, signifying an increased angiogenic effect. In addition, the MAC-SMC communication led to an increase in inflammatory IL-1β and TLR-2, which could be responsible for cellular signaling. In conclusion, MAC-SMC communication affects factors and molecules that could alter ECM composition and neo-angiogenesis, features that could directly dictate the progression of atheroma towards the vulnerable plaque. Targeting the MAC-SMC cross-talk may represent a novel therapeutic strategy to slow-down or retard the plaque progression.

Monocytes and smooth muscle cells cross-talk activates STAT3 and induces resistin and reactive oxygen species and production

During the early phase of atherosclerosis, monocytes attach to and migrate through the vessel wall where they activate and communicate with smooth muscle cells (SMC) affecting plaque progression by largely unknown mechanisms. Activation of STAT3 transcription factor is suggested to be critically involved in dedifferentiation, migration, and proliferation of SMC in the neointima formation after vascular injury. Monocytes‐SMC cross‐talk induces an inflammatory phenotype of the resident SMC, but the involvement of STAT3 in phenotype switching is not known. Resistin is a cytokine found in human atheroma associated to monocytes/macrophages with role in inflammation associated with cardiovascular disease. The aim of this study was to follow the effect of activated monocytes‐SMC cross‐talk on STAT3 activation and subsequent resistin and reactive oxygen species (ROS) production. Our results showed that the interaction of activated monocytes with SMC determines: (i) phosphorylation of STAT3 and reduction of SOCS3 expression in both cell types; (ii) intracellular ROS production dependent on NADPH oxidase (by increased Nox1 expression) and STAT3 activation in SMC; (iii) up‐regulation of resistin expression in monocytes dependent on STAT3 activation. Furthermore, exposure of SMC to resistin induces ROS by increasing NADPH oxidase activity and the p22phox and Nox1 expression. In conclusion, the cross‐talk between SMC and monocytes activates STAT3 transcription factor and lead to resistin up‐regulation in monocytes and ROS production in SMC. Moreover, resistin increases the ROS levels in SMC. These data indicate that monocyte‐SMC communication may represent an important factor for progression of the atherosclerotic lesion. J. Cell. Biochem. 114: 2273–2283, 2013.

VCAM-1 directed target-sensitive liposomes carrying CCR2 antagonists bind to activated endothelium and reduce adhesion and transmigration of monocytes

Chemokines are critically involved in the development of chronic inflammatory-associated diseases such as atherosclerosis. We hypothesized that targeted delivery of compounds to the surface of activated endothelial cells (EC) interferes with chemokine/receptor interaction and thereby efficiently blocks inflammation. We developed PEGylated target-sensitive liposomes (TSL) encapsulating a CCR2 antagonist (Teijin compound 1) coupled with a specific peptide recognized by endothelial VCAM-1 (Vp-TSL-Tj). TSL were characterized for size (by dynamic light scattering), the amount of peptide coupled at the liposomal surface and Teijin release (by HPLC). We report that Vp-TSL-Tj binds specifically to activated EC in vitro and in situ, release the entrapped Teijin and prevent the transmigration of monocytes through activated EC. This is the first evidence that nanocarriers which transport and release chemokine inhibitors at specific pathological sites can reduce chemokine-dependent inflammatory processes.

Conjugation of curcumin-loaded lipid nanoemulsions with cell-penetrating peptides increases their cellular uptake and enhances the anti-inflammatory effects in endothelial cells.

To prepare and characterize in vitro and in vivo lipid nanoemulsions (LN) loaded with curcumin (Cm) and functionalized with a cell‐penetrating peptide.

Monocytes and smooth muscle cells cross-talk activates STAT3 and induces resistin and reactive oxygen species production [corrected].

During the early phase of atherosclerosis, monocytes attach to and migrate through the vessel wall where they activate and communicate with smooth muscle cells (SMC) affecting plaque progression by largely unknown mechanisms. Activation of STAT3 transcription factor is suggested to be critically involved in dedifferentiation, migration, and proliferation of SMC in the neointima formation after vascular injury. Monocytes‐SMC cross‐talk induces an inflammatory phenotype of the resident SMC, but the involvement of STAT3 in phenotype switching is not known. Resistin is a cytokine found in human atheroma associated to monocytes/macrophages with role in inflammation associated with cardiovascular disease. The aim of this study was to follow the effect of activated monocytes‐SMC cross‐talk on STAT3 activation and subsequent resistin and reactive oxygen species (ROS) production. Our results showed that the interaction of activated monocytes with SMC determines: (i) phosphorylation of STAT3 and reduction of SOCS3 expression in both cell types; (ii) intracellular ROS production dependent on NADPH oxidase (by increased Nox1 expression) and STAT3 activation in SMC; (iii) up‐regulation of resistin expression in monocytes dependent on STAT3 activation. Furthermore, exposure of SMC to resistin induces ROS by increasing NADPH oxidase activity and the p22phox and Nox1 expression. In conclusion, the cross‐talk between SMC and monocytes activates STAT3 transcription factor and lead to resistin up‐regulation in monocytes and ROS production in SMC. Moreover, resistin increases the ROS levels in SMC. These data indicate that monocyte‐SMC communication may represent an important factor for progression of the atherosclerotic lesion. J. Cell. Biochem. 114: 2273–2283, 2013.