Chemokine | EPFL Graph Search

Chemokines (), or chemotactic cytokines, are a family of small cytokines or signaling proteins secreted by cells that induce directional movement of leukocytes, as well as other cell types, including endothelial and epithelial cells. In addition to playing a major role in the activation of host immune responses, chemokines are important for biological processes, including morphogenesis and wound healing, as well as in the pathogenesis of diseases like cancers. Cytokine proteins are classified as chemokines according to behavior and structural characteristics. In addition to being known for mediating chemotaxis, chemokines are all approximately 8-10 kilodaltons in mass and have four cysteine residues in conserved locations that are key to forming their 3-dimensional shape. These proteins have historically been known under several other names including the SIS family of cytokines, SIG family of cytokines, SCY family of cytokines, Platelet factor-4 superfamily or interc

Evidence of dysregulation of dendritic cells in primary HIV infection

Jacques Fellay, Nan Hu, Marie Larsson

Myeloid and plasmacytoid dendritic cells (DCs) are important mediators of both innate and adaptive immunity against pathogens such as HIV. During the course of HIV infection, blood DC numbers fall substantially. In the present study, we sought to determine how early in HIV infection the reduction occurs and whether the remaining DC subsets maintain functional capacity. We find that both myeloid DC and plasmacytoid DC levels decline very early during acute HIV infection. Despite the initial reduction in numbers, those DCs that remain in circulation retain their function and are able to stimulate allogeneic T-cell responses, and up-regulate maturation markers plus produce cytokines/chemokines in response to stimulation with TLR7/8 agonists. Notably, DCs from HIV-infected subjects produced significantly higher levels of cytokines/chemokines in response to stimulation with TLR7/8 agonists than DCs from uninfected controls. Further examination of gene expression profiles indicated in vivo activation, either directly or indirectly, of DCs during HIV infection. Taken together, our data demonstrate that despite the reduction in circulating DC numbers, those that remain in the blood display hyperfunctionality and implicates a possible role for DCs in promoting chronic immune activation.

2010

Influence of TECK on chondrocyte differentiation

Benjamin David

Nowadays, cartilage repair is a worldwide centre of interest due to the low potential of cartilage to heal spontaneously and the increasing number of patients around the world. One of the techniques to treat cartilage defect is to use autologous human serum in cell-free implants to recruit chondrocytes. However, the serum is variable in its quality and therefore the chemokine TECK might be used as a reliable bioactive pharmaceutical component to recruit chondrocytes in cartilage regeneration techniques. In this study, the influence of the chemokine TECK on chondrocytes re-differentiation was studied during early chondrogenesis. So, high-density pellets were formed from three donors and cultivated for two and four days in three different concentrations of TECK, 0 [nM], 10 [nM] and 1000 [nM]. The high-density pellets were compared and analyzed at the protein and mRNA levels. Indeed, proteoglycans and type II collagen were stained to reveal the production of these two essential markers of chondrogenesis and RT-PCR was performed to evaluate the mRNA expression levels of various genes, type II collagen, type IX collagen, aggrecan, Sox 9, COMP, MMP 13 and Timp 1-2. It resulted that chondrocytes of two out of three donors showed a potential to re-differentatiate. In fact, these two donors increased their productions of proteolycans and type II collagen between day two and day four, a lapse of time considered as early chondrogenesis. These results were confirmed by the mRNA expression levels, which indicated increases of the expression levels in type II collagen, type IX collagen, aggrecan and Sox 9. Thus, the chemokine TECK showed no evidence that it modified the behaviours of chondrocytes in high-density pellets during the first four days. So, TECK might be a reliable bioactive pharmaceutical component to recruit chondrocytes in order to regenerate cartilage in the future

2010

Biophysical Regulation of Lymphatic Vessel Function

Dimana Miteva

Lymphatic capillaries collect interstitial fluid and dendritic cells from the periphery and deliver them to the lymph nodes for immune surveillance and tolerance maintenance. Upon injury and inflammation, lymphatic drainage can increase rapidly, and thus the lymphatic capillaries experience a broad range of fluid stresses and need to respond rapidly to such changes. Our understanding of their functional biology, adaptive ability and response to pathological changes in the biophysical environment is still very limited. This thesis focuses on how the lymphatic capillary endothelium senses and responds to changes of its biophysical environment with respect to its function, including fluid and cell transport, in the context of physiological and pathophysiological conditions. Using in vitro and in vivo models, we demonstrate that lymphatic endothelium is exquisitely sensitive to transmural flow, modulating both fluid and cell transport functions even in the absence of inflammatory cytokines. Flow increased lymphatic permeability and dendritic cell (DC) transmigration, which were coincident with changes in gene and protein expression of factor known to be involved in these, including chemoattractant chemokines, adhesion molecules and junctional proteins. These data provide the first evidence that lymphatic endothelium can regulate its transport functions in response to flow cues. They also show for the first time that transmural flow can, in the absence of inflammatory cues like TNF-a, drive expression of DC adhesion molecules like ICAM-1 and chemokines like CCL21 by lymphatic endothelium. Based on these findings we suggest that lymphatic flow is an important mediator of lymphatic function, particularly with respect to DC recruitment and trafficking to the lymph node. Furthermore, the response of the lymphatic endothelium to flow may be specific to the type of low, as lymphatic endothelial cells (LECs) might react differently to luminal shear flow, at physiological and pathophysiological levels, compared to transmural flow. To address this we used laminar shear stress chambers to expose only the apical surface of the lymphatic endothelial cells (LECs) to shear stress and demonstrated that lymphatic endothelium is indeed sensitive to luminal flow, fine-tuning its expression of adhesion molecules to modulate DC adhesion according to the shear stress. Specifically, at extremely low shear, adhesion was enhanced, unlike at higher shear, adhesion was downregulated. This is consistent with the notion that DC adhesion to LECs is only needed for entry but not transport in conducting vessels, since only the absorbing capillaries have low shear stresses. The interactions between DCs and LECs were strongly mediated by CCL21 and its receptor CCR7. These findings suggest that luminal shear stress acts as an active mechanosignal in LECs to potentially facilitate the traffic of immune cells inside of the lymphatic vessel to reach the lymph node and trigger an immune response. Additionally, we demonstrated that lymphatic vessels respond differentially to immunogenic and tolerogenic inflammatory stimulus. We used in vitro models to evaluate lymphatic uptake and lymphatic participation in dendritic cell transmigration in the presence of various inflammatory stimuli. We found that lymphatic endothelium exposed to TNF-a or complement activation were more conductive to dendritic cell transmigration, while LPS and TGF-β had opposite effect, affecting DCs to decrease DC transmigration. We further presented some insights in similarities in tumor and dendritic cells intravasation into inflamed lymphatic capillaries. These findings imply that lymphatic activation and participation in immune cells transport is not a universal phenomenon, but is strongly dependent on the nature of the inflammation. In conclusion, this work highlights the critical role of biophysical environment in lymphatic endothelial function, and how exquisitely sensitive the lymphatic capillaries are to their extracellular environment and how they use multiple cues to sense inflammation and danger, modulating their transport functions accordingly to regulate the delivery of antigens and immune cells to the lymph nodes.

EPFL2010

Biophysical Regulation of Lymphatic Vessel Function

Dimana Miteva

EPFL2010