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F-actin Cytoskeleton (f-actin + cytoskeleton)

Distribution by Scientific Domains
Medical Sciences75%

Selected Abstracts

PPP1R9B (Neurabin 2): Involvement and dynamics in the NK immunological synapse

EUROPEAN JOURNAL OF IMMUNOLOGY, Issue 2 2009
Xiaobo Meng
Abstract The NK immunological synapse (NKIS) is a dynamic structure dependent on the assembly of membrane, cytoskeletal and signaling components. These serve to focus and generate stimuli for adhesion and orientation of the cytoskeleton for targeted cytolytic granule release. Previous studies have demonstrated the importance of the cytoskeleton in these processes. We previously identified PPP1R9B (neurabin 2, spinophilin) as a cytoskeletal component of the NK-like cell line YTS. We demonstrate that (i) PPP1R9B gradually accumulates at the NKIS in a maturation stage-dependent manner; (ii) it mimics the early kinetics of actin recruitment to the NKIS but it precedes actin departure from the site; (iii) it is recruited by CD18 stimulation but not by CD28 ligation; (iv) it is required for the maintenance of the cortical F-actin organization in the YTS cells and knocking down PPP1R9B reduces the frequency of YTS,target cell conjugation, possibly due to the collapsed F-actin cytoskeleton in these cells. These results indicate that PPP1R9B is required for synapse formation in the NK cells and suggest that it may be involved in the maintenance of cellular architecture by regulation of actin assembly, possibly acting to stabilize the NKIS until granule release is eminent. [source]

Microinjected neutrophils retain the ability to take up bacteria

JOURNAL OF ANATOMY, Issue 5 2002
M. M. Bird
It is now possible to microinject protein to probe specific biochemical pathways and/or cell functions in small cells such as human neutrophils (Bird et al. J.Anat.198, 2001). We have shown that these cells retain their ability to modify their F-actin cytoskeleton following the microinjection procedure. The principal task of neutrophils is to hunt and kill bacteria by responding to chemotactic gradients which cause them to extend actin rich pseudopodia in the direction of the highest concentration of these molecules. On reaching their target the neutrophils make tight contact with the bacteria and phagocytosis ensues. Here we address the question of whether or not the microinjected cells are still able to maintain their normal phagocytic activities. Human neutrophils maintained in culture for 20 mins were confronted with Staphylococcus aureus (1 × 104 cells/mL) for 5 min and then injected with rat IgG as an exogenous protein that also serves as a marker for injected cells. After 30 min the cells were fixed for fluorescence or confocal microscopy in 3.7% formaldehyde and permeabilised for 5 min (0.2% Triton X-100 in PBS). They were then incubated for 45 min in 2.5 µL FITC-anti rat IgG and 1 µL TRITC-phalloidin (to show the F-actin cytoskeleton), in 996.5 µL of PBS, washed 6 times in PBS and mounted on slides in 5 µL Mowiol containing a grain of antiquench. For TEM cells were fixed in 1.5% glutaraldehyde in cacodylate buffer for 3 min at room temperature and then washed in 0.2 m cacodylate buffer 6 times before incubation with 1 mm NiCl2 and SIGMA fast DAB peroxidase tablets for 30 min. The cells were postfixed in a 2% solution of osmium tetroxide for 30 min, dehydrated through a series of graded ethanols, and embedded and sectioned for TEM. By TEM the injected neutrophils were observed to have taken up bacteria into vacuoles of varying size. At the earliest stages of this process, prior to and immediately following the initial release of granular contents and the initiation of mechanisms to rapidly destroy bacteria, the bacteria fitted more tightly in the vacuoles than at later stages. Injected neutrophils commonly contained several bacteria; more than one bacterium was frequently located within a single vacuole of substantial size. Confocal laser microscopic observations confirmed that cells containing ingested bacteria also contained IgG. Thus injected cells not only survive the microinjection procedure but also retain their ability to take up bacteria and initiate the digestive process. [source]

ORIGINAL ARTICLE: Impact of Female Sex Hormones on the Maturation and Function of Human Dendritic Cells

AMERICAN JOURNAL OF REPRODUCTIVE IMMUNOLOGY, Issue 3 2009
Sabine E. Segerer
Problem, During pregnancy, the immune and the endocrine system cooperate to ensure that the fetal allograft develops without eliciting a maternal immune response. This is presumably in part achieved by dendritic cells (DCs) that play a dominant role in maintaining peripheral tolerance. In this study, we investigated whether female sex hormones, such as human chorionic gonadotropin (hCG), progesterone (Prog), and estradiol (E2), which are highly elevated during pregnancy, induce the differentiation of DCs into a tolerance-inducing phenotype. Methods/Results, Immature DCs were generated from blood-derived monocytes and differentiated in the presence of hCG, Prog, E2, or Dexamethasone (Dex) as a control. Unlike Dex, female sex hormones did not prevent the upregulation of surface markers characteristic for mature DCs, such as CD40, CD83, and CD86, except for hCG, which inhibited HLA-DR expression. Similarly, hCG, Prog, and E2 had any impact on neither the rearrangement of the F-actin cytoskeleton nor the enhanced chemokine secretion following DC maturation, both of which were strongly altered by Dex. Nevertheless, the T-cell stimulatory capacity of DCs was significantly reduced after hCG and E2 exposure. Conclusion, Our findings suggest that the female sex hormones hCG and E2 inhibit the T-cell stimulatory capacity of DCs, which may help in preventing an allogenic T-cell response against the embryo. [source]

Monocyte-Induced Endothelial Calcium Signaling Mediates Early Xenogeneic Endothelial Activation

AMERICAN JOURNAL OF TRANSPLANTATION, Issue 2 2005
Mark D. Peterson
Hallmarks of delayed xenograft rejection include monocyte infiltration, endothelial cell activation and disruption of the endothelial barrier. The monocyte is an important initiator of this type of rejection because monocytes accumulate within hours after xenografting and prior monocyte depletion suppresses the development of this type of rejection. However, the mechanisms that mediate monocyte-induced xenograft injury are unclear at present. Here we report that human monocytes activate xenogeneic endothelial cells through calcium signals. Monocyte contact with porcine but not human endothelium leads to an endothelial calcium transient mediated via a G-protein-coupled receptor (GPCR) that results in up-regulation of porcine VCAM-1 and E-selectin. Although human monocyte adhesion was greater to porcine than to human endothelium, especially when studied under laminar flow, blockade of the xeno-specific endothelial calcium signals did not reduce adhesion of human monocytes to porcine endothelium. Human monocyte contact to porcine endothelium also resulted in reorganization of the F-actin cytoskeleton with a concomitant increase in endothelial monolayer permeability. In contrast to the effect on adhesion, these changes appear to be regulated through endothelial calcium signals. Taken together, these data suggest that human monocytes are capable of activating xenogeneic endothelial cells through calcium transients, as well as other distinct pathways. [source]