IgG surface mobility promotes antibody dependent cellular phagocytosis by Syk and Arp2/3 mediated reorganization of Fcγ receptors in macrophages
Seongwan JoNicholas M. CroninNi Putu Dewi NurmalasariJason G. KerkvlietElizabeth M. BaileyR. B. AndersonBrandon L. ScottAdam D. Hoppe
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Abstract By visualizing the movements of Rituximab during Antibody dependent cellular phagocytosis (ADCP) of B lymphoma cells by macrophages, we found that Fcγ receptors (FcγR) on the macrophage surface microcluster, recruit Syk and undergro large-scale reorganization at the phagocytic synapse prior to and during engulfment of the target cell. Given these dramatic rearrangements, we analyzed how the surface mobility of Rituximab contributes to FcγR signal amplification and ADCP efficiency. Depolymerization of the target cell actin cytoskeleton resulted in free diffusion of Rituximab docked to CD20, enhanced microcluster reorganization, Syk recruitment and ADCP. Conversely, immobilization of Rituximab by chemical fixation impaired microcluster formation and diminished Syk recruitment and ADCP. In macrophages lacking Syk, Rituximab accumulated at the base of the phagosome and were trogocytosed, consistent with Syk kinase activity being necessary to trigger redistribution of Rituximab-FcγR during engulfment and to prevent antigenic modulation of the target. Total internal reflection fluorescence analysis of FcγR-IgG on fluid supported lipid bilayers revealed a membrane topography displaying inward reaching leading edges and protruding contact sites reminiscent of podosomes. This topography was distinct from the closely apposed macrophage/target membranes observed during engagement of IgG displayed on immobile supported lipid bilayers. The organization of this contact, pseudopod extension and the rearrangement of microclusters depended critically on Arp 2/3. Thus, Syk and Arp2/3 coordinate actin rearrangements and FcγR-IgG complexes that were of previously unrecognized complexity for the clearance of cells displaying surface-mobile antigens. Significance Statement ADCP is an important effector mechanism for the removal of malignant, immunologically aberrant, and infected cells during treatment with therapeutic antibodies or adaptive immune responses. Most transmembrane protein antigens are mobile with transient confinement from the actin of the target cell. This work demonstrates that macrophage forces overcome these confinements to rearrange FcγR-IgG-antigen complexes before and during ADCP. Thus, new paradigms are needed as ADCP has largely been studied using model target particles that display immobile antigens. Moreover, we found that the mobility of the therapeutic antibody, Rituximab, on the surface of B lymphoma cells foretells ADCP efficacy, with lower densities of IgG mediating ADCP on increasingly mobile antigens.Keywords:
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Syk is a non‐receptor protein‐tyrosine kinase and primarily expressed in hematopoietic cells. We previously reported that Syk plays an essential role in complement‐mediated phagocytosis, especially in engulfment process. In the current study, we aimed at clarifying the role of Syk in phagosome maturation process in complement‐mediated phagocytosis. To reveal the role of Syk in the phagocytosis, we established various Syk‐knockout (Syk‐KO) cell lines by using CRISPR/Cas9 system in HL60 cells. Using these parental and mutant HL60 cells, we performed complement‐mediated phagocytosis assay after macrophage‐like differentiation. As a result, we found that Syk‐KO macrophages permitted escape of C. albicans from the phagosomes because of the insufficient phagosome acidification. Additionally, we found that fusion of phagosomes with lysosomes did not occur in Syk‐KO cells and phagosomes of Syk‐KO cells still remained surrounded by thick F‐actin structure after engulfment process. These results demonstrate that Syk accelerates phagosome acidification by facilitating the collapse of F‐actin surrounding phagosomes and resultant fusion of lysosomes to the phagosomes in complement‐mediated phagocytosis. In conclusion, our results indicate that actin‐remodeling is essential not only for phagosome formation but also for phagosome maturation process in complement‐mediated phagocytosis. Support or Funding Information This work was supported by JSPS KAKENHI Grant Number JP 18K07432.
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Borrelia burgdorferi is the causative agent of Lyme disease, an infectious disease that primarily affects the skin, nervous system, and joints. Uptake of borreliae by immune cells is decisive for the course of the infection, and remodelling of the host actin cytoskeleton is crucial in this process. In this study, we showed that the actin-regulatory formin Daam1 is important in Borrelia phagocytosis by primary human macrophages. Uptake of borreliae proceeds preferentially through capture by filopodia and formation of coiling pseudopods that enwrap the spirochetes. Using immunofluorescence, we localized endogenous and overexpressed Daam1 to filopodia and to F-actin-rich uptake structures. Live-cell imaging further showed that Daam1 is enriched at coiling pseudopods that arise from the macrophage surface. This filopodia-independent step was corroborated by control experiments of phagocytic cup formation with latex beads. Moreover, siRNA-mediated knockdown of Daam1 led to a 65% reduction of borreliae-induced filopodia, and, as shown by the outside–inside staining technique, to a 50% decrease in phagocytic uptake of borreliae, as well as a 37% reduction in coiling pseudopod formation. Collectively, we showed that Daam1 plays a dual role in the phagocytic uptake of borreliae: first, as a regulator of filopodia, which are used for capturing spirochetes, and second, in the formation of the coiling pseudopod that enwraps the bacterial cell. These data identify Daam1 as a novel regulator of B. burgdorferi phagocytosis. At the same time, this is the first demonstration of a role for Daam1 in phagocytic processes in general.—Hoffmann, A.-K., Naj, X., Linder, S. Daam1 is a regulator of filopodia formation and phagocytic uptake of Borrelia burgdorferi by primary human macrophages. FASEB J. 28, 3075–3089 (2014). www.fasebj.org
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To study the invasive behaviour of squamous cell carcinoma of the tongue.The cryofracture technique for scanning electron microscope (SEM) and transmission electron microscope (TEM) was used.Cancer cells invaded surrounding tissues by proliferation and penetration en masse, and projected with pseudopodia and lamellipodia. The tensile fibers along and under the cell membrane protruded into the interdigitated filopodia. There were dilatation of intercellular spaces, less number of desmosomes and few gap junctions. All the properties above-described together with increase of cell motility, lytic activity, and decrease of intercellular adhesion were likely to contribute to invasiveness.In addition, it was identified that highly dense lymphocytes enclosed cancer nest, which could inhibit invasive action of cancer cells.
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Objective To explore the destructive effect ofphotodynamic therapy(PDT)on the invasive specialized structures on the surface of glioma cells.Methods Nano-scale morphological contrast study of specialized membrane structures on the surface of U251 glioma cells before and after being acted on by 5-aminolevulinic acid(5-ALA)was performed through the application of cell culture and atomic force microscopy.Results The abundance of pseudopodia and microvillus structures on the surface of glioma cell membrane,which used to be about 400 nm in diameter,1μm in length and finger-like protuberance became spherical granules with the diameter of 300nm,and finger-like protuberance and membraneous pseudopodia and filopodia disappeared,after 5-ALA-induced PDT. Conclusion The 5-ALA-induced PDT has significant destruction effect on invasiveness of glioma cells.
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Elimination of fungal pathogens by phagocytes requires phagosome maturation, a process that involves the recruitment and fusion of intracellular proteins. The role of Dectin-1, a β-1,3-glucan receptor, critical for fungal recognition and triggering of Th17 responses, to phagosomal maturation has not been defined. We show that GFP-Dectin-1 translocates to the fungal phagosome, but its signal decays after 2 h. Inhibition of acidification results in retention of GFP-Dectin-1 to phagosome membranes highlighting the requirement for an acidic pH. Following β-1,3-glucan recognition, GFP-Dectin-1 undergoes tyrosine phosphorylation by Src kinases with subsequent Syk activation. Our results demonstrate that Syk is activated independently of intraphagosomal pH. Inhibition of Src or Syk results in prolonged retention of GFP-Dectin-1 to the phagosome signifying a link between Syk and intraphagosomal pH. β-1,3-glucan phagosomes expressing a signaling incompetent Dectin-1 failed to mature as demonstrated by prolonged Dectin-1 retention, presence of Rab5B, failure to acquire LAMP-1 and inability to acidify. Phagosomes containing Candida albicans also require Dectin-1-dependent Syk activation for phagosomal maturation. Taken together, these results support a model where Dectin-1 not only controls internalization of β-1,3-glucan containing cargo and triggers proinflammatory cytokines, but also acts as a master regulator for subsequent phagolysosomal maturation through Syk activation.
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Entamoeba histolytica, the causal agent of human amoebiasis, has two morphologically different phases: a resistant cyst and a trophozoite responsible for the invasion of the host tissues such as the colonic mucosa and the intestinal epithelium. During in vitro migration, trophozoites usually produce protuberances such as pseudopods and rarely filopodia, structures that have been observed in the interaction of trophozoites with human colonic epithelial tissue. To study the different membrane projections produced by the trophozoites, including pseudopods, filopodia, uropods, blebs and others, we designed an induction system using erythrocyte extract or fibronectin (FN) in micropatterned grill lines (each micro-line containing multiple micro-portions of FN or erythrocyte extract) on which the trophozoites were placed in culture for migration assays. Using light, confocal, and scanning electron microscopy, we established that E. histolytica trophozoites frequently produce short and long filopodia, large retractile uropods in the rear, pseudopods, blebs and others structures, also showing continuous migration periods. The present study provides a simple migration method to induce trophozoites to generate abundant membrane protrusion structures that are rarely obtained in normal or induced cultures, such as long filopodia; this method will allow a –better understanding of the interactions of trophozoites with FN and cell debris. E. histolytica trophozoites motility plays an important role in invasive amoebiasis. It has been proposed that both physical forces and chemical signals are involved in the trophozoite motility and migration. However, the in vivo molecules that drive the chemotactic migration remain to be determined. We propose the present assay to study host molecules that guide chemotactic behavior because the method is highly reproducible, and a live image of cell movement and migration can be quantified.
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Science 's STKE explores the molecular mechanisms that allow cells to navigate and migrate in a particular direction. New models for forming cellular extensions called filopodia that initiate migration, along with methods for analysis of the proteomic differences between the cell body and cellular protrusions (pseudopodia), are highlighted. The processes by which groups of cells, as well as individual cells, navigate in a particular direction are also featured.
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The current dominant model of cell locomotion proposes that actin polymerization pushes against the membrane at the leading edge producing filopodia and lamellipodia that move the cell forward. Despite its success, this model does not fully explain the complex process of amoeboid motility, such as that occurring during embryogenesis and metastasis. Here, we show that Dictyostelium cells moving in a physiological milieu continuously produce `blebs' at their leading edges, and demonstrate that focal blebbing contributes greatly to their locomotion. Blebs are well-characterized spherical hyaline protrusions that occur when a patch of cell membrane detaches from its supporting cortex. Their formation requires the activity of myosin II, and their physiological contribution to cell motility has not been fully appreciated. We find that pseudopodia extension, cell body retraction and overall cell displacement are reduced under conditions that prevent blebbing, including high osmolarity and blebbistatin, and in myosin-II-null cells. We conclude that amoeboid motility comprises two mechanically different processes characterized by the production of two distinct cell-surface protrusions, blebs and filopodia-lamellipodia.
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The ability of mammalian cells to adhere and to migrate is an essential prerequisite to form higher organisms. Early migratory events include substrate sensing, adhesion formation, actin bundle assembly and force generation. Latest research revealed that filopodia are important not only for sensing the substrate but for all of the aforementioned highly regulated processes. However, the exact regulatory mechanisms are still barely understood. Here, we deomonstrate that filopodia of human keratinocytes exhibit distinct cycles of repetitive elongation and persistence. A single filopodium thereby is able to initiate the formation of several stable adhesions. Every single filopodial cycle is characterized by an elongation phase, followed by a stabilization time and in many cases a persistence phase. The whole process is strongly connected to the velocity of the lamellipodial leading edge, characterized by a similar phase behavior with a slight time shift compared to filopodia and a different velocity. Most importantly, re-growth of existing filopodia is induced at a sharply defined distance between the filopodial tip and the lamellipodial leading edge. On the molecular level this re-growth is preceded by a strong filopodial reduction of the actin bundling protein fascin. This reduction is achieved by a switch to actin polymerization without fascin incorporation at the filopodial tip and therefore subsequent out-transport of the cross-linker by actin retrograde flow.
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