SUMMARY Mucocutaneous fungal infections are typically found in patients who have no known immune defects. We describe a family in which four women who were affected by either recurrent vulvovaginal candidiasis or onychomycosis had the early-stop-codon mutation Tyr238X in the β-glucan receptor dectin-1. The mutated form of dectin-1 was poorly expressed, did not mediate β-glucan binding, and led to defective production of cytokines (interleukin-17, tumor necrosis factor, and interleukin-6) after stimulation with β-glucan or Candida albicans. In contrast, fungal phagocytosis and fungal killing were normal in the patients, explaining why dectin-1 deficiency was not associated with invasive fungal infections and highlighting the specific role of dectin-1 in human mucosal antifungal defense.
Mature dendritic cells (mDCs) can trigger the effector functions of natural killer (NK) cells. Knockout , small-interfering RNA or neutralizing antibodies targeting interleukin 12 (IL-12) subunits revealed a critical role for IL-12 in NK cell interferon (IFN-) secretion promoted by mDCs. However, NK cell activation by DCs also required direct cell-to-cell contacts. DC-mediated NK cell activation involved the formation of stimulatory synapses between DCs and NK cells. The formation of DC/NK cell conjugates depended on cy-toskeleton remodeling and lipid raft mobilization in DCs. Moreover, the disruption of the DC cytoskeleton using pharmaco-logic agents or the loss-of-function mutation of the Wiskott-Aldrich syndrome protein abolished the DC-mediated NK cell activation. Synapse formation promoted the polarized secretion of preassembled stores of IL-12 by DCs toward the NK cell. The synaptic delivery of IL-12 by DCs was required for IFN-secretion by NK cells, as assessed using inhibitors of cytoskel-eton rearrangements and transwell experiments. Therefore, the cross-talk between DCs and NK cells is dictated by functional synapses. (Blood. 2004;104:3267-3275) Introduction Natural killer (NK) cells recognize and kill target cells expressing virus-encoded proteins, as well as tumor cells that have lost the expression of major histocompatibility complex (MHC) class I antigens. 1-5 Activation of NK cells results from a balance between inhibitory and activating signaling pathways. 6 Incompatibilities in HLA-Cw alleles between NK and target cells promote the cytolytic function of NK cells involved in the graft-versus-leukemia reaction. 7 In contrast, receptor-ligand interactions between MHC class I molecules and killer inhibitory immunoglobulin-like receptor (KIR) or lectin-type inhibitory NK cell receptor can initiate a dominant inhibitory signaling cascade that blocks NK cell cytotoxicity. Recent studies of the physical interaction between NK cells and target cells have highlighted the functional impact of its synaptic organization. Thus, Lou et al 8 reported that, within the NK/ target cell synapse, lipid rafts polarized to the site of the cell contact in conjugates with sensitive MHC class I-negative targets but not in conjugates with resistant MHC class I-positive targets. Moreover, the negative signals between an NK cell and a target cell are transmitted by KIR at the site of membrane apposition, where inhibitory receptors become clustered with MHC class I ligands in a supramolecular structure known as an inhibitory NK immune synapse (IS). 9,10 KIR signaling is critical for blocking lipid raft polarization and NK cell cytotoxicity, both depending on movements of microtubuli and actin filaments. 11 The composition of adhesion, costimulatory, cytoskel-etal, and signaling molecules in the supramolecular activation clusters (SMACs) of the cytolytic and noncytolytic NK cell IS revealed profound differences. 12 Indeed, cytoskeleton remodel-ing and redistribution of NK cell signaling molecules occur mainly in cytolytic NK ...
SummaryGlycosylation of proteins has proven extremely important in a variety of cellular processes, including enzyme trafficking, tissue homing and immune functions. In the past decade, increasing interest in carbohydrate-mediated mechanisms has led to the identification of novel carbohydrate-recognizing receptors expressed on cells of the immune system. These non-enzymatic lectins contain one or more carbohydrate recognition domains (CRDs) that determine their specificity. In addition to their cell adhesion functions, lectins now also appear to play a major role in pathogen recognition. Depending on their structure and mode of action, lectins are subdivided in several groups. In this review, we focus on the calcium (Ca 2+ + + + )-dependent lectin group, known as C-type lectins, with the dendritic cell-specific ICAM-3 grabbing nonintegrin (DC-SIGN) as a prototype type II C-type lectin organized in microdomains, and their role as pathogen recognition receptors in sensing microbes. Moreover, the cross-talk of C-type lectins with other receptors, such as Toll-like receptors, will be discussed, highlighting the emerging model that microbial recognition is based on a complex network of interacting receptors.
Dendritic cells (DC) that express the type II C-type lectin DC-SIGN (CD209) are located in the submucosa of tissues, where they mediate HIV-1 entry. Interestingly, the pathogen Candida albicans, the major cause of hospital-acquired fungal infections, penetrates at similar submucosal sites. Here we demonstrate that DC-SIGN is able to bind C. albicans both in DC-SIGN-transfected cell lines and in human monocyte-derived DC. The binding was shown to be time-as well as concentration-dependent, and live as well as heat-inactivated C. albicans were bound to the same extent. Moreover, in immature DC, DC-SIGN was able to internalize C. albicans in specific DC-SIGN-enriched vesicles, distinct from those containing the mannose receptor, the other known C. albicans receptor expressed by DC. Together, these results demonstrate that DC-SIGN is an exquisite pathogen-uptake receptor that captures not only viruses but also fungi.
The C-type lectin dendritic cell (DC)–specific intercellular adhesion molecule grabbing non-integrin (DC-SIGN; CD209) facilitates binding and internalization of several viruses, including HIV-1, on DCs, but the underlying mechanism for being such an efficient phagocytic pathogen-recognition receptor is poorly understood. By high resolution electron microscopy, we demonstrate a direct relation between DC-SIGN function as viral receptor and its microlocalization on the plasma membrane. During development of human monocyte-derived DCs, DC-SIGN becomes organized in well-defined microdomains, with an average diameter of 200 nm. Biochemical experiments and confocal microscopy indicate that DC-SIGN microdomains reside within lipid rafts. Finally, we show that the organization of DC-SIGN in microdomains on the plasma membrane is important for binding and internalization of virus particles, suggesting that these multimolecular assemblies of DC-SIGN act as a docking site for pathogens like HIV-1 to invade the host.
Early studies have revealed that some mammalian plasma membrane proteins exist in small nanoclusters. The advent of super-resolution microscopy has corroborated and extended this picture, and led to the suggestion that many, if not most, membrane proteins are clustered at the plasma membrane at nanoscale lengths. In this Commentary, we present selected examples of glycosylphosphatidyl-anchored proteins, Ras family members and several immune receptors that provide evidence for nanoclustering. We advocate the view that nanoclustering is an important part of the hierarchical organization of proteins in the plasma membrane. According to this emerging picture, nanoclusters can be organized on the mesoscale to form microdomains that are capable of supporting cell adhesion, pathogen binding and immune cell-cell recognition amongst other functions. Yet, a number of outstanding issues concerning nanoclusters remain open, including the details of their molecular composition, biogenesis, size, stability, function and regulation. Notions about these details are put forth and suggestions are made about nanocluster function and why this general feature of protein nanoclustering appears to be so prevalent.
Dendritic Cell Interaction with Candida albicans Critically Depends on N-Linked Mannan
The fungus Candida albicans is the most common cause of mycotic infections in immunocompromised hosts. Little is known about the initial interactions between Candida and immune cell receptors, because a detailed characterization at the structural level is lacking. Antigen-presenting dendritic cells (DCs), strategically located at mucosal surfaces and in the skin, may play an important role in anti-Candida protective immunity. However, the contribution of the various Candida-associated molecular patterns and their counter-receptors to DC function remains unknown. Here, we demonstrate that two C-type lectins, DC-SIGN and the macrophage mannose receptor, specifically mediate C. albicans binding and internalization by human DCs. Moreover, by combining a range of C. albicans glycosylation mutants with receptor-specific blocking and cytokine production assays, we determined that N-linked mannan but not O-linked or phosphomannan is the fungal carbohydrate structure specifically recognized by both C-type lectins on human DCs and directly influences the production of the proinflammatory cytokine IL-6. Better insight in the carbohydrate recognition profile of C-type lectins will ultimately provide relevant information for the development of new drugs targeting specific fungal cell wall antigens.
Recruitment of receptor proteins to lipid rafts has been proposed as an important mechanism to regulate their cellular function. In particular, rafts have been implicated in regulation of integrin-mediated cell adhesion, although the underlying mechanism remains elusive. We used single-molecule near-field optical microscopy (NSOM) with localization accuracy of approximately 3 nm, to capture the spatio-functional relationship between the integrin LFA-1 and raft components (GPI-APs) on immune cells. Dual color nanoscale imaging revealed the existence of a nanodomain GPI-AP subpopulation that further concentrated in regions smaller than 250 nm, suggesting a hierarchical prearrangement of GPI-APs on resting monocytes. We previously demonstrated that in quiescent monocytes, LFA-1 preorganizes in nanoclusters. We now show that integrin nanoclusters are spatially different but reside proximal to GPI-AP nanodomains, forming hotspots on the cell surface. Ligandmediated integrin activation resulted in an interconversion from monomers to nanodomains of GPI-APs and the generation of nascent adhesion sites where integrin and GPI-APs colocalized at the nanoscale. Cholesterol depletion significantly affected the reciprocal distribution pattern of LFA-1 and GPI-APs in the resting state, and LFA-1 adhesion to its ligand. As such, our data demonstrate the existence of nanoplatforms as essential intermediates in nascent cell adhesion. Since raft association with a variety of membrane proteins other than LFA-1 has been documented, we propose that hotspots regions enriched with raft components and functional receptors may constitute a prototype of nanoscale inter-receptor assembly and correspond to a generic mechanism to offer cells with privileged areas for rapid cellular function and responses to the outside world.integrin LFA-1 ͉ membrane nanocompartments ͉ near-field scanning optical microscopy (NSOM) ͉ single molecule detection
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