Externalized phosphatidylinositides on apoptotic cells are eat-me signals recognized by CD14

Apoptotic cells are rapidly engulfed and removed by phagocytes after displaying cell surface eat-me signals. Among many phospholipids, only phosphatidylserine (PS) is known to act as an eat-me signal on apoptotic cells. Using unbiased proteomics, we identified externalized phosphatidylinositides (PIPs) as apoptotic eat-me signals recognized by CD14⁺ phagocytes. Exofacial PIPs on the surfaces of early and late-apoptotic cells were observed in patches and blebs using anti-PI(3,4,5)P₃ antibody, AKT- and PLCδ PH-domains, and CD14 protein. Phagocytosis of apoptotic cells was blocked either by masking exofacial PIPs or by CD14 knockout in phagocytes. We further confirmed that exofacial PIP⁺ thymocytes increased dramatically after in vivo irradiation and that exofacial PIP⁺ cells represented more significant populations in tissues of Cd14^−/− than WT mice, especially after induction of apoptosis. Our findings reveal exofacial PIPs to be previously unknown cell death signals recognized by CD14⁺ phagocytes.Subject terms: Phospholipids, Cell death and immune response     

Protein turnover and cell-cycle initiation in yeast

The effects of short pulses of cycloheximide on the traversal of the G1 phase of the cell cycle of the yeast Saccharomyces cerevisiae were examined. Cells were released from a block at the regulatory stage of G1, termed ‘start’, and pulsed with cycloheximide. Delays in budding which were considerably longer than the length of the pulse were observed. During the delay the cells remained blocked at ‘start’. No delay in budding was observed after cycloheximide pulses, when cells were released from a cdc 24 block which arrests the budding process but not ‘start’. Overall protein synthesis did not show an additional delay after the pulse. The extra lag following cycloheximide pulses appears to reflect a unique feature of ‘start’. It may be accounted for by a requirement at ‘start’ for a labile protein with a half-life time of about 6 min.     

Atypical antiinflammatory activation of microglia induced by apoptotic neurons

In the central nervous system (CNS), apoptosis plays an important role during development and is a primary pathogenic mechanism in several adult neurodegenerative diseases. A main feature of apoptotic cell death is the efficient and fast removal of dying cells by macrophages and nonprofessional phagocytes, without eliciting inflammation in the surrounding tissue. Apoptotic cells undergo several membrane changes, including the externalization of so-called "eat me" signals whose cognate receptors are present on professional phagocytes. Among these signals, the aminophospholipid phosphatidylserine (PS) appears to have a crucial and unique role in preventing the classical pro-inflammatory activation of macrophages, thus ensuring the silent and safe removal of apoptotic cells. Although extensively studied in the peripheral organs, the process of recognition and removal of apoptotic cells in the brain has only recently begun to be unraveled. Here, we summarize the evidence suggesting that upon interaction with PS-expressing apoptotic neurons, microglia may no longer promote the inflammatory cascade, but rather facilitate the elimination of damaged neurons through antiinflammatory and neuroprotective functions. We propose that the anti-inflammatory microglial phenotype induced through the activation of the specific PS receptor (PtdSerR), expressed by resting and activated microglial cells, could be relevant to the final outcome of neurodegenerative diseases, in which apoptosis seems to play a crucial role.     

Chemokines act as phosphatidylserine-bound “find-me” signals in apoptotic cell clearance

Removal of apoptotic cells is essential for maintenance of tissue homeostasis. Chemotactic cues termed “find-me” signals attract phagocytes toward apoptotic cells, which selectively expose the anionic phospholipid phosphatidylserine (PS) and other “eat-me” signals to distinguish healthy from apoptotic cells for phagocytosis. Blebs released by apoptotic cells can deliver find-me signals; however, the mechanism is poorly understood. Here, we demonstrate that apoptotic blebs generated in vivo from mouse thymus attract phagocytes using endogenous chemokines bound to the bleb surface. We show that chemokine binding to apoptotic cells is mediated by PS and that high affinity binding of PS and other anionic phospholipids is a general property of many but not all chemokines. Chemokines are positively charged proteins that also bind to anionic glycosaminoglycans (GAGs) on cell surfaces for presentation to leukocyte G protein–coupled receptors (GPCRs). We found that apoptotic cells down-regulate GAGs as they up-regulate PS on the cell surface and that PS-bound chemokines, unlike GAG-bound chemokines, are able to directly activate chemokine receptors. Thus, we conclude that PS-bound chemokines may serve as find-me signals on apoptotic vesicles acting at cognate chemokine receptors on leukocytes.

Chemokines attract leukocytes by activating chemokine receptors, but many also bind anionic phospholipids. This study shows that phosphatidylserine-binding chemokines endow extracellular apoptotic bodies with “find-me” signals that trigger phagocyte migration for potential apoptotic cell clearance.     

细胞死亡清除的趋化和危险信号分子

细胞死亡是机体组成发育及其平衡的重要组成部分,细胞死亡后能够迅速被邻近细胞或巨噬细胞识别吞噬及消化.死细胞自身或细胞死亡时释放的物质有利于死亡细胞的清除及免疫学转归.研究发现凋亡细胞主要通过释放dRPS19、LPC、EMAPⅡ、TSP-1、核苷酸、FKN等趋化信号分子招来吞噬细胞,启动清除过程;坏死细胞则主要通过危险信号分子HSP、S100蛋白、HMGB-1、ATP、尿酸等物质启动和介导炎性反应.然而任何一个信号都不能独立执行功能,多种信号间往往相互联系与制约,共同构成了死细胞清除的信号网络.     

Live Imaging of Apoptotic Cell Clearance during Drosophila Embryogenesis

The proper elimination of unwanted or aberrant cells through apoptosis and subsequent phagocytosis (apoptotic cell clearance) is crucial for normal development in all metazoan organisms. Apoptotic cell clearance is a highly dynamic process intimately associated with cell death; unengulfed apoptotic cells are barely seen in vivo under normal conditions. In order to understand the different steps of apoptotic cell clearance and to compare ''professional'' phagocytes - macrophages and dendritic cells to ''non-professional'' - tissue-resident neighboring cells, in vivo live imaging of the process is extremely valuable. Here we describe a protocol for studying apoptotic cell clearance in live Drosophila embryos. To follow the dynamics of different steps in phagocytosis we use specific markers for apoptotic cells and phagocytes. In addition, we can monitor two phagocyte systems in parallel: ''professional'' macrophages and ''semi-professional'' glia in the developing central nervous system (CNS). The method described here employs the Drosophila embryo as an excellent model for real time studies of apoptotic cell clearance.     

The spread of apoptosis through gap-junctional channels in BHK cells transfected with Cx32

Programmed cell death (apoptosis) occurs both during normal development and as a result of various pathological conditions. An in vitro system was used to explore the transmission of death signals from apoptotic cells to cells with which they were coupled via gap junctions. Confluent cultures of baby hamster kidney (BHK) cells, stably transfected with the gap-junctional protein connexin32, were scrape loaded with cytochrome C (cyC), a mitochondria-derived apoptotic agent, to introduce the protein into cells injured by the cut. The cultures were subsequently analyzed for the presence of activated caspases, the distribution of TUNEL staining, and the binding of annexin V. Although cyC is too large to traverse the gap junctional channel, each of the assays revealed that apoptosis had spread from dying cells at the margin of the scrape to otherwise healthy neighboring cells to which they were coupled. This ‘bystander effect’ was significantly reduced in the presence of agents that block gap junctional intercellular communication.     

Friendly fire against neutrophils: proteolytic enzymes confuse the recognition of apoptotic cells by macrophages

Physiologically the only acceptable fate for almost all damaged or unwanted cells is their apoptotic death, followed by engulfment of the corpses by healthy neighbors or professional phagocytes. Efficient clearance of cells that have succumbed to apoptosis is crucial for normal tissue homeostasis, and for the modulation of immune responses. The disposal of apoptotic cells is finely regulated by a highly redundant system of receptors, bridging molecules and 'eat me' signals. The complexity of the system is reflected by the term: 'engulfment synapse', used to describe the interaction between a phagocytic cell and its target. In healthy humans, dying neutrophils are the most abundant and important targets for such recognition and engulfment. In inflammation the scope and importance of this complicated task is further increased. Paradoxically, despite growing evidence highlighting the priority of neutrophils clearance, the recognition of these cells by phagocytes is not as well understood as the recognition of other apoptotic cell types. New findings indicate that the interaction of phosphatidylserine (PS) on apoptotic neutrophils with its receptor on macrophages is not as critical for the specific clearance of neutrophil corpses it was previously believed. In this review we focus on recent findings regarding alternative, PS-independent "eat me" signals expressed on neutrophils during cell death and activation. Based on our own research, we emphasize the clearance of dying neutrophils, especially at the focus of bacterial infection; and the associated inflammatory reaction, which occurs in a highly proteolytic milieu containing both host and bacteria-derived proteinases. In these environments, eat-me signals expressed by neutrophils are drastically modified; arguing against the phospholipid-based detection of apoptotic cells, but supporting the importance of proteinaceous ligand(s) for the recognition of neutrophils by macrophages. In this context we discuss the effect of the gingipain R (Rgp) proteinases from Porphyromonas gingivalis on neutrophils interactions with macrophages. Since the recognition of apoptotic neutrophils is an important fundamental process, serving multiple functions in the regulation of immunity and homeostasis, we hypothesize that many pathogenic bacteria may have developed similar strategies to confuse macrophage-neutrophil interaction as a common pathogenic strategy.     

Clearance of apoptotic cells by phagocytes

Phagocytic clearance of apoptotic cells may be considered to consist of four distinct steps: accumulation of phagocytes at the site where apoptotic cells are located; recognition of dying cells through a number of bridge molecules and receptors; engulfment by a unique uptake process; and processing of engulfed cells within phagocytes. Here, we will discuss these individual steps that collectively are essential for the effective removal of apoptotic cells. This will illustrate our relative lack of knowledge about the initial attraction signals, the specific mechanisms of engulfment and processing in comparison to the extensive literature on recognition mechanisms. There is now mounting evidence that clearance defects are responsible for chronic inflammatory disease and contribute to autoimmunity. Therefore, a better understanding of all aspects of the clearance process is required before it can truly be manipulated for therapeutic gain.     

Intracellular signalling proteins as ‘smart’ agents in parallel distributed processes

In eucaryotic organisms, responses to external signals are mediated by a repertoire of intracellular signalling pathways that ultimately bring about the activation/inactivation of protein kinases and/or protein phosphatases. Until relatively recently, little thought had been given to the intracellular distribution of the components of these signalling pathways. However, experimental evidence from a diverse range of organisms indicates that rather than being freely distributed, many of the protein components of signalling cascades show a significant degree of spatial organisation. Here, we briefly review the roles of ‘anchor’, ‘scaffold’ and ‘adaptor’ proteins in the organisation and functioning of intracellular signalling pathways. We then consider some of the parallel distributed processing capacities of these adaptive systems. We focus on signalling proteins-both as individual ‘devices’ (agents) and as ‘networks’ (ecologies) of parallel processes. Signalling proteins are described as ‘smart thermodynamic machines’ which satisfy ‘gluing’ (functorial) roles in the information economy of the cell. This combines two information-processing views of signalling proteins. Individually, they show ‘cognitive’ capacities and collectively they integrate (cohere) cellular processes. We exploit these views by drawing comparisons between signalling proteins and verbs. This text/dialogical metaphor also helps refine our view of signalling proteins as context-sensitive information processing agents.     

Galectin-3 is a new MerTK-specific eat-me signal

Phagocytosis of apoptotic cells and cellular debris is a critical process of maintaining tissue and immune homeostasis. Defects in the phagocytosis process cause autoimmunity and degenerative diseases. Phagocytosis ligands or "eat-me" signals control the initiation of the process by linking apoptotic cells to receptors on phagocyte surface and triggering signaling cascades for cargo engulfment. Eat-me signals are traditionally identified on a case-by-case basis with challenges, and the identification of their cognate receptors is equally daunting. Here, we identified galectin-3 (Gal-3) as a new MerTK ligand by an advanced dual functional cloning strategy, in which phagocytosis-based functional cloning is combined with receptor-based affinity cloning to directly identify receptor-specific eat-me signal. Gal-3 interaction with MerTK was independently verified by co-immunoprecipitation. Functional analyses showed that Gal-3 stimulated the phagocytosis of apoptotic cells and cellular debris by macrophages and retinal pigment epithelial cells with MerTK activation and autophosphorylation. The Gal-3-mediated phagocytosis was blocked by excessive soluble MerTK extracellular domain and lactose. These results suggest that Gal-3 is a legitimate MerTK-specific eat-me signal. The strategy of dual functional cloning with applicability to other phagocytic receptors will facilitate unbiased identification of their unknown ligands and improve our capacity for therapeutic modulation of phagocytic activity and innate immune response.     

Phagocytosis of apoptotic cells and the resolution of inflammation

Clearance of apoptotic cells by phagocytic cells plays a significant role in the resolution of inflammation, protecting tissue from harmful exposure to the inflammatory and immunogenic contents of dying cells. Apoptosis induces cell surface changes that are important for recognition and engulfment of cells by phagocytes. These changes include alterations in surface sugars, externalization of phosphatidylserine and qualitative changes in the adhesion molecule ICAM-3. Several studies have contributed to clarify the role of the receptors on the surface of phagocytes that are involved in apoptotic cell clearance. The phagocytic removal of apoptotic cells does not elicit pro-inflammatory responses; in contrast, apoptotic cell engulfment appears to activate signals that suppress release of pro-inflammatory cytokines. Therefore, clearance of apoptotic leucocytes is implicated in the resolution of inflammation and mounting evidence suggests that defective clearance of apoptotic cells contributes to inflammatory and autoimmune diseases. Defining the ligands on apoptotic cells and the corresponding receptors on phagocytes with which they engage, is likely to lead to the development of novel anti-inflammatory pro-resolution drugs. In this article, we will review the recognition and signaling mechanisms involved in the phagocytosis of apoptotic cells as well as the role of endogenous compounds that play a relevant role in the modulation of inflammation. We will also discuss what is currently known about diseases that may reflect impaired phagocytosis and the consequences on inflammation and immune responses.     

Apoptosis and necrosis: detection, discrimination and phagocytosis.

Three major morphologies of cell death have been described: apoptosis (type I), cell death associated with autophagy (type II) and necrosis (type III). Apoptosis and cell death associated with autophagy can be distinguished by certain biochemical events. However, necrosis is characterized mostly in negative terms by the absence of caspase activation, cytochrome c release and DNA oligonucleosomal fragmentation. A particular difficulty in defining necrosis is that in the absence of phagocytosis apoptotic cells become secondary necrotic cells with many morphological features of primary necrosis. In this review, we present a selection of techniques that can be used to identify necrosis and to discriminate it from apoptosis. These techniques rely on the following cell death parameters: (1) morphology (time-lapse and transmission electron microscopy and flow fluorocytometry); (2) cell surface markers (phosphatidylserine exposure versus membrane permeability by flow fluorocytometry); (3) intracellular markers (oligonucleosomal DNA fragmentation by flow fluorocytometry, caspase activation, Bid cleavage and cytochrome c release by western blotting); (4) release of extracellular markers in the supernatant (caspases, HMGB-1 and cytokeratin 18). Finally, we report on methods that can be used to examine interactions between dying cells and phagocytes. We illustrate a quantitative method for detecting phagocytosis of dying cells by flow fluorocytometry. We also describe a recently developed approach based on the use of fluid phase tracers and different kind of microscopy, transmission electron and fluorescence microscopy, to characterize the mechanisms used by phagocytes to internalize dying cells.     

Dangerous attraction: phagocyte recruitment and danger signals of apoptotic and necrotic cells

Tissue homeostasis in metazoa requires the rapid and efficient clearance of dying cells by professional or semi-professional phagocytes. Impairment of this finely regulated, fundamental process has been implicated in the development of autoimmune diseases, such as systemic lupus erythematosus. Various studies have provided us a detailed understanding of the interaction between dying cells and phagocytes as well as the current concept that apoptotic cell removal leads to a non- or anti-inflammatory response, whereas necrotic cell removal stimulates a pro-inflammatory reaction. In contrast, our knowledge about the soluble factors released from dying cells is rather limited, although meanwhile it is generally accepted that not only the dying cell itself but also the substances liberated during cell death contribute to the process of corpse clearance and the subsequent immune response. This review article is intended as an up-to-date survey over attraction and danger signals of apoptotic, primary and secondary necrotic cells, their function as chemoattractants in phagocyte recruitment, additional effects on the immune system, and the receptors, which are engaged in this scenario.     

Phagocytotic activity of glial cells in culture

The phagocytotic activity of glial cells was tested in primary cultures of astrocytes and C6 glioma cultures. Latex bead uptake served as an index of the respective phagocytotic activity. The content of latex beads in glial cells continued to increase for 24 h and this increase could be inhibited by incubation in ice bath or treatment with cytochalasin B (CB) or D (CD) at 37 °C. Addition of brain extract reduced latex bead uptake, whereas the phagocytotic activity was not markedly influenced by serum withdrawal and/or db-cAMP addition, both of which are usually used to induce certain characteristics of differentiated glial cells. Our results support the hypothesis that astroglial cells may act as phagocytes in situations where ‘professional’ phagocytes are not so numerous. In addition, the results imply that the phagocytotic activity of glial cells also depends on environmental conditions.     

Apoptotic cells induce migration of phagocytes via caspase-3-mediated release of a lipid attraction signal

Efficient engulfment of the intact cell corpse is a critical end point of apoptosis, required to prevent secondary necrosis and inflammation. The presentation of "eat-me" signals on the dying cell is an important part of this process of recognition and engulfment by professional phagocytes. Here, we present evidence that apoptotic cells secrete chemotactic factor(s) that stimulate the attraction of monocytic cells and primary macrophages. The activation of caspase-3 in the apoptotic cell was found to be required for the release of this chemotactic factor(s). The putative chemoattractant was identified as the phospholipid, lysophosphatidylcholine. Further analysis showed that lysophosphatidylcholine was released from apoptotic cells due to the caspase-3 mediated activation of the calcium-independent phospholipase A(2). These data suggest that in addition to eat-me signals, apoptotic cells display attraction signals to ensure the efficient removal of apoptotic cells and prevent postapoptotic necrosis.     

Phosphatidylserine receptor and apoptosis: consequences of a non-ingested meal

Apoptosis, a physiological process of controlled cell death, is essential during embryonic development and for the maintenance of tissue homeostasis. In recent years the view has emerged that dying cells can provide specific signals that enable recruitment and recognition by phagocytes. Exposure of phosphatidylserine, the best characterized of such signals, allows safe clearance of apoptotic waste without induction of inflammation. Here I re-examine some of the arguments that underpin the importance of these clearance mechanisms in light of recent observations from an animal model that lacks the receptor specific for phosphatidylserine.     

C1q binds phosphatidylserine and likely acts as a multiligand-bridging molecule in apoptotic cell recognition

Efficient apoptotic cell clearance is critical for maintenance of tissue homeostasis, and to control the immune responses mediated by phagocytes. Little is known about the molecules that contribute "eat me" signals on the apoptotic cell surface. C1q, the recognition unit of the C1 complex of complement, also senses altered structures from self and is a major actor of immune tolerance. HeLa cells were rendered apoptotic by UV-B treatment and a variety of cellular and molecular approaches were used to investigate the nature of the target(s) recognized by C1q. Using surface plasmon resonance, C1q binding was shown to occur at early stages of apoptosis and to involve recognition of a cell membrane component. C1q binding and phosphatidylserine (PS) exposure, as measured by annexin V labeling, proceeded concomitantly, and annexin V inhibited C1q binding in a dose-dependent manner. As shown by cosedimentation, surface plasmon resonance, and x-ray crystallographic analyses, C1q recognized PS specifically and avidly (K(D) = 3.7-7 x 10(-8) M), through multiple interactions between its globular domain and the phosphoserine group of PS. Confocal microscopy revealed that the majority of the C1q molecules were distributed in membrane patches where they colocalized with PS. In summary, PS is one of the C1q ligands on apoptotic cells, and C1q-PS interaction takes place at early stages of apoptosis, in newly organized membrane patches. Given its versatile recognition properties, these data suggest that C1q has the unique ability to sense different markers which collectively would provide strong eat me signals, thereby allowing efficient apoptotic cell removal.