Distinct modes of macrophage recognition for apoptotic and necrotic cells are not specified exclusively by phosphatidylserine exposure

The distinction between physiological (apoptotic) and pathological (necrotic) cell deaths reflects mechanistic differences in cellular disintegration and is of functional significance with respect to the outcomes that are triggered by the cell corpses. Mechanistically, apoptotic cells die via an active and ordered pathway; necrotic deaths, conversely, are chaotic and passive. Macrophages and other phagocytic cells recognize and engulf these dead cells. This clearance is believed to reveal an innate immunity, associated with inflammation in cases of pathological but not physiological cell deaths. Using objective and quantitative measures to assess these processes, we find that macrophages bind and engulf native apoptotic and necrotic cells to similar extents and with similar kinetics. However, recognition of these two classes of dying cells occurs via distinct and noncompeting mechanisms. Phosphatidylserine, which is externalized on both apoptotic and necrotic cells, is not a specific ligand for the recognition of either one. The distinct modes of recognition for these different corpses are linked to opposing responses from engulfing macrophages. Necrotic cells, when recognized, enhance proinflammatory responses of activated macrophages, although they are not sufficient to trigger macrophage activation. In marked contrast, apoptotic cells profoundly inhibit phlogistic macrophage responses; this represents a cell-associated, dominant-acting anti-inflammatory signaling activity acquired posttranslationally during the process of physiological cell death.     

Cellular heterogeneity in normal human urothelium: Quantitative studies of lectin binding

Summary A panel of 10 FITC-labelled lectins (MPA, PNA, ConA, DBA, SBA, RCA-120, WGA, UEA, GS-I, GS-II) was applied to cryosections of seven specimens of normal urothelium. Seven of the lectins (MPA, ConA, RCA, WGA, UEA, GS-I and GS-II) showed a pattern of increasing fluorescence intensity from basal to superficial cells of the urothelium whereas PNA, DBA and SBA showed more uniform binding throughout the urothelium. Urothelial cell suspensions labelled with FITC-lectins were studied by flow cytometry to quantify the variation in binding to different cells types. Three cellular subpopulations were identified in normal urothelium on the basis of their optical properties. Fluorescence intensity due to specific lectin binding was then measured separately for each subpopulation. Although there was some variation among individual cases, a general pattern emerged in this small series. WGA, RCA, and GS-II bind in large quantities to all urothelial cells while PNA, SBA, ConA and DBA show little binding. MPA, RCA, UEA and GS-I showed the most marked increase in fluorescence intensity from basal to superficial cells as observed microscopically and quantified by flow cytometry.     

Quinidine and procainamide inhibit murine macrophage uptake of apoptotic and necrotic cells: A novel contributing mechanism of drug-induced-lupus

A number of mechanisms have been proposed to explain the etiology of drug-induced lupus (DIL) but the effect of apoptotic and necrotic cell handling has not been previously examined.Objective. To evaluate the effect of quinidine and procainamide at therapeutic range concentrations, on the uptake of apoptotic and necrotic thymocytes by murine peritoneal macrophages and on macrophage survival, as a novel mechanism for DIL.Methods. Thymocytes were stained and induced to undergo apoptosis by serum withdrawal. Apoptosis was evaluated using annexin V and propidum iodide (PI) and PI staining. Necrosis was induced by heating. Peritoneal macrophages were treated with quinidine or procainamide at a range of therapeutic concentrations and incubated with stained apoptotic and necrotic thymocytes. Apoptotic and necrotic cell uptake was evaluated by flow cytometry using double staining of thymocytes and macrophages and by confocal microscopy. Green fluorescent latex beads were used as controls for phagocytosis.Results. Significantly decreased uptake of apoptotic and necrotic cells was seen in the presence of quinidine and procainamide. The documented effect was mainly on the number of apoptotic/necrotic cells per macrophage. Uptake of fluorescent latex beads offered to resident macrophages was not significantly affected by quinidine or procainamide. No pro-apoptotic effect of quinidine or procainamide on macrophages was seen.Conclusion. Quinidine and procainamide at therapeutic range concentrations specifically inhibit clearance of apoptotic and necrotic cells by peritoneal macrophages. Altered handling of apoptotic and necrotic cells may represent a contributing mechanism for DIL.     

Serum-dependent processing of late apoptotic cells for enhanced efferocytosis

Binding of the serum protein complement component C1q to the surface of dying cells facilitates their clearance by phagocytes in a process termed efferocytosis. Here, we investigate during which phase of apoptotic cell death progression C1q binding takes place. Purified C1q was found to bind to all dying cells and, albeit weaker, also to viable cells. The presence of serum abrogated completely the binding to viable cells. In addition, C1q binding to dying cells was limited to a specific subpopulation of late apoptotic/secondary necrotic cells. Co-culturing serum-treated apoptotic cells with human monocytes revealed a much higher phagocytosis of C1q-positive than of C1q-negative late apoptotic/secondary necrotic cells. But this phagocytosis-promoting activity could not be observed with purified C1q. Serum-treated C1q-positive late apoptotic/secondary necrotic cells exhibited a similar volume, a similar degraded protein composition, but a much lower DNA content in comparison with the remaining late apoptotic/secondary necrotic cells. This was mediated by a serum-bound nuclease activity that could be abrogated by G-actin, which is a specific inhibitor of serum DNase I. These results show that serum factors are involved in the prevention of C1q binding to viable cells and in the processing of late apoptotic/secondary necrotic cells promoting cell death progression toward apoptotic bodies. This process leads to the exposure of C1q-binding structures and facilitates efferocytosis.     

An essential role of the NF-kappa B/Toll-like receptor pathway in induction of inflammatory and tissue-repair gene expression by necrotic cells

Tissue damage induced by infection or injury can result in necrosis, a mode of cell death characterized by induction of an inflammatory response. In contrast, cells dying by apoptosis do not induce inflammation. However, the reasons for underlying differences between these two modes of cell death in inducing inflammation are not known. Here we show that necrotic cells, but not apoptotic cells, activate NF-kappaB and induce expression of genes involved in inflammatory and tissue-repair responses, including neutrophil-specific chemokine genes KC and macrophage-inflammatory protein-2, in viable fibroblasts and macrophages. Intriguingly, NF-kappaB activation by necrotic cells was dependent on Toll-like receptor 2, a signaling pathway that induces inflammation in response to microbial agents. These results have identified a novel mechanism by which cell necrosis, but not apoptosis, can induce expression of genes involved in inflammation and tissue-repair responses. Furthermore, these results also demonstrate that the NF-kappaB/Toll-like receptor 2 pathway can be activated both by exogenous microbial agents and endogenous inflammatory stimuli.     

Clearance of apoptotic and necrotic cells and its immunological consequences

The ultimate and most favorable fate of almost all dying cells is engulfment by neighboring or specialized cells. Efficient clearance of cells undergoing apoptotic death is crucial for normal tissue homeostasis and for the modulation of immune responses. Engulfment of apoptotic cells is finely regulated by a highly redundant system of receptors and bridging molecules on phagocytic cells that detect molecules specific for dying cells. Recognition of necrotic cells by phagocytes is less well understood than recognition of apoptotic cells, but an increasing number of recent studies, which are discussed here, are highlighting its importance. New observations indicate that the interaction of macrophages with dying cells initiates internalization of the apoptotic or necrotic targets, and that internalization can be preceded by “zipper”-like and macropinocytotic mechanisms, respectively. We emphasize that clearance of dying cells is an important fundamental process serving multiple functions in the regulation of normal tissue turnover and homeostasis, and is not just simple anti- or pro-inflammatory responses. Here we review recent findings on genetic pathways participating in apoptotic cell clearance, mechanisms of internalization, and molecules involved in engulfment of apoptotic versus necrotic cells, as well as their immunological consequences and relationships to disease pathogenesis. Katharina D’Herde and Peter Vandenabeele share senior authorship. This study was supported by Ghent University GOA grant No. 12050502, IUAP-V/12-12.0C14.02, FWO-Vlaanderen 3G.0218.06, and Flanders Interuniversity Institute for Biotechnology (VIB).     

Complement binding is an early feature of necrotic and a rather late event during apoptotic cell death

The phagocytosis of dying cells is an integral feature of apoptosis and necrosis. There are many receptors involved in recognition of dying cells, however, the molecular mechanisms of the scavenging process remain elusive. The activation by necrotic cells of complement is well established, however, the importance of complement in the scavenging process of apoptotic cells was just recently described. Here we report that the complement components C3 and C4 immediately bound to necrotic cells. The binding of complement was much higher for lymphocytes compared to granulocytes. In case of apoptotic cell death complement binding was a rather late event, which in lymphocytes was preceded by secondary necrosis. Taken together complement binding is an immediate early feature of necrosis and a rather late event during apoptotic cell death. We conclude that complement may serve as an opsonin for fragments of apoptotic cells that have escaped regular scavenging mechanisms.     

Epithelial heterogeneity in the murine thymus: fucose-specific lectins bind medullary epithelial cells

By means of histochemical techniques, two lectins with nominal specificity for L-fucose, Tetragonolobus purpureas agglutinin (TPA), and Ulex europeus agglutinin (UEA) were found to specifically label the medullary area of murine thymuses. Although the binding of both lectins was restricted to the medullary area of the thymus, each staining pattern was unique. Cells binding UEA formed a reticular network throughout the medulla, whereas cells binding TPA occurred as single cells or small clumps of cells and resembled Hassall's corpuscles. The cells binding either lectin were identified as epithelial on the basis of ultrastructural features (tonofilaments, desmosomes, and keratohyalin bodies) and resembled Ia+ medullary epithelial cells described previously. An age-related decline in UEA binding was observed, whereas labeling with TPA remained unchanged. On the basis of the labeling patterns obtained with UEA and TPA and the reported specificities of these two lectins, it is suggested that the majority of the fucose detected is associated with type 1 carbohydrate chains.     

A Role for Potassium Permeability in the Recognition,Clearance, and Anti-inflammatory Effects of Apoptotic Cells

The benefits of programmed cell death by apoptosis are the safe and efficient clearance of damaged, infected, or surplus cells, primarily mediated by tissue-resident macrophages or tissue-infiltrating blood monocytes that differentiate into macrophages. Microglial cells are macrophages of the brain parenchyma, important immune surveillance cells that respond to various injuries and diseases of the brain. It is often stated that how a macrophage interacts with an apoptotic cell defines subsequent inflammatory responses, i.e., will engulfment be beneficial or detrimental for tissue repair, regeneration, and immunity. Our focus has been to better understand how macrophages discriminate between living and dying cells. Following our initial findings with platelet endothelial cell adhesion molecule (PECAM)-1, our studies have revealed a key role for potassium ion permeability in regulating integrin-dependent binding of apoptotic cells by macrophages and their subsequent response to proinflammatory stimuli. Specifically, apoptotic cells represent a depolarizing stimulus for macrophages where PECAM-1-mediated cell–cell interactions delay subsequent membrane repolarization. It is salient that potassium leak represents an early feature of cells destined to die by apoptosis that could trigger depolarization of macrophages that lie in close apposition. We speculate that how a tissue-resident macrophage responds to strong depolarizing stimuli has wider implications for inflammation and autoimmunity.     

Tim4- and MerTK-Mediated Engulfment of Apoptotic Cells by Mouse Resident Peritoneal Macrophages

Apoptotic cells are swiftly engulfed by macrophages to prevent the release of noxious materials from dying cells. Apoptotic cells expose phosphatidylserine (PtdSer) on their surface, and macrophages engulf them by recognizing PtdSer using specific receptors and opsonins. Here, we found that mouse resident peritoneal macrophages expressing Tim4 and MerTK are highly efficient at engulfing apoptotic cells. Neutralizing antibodies against either Tim4 or MerTK inhibited the macrophage engulfment of apoptotic cells. Tim4-null macrophages exhibited reduced binding and engulfment of apoptotic cells, whereas MerTK-null macrophages retained the ability to bind apoptotic cells but failed to engulf them. The incubation of wild-type peritoneal macrophages with apoptotic cells induced the rapid tyrosine phosphorylation of MerTK, which was not observed with Tim4-null macrophages. When mouse Ba/F3 cells were transformed with Tim4, apoptotic cells bound to the transformants but were not engulfed. Transformation of Ba/F3 cells with MerTK had no effect on the binding or engulfment of apoptotic cells; however, Tim4/MerTK transformants exhibited strong engulfment activity. Taken together, these results indicate that the engulfment of apoptotic cells by resident peritoneal macrophages proceeds in two steps: binding to Tim4, a PtdSer receptor, followed by MerTK-mediated cell engulfment.     

Involvement of the Galbeta1 - 3GalNAcbeta structure in the recognition of apoptotic bodies by THP-1 cells

A specific apoptotic glycosylation pattern may play an assistant or even a causative role in phagocytosis of apoptotic bodies. To elucidate the role of macrophages in lectin-mediated phagocytosis, an experimental system was used, where monocyte-derived THP-1 cells engulf the apoptotic bodies from the melanoma cell line MELJUSO. A flow cytometry assay was performed to reveal lectin expression and quantify the phagocytosis of apoptotic bodies. Taking into account that siglecs, a mannose receptor and galectins expressed on macrophages could be involved in engulfment of apoptotic bodies we studied their potential expression on THP-1 cells by means of polyacrylamide glycoconjugates. A strong binding of the cells to siglec ligands (3'SiaLac, 6'SiaLac, [Neu5Acalpha2-8]2) and galectin ligands (LacNAc, GalNAcbeta1 - 4GlcNAc, Galbeta1 - 3GalNAcbeta and asialoGM1) was observed. To reveal the corresponding targets on apoptotic bodies, the carbohydrate pattern of MELJUSO cells was analyzed. The apoptotic membrane was characterized by a high level of glycans terminated by galactose or sialic acid. To study lectin-mediated phagocytosis of apoptotic bodies by THP-1 cells, an inhibitory phagocytosis assay was performed. Binding of Galbeta1 - 3GalNAc- or LacNAc-specific reagents (lectins and antibodies) to apoptotic bodies abolished their engulfment by the THP-1 cells whereas blocking of Neu5Acalpha2 - 6 or Neu5Acalpha2 - 3 sites by the corresponding lectins was not effective. Furthermore, Galbeta1 - 3GalNAcbeta-PAA or asialoGM1-PAA binding to the THP-1 cells decreased phagocytosis, whereas two other potent THP-1-binding probes, LacNAc-PAA and GalNAcbeta1 - 4GlcNAc-PAA did not inhibit phagocytosis. Thus, Galbeta1 - 3GalNAcbeta-terminated chains represented on the apoptotic bodies but not the other tested galectin ligands appear to be a target for THP-1 cells.     

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.     

ATP release from dying autophagic cells and their phagocytosis are crucial for inflammasome activation in macrophages

Pathogen-activated and damage-associated molecular patterns activate the inflammasome in macrophages. We report that mouse macrophages release IL-1β while co-incubated with pro-B (Ba/F3) cells dying, as a result of IL-3 withdrawal, by apoptosis with autophagy, but not when they are co-incubated with living, apoptotic, necrotic or necrostatin-1 treated cells. NALP3-deficient macrophages display reduced IL-1β secretion, which is also inhibited in macrophages deficient in caspase-1 or pre-treated with its inhibitor. This finding demonstrates that the inflammasome is activated during phagocytosis of dying autophagic cells. We show that activation of NALP3 depends on phagocytosis of dying cells, ATP release through pannexin-1 channels of dying autophagic cells, P(2)X(7) purinergic receptor activation, and on consequent potassium efflux. Dying autophagic Ba/F3 cells injected intraperitoneally in mice recruit neutrophils and thereby induce acute inflammation. These findings demonstrate that NALP3 performs key upstream functions in inflammasome activation in mouse macrophages engulfing dying autophagic cells, and that these functions lead to pro-inflammatory responses.     

Recognition of Apoptotic Cells by Epithelial Cells: CONSERVED VERSUS TISSUE-SPECIFIC SIGNALING RESPONSES*

During apoptosis, cells acquire new activities that enable them to modulate the fate and function of interacting phagocytes, particularly macrophages (mϕ). Although the best known of these activities is anti-inflammatory, apoptotic targets also influence mϕ survival and proliferation by modulating proximal signaling events, such as MAPK modules and Akt. We asked whether modulation of these same signaling events extends to epithelial cells, a minimally phagocytic cell type. We used BU.MPT cells, a mouse kidney epithelial cell line, as our primary model, but we also evaluated several epithelial cell lines of distinct tissue origins. Like mϕ, mouse kidney epithelial cells recognized apoptotic and necrotic targets through distinct non-competing receptors, albeit with lower binding capacity and markedly reduced phagocytosis. Also, modulation of inflammatory activity and MAPK-dependent signaling by apoptotic and necrotic targets was indistinguishable in kidney epithelial cells and mϕ. In contrast, modulation of Akt-dependent signaling differed dramatically between kidney epithelial cells and mϕ. In kidney epithelial cells, modulation of Akt was linked to target cell recognition, independently of phagocytosis, whereas in mϕ, modulation was linked to phagocytosis. Moreover, recognition of apoptotic and necrotic targets by kidney epithelial cells elicited opposite responses; apoptotic targets inhibited whereas necrotic targets stimulated Akt activity. These data confirm that nonprofessional phagocytes recognize and respond to dying cells, albeit in a manner partially distinct from mϕ. By acting as sentinels of environmental change, apoptotic and necrotic targets may permit neighboring viable cells, especially non-migratory epithelial cells, to monitor and adapt to local stresses.     

Properdin binds to late apoptotic and necrotic cells independently of C3b and regulates alternative pathway complement activation

Cells that undergo apoptosis or necrosis are promptly removed by phagocytes. Soluble opsonins such as complement can opsonize dying cells, thereby promoting their removal by phagocytes and modulating the immune response. The pivotal role of the complement system in the handling of dying cells has been demonstrated for the classical pathway (via C1q) and lectin pathway (via mannose-binding lectin and ficolin). Herein we report that the only known naturally occurring positive regulator of complement, properdin, binds predominantly to late apoptotic and necrotic cells, but not to early apoptotic cells. This binding occurs independently of C3b, which is additional to the standard model wherein properdin binds to preexisting clusters of C3b on targets and stabilizes the convertase C3bBb. By binding to late apoptotic or necrotic cells, properdin serves as a focal point for local amplification of alternative pathway complement activation. Furthermore, properdin exhibits a strong interaction with DNA that is exposed on the late stage of dying cells. Our data indicate that direct recognition of dying cells by properdin is essential to drive alternative pathway complement activation.     

Effect of trypsinization on lectin binding to germ cells from ICR and T/t6 mice

Flow cytometry was used to quantify the binding of fluorescein isothiocyanate (FITC)-labeled lectins to testis cells from ICR and T/t6 mice before and after trypsin treatment. Soybean agglutinin, wheat germ agglutinin, and concanavalin A bound well to testis cells of both mouse strains. Limax flavus agglutinin (LFA) bound very slightly and Ulex europeas agglutinin (UEA) did not bind at all. Trypsinization increased binding of soybean agglutinin and decreased binding of wheat germ agglutinin in both mouse strains, providing evidence for masked carbohydrate-binding sites on the surface of germ cells. It did not affect binding of the other lectins. Trypsin treatment was an attempt to increase lectin binding, particularly the binding of LFA and UEA to the reported T/t-specific carbohydrates, sialic acid, and L-fucose, respectively. These studies indicate that the T/t6 locus alleles do not alter the surface carbohydrate content of testis cells sufficiently to be detected by lectin-binding differences.     

Lectin binding to rat spermatogenic cells: Effects of different fixation methods and proteolytic enzyme treatment

Summary The binding of a panel of eight different fluorescein-conjugated lectins to rat spermatogenic cells was investigated. Particular attention was paid to the effects of different fixation methods and proteolytic enzyme digestion on the staining pattern.Concanavalin A (Con A), wheatgerm agglutinin (WGA), succinylated WGA (s-WGA) and agglutinin from gorse (UEA I) stained the cytoplasm of most germ cells as well as the spermatid acrosome. In contrast, peanut agglutinin (PNA), castor bean agglutinin (RCAI) and soy bean agglutinin (SBA) mainly stained the acrosome. The staining pattern varied depending on the fixation method used. PNA was particularly sensitive to formalin fixation, while SBA, DBA and UEA I showed decreased binding and Con A, WGA, s-WGA and RCA I were insensitive to this type of fixation. Pepsin treatment of the sections before lectin staining caused marked changes in the staining pattern; staining with PNA in formalin-fixed tissue sections was particularly improved but there was also enhanced staining with SBA and horse gram agglutinin (DBA). On the other hand, in Bouin- and particularly in acetone-fixed tissue sections, pepsin treatment decreased the staining with several of the lectins, for example WGA and UEA I.     

After shrinkage apoptotic cells expose internal membrane-derived epitopes on their plasma membranes

Apoptosis and phagocytosis of apoptotic cells are crucial processes. At best the phagocytic machinery detects and swallows all apoptotic cells in a way that progression to secondary necrosis is avoided. Otherwise, inflammation and autoimmune diseases may occur. Most apoptotic cells are phagocytosed instantaneously in a silent fashion; however, some dying cells escape their clearance. If the cells are not cleared early, they lose membranes due to extensive shedding of membrane surrounded vesicles (blebbing) and shrink. It is unclear how apoptotic cells compensate their massive loss of plasma membrane. Here, we demonstrate that endoplasmic reticulum- (ER) resident proteins (calnexin, the KDEL receptor and a dysfunctional immunoglobulin heavy chain) were exposed at the surfaces of shrunken late apoptotic cells. Additionally, these cells showed an increased binding of lectins, which recognize sugar structures predominantly found as moieties of incompletely processed proteins in ER and Golgi. In addition the ER resident lipophilic ER-Tracker Blue-White DPX, and internal GM1 were observed to translocate to the cell surfaces during late apoptosis. We conclude that during blebbing of apoptotic cells the surface membrane loss is substituted by immature membranes from internal stores. This mechanism explains the simultaneous appearance of preformed recognition structures for several adaptor proteins known to be involved in clearance of dead cells.