Apoptotic cell clearance facilitates the removal of aged, damaged, infected or dangerous cells although minimizing perturbation of surrounding tissues, and is a vital process in the development and homeostasis of multicellular organisms. Importantly, failure to correctly execute programmed cell death and subsequent corpse clearance is broadly associated with chronic inflammatory and/or autoimmune diseases such as systemic lupus erythematosus. Apoptotic cells develop dramatic morphological changes including contraction, membrane blebbing and apoptotic body formation, which were among the first and most readily identifiable features of cellular suicide. However, understanding the purpose of apoptotic cell morphological changes has proven to be elusive, and recent studies have made somewhat surprising, and occasionally opposing, conclusions about the contribution of blebbing to phagocytic clearance and prevention of inflammatory/autoimmune disease. We review the evidence indicating how apoptotic blebs actively promote corpse recognition, uptake, and generation of auto-reactive antibodies.
Actomyosin contraction provides the force-driving contraction, membrane blebbing and apoptotic body formation during programmed cell death.
Apoptotic cells display cell surface markers that facilitate recognition and uptake by phagocytic cells.
Impaired apoptotic cell clearance may contribute to inflammation and autoimmunity.
How are apoptotic cell surface markers concentrated on blebs?
How do markers such as calreticulin and N-acetylglucosamine come to be displayed on the surface of apoptotic cells?
What is the role of blebbing in the recognition and clearance of apoptotic cells?
Actomyosin Contraction Drives Apoptotic Blebbing
Apoptotic cells can often be discriminated from viable counterparts based on several morphological hallmarks including highly conspicuous nuclear condensation and fragmentation, and frequent appearance of characteristic plasma membrane blebs (Figure 1a). Blebs are balloon-like protrusive blisters formed when cellular plasma membrane delaminates from the cortical cytoskeleton, and which can be retracted and reformed in a dynamic cycling process covering the entire surface of apoptotic cells. The formation of apoptotic blebs is a physical process that results from increased hydrostatic pressure following actomyosin-mediated cellular contraction.1, 2 When newly formed, blebs are devoid of actin and other cytoskeletal proteins. Subsequently, an actin cortex rapidly polymerizes within the protruding bleb, followed by the recruitment of cytoskeletal bundling proteins and myosin that then power bleb retraction.3 In apoptotic cells this cyclic process of bleb formation and retraction can occur over sustained periods, and as programmed cell death progresses blebs may become packed with cellular organelles and condensed chromatin to form the basis of fragmentary membrane-clad apoptotic bodies (Figure 1a).4 However, it should be noted that apoptotic blebbing is not a universal feature of programmed cell death, some cell types do not appear to generate membrane blebs nor undergo fragmentation.5 Nonetheless, blebbing is a very common feature of apoptotic cells and has become a morphological hallmark of programmed cell death.
In 2001, it was discovered that apoptotic blebbing is dependent upon activity of the actomyosin regulator ROCK1 kinase.6, 7 Moreover, it was apparent that apoptotic ROCK1 activation is independent of its canonical activator Rho GTPase. This atypical form of ROCK activation was associated with caspase cleavage of ROCK1, but not ROCK2, after a conserved site within the C-terminus (1110DETD1113)6 (Figure 1b). Further investigation revealed that caspase cleavage of ROCK1 yields a constitutively active kinase fragment that is sufficient to induce membrane blebbing resembling that seen in apoptotic cells. In addition, the cleaved ROCK1 fragment appears to be important for disruption of nuclear integrity and the packaging of fragmented DNA into membrane blebs and apoptotic bodies.4, 6 Thus, the generation of constitutively active ROCK1 kinase fragments appears to be an important mechanism to complete the execution phase of cellular apoptosis. When cell death has been triggered by extrinsic factors such as TNFα, ceramide or Fas-receptor ligation, ROCK1 cleavage and activation are relatively late events,6, 7 consequently ROCK inhibition does not halt the apoptotic process.6 However, in some contexts chronic or high-intensity ROCK activity may contribute to the initiation of apoptosis. Data from ROCK1 knockout mice revealed that blood pressure overload was less effective at inducing cardiomyocyte apoptosis compared with control wild-type mice, suggesting a potential role for ROCK1 activation in myocardial failure.8 Although ROCK1 cleavage and activation is associated with the formation of apoptotic blebs, and ROCK activity is necessary for blebbing, formal proof of the absolute requirement for ROCK1 cleavage as the causal event leading to apoptotic blebbing remains to be provided. Although ROCK2 is not cleaved by caspases and is therefore unlikely to be involved in apoptotic blebbing induced by conventional intrinsic and extrinsic stimuli, it can be cleaved by granzyme B,9 a serine protease injected into target cells by cytotoxic T-cells and natural killer cells to induce cell death by mitochondrial disruption and caspase 3 cleavage and activation.10 Interestingly, granzyme B cleaves ROCK2 analogously to caspase 3 cleavage of ROCK1; ROCK2 cleavage after D1131 releases the C-terminal autoinhibitory domain leading to constitutive kinase domain activation capable of inducing membrane blebs.9 Due to the activation of caspase 3 during granzyme B-induced apoptosis, ROCK1 cleavage also occurs, thus the relative contribution of ROCK2 cleavage towards the formation of apoptotic blebs remains unclear. Furthermore, as ROCK2 is not cleaved during apoptosis induced by conventional signals, the post-translational modification that produces constitutively active ROCK2 appears not to be generally required for apoptotic blebbing.
Although ROCK1 cleavage is apparently vital for blebbing, it seems dispensable for many other apoptotic phenomena including caspase activation, phosphatidylserine (PS) externalization, and poly ADP-ribose polymerase cleavage.6, 7, 11 This leaves open the question of precisely what the purpose of ROCK1 cleavage, and by extension membrane blebbing, in apoptosis might be.
Apoptotic Cell Recognition
Programmed cell death, or apoptosis, is vital for the removal of problematic or unnecessary cells in multicellular organisms.12, 13 First defined in 1972,14 apoptosis is an active process that ultimately concludes with the final act of cellular disposal in which phagocytic cells ingest cellular corpses and associated debris, a process termed efferocytosis. As a testament to the efficiency and rapidity of efferocytosis, it is surprisingly difficult to histologically detect apoptotic cells despite >109 cellular suicides occurring per day in adult tissues.15, 16 There are several broadly defined phases of phagocytic clearance of apoptotic cells: (1) Find-me, characterized by the release of soluble signals that attract macrophages to the dying cell; (2) Eat-me, in which a phagocyte becomes stimulated by engaging with signals expressed on the apoptotic cell membrane; (3) Engulfment, a series of cytoskeletal modifications in the phagocyte enabling it to take up the dead cell; (4) Processing, digestion of the cellular remains through lysosomal degradation.17, 18, 19
Importantly, apoptotic cells actively participate in the initial phases by displaying significant modifications to their membranes (which can include lipids, proteins and modified carbohydrates) that are important aids to recognition and uptake. The best characterized of these externalized factors is PS, which is normally confined to the inner leaflet of the plasma membrane.20 During early apoptosis membrane asymmetry is lost; PS becomes externalized and serves as a major factor for apoptotic cell recognition (Figure 2a). A protein that mediates PS externalization was recently identified as the eight transmembrane spanning Transmembrane Protein 16F (TMEM16F).21 Externalized PS can be bound by milk fat globule epidermal growth factor 8 (MFG-E8), which tethers the phospolipid to integrin αvβ3 and/or αvβ5 expressed on macrophages and monocytes (Figure 2a).22 Alternatively, PS can be recognized directly by one or more receptors expressed on macrophages, including; Bai1, Tim5, and Stabilin2 (Figure 2).12 PS externalization has also been detected on viable cells in some instances, suggesting that PS exposure alone may be insufficient to trigger phagocytosis and that additional signals are necessary.23, 24 In fact, enforced PS externalization induced by expression of active TMEM16F did not induce engulfment by macrophages in vitro or by dendritic cells (DCs) in vivo.21 Therefore, it has been proposed that the ‘Eat-me’ signal received by phagocytes must be above a threshold level to initiate efferocytosis.25 The strength of such a signal could be augmented by the binding of additional ‘Eat-me’ molecules, such as MFG-E8.11 Alternatively, spatial concentration of PS or other ‘Eat-me’ molecules on apoptotic cell membranes may also serve as phagocytic triggers that focally surpass the required threshold (discussed below).25 In addition to PS externalization, apoptotic cells have further modifications to their membrane constituents. The release and dissociation of sub-cellular membrane clad particles called apoptotic bodies results in bulk membrane loss that must be replaced from intracellular organelles such as the Golgi or endoplasmic reticulum.26 This scavenging of intracellular membranes leads to the externalization of protein and glycan groups, including calreticulin and N-acetylglucosamine (GlcNAc), that are normally expressed only on intracellular membranes and which appear to be important for efferocytosis (Figure 2a).27, 28 Externalization of GlcNAc is recognized as a determinant of apoptotic thymocyte phagocytosis while calreticulin binds complement C1q and aids phagocytosis of apoptotic cells (Figure 2a).27, 29, 30 Moreover, many of the externalized proteins are modified by cleavage, likely by activated caspases, which might easily affect their function and/or recognition.31 The atypical externalization of intracellular material contributes to apoptotic cell-associated molecular patterns (ACAMP), which either alone or in conjunction with plasma proteins such as MFG-E8, complement C1q, mannose-binding lectin and surfactant protein A are then recognized by macrophages to promote clearance.25, 29, 32, 33 The binding of a macrophage to a target apoptotic cell creates an engulfment synapse and the diverse molecular interactions between ACAMP and macrophages initiate important phases of efferocytosis, such as binding and engulfment.34, 35, 36
Apoptotic Blebbing: promoting Cell Clearance?
A number of studies have attempted to define the role of blebbing in apoptotic clearance and revealed some potentially contradictory roles for blebs and apoptotic bodies. Several in vitro studies reported that inhibition of apoptotic blebbing significantly impaired corpse clearance by monocytes and macrophages.5, 11, 28 Further investigation revealed that impaired corpse clearance following defective blebbing could be rescued by the PS-bridging protein, MFG-E8.11 The implications of these studies are two-fold: firstly, apoptotic blebbing directly influences efferocytosis; and secondly, PS externalization may be a mechanism linking blebbing and phagocytosis. Although the apoptotic externalization of PS appears to be ROCK-independent, its sub-cellular localization is ROCK-dependent.6, 11 In fact, microscopic analysis revealed that apoptotic blebs become highly enriched for the externalized phospholipids.37 Thus, it appears that apoptotic blebs serve as focal points for accumulation of externalized PS, which is then recognized by macrophages to trigger engulfment. The possibility that apoptotic blebs provide topological context for macrophage recognition is consistent with data demonstrating PS exposure on viable cells is insufficient to trigger phagocytosis. Surprisingly, MFG-E8 failed to further enhance the in vitro phagocytic uptake of normal blebbing apoptotic cells,11 suggesting that apoptotic blebbing and subsequent PS concentration on blebs is sufficient to trigger corpse clearance in the absence of additional extracellular factors. When blebbing is impaired, efferocytosis can be rescued by bridging molecules like MFG-E8; thus there appears to be redundancy in clearance mechanisms. Such redundant compensating mechanisms may explain why several genetically modified mice with defective clearance mechanisms are neither developmentally lethal nor display severe auto-immune phenotypes (if displayed at all), as measured by survival and overall health. In addition to serving as organizational centers for PS externalization, apoptotic blebs are associated with additional membrane modifications. One of the most striking examples highlighting the potential importance of apoptotic blebs is their robust opsonization with complement C1q in human endothelial cells (Figure 2b).38, 39 The high-density opsonization on the surface of apoptotic blebs would be expected to efficiently trigger efferocytosis by activating specific complement receptors such as CD91 expressed by macrophages.29, 40, 41 Although the binding of C1q to apoptotic cells appears to be important for recognition and clearance, clearance is not dependent on further activation of the complement cascade.42 The importance of this mechanism for triggering clearance is underscored by the autoimmune disorders observed in C1q-deficient mice.43 Thus, ROCK-mediated actomyosin contraction, consequent membrane blebbing and focalized accumulation of ‘Eat-me’ factors might be expected to facilitate rapid efferocytosis and thus maintain self-tolerance.
Apoptosis, Clearance and Autoimmunity
The execution phase of apoptosis and subsequent corpse clearance convey powerful anti-inflammatory signals to engulfing cells and, importantly, enable apoptotic cells to remain immunologically silent.44, 45, 46 Furthermore, apoptotic cell engulfment helps induce a tolerogenic response and facilitates proteins to be appropriately recognized as ‘self’, thus avoiding activation of adaptive immunity towards apoptotic material.47 Collectively, the combination of rapid apoptotic cell clearance linked to suppression of immune activation allows apoptosis to proceed rapidly and efficiently with minimal collateral damage to maintain tissue homeostasis. One of the key features of apoptotic cells that allows for the rapid and stealthy removal of cellular fragments is a stable intact membrane (detectable by the exclusion of impermeable dyes such as propidium iodide) that prevents release of intracellular proteins and consequent immunological activation.48 This is in contrast to necrotic cell death, wherein cells inappropriately lyse and release their intracellular contents leading to rapid pro-inflammatory responses.45, 49 Secondarily necrotic cells release ‘alarmins’, of which high-mobility group protein B1 (HMGB1) is the archetype, that are recognized as danger signals and provoke innate immune cells into a pro-inflammatory state (Figure 3).50 For this reason, defects in efferocytosis are believed to cause inappropriate pathological inflammation leading to the development of autoimmune diseases. Indeed, genetically modified mouse models in which genes for vital elements of cell recognition and clearance machinery such as compliment C1q or MFG-E8 have been deleted display an autoimmune phenotype resembling systemic lupus erythematosus (SLE). SLE is a chronic systemic autoimmune disease that affects multiple organ systems including joints, skin, lymph and kidneys in nearly 5 million people globally, 90% of whom are female.51 The disease is characterized by the generation of auto-reactive antibodies (particularly against nuclear antigens), the formation of antibody immune complexes and pro-inflammatory cytokine production.52, 53 Animal models with defective efferocytosis develop a similar age- and sex-dependent pathology as seen in human sufferers, associated with the presence of anti-nuclear antibodies (ANA), splenomegaly and glomerulonephritis.43, 54 Although the pathophysiology of SLE is multifactorial, the best-defined abnormality associated with the disease is defective apoptotic cell clearance. Not only are macrophages from SLE patients deficient in autologous efferocytosis in vitro, but the number of tingible body macrophages that are responsible for the ingestion of apoptotic corpses in lymphoid tissue germinal centers are frequently reduced in SLE sufferers.55, 56 Consistent with these observations, SLE is associated with elevated circulating apoptotic bodies and an accumulation of apoptotic cells in lymph node germinal centers.57, 58 Furthermore, compliment C1q deficiency, which is associated with increased undigested apoptotic debris, is a potent trigger for SLE.59 The increase in free uningested apoptotic debris likely contributes to the induction of ANAs, which is a classic diagnostic feature of SLE. Overcoming self-tolerance is a pathological process closely associated with failed efferocytosis that results in immune activation towards intracellular material, including nuclear proteins and DNA. Supporting this possibility, SLE-associated ANAs can be specific for novel epitopes produced only after enzymatic modifications such as caspase-mediated cleavage.60 Furthermore, these autoreactive antibodies are somatically mutated IgG isotypes suggesting that they are products of B-cell affinity maturation and thus the result of an antigen-driven immune response.61, 62
The generation of self-reactive antibodies appears to be linked to phagocytosis of apoptotic debris by professional antigen-presenting DCs.63 DC are potent stimulators of adaptive immune responses and in an inflammatory context present peptides generated from apoptotic proteins and potently stimulate immune responses consistent with the generation of self-reactive antibodies (Figure 3).64 In fact, the ingestion of secondarily necrotic apoptotic bodies by DC is vital for their maturation leading to expression of co-stimulatory molecules necessary for adaptive immunity.64 These features of DC make them likely candidates to mediate auto-antibody generation following phagocytosis of apoptotic debris accumulated due to failed efferocytosis and further suggests that additional signals associated with secondary necrosis, such as HMGB1 release, are important components in the development of autoimmunity.65, 66 Moreover, the ingestion of apoptotic bodies by DC can stimulate the release of pro-inflammatory cytokines, such as interleukin-6 (IL-6), thereby inducing auto- and paracrine signaling loops favoring the generation of auto-reactive antibodies.64, 67, 68, 69 Once an auto-reactive antibody is produced, it would be expected to opsonize apoptotic cells and potentially encourage inappropriate inflammatory responses leading to the development of auto-immune/inflammatory diseases such as SLE (Figure 3).70 Although auto-immune diseases resulting from failed efferocytosis are clearly multifactorial, apoptotic blebbing appears to lie at foundational stages of disease onset.
Although apoptotic blebs certainly accumulate a collection of important ‘Eat-me’ factors such as PS and C1q, they also appear to be rich in auto-antigens frequently associated with autoimmune disorders such as SLE. In particular, apoptotic blebs and discrete apoptotic bodies display many nuclear auto-antigens such as DNA, nucleosomes, Ro and La (Figure 4).25, 26, 71, 72 The implication of these observations is that blebs and apoptotic bodies are reservoirs of antigens that may contribute to the generation of auto-immune disease.63 As previously mentioned, self-tolerance can be challenged by DC uptake of apoptotic cells. Apoptotic blebbing appears to participate in this process as DC prefer smaller apoptotic body-sized cell remnants that are rich in potential auto-antigens. Furthermore, the ingestion of this material can stimulate production of the pro-inflammatory cytokine IL-6 and induce DC maturation.64, 68 The uptake of antigen-rich apoptotic bodies by DC coupled with the subsequent release of inflammatory mediators and cellular maturation appears to drive adaptive immunity leading to auto-immunity (Figure 4).64 Because of these observations, inhibition of apoptotic blebbing has been proposed as a potential therapy to avoid or attenuate auto-immune disease severity.70 In fact, inhibition of blebbing with the ROCK selective inhibitor Y27632 not only impaired DC phagocytosis of apoptotic bodies but completely abolished enhanced uptake following auto-antibody opsonization.70
These observations underscore the importance of apoptotic cell clearance in the maintenance of self-tolerance. However, it is important to note that apoptotic clearance failure in itself may be insufficient to promote auto-immune disease; in fact, mannose-binding lectin-deficient mice have demonstrated apoptotic clearance defects without autoimmunity.73 This suggests that determinants, in addition to clearance, participate in the immunological processing of apoptotic cell debris. It has been proposed that immunosuppressive transforming growth factor β (TGF-β) release stimulated by binding of apoptotic cells to macrophages may be sufficient to avoid potentially problematic auto-antibody generation, even in the absence of clearance.16 Nonetheless, defective cell clearance, resulting from impairment or elimination of the myriad components of efferocytosis, is undoubtedly linked to autoimmune disease as well as several other disorders in human and mice including atherosclerosis, neuropathy, arthritis, and anemia.12, 74
Collectively, these studies indicate that apoptotic blebbing, as a mechanism to promote cell clearance, is a double-edged sword. Although blebs appear to be important for rapid uptake and clearance to maintain homeostasis, simultaneously they also are sources of auto-antigens (Figure 4). It appears that the same material recognized by macrophages to trigger clearance may also be recognized by other cell types, such as DCs, to generate auto-immune antibodies. The mechanisms that may lead to these opposing outcomes is currently unclear; however, defects in macrophage uptake or increases in apoptosis appear to be important determinants. Hypothetically, the accumulation of apoptotic debris would likely lead to increased probability of DC activation and, over time, this inappropriate activation would overcome self-tolerance and lead to the generation of auto-reactive antibodies characteristic of autoimmunity. Although the linkage between apoptotic blebbing and autoimmune disease has been inferred, there has been no definitive demonstration of the importance of apoptotic blebbing in vivo. To date, studies investigating apoptotic blebbing in the context of clearance and auto-immune disease have been largely limited to in vitro experimentation that cannot recapitulate the complexity of interactions between apoptotic cells and their environment. Furthermore, these studies may also be compromised by certain aspects of their experimental design that could affect outcomes in subsequent assays, such as their dependence on chemical inhibitors to interfere with apoptotic blebbing, and extensive washing steps that might alter the stability and structure of the apoptotic cells. As a result, many of the observations from in vitro studies regarding the possible influence of blebbing towards apoptotic cell clearance and consequently on the development of autoimmune disease are potentially compromised. Ultimately clear determination of the role that apoptotic blebs have in cell clearance and/or the generation of autoimmune disease will require an in vivo model of defective blebbing.
apoptotic cell-associated molecular pattern
high-mobility group protein B1
milk fat globule epidermal growth factor 8
systemic lupus erythematosus
transforming growth factor β
Transmembrane protein 16F
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Work in the Molecular Cell Biology laboratory of the Beatson Institute for Cancer Research is supported by Cancer Research UK.
The authors declare no conflict of interest.
Edited by G Melino
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Wickman, G., Julian, L. & Olson, M. How apoptotic cells aid in the removal of their own cold dead bodies. Cell Death Differ 19, 735–742 (2012). https://doi.org/10.1038/cdd.2012.25
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