Summary When wounded, eukaryotic cells reseal in a few seconds. Ca2+ influx induces exocytosis of lysosomes, a process previously thought to promote repair by “patching” wounds. New evidence suggests that resealing involves direct wound removal. Exocytosis of lysosomal acid sphingomyelinase triggers endocytosis of lesions, followed by intracellular degradation. Characterization of injury-induced endosomes revealed a role for caveolae, sphingolipid-enriched plasma membrane invaginations that internalize toxin pores and are abundant in mechanically stressed cells. These findings provide a novel mechanistic explanation for the muscle pathology associated with mutations in caveolar proteins. Membrane remodeling by the ESCRT complex was also recently shown to participate in small wound repair, emphasizing that cell resealing involves previously unrecognized mechanisms for lesion removal, which are distinct from the “patch” model.
Rapid repair of plasma membrane wounds is critical for cellular survival. Muscle fibers are particularly susceptible to injury, and defective sarcolemma resealing causes muscular dystrophy. Caveolae accumulate in dystrophic muscle fibers and caveolin and cavin mutations cause muscle pathology, but the underlying mechanism is unknown. Here we show that muscle fibers and other cell types repair membrane wounds by a mechanism involving Ca2+-triggered exocytosis of lysosomes, release of acid sphingomyelinase, and rapid lesion removal by caveolar endocytosis. Wounding or exposure to sphingomyelinase triggered endocytosis and intracellular accumulation of caveolar vesicles, which gradually merged into larger compartments. The pore-forming toxin SLO was directly visualized entering cells within caveolar vesicles, and depletion of caveolin inhibited plasma membrane resealing. Our findings directly link lesion removal by caveolar endocytosis to the maintenance of plasma membrane and muscle fiber integrity, providing a mechanistic explanation for the muscle pathology associated with mutations in caveolae proteins.DOI: http://dx.doi.org/10.7554/eLife.00926.001
Tissue wound repair has been studied extensively. It involves the coordinated activation of several intracellular and intercellular pathways, as well as remodeling from the sequential recruitment of different cell types to the wound site. There is, however, an equally important process that happens at the single cell level, when the integrity of the plasma membrane is compromised. Individual eukaryotic cells can rapidly repair their plasma membrane after injury, through a process that restores internal homeostasis and prevents cell death. Despite its importance, investigations of this fascinating mechanism have been limited. Only recently have we begun to understand that plasma-membrane repair resembles tissue healing, in the sense that it also involves sequential, highly localized remodeling steps that ultimately eliminate all traces of the injury.
Phospholipase D (PLD) produces phosphatidic acid (PA), an established intracellular signalling lipid that has been also implicated in vesicular trafficking, and as such, PLD could play multiple roles during phagocytosis. Using an RNA interference strategy, we show that endogenous PLD1 and PLD2 are necessary for efficient phagocytosis in murine macrophages, in line with results obtained with wild-type constructs and catalytically inactive PLD mutants which, respectively, enhance and inhibit phagocytosis. Furthermore, we found that PA is transiently produced at sites of phagosome formation. Macrophage PLD1 and PLD2 differ in their subcellular distributions. PLD1 is associated with cytoplasmic vesicles, identified as a late endosomal/lysosomal compartment, whereas PLD2 localizes at the plasma membrane. In living cells undergoing phagocytosis, PLD1 vesicles are recruited to nascent and internalized phagosomes, whereas PLD2 is only observed on nascent phagosomes. These results provide evidence that both PLD isoforms are required for phagosome formation, but only PLD1 seems to be implicated in later stages of phagocytosis occurring after phagosomal internalization. Phagocytosis is an essential process of the innate immune response, enabling immune cells, such as macrophages, to eliminate large extracellular particles, invasive pathogens, cellular debris and apoptotic cells, by internalizing them in membrane-bound vacuoles, the phagosomes [reviewed in (1,2)]. Binding of the particle to diverse cell-surface receptors triggers phagocytosis. Certain phagocytic receptors recognize particle ligands, for example mannose and phosphatidylserine residues, whereas opsonin receptors, like the Fc receptors and complement receptors bind, respectively, the constant domain of immunoglobulins and complement proteins that coat particles. Clustering of phagocytic receptors activates complex intracellular signalling networks that have been extensively studied in the case of the Fc receptor [reviewed by (3)], and this initiates the extension of pseudopods which engulf the particle. Following internalization, phagosomes mature into phagolysosomes where the ingested material is degraded or processed for antigen presentation.During phagosome formation, pseudopod extension around the particle is driven by transient localized actin polymerization (4,5). This surface expansion also requires focal exocytosis of endomembranes, as demonstrated by capacitance and spectroscopic measurements (6,7). Hence, phagosome formation, as well as maturation, involves membrane trafficking between multiple intracellular membrane compartments [reviewed by (2)]. Classical actors of the exocytotic process such as the SNARE complex proteins (8) and specific phospholipids (9,10) participate in these trafficking events, although details of how these elements are interlinked to ensure an efficient machinery for phagocytosis remain to be established.Phospholipase D (PLD) has been recently described as a critical factor for exocytosis in neurons (11) and endocrine cells ...
Cells permeabilized by the bacterial pore-forming toxin streptolysin O (SLO) reseal their plasma membrane in a Ca2+-dependent manner. Resealing involves Ca2+-dependent exocytosis of lysosomes, release of acid sphingomyelinase and rapid formation of endosomes that carry the transmembrane pores into the cell. The intracellular fate of the toxin-carrying endocytic vesicles, however, is still unknown. Here, we show that SLO pores removed from the plasma membrane by endocytosis are sorted into the lumen of lysosomes, where they are degraded. SLO-permeabilized cells contain elevated numbers of total endosomes, which increase gradually in size while transitioning from endosomes with flat clathrin coats to large multivesicular bodies (MVBs). Under conditions that allow endocytosis and plasma membrane repair, SLO is rapidly ubiquitinated and gradually degraded, in a process sensitive to inhibitors of lysosomal hydrolysis but not of proteasomes. The endosomes induced by SLO permeabilization become increasingly acidified and promote SLO degradation under normal conditions, but not in cells silenced for expression of Vps24, an ESCRT-III complex component required for the release of intraluminal vesicles into MVBs. Thus, cells dispose of SLO transmembrane pores by ubiquitination/ESCRT-dependent sorting into the lumen of late endosomes/lysosomes.
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