Abstract
Phagosomes mature by sequentially fusing with endosomes and lysosomes. Vesicle budding is presumed to occur concomitantly, mediating the retrieval of plasmalemmal components and the regulation of phagosomal size. We analyzed whether fission of vesicles from phagosomes requires COPI, a multimeric complex known to be involved in budding from the Golgi and endosomes. The role of COPI was studied using ldlF cells, that harbor a temperature-sensitive mutation in epsilon-COP, a subunit of the coatomer complex. These cells were made phagocytic toward IgG-opsonized particles by heterologous expression of human FcgammaRIIA receptors. Following incubation at the restrictive temperature, epsilon-COP was degraded in these cells and their Golgi complex dispersed. Nevertheless, phagocytosis persisted for hours in cells devoid of epsilon-COP. Retrieval of transferrin receptors from phagosomes became inefficient in the absence of epsilon-COP, while clearance of the FcgammaRIIA receptors was unaffected. This indicates that fission of vesicles from the phagosomal membrane involves at least two mechanisms, one of which requires intact COPI. Traffic of fluid-phase markers and aggregated IgG-receptor complexes along the endocytic pathway was abnormal in epsilon-COP-deficient cells. In contrast, phagosome fusion with endosomes and lysosomes was unimpaired. Moreover, the resulting phagolysosomes were highly acidic. Similar results were obtained in RAW264.7 macrophages treated with brefeldin A, which precludes COPI assembly by interfering with the activation of adenosine ribosylation factor. These data indicate that neither phagosome formation nor maturation are absolutely dependent on COPI. Our findings imply that phagosomal maturation differs from endosomal progression, which appears to be more dependent on COPI-mediated formation of carrier vesicles.
Highlights
LdlF Cells Expressing the Human Fc␥RIIA Receptor Are Phagocytic—The interaction of -COP and adenosine ribosylation factor (ARF) with phagosomal membranes in vitro [6] and the role played by COPI in the progression of the endocytic pathway [30, 33, 35, 53] were suggestive of a role of COPI in vesicular budding during phagosome maturation
We used two different approaches to analyze the involvement of COPI in phagosomal maturation: (i) inhibition of ARF nucleotide exchange factors using brefeldin A in the professional phagocyte cell line RAW264.7 and (ii) elimination of ⑀-COP in the temperature-sensitive mutant ldlF cells
Phagocytosis of red blood cells (RBC) by ldlF cells was strictly dependent on opsonization of the particles with IgG and occurred only in cells transfected with Fc␥RIIA receptors
Summary
Retrieval of transferrin receptors from phagosomes became inefficient in the absence of ⑀-COP, while clearance of the Fc␥RIIA receptors was unaffected This indicates that fission of vesicles from the phagosomal membrane involves at least two mechanisms, one of which requires intact COPI. Phagocytosis plays a key role in the host immune defense by sequestering invading microorganisms within vacuoles formed by invagination of the plasma membrane of neutrophils and macrophages [1,2,3] Such vacuoles, known as phagosomes, undergo sequential fusion with early and late endosomes and. Despite the importance of vesicular budding in the salvage of plasmalemmal components, antigen presentation and the maintenance of phagosomal size, little is known about the underlying mechanisms In other organelles, such as the Golgi complex, several fission systems have been characterized, including the clathrin, COPI, and COPII complexes. A similar conclusion was reached using the ldlF Chinese hamster ovary (CHO) cell line, which have a temperature-sensitive mutation in ⑀-COP, a subunit of
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