Sophie Duclos

Endoplasmic Reticulum-Mediated Phagocytosis Is a Mechanism of Entry into Macrophages

Phagocytosis is a key aspect of our innate ability to fight infectious diseases. In this study, we have found that fusion of the endoplasmic reticulum (ER) with the macrophage plasmalemma, underneath phagocytic cups, is a source of membrane for phagosome formation in macrophages. Successive waves of ER become associated with maturing phagosomes during phagolysosome biogenesis. Thus, the ER appears to possess unexpectedly pluripotent fusion properties. ER-mediated phagocytosis is regulated in part by phosphatidylinositol 3-kinase and used for the internalization of inert particles and intracellular pathogens, regardless of their final trafficking in the host. In neutrophils, where pathogens are rapidly killed, the ER is not used as a major source of membrane for phagocytosis. We propose that intracellular pathogens have evolved to adapt and exploit ER-mediated phagocytosis to avoid destruction in host cells.

Flotillin-1-enriched lipid raft domains accumulate on maturing phagosomes.

Flotillin-1 was recently shown to be enriched on detergent-resistant domains of the plasma membrane called lipid rafts. These rafts, enriched in sphingolipids and cholesterol, sequester certain proteins while excluding others. Lipid rafts have been implicated in numerous cellular processes including signal transduction, membrane trafficking, and molecular sorting. In this study, we demonstrate both morphologically and biochemically that lipid rafts are present on phagosomes. These structures are enriched in flotillin-1 and devoid of the main phagosomes membrane protein lysosomal-associated membrane protein (LAMP1). The flotillin-1 present on phagosomes does not originate from the plasma membrane during phagocytosis but accumulates gradually on maturing phagosomes. Treatment with bafilomycin A1, a compound that inhibits the proton pump ATPase and prevents the fusion of phagosomes with late endocytic organelles, prevents the acquisition of flotillin-1 by phagosomes, indicating that this protein might be recruited on phagosomes from endosomal organelles. A proteomic characterization of the lipid rafts of phagosomes indicates that actin, the α- and β-subunits of heterotrimeric G proteins, as well as subunits of the proton pump V-ATPase are among the constituents of these domains. Remarkably, the intracellular parasite Leishmania donovani can actively inhibit the acquisition of flotillin-1-enriched lipid rafts by phagosomes and the maturation of these organelles. These results indicate that specialized functions required for phagolysosome biogenesis may occur at focal points on the phagosome membrane, and therefore represent a potential target of intracellular pathogens.

Subversion of a young phagosome: the survival strategies of intracellular pathogens

Infection by intracellular pathogens remains a major cause of human diseases and death worldwide. The emergence of various resistant microbe strains associated to the problem of multidrug resistance emphasizes the urgency of finding new approaches to fight intracellular pathogens. Despite the severity of this health problem, it is surprising to realize that, until recently, little was known about the molecular mechanisms taking place at the subcellular level during host±pathogen interaction. Hopefully, a significant body of data has accumulated in the past few years and contributed to the birth of a new field at the frontier of microbiology and cell biology, cellular microbiology (Falkow, 1999). This interest has widened our understanding of the strategies used by microorganisms to survive in mammalian cells. Recent reviews have described with details the survival strategies of intracellular pathogens within their host cells (Finlay and Falkow, 1997; Sinai and Joiner, 1997; Aderem and Underhill, 1999; Dermine and Desjardins, 1999; MeÂresse et al., 1999a). Here, we will discuss mainly the mechanisms and molecules involved in phagolysosome biogenesis, and those used by intracellular pathogens to subvert the properties of host cell phagosomes and avoid the encounter with the harsh environment of phagolysosomes. We will also present some of the new approaches and technical developments that are likely to have a significant impact in our ability to decode and expose the subversive strategies of intracellular pathogens.

Modulation of the phagosome proteome by interferon-gamma.

Macrophages are immune cells that function in the clearance of infectious particles. This process involves the engulfment of microbes into phagosomes where these particles are lysed and degraded. In the current study, we used a large scale quantitative proteomics approach to analyze the changes in protein abundance induced on phagosomes by interferon-γ (IFN-γ), an inflammatory cytokine that activates macrophages. Our analysis identified 167 IFN-γ-modulated proteins on phagosomes of which more than 90% were up-regulated. The list of phagosomal proteins regulated by IFN-γ includes proteins expected to alter phagosome maturation, enhance microbe degradation, trigger the macrophage immune response, and promote antigen loading on major histocompatibility complex (MHC) class I molecules. A dynamic analysis of IFN-γ-sensitive proteins by Western blot indicated that newly formed phagosomes display a delayed proteolytic activity coupled to an increased recruitment of the MHC class I peptide-loading complex. These phagosomal conditions may favor antigen presentation by MHC class I molecules on IFN-γ-activated macrophages.

Quantitative proteomics reveals that only a subset of the endoplasmic reticulum contributes to the phagosome

Phagosomes, by killing and degrading pathogens for antigen presentation, are organelles implicated in key aspects of innate and adaptive immunity. Although it has been well established that phagosomes consist of membranes from the plasma membrane, endosomes, and lysosomes, the notion that the endoplasmic reticulum (ER) membrane could play an important role in the formation of the phagosome is debated. However, a method to accurately estimate the contribution of potential source organelles and contaminants to the phagosome proteome has been lacking. Herein, we have developed a proteomic approach for objectively quantifying the contribution of various organelles to the early and late phagosomes by comparing these fractions to their total membrane and postnuclear supernatant of origin in the J774A.1 murine macrophage cell line. Using quantitative label-free mass spectrometry, the abundance of peptides corresponding to hundreds of proteins was estimated and attributed to one of five organelles (e.g. plasma membrane, endosomes/lysosomes, ER, Golgi, and mitochondria). These data in combination with a stable isotope labeling in cell culture method designed to detect potential contaminant sources revealed that the ER is part of the phagosomal membrane and contributes ∼20% of the early phagosome proteome. In addition, only a subset of ER proteins is recruited to the phagosome, suggesting that a specific subdomain(s) of the ER might be involved in phagocytosis. Western blotting and immunofluorescence substantially validated this conclusion; we were able to demonstrate that the fraction of the ER in which the ER marker GFP-KDEL accumulates is excluded from the phagosomes, whereas that containing the mVenus-Syntaxin 18 is recruited. These results highlight promising new avenues for the description of the pathogenic mechanisms used by Leishmania, Brucella, and Legionella spp., which thrive in ER-rich phagosomes.

The endosomal proteome of macrophage and dendritic cells.

The essential roles of the endovacuolar system in health and disease call for the development of new tools allowing a better understanding of the complex molecular machinery involved in endocytic processes. We took advantage of the floating properties of small latex beads (sLB) on a discontinuous sucrose gradient to isolate highly purified endosomes following internalization of small latex beads in J774 macrophages and bone marrow‐derived dendritic cells (DC). We particularly focused on the isolation of macrophages early endosomes and late endosomes/lysosomes (LE/LYS) as well as the isolation of LE/LYS from immature and lipopolysaccharide‐activated (mature) DC. We subsequently performed a comparative analysis of their respective protein contents by MS. As expected, proteins already known to localize to the early endosomes were enriched in the earliest fraction of J774 endosomes, while proteins known to accumulate later in the process, such as hydrolases, were significantly enriched in the LE/LYS preparations. We next compared the LE/LYS protein contents of immature DC and mature DC, which are known to undergo massive reorganization leading to potent immune activation. The differences between the protein contents of endocytic organelles from macrophages and DC were underlined by focusing on previously poorly characterized biochemical pathways, which could have an unexpected but important role in the endosomal functions of these highly relevant immune cell types.

Proteomic Characterization of Phagosomal Membrane Microdomains During Phagolysosome Biogenesis and Evolution

After their formation at the cell surface, phagosomes become fully functional through a complex maturation process involving sequential interactions with various intracellular organelles. In the last decade, series of data indicated that some of the phagosome functional properties occur in specialized membrane microdomains. The molecules associated with membrane microdomains, as well as the organization of these structures during phagolysosome biogenesis are largely unknown. In this study, we combined proteomics and bioinformatics analyses to characterize the dynamic association of proteins to maturing phagosomes. Our data indicate that groups of proteins shuffle from detergent-soluble to detergent-resistant membrane microdomains during maturation, supporting a model in which the modulation of the phagosome functional properties involves an important reorganization of the phagosome proteome by the coordinated spatial segregation of proteins.

18 Proteomic analysis of phagosomes

Publisher Summary This chapter focuses on the proteomic analysis of phagosomes. The vast sum of information generated by the analysis of the genome of many organisms is going to have major impacts on many aspects of biology, as it will allow one to find the differences associated to particular diseases, the differences between host and tumor cells and the reason why one is predisposed to various genetic diseases. Proteomics is a powerful new approach for the study of host-pathogen interaction. The global analysis of phagosomes containing various micro-organisms allows one to compare the protein content of all these organelles and identify the specific features associated to the properties of each of them. This approach indicate why some phagosomes are fusogenic while others do not fuse with endocytic organelles, and why some phagosomes can fuse with organelles such as endoplasmic reticulum (ER) and avoid the degradative pathway. Isolation of phagosomes at different times after their formation further indicate the precise mechanisms involved in these processes by providing a constant state of the phagosome composition, and this in various cellular conditions or after various stimuli.