Phagosome Maturation: Aging with pH, Lysosome-associated membrane proteins, and Cholesterol; while staying young with Burkholderia cenocepacia

Huynh, Kassidy

03 March 2010

Phagocytosis is an innate immune response that is paramount in the clearance of pathogenic particles. Recognition of target particles by phagocytic receptors expressed on phagocytes induces modifications in the underlying actin cytoskeleton to form pseudopods that encircle and internalize the target particle into a membrane bound organelle called the phagosome. The nascent phagosome undergoes a maturation sequence that is characterized by substantial remodeling of the membrane and its luminal contents through interactions with components of the endocytic pathway, culminating in an acidic and hydrolytic organelle capable of digesting and elminating pathogens. Phagosome maturation is a complicated pathway that involves many protein and lipid signaling molecules. Several factors that influence phagosome maturation particularly the participation of pH, lysosome-associated membrane proteins-1 and –2, cholesterol, in addition to the survival and escape mechanisms used by, Burkholderica cenocepacia were explored. All three tenets are essential for phagosome maturation, although each factor has different mechanistic consequences. Acidification alters Rab5 activation, while ablation of LAMPs and accumulation of cholesterol interferes with various aspects of Rab 7 turnover in phagosomes and/or endosome membranes. Moreover, Burkholderia cenocepacia, an intracellular pathogen, inactivates Rab7 on phagosome membranes from within the vacuole lumen. Herein, mechanisms that govern phagosome maturation are explored and several molecules are added to the long list of essential players in this complicated pathway.

phagocytosis

phagosome maturation

lysosome

cholesterol

acidification

0379

Phagosome Maturation: Aging with pH, Lysosome-associated membrane proteins, and Cholesterol; while staying young with Burkholderia cenocepacia

Huynh, Kassidy

03 March 2010

Phagocytosis is an innate immune response that is paramount in the clearance of pathogenic particles. Recognition of target particles by phagocytic receptors expressed on phagocytes induces modifications in the underlying actin cytoskeleton to form pseudopods that encircle and internalize the target particle into a membrane bound organelle called the phagosome. The nascent phagosome undergoes a maturation sequence that is characterized by substantial remodeling of the membrane and its luminal contents through interactions with components of the endocytic pathway, culminating in an acidic and hydrolytic organelle capable of digesting and elminating pathogens. Phagosome maturation is a complicated pathway that involves many protein and lipid signaling molecules. Several factors that influence phagosome maturation particularly the participation of pH, lysosome-associated membrane proteins-1 and –2, cholesterol, in addition to the survival and escape mechanisms used by, Burkholderica cenocepacia were explored. All three tenets are essential for phagosome maturation, although each factor has different mechanistic consequences. Acidification alters Rab5 activation, while ablation of LAMPs and accumulation of cholesterol interferes with various aspects of Rab 7 turnover in phagosomes and/or endosome membranes. Moreover, Burkholderia cenocepacia, an intracellular pathogen, inactivates Rab7 on phagosome membranes from within the vacuole lumen. Herein, mechanisms that govern phagosome maturation are explored and several molecules are added to the long list of essential players in this complicated pathway.

phagocytosis

phagosome maturation

lysosome

cholesterol

acidification

0379

Ubiquitylation regulates vesicle trafficking and innate immune responses on the phagosome of inflammatory macrophages

Bilkei-Gorzo, Orsolya

January 2018

Macrophages are sentinels present in most tissues of the body, where they recognise and respond to biological dangers. Recognition and uptake of particles is mediated through phagocytic receptors which upon activation induce appropriate responses. These responses need to be tightly regulated in order to destroy pathogens but prevent uncontrolled inflammation. Phagocytosis is an evolutionarily conserved process required for host defence and homeostasis. During phagocytosis, particles are recognised by cell surface receptors that trigger rearrangement of the actin cytoskeleton and internalization of the bound particle into a de novo, membranous organelle known as the phagosome. Regulation of phagocytosis and phagosome maturation can be achieved through changes in transcription/translation and differential recruitment of proteins but also through their non-translational modifications. Here I explored the role of ubiquitylation in the phagosome biogenesis of Interferon-gamma (IFN-ɣ) activated macrophages. Ubiquitylation is a diverse, reversible post-translational modification which is not only involved in protein degradation but also in vesicle trafficking and immune signalling. My data shows that phagosomes are enriched in polyubiquitylation, which is further enhanced by IFN-ɣ. I applied a targeted AQUA peptide approach by which we quantified ubiquitin chain linkage peptides from phagosome samples by PRM. This data shows that all chain linkages apart from M1/linear chains are present on phagosomes. Furthermore, IFN-ɣ activation enhanced K11, K48 and K63 chains significantly. In order to identify the molecular function of this polyubiquitylation, I characterized the ubiquitinome of phagosomes of IFN-γ activated macrophages and can demonstrate that ubiquitylation is preferentially attached to proteins involved in vesicle trafficking, thereby delaying fusion with late endosomes and lysosomes. I demonstrated that most ubiquitin chains are on the cytoplasmic site of the phagosome enabling an interaction of ubiquitin chains with cytosolic proteins such as Rab7. Rab7 a major regulator of vesicle trafficking could be shown to be ubiquitylated on phagosomes. I further showed that phagosomal recruitment of the E3 ligase RNF115 is enhanced upon IFN-γ stimulation and RNF115 is responsible for most of the increase of K63 polyubiquitylation of phagosomal proteins. Knock-down of RNF115 promotes phagosome maturation and induces an increased pro-inflammatory response to Toll-like receptor (TLR) agonists, indicating that RNF115 is a negative regulator of vesicular trafficking to the lysosome and disruption of this pathway induces pro-inflammatory responses in macrophages. In conclusion, this is the first study showing unbiasedly that ubiquitylation plays an important role in vesicle trafficking to the lysosome.

Characterization of the PdpA protein and its role in the intracellular lifestyle of Francisella novicida

Schmerk, Crystal Lynn

29 April 2010

Francisella tularensis is a highly virulent, intracellular pathogen that causes the disease tularaemia. Francisella species contain a cluster of genes referred to as the Francisella pathogenicity island (FPI). Several genes contained in the FPI encode proteins needed for the intracellular growth and virulence of Francisella tularensis. Pathogenicity determinant protein A (PdpA), encoded by the pdpA gene, is located within the FPI and has been associated with the virulence of Francisella species. The experiments outlined in this dissertation examine the properties of PdpA protein expression and localization as well as the phenotypes of non-polar F. novicida pdpA mutants. Monoclonal antibody detection of PdpA showed that it is a soluble protein that is upregulated in iron-limiting conditions and undetectable in an mglA or mglB mutant background. Deletion of pdpA resulted in a strain that was highly attenuated for virulence in chicken embryos and mice. The ΔpdpA strain was capable of a small amount of intracellular replication but, unlike wild-type F. novicida, remained associated with the lysosomal marker LAMP-1, suggesting that PdpA is necessary for progression from the early phagosome phase of infection. Infection of macrophages with the ΔpdpA mutant generated a host-cell mRNA profile distinct from that generated by infection with wild type F. novicida. The transcriptional response of the host macrophage indicates that PdpA functions directly or indirectly to suppress macrophage ability to signal via growth factors, cytokines and adhesion ligands. Experiments were designed to mutagenize a putative F-box domain within the amino terminus of PdpA. Deletion of amino acids 112-227 created a strain which was impaired in intracellular replication and exhibited severely reduced virulence. However, alanine mutagenesis of key conserved leucine residues required for the interaction of F-box domains with host proteins had no observed effect on bacterial growth in macrophages and did not affect virulence in chicken embryos or mice. Mono and polyubiquitinated proteins associated with both the wild type F. novicida and ΔpdpA bacterial strains early during the infection of J774A.1 macrophages. After 1 hour of infection the wild type strain developed a more intimate association with mono and polyubiquitinated proteins whereas the ΔpdpA strain did not. Inhibition of the host cell proteasome during infection did not affect the intracellular growth of wild type F. novicida. PdpA research concludes by examining the secretion patterns of F. novicida. PdpA was not detected as a surface exposed protein using biotinylation whereas IglA, IglB and IglC were found to be surface exposed in both wild type and ΔpdpA backgrounds. These observations suggest that PdpA is not involved in the assembly or function of the Francisella secretion system. FLAG tagged PdpA protein could not be detected in the TCA precipitated supernatant of broth grown cultures or in the immunoprecipitated cytosol of infected macrophages suggesting that PdpA is not a secreted protein.

Francisella tularensis

pathogenicity island

type VI secretion

molecular biology

phagosome maturation

ubiquitination

PdpA

Macrophage et infection par le VIH‐1 : perturbation des fonctions de clairance et d’activation / Macrophage and HIV-1 infection : perturbations of their clearance and activation functions

Dumas, Audrey

24 October 2014

La phagocytose, fonction fondamentale des macrophages, est un processus qui se décompose en deux étapes bien distinctes : les étapes précoces d’internalisation menant à la formation du phagosome et les étapes tardives de maturation du phagosome. Le virus de l’immunodéficience humaine de type I (VIH-1) infecte les macrophages, ce qui perturbe leurs fonctions. L’effet de l’infection virale dans ces cellules est peu caractérisé en comparaison des lymphocytes T. Des travaux antérieurs ont montré d’une part que l’étape précoce d’internalisation de larges particules et bactéries était bloquée de moitié dans les macrophages primaires humains infectés par le VIH-1 via Nef, la protéine de virulence majeure du virus et d’autres part, que la réponse cytokinique était atténuée chez les patients infectés. Ainsi, nous avons étudié l’effet du VIH-1 sur les étapes tardives de la phagocytose : la maturation du phagosome et l’activation des macrophages qui en résulte. Nous avons montré que le VIH-1 altère les étapes tardives de la phagocytose en inhibant la maturation du phagosome, définie par le recrutement de marqueurs tardifs de la voie d’endocytose, d’hydrolases et la production d’espèces réactives oxygénées. Malgré une pré-activation basale, les macrophages infectés par le VIH-1 sont incapables de répondre efficacement à une stimulation induite par phagocytose, ce qui conduit à une modulation de la réponse transcriptionnelle et cytokinique. La dynamique des microtubules et la migration centripète des phagosomes sont profondément affectées par le virus. De façon inattendue, la protéine virale Vpr est impliquée dans ces perturbations, alors que Nef ne joue pas de rôle notable. Nos résultats indiquent que les composants intracellulaires de la machinerie de tri endosomal sont détournés par le compartiment viral dans les macrophages infectés. Par cette étude, nous avons donc identifié la protéine Vpr comme nouveau modulateur de la dynamique des microtubules et du trafic intracellulaire, entraînant ainsi une altération profonde de la maturation du phagosome et de la clairance bactérienne dans les macrophages infectés. Ce travail contribue à mieux comprendre l’établissement d’infections opportunistes chez les patients infectés. / Phagocytosis, a crucial function of macrophages, is composed of two well defined steps : the early step of internalization leading to phagosome formation and the late step of phagosome maturation. The immunodeficiency virus type I (HIV-1) infects macrophages, which disturbs theirs functions. The effects of HIV-1 infection are poorly characterized in this cell type compared to T lymphocytes. Previous results have already shown that the early step of internalization of large particles and bacteria are half blocked by Nef in HIV-1 infected primary macrophages and that the cytokine response is attenuated in infected patients. Thus, we have studied the effect of HIV-1 infection on the late step of phagocytosis : phagosome maturation and the resulting macrophage activation. We shown that HIV-1 impairs late phagocytic events affecting the phagosome maturation, as defined by late endocytic markers and hydrolases recruitment, and reactives oxygens species production. HIV-1 infected macrophages exhibited a basal preactivation but appeared unable to respond efficiently to phagocytic triggers leading to cytokine and transcriptional modifications. Centripetal migration of phagosomes and microtubule dynamics were deeply altered upon viral infection. Surprisingly, the Vpr viral protein was implicated in these pertubations, while Nef was not. Our results revealed that elements of the endosomal sorting machinery were hijacked to the virus-containing compartments in HIV-infected macrophages. With this study, we identify Vpr as a modulator of the microtubule dynamics and intracellular trafficking, leading to alterations in phagosome maturation and bacterial clearance in HIV-1 infected macrophages. This work contribute to better understanding of the establishment of opportunistic infections in HIV-infected patients.

Macrophages

Maturation du phagosome

Activation

HIV-1

Vpr

Microtubules

Clairance bactérienne

Voie d’endocytose

Macrophages

Phagosome maturation

Activation

HIV-1

Vpr

Microtubules

Bacterial clearance

Endocytic pathways

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