Your search keyword '"xenophagy"' showing total 754 results

1. An Intrinsic Host Defense against HSV-1 Relies on the Activation of Xenophagy with the Active Clearance of Autophagic Receptors.

Author

Pino-Belmar, Camila, Aguilar, Rayén, Valenzuela-Nieto, Guillermo E., Cavieres, Viviana A., Cerda-Troncoso, Cristóbal, Navarrete, Valentina C., Salazar, Paula, Burgos, Patricia V., Otth, Carola, and Bustamante, Hianara A.

Subjects

*HUMAN herpesvirus 1, *CELL anatomy, *INTRACELLULAR pathogens, *LYSOSOMES, *AUTOPHAGY

Abstract

Autophagy engulfs cellular components in double-membrane-bound autophagosomes for clearance and recycling after fusion with lysosomes. Thus, autophagy is a key process for maintaining proteostasis and a powerful cell-intrinsic host defense mechanism, protecting cells against pathogens by targeting them through a specific form of selective autophagy known as xenophagy. In this context, ubiquitination acts as a signal of recognition of the cargoes for autophagic receptors, which direct them towards autophagosomes for subsequent breakdown. Nevertheless, autophagy can carry out a dual role since numerous viruses including members of the Orthoherpesviridae family can either inhibit or exploit autophagy for its own benefit and to replicate within host cells. There is growing evidence that Herpes simplex virus type 1 (HSV-1), a highly prevalent human pathogen that infects epidermal keratinocytes and sensitive neurons, is capable of negatively modulating autophagy. Since the effects of HSV-1 infection on autophagic receptors have been poorly explored, this study aims to understand the consequences of HSV-1 productive infection on the levels of the major autophagic receptors involved in xenophagy, key proteins in the recruitment of intracellular pathogens into autophagosomes. We found that productive HSV-1 infection in human neuroglioma cells and keratinocytes causes a reduction in the total levels of Ub conjugates and decreases protein levels of autophagic receptors, including SQSTM1/p62, OPTN1, NBR1, and NDP52, a phenotype that is also accompanied by reduced levels of LC3-I and LC3-II, which interact directly with autophagic receptors. Mechanistically, we show these phenotypes are the result of xenophagy activation in the early stages of productive HSV-1 infection to limit virus replication, thereby reducing progeny HSV-1 yield. Additionally, we found that the removal of the tegument HSV-1 protein US11, a recognized viral factor that counteracts autophagy in host cells, enhances the clearance of autophagic receptors, with a significant reduction in the progeny HSV-1 yield. Moreover, the removal of US11 increases the ubiquitination of SQSTM1/p62, indicating that US11 slows down the autophagy turnover of autophagy receptors. Overall, our findings suggest that xenophagy is a potent host defense against HSV-1 replication and reveals the role of the autophagic receptors in the delivery of HSV-1 to clearance via xenophagy. [ABSTRACT FROM AUTHOR]

Published

2024

2. An Update on the Study of the Molecular Mechanisms Involved in Autophagy during Bacterial Pathogenesis.

Author

Rahman, Md Ataur, Sarker, Amily, Ayaz, Mohammed, Shatabdy, Ananya Rahman, Haque, Nabila, Jalouli, Maroua, Rahman, MD. Hasanur, Mou, Taslin Jahan, Dey, Shuvra Kanti, Hoque Apu, Ehsanul, Zafar, Muhammad Sohail, and Parvez, Md. Anowar Khasru

Subjects

BACTERIAL toxins, PATHOGENIC bacteria, CELL anatomy, INTRACELLULAR pathogens, EUKARYOTIC cells

Abstract

Autophagy is a unique catabolic process that degrades irrelevant or damaged components in eukaryotic cells to maintain homeostasis and eliminate infections from pathogenesis. Pathogenic bacteria have developed many autophagy manipulation techniques that affect host immune responses and intracellular bacterial pathogens have evolved to avoid xenophagy. However, reducing its effectiveness as an innate immune response has not yet been elucidated. Bacterial pathogens cause autophagy in infected cells as a cell-autonomous defense mechanism to eliminate the pathogen. However, harmful bacteria have learned to control autophagy and defeat host defenses. Intracellular bacteria can stimulate and control autophagy, while others inhibit it to prevent xenophagy and lysosomal breakdown. This review evaluates the putative functions for xenophagy in regulating bacterial infection, emphasizing that successful pathogens have evolved strategies to disrupt or exploit this defense, reducing its efficiency in innate immunity. Instead, animal models show that autophagy-associated proteins influence bacterial pathogenicity outside of xenophagy. We also examine the consequences of the complex interaction between autophagy and bacterial pathogens in light of current efforts to modify autophagy and develop host-directed therapeutics to fight bacterial infections. Therefore, effective pathogens have evolved to subvert or exploit xenophagy, although autophagy-associated proteins can influence bacterial pathogenicity outside of xenophagy. Finally, this review implies how the complex interaction between autophagy and bacterial pathogens affects host-directed therapy for bacterial pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2024

3. Individual Atg8 paralogs exhibit unique properties in <italic>streptococcus pneumoniae</italic>-induced hierarchical autophagy.

Author

Shizukuishi, Sayaka, Ogawa, Michinaga, and Akeda, Yukihiro

Subjects

*STREPTOCOCCUS pneumoniae, *AUTOPHAGY, *BACTERIAL diseases, *FUNCTIONAL analysis

Abstract

Individual Atg8 (autophagy related 8) paralogs, comprising MAP1LC3A/LC3A, LC3B, LC3C, GABARAP, GABARAPL1 and GABARAPL2/GATE16, play a crucial role in canonical macroautophagy/autophagy. However, their functions remain unclear owing to functional redundancy. In a previous study, we reported that intracellular Streptococcus pneumoniae triggers hierarchical autophagy in response to bacterial infection. This process commences with the induction of conjugation of Atg8 paralogs (Atg8s) to single membranes (CASM), followed by CASM shedding and subsequent induction of xenophagy. In our recent study, we performed functional analysis of Atg8s during pneumococci-induced hierarchical autophagy. Our findings suggest that LC3A and GABARAPL1 are crucial for CASM induction, whereas GABARAPL2 and GABARAP play sequential roles in CASM shedding and subsequent induction of xenophagy, respectively.Abbreviation: Atg8: autophagy related 8; Atg8s: Atg8 paralogs; CASM: conjugation of Atg8s to single membranes; mpi: minutes post-infection; mpi: minutes post-infection; PcAV: pneumococci-containing autophagic vesicles; PcLV: LC3-associated phagosome (LAPosome)-like vacuole; PcV: pneumococci-containing vesicles; Sp: S. pneumoniae. [ABSTRACT FROM AUTHOR]

Published

2024

4. Xenophagy receptors Optn and p62 and autophagy modulator Draml independently promote the zebrafish host defense against Mycobacterium marinum.

Author

Jiajun Xie and Meijer, Annemarie H.

Subjects

MYCOBACTERIUM, AUTOPHAGY, BRACHYDANIO, MYCOBACTERIUM tuberculosis

Abstract

Anti-bacterial autophagy, also known as xenophagy, is a crucial innate immune process that helps maintain cellular homeostasis by targeting invading microbes. This defense pathway is widely studied in the context of infections with mycobacteria, the causative agents of human tuberculosis and tuberculosislike disease in animal models. Our previous work in a zebrafish tuberculosis model showed that host defense against Mycobacterium marinum (Mm) is impaired by deficiencies in xenophagy receptors, optineurin (Optn) or sequestome 1 (p62), and Damage-regulated autophagy modulator 1 (Dram1). However, the interdependency of these receptors and their interaction with Dram1 remained unknown. In the present study, we used single and double knockout zebrafish lines in combination with overexpression experiments. We show that Optn and p62 can compensate for the loss of each other's function, as their overexpression restores the infection susceptibility of the mutant phenotypes. Similarly, Dram1 can compensate for deficiencies in Optn and p62, and, vice versa, Optn and p62 compensate for the loss of Dram1, indicating that these xenophagy receptors and Dram1 do not rely on each other for host defense against Mm. In agreement, Dram1 overexpression in optn/p62 double mutants restored the interaction of autophagosome marker Lc3 with Mm. Finally, optn/p62 double mutants displayed more severe infection susceptibility than the single mutants. Taken together, these results suggest that Optn and p62 do not function downstream of each other in the anti-mycobacterial xenophagy pathway, and that the Dram1-mediated defense against Mm infection does not rely on specific xenophagy receptors. [ABSTRACT FROM AUTHOR]

Published

2024

5. Xenophagy as a Strategy for Mycobacterium leprae Elimination during Type 1 or Type 2 Leprosy Reactions: A Systematic Review.

Author

Cerqueira, Débora Dantas Nucci, Pereira, Ana Letícia Silva, da Costa, Ana Elisa Coelho, de Souza, Tarcísio Joaquim, de Sousa Fernandes, Matheus Santos, Souto, Fabrício Oliveira, and Santos, Patrícia d'Emery Alves

Subjects

MYCOBACTERIUM leprae, HANSEN'S disease, NEGLECTED diseases, SCHWANN cells, NEURONS

Abstract

Background: Mycobacterium leprae is an intracellular bacillus that causes leprosy, a neglected disease that affects macrophages and Schwann cells. Leprosy reactions are acute inflammatory responses to mycobacterial antigens, classified as type1 (T1R), a predominant cellular immune response, or type2 (T2R), a humoral phenomenon, leading to a high number of bacilli in infected cells and nerve structures. Xenophagy is a type of selective autophagy that targets intracellular bacteria for lysosomal degradation; however, its immune mechanisms during leprosy reactions are still unclear. This review summarizes the relationship between the autophagic process and M. leprae elimination during leprosy reactions. Methods: Three databases, PubMed/Medline (n = 91), Scopus (n = 73), and ScienceDirect (n = 124), were searched. After applying the eligibility criteria, articles were selected for independent peer reviewers in August 2023. Results: From a total of 288 studies retrieved, eight were included. In multibacillary (MB) patients who progressed to T1R, xenophagy blockade and increased inflammasome activation were observed, with IL-1β secretion before the reactional episode occurrence. On the other hand, recent data actually observed increased IL-15 levels before the reaction began, as well as IFN-γ production and xenophagy induction. Conclusion: Our search results showed a dichotomy in the T1R development and their relationship with xenophagy. No T2R studies were found. [ABSTRACT FROM AUTHOR]

Published

2023

6. An Update on the Study of the Molecular Mechanisms Involved in Autophagy during Bacterial Pathogenesis

Author

Md Ataur Rahman, Amily Sarker, Mohammed Ayaz, Ananya Rahman Shatabdy, Nabila Haque, Maroua Jalouli, MD. Hasanur Rahman, Taslin Jahan Mou, Shuvra Kanti Dey, Ehsanul Hoque Apu, Muhammad Sohail Zafar, and Md. Anowar Khasru Parvez

Subjects

autophagy, xenophagy, bacteria, pathogenesis, bacterial toxins, Biology (General), QH301-705.5

Abstract

Autophagy is a unique catabolic process that degrades irrelevant or damaged components in eukaryotic cells to maintain homeostasis and eliminate infections from pathogenesis. Pathogenic bacteria have developed many autophagy manipulation techniques that affect host immune responses and intracellular bacterial pathogens have evolved to avoid xenophagy. However, reducing its effectiveness as an innate immune response has not yet been elucidated. Bacterial pathogens cause autophagy in infected cells as a cell-autonomous defense mechanism to eliminate the pathogen. However, harmful bacteria have learned to control autophagy and defeat host defenses. Intracellular bacteria can stimulate and control autophagy, while others inhibit it to prevent xenophagy and lysosomal breakdown. This review evaluates the putative functions for xenophagy in regulating bacterial infection, emphasizing that successful pathogens have evolved strategies to disrupt or exploit this defense, reducing its efficiency in innate immunity. Instead, animal models show that autophagy-associated proteins influence bacterial pathogenicity outside of xenophagy. We also examine the consequences of the complex interaction between autophagy and bacterial pathogens in light of current efforts to modify autophagy and develop host-directed therapeutics to fight bacterial infections. Therefore, effective pathogens have evolved to subvert or exploit xenophagy, although autophagy-associated proteins can influence bacterial pathogenicity outside of xenophagy. Finally, this review implies how the complex interaction between autophagy and bacterial pathogens affects host-directed therapy for bacterial pathogenesis.

Published

2024

7. An Intrinsic Host Defense against HSV-1 Relies on the Activation of Xenophagy with the Active Clearance of Autophagic Receptors

Author

Camila Pino-Belmar, Rayén Aguilar, Guillermo E. Valenzuela-Nieto, Viviana A. Cavieres, Cristóbal Cerda-Troncoso, Valentina C. Navarrete, Paula Salazar, Patricia V. Burgos, Carola Otth, and Hianara A. Bustamante

Subjects

HSV-1, autophagy, autophagic receptor, intrinsic host defense, xenophagy, US11, Cytology, QH573-671

Abstract

Autophagy engulfs cellular components in double-membrane-bound autophagosomes for clearance and recycling after fusion with lysosomes. Thus, autophagy is a key process for maintaining proteostasis and a powerful cell-intrinsic host defense mechanism, protecting cells against pathogens by targeting them through a specific form of selective autophagy known as xenophagy. In this context, ubiquitination acts as a signal of recognition of the cargoes for autophagic receptors, which direct them towards autophagosomes for subsequent breakdown. Nevertheless, autophagy can carry out a dual role since numerous viruses including members of the Orthoherpesviridae family can either inhibit or exploit autophagy for its own benefit and to replicate within host cells. There is growing evidence that Herpes simplex virus type 1 (HSV-1), a highly prevalent human pathogen that infects epidermal keratinocytes and sensitive neurons, is capable of negatively modulating autophagy. Since the effects of HSV-1 infection on autophagic receptors have been poorly explored, this study aims to understand the consequences of HSV-1 productive infection on the levels of the major autophagic receptors involved in xenophagy, key proteins in the recruitment of intracellular pathogens into autophagosomes. We found that productive HSV-1 infection in human neuroglioma cells and keratinocytes causes a reduction in the total levels of Ub conjugates and decreases protein levels of autophagic receptors, including SQSTM1/p62, OPTN1, NBR1, and NDP52, a phenotype that is also accompanied by reduced levels of LC3-I and LC3-II, which interact directly with autophagic receptors. Mechanistically, we show these phenotypes are the result of xenophagy activation in the early stages of productive HSV-1 infection to limit virus replication, thereby reducing progeny HSV-1 yield. Additionally, we found that the removal of the tegument HSV-1 protein US11, a recognized viral factor that counteracts autophagy in host cells, enhances the clearance of autophagic receptors, with a significant reduction in the progeny HSV-1 yield. Moreover, the removal of US11 increases the ubiquitination of SQSTM1/p62, indicating that US11 slows down the autophagy turnover of autophagy receptors. Overall, our findings suggest that xenophagy is a potent host defense against HSV-1 replication and reveals the role of the autophagic receptors in the delivery of HSV-1 to clearance via xenophagy.

Published

2024

8. Autophagy as a Biomarker of Cytotoxicity

Author

Hirano, Seishiro, Patel, Vinood B., Series Editor, Preedy, Victor R., Series Editor, and Rajendram, Rajkumar, editor

Published

2023

9. TRIMming down Mycobacterium tuberculosis replication: TRIM32 is required for bacterial ubiquitination and autophagy induction in macrophages

Author

Alessandra Romagnoli, Martina Di Rienzo, Mauro Piacentini, and Gian Maria Fimia

Subjects

Xenophagy, TRIM ubiquitin ligases, Mycobacterium tuberculosis, Ubiquitin, Cytology, QH573-671

Abstract

ABSTRACTMycobacterium tuberculosis (Mtb) promotes its intracellular persistence by subverting defense mechanisms, such as autophagy. Remarkably, enhancing autophagy is sufficient to trigger intracellular Mtb killing and effective immune response, making this process a valid target of host-directed therapies. However, several aspects of autophagy regulation during Mtb infection remain unsolved. Tripartite motif (TRIM) proteins are a large family of ubiquitin ligases primarily involved in innate immunity by regulating inflammation and autophagy. By combining transcriptomic and infectivity screens, we recently identified a set of TRIMs that modulate Mtb replication. In detail, overexpression of TRIM22 and TRIM32 reduces Mtb growth in THP1 macrophages, while that of TRIM36 and TRIM56 promotes Mtb replication. Analysis of the molecular mechanisms underlying inhibition of Mtb replication by TRIM32 showed that its overexpression promote xenophagy, a selective autophagy of pathogens, by increasing Mtb ubiquitination and the recruitment of CALCOCO2/NDP52 (calcium binding and coiled-coil domain 2) and MAP1LC3B (microtubule-associated protein 1 light chain 3B) to intracellular bacteria. Consistently, TRIM32 downregulation reduces the xenophagic response, resulting in increased Mtb replication. Altogether, we characterized a novel role for TRIM32 in the host response to pathogen infections and identify TRIM36 and TRIM56 as possible host factors required for Mtb infection.Abbreviations: CALCOCO2/NDP52, calcium binding and coiled-coil domain 2; AMBRA1, activating molecule In BECN1-regulated autophagy; BECN1, BECLIN-1; MAP1LC3B, microtubule-associated proteins 1 light chain 3B; Mtb, Mycobacterium tuberculosis; TRIM proteins, tripartite motif proteins; PRKN/PARKIN, parkin RBR E3 ubiquitin protein ligase; CFU: colony forming units; SMURF1, SMAD specific E3 ubiquitin protein ligase 1; STING, Stimulator of interferon genes protein; TLR, Toll-like receptor; SAR selective autophagy receptor.

Published

2023

10. p38MAPK/MK2 signaling stimulates host cells autophagy pathways to restrict Salmonella infection.

Author

Suwandi, Abdulhadi, Menon, Manoj B., Kotlyarov, Alexey, Grassl, Guntram A., and Gaestel, Matthias

Subjects

SALMONELLA diseases, SALMONELLA enterica serovar Typhi, AUTOPHAGY, WESTERN immunoblotting, INTRACELLULAR pathogens

Abstract

Autophagy plays an important role in recognizing and protecting cells from invading intracellular pathogens such as Salmonella. In this work, we investigated the role of p38MAPK/MK2 in modulating the host cell susceptibility to Salmonella infection. Inhibition of p38MAPK or MK2 led to a significant increase of bacterial counts in Salmonella infected mouse embryonic fibroblasts (MEFs), as well as in MK2-deficient (Mk2-/-) cells. Furthermore, western blot analysis showed that Mk2-/- cells have lower level of LC3 lipidation, which is the indicator of general autophagy compared to Mk2-rescued cells. In Mk2-/- cells, we also observed lower activated TANK-binding kinase-1 phosphorylation on Ser172 and p62/SQTM1-Ser403 phosphorylation, which are important to promote the translocation of p62 to ubiquitinated microbes and required for efficient autophagy of bacteria. Furthermore, immunofluorescence analysis revealed reduced colocalization of Salmonella with LC3 and p62 in MEFs. Inhibition of autophagy with bafilomycin A1 showed increased bacterial counts in treated cells compared to control cell. Overall, these results indicate that p38MAPK/MK2-mediated protein phosphorylation modulates the host cell susceptibility to Salmonella infection by affecting the autophagy pathways. [ABSTRACT FROM AUTHOR]

Published

2023

11. The autophagy machinery interacts with EBV capsids during viral envelope release.

Author

Pena-Francesch, Maria, Vanoaica, Liliana Danusia, Gao-Feng Zhu, Stumpe, Michael, Sankar, Devanarayanan Siva, Nowag, Heike, Valencia-Camargo, Alma Delia, Hammerschmidt, Wolfgang, Dengjel, Jörn, Ligeon, Laure-Anne, and Münz, Christian

Subjects

*VIRAL envelopes, *AUTOPHAGY, *CAPSIDS, *VIRAL proteins, *EPSTEIN-Barr virus

Abstract

Autophagy serves as a defense mechanism against intracellular pathogens, but several microorganisms exploit it for their own benefit. Accordingly, certain herpesviruses include autophagic membranes into their infectious virus particles. In this study, we analyzed the composition of purified virions of the Epstein-Barr virus (EBV), a common oncogenic γ-herpesvirus. In these, we found several components of the autophagy machinery, including membrane-associated LC3B-II, and numerous viral proteins, such as the capsid assembly proteins BVRF2 and BdRF1. Additionally, we showed that BVRF2 and BdRF1 interact with LC3B-II via their common protein domain. Using an EBV mutant, we identified BVRF2 as essential to assemble mature capsids and produce infectious EBV. However, BdRF1 was sufficient for the release of noninfectious viral envelopes as long as autophagy was not compromised. These data suggest that BVRF2 and BdRF1 are not only important for capsid assembly but together with the LC3B conjugation complex of ATG5-ATG12-ATG15L1 are also critical for EBV envelope release. [ABSTRACT FROM AUTHOR]

Published

2023

12. Modulation of Autophagy and Cell Death by Bacterial Outer-Membrane Vesicles.

Author

Pin, Camille, David, Laure, and Oswald, Eric

Subjects

*CELL death, *BACTERIAL cells, *EXTRACELLULAR vesicles, *EUKARYOTIC cells, *AUTOPHAGY, *COATED vesicles

Abstract

Bacteria, akin to eukaryotic cells, possess the ability to release extracellular vesicles, lipidic nanostructures that serve diverse functions in host–pathogen interactions during infections. In particular, Gram-negative bacteria produce specific vesicles with a single lipidic layer called OMVs (Outer Membrane Vesicles). These vesicles exhibit remarkable capabilities, such as disseminating throughout the entire organism, transporting toxins, and being internalized by eukaryotic cells. Notably, the cytosolic detection of lipopolysaccharides (LPSs) present at their surface initiates an immune response characterized by non-canonical inflammasome activation, resulting in pyroptotic cell death and the release of pro-inflammatory cytokines. However, the influence of these vesicles extends beyond their well-established roles, as they also profoundly impact host cell viability by directly interfering with essential cellular machinery. This comprehensive review highlights the disruptive effects of these vesicles, particularly on autophagy and associated cell death, and explores their implications for pathogen virulence during infections, as well as their potential in shaping novel therapeutic approaches. [ABSTRACT FROM AUTHOR]

Published

2023

13. Autophagy in Crohn's Disease: Converging on Dysfunctional Innate Immunity.

Author

Alula, Kibrom M. and Theiss, Arianne L.

Subjects

*INFLAMMATORY bowel diseases, *CROHN'S disease, *NATURAL immunity, *AUTOPHAGY, *DISEASE relapse, *DENDRITIC cells

Abstract

Crohn's disease (CD) is a chronic inflammatory bowel disease marked by relapsing, transmural intestinal inflammation driven by innate and adaptive immune responses. Autophagy is a multi-step process that plays a critical role in maintaining cellular homeostasis by degrading intracellular components, such as damaged organelles and invading bacteria. Dysregulation of autophagy in CD is revealed by the identification of several susceptibility genes, including ATG16L1, IRGM, NOD2, LRRK2, ULK1, ATG4, and TCF4, that are involved in autophagy. In this review, the role of altered autophagy in the mucosal innate immune response in the context of CD is discussed, with a specific focus on dendritic cells, macrophages, Paneth cells, and goblet cells. Selective autophagy, such as xenophagy, ERphagy, and mitophagy, that play crucial roles in maintaining intestinal homeostasis in these innate immune cells, are discussed. As our understanding of autophagy in CD pathogenesis evolves, the development of autophagy-targeted therapeutics may benefit subsets of patients harboring impaired autophagy. [ABSTRACT FROM AUTHOR]

Published

2023

14. Out of the ESCPE room: Emerging roles of endosomal SNX‐BARs in receptor transport and host–pathogen interaction.

Author

Simonetti, Boris, Daly, James L., and Cullen, Peter J.

Subjects

*CELL motility, *HOMEOSTASIS, *MEMBRANE proteins, *EUKARYOTIC cells, *CELL membranes, *CELL physiology

Abstract

Several functions of the human cell, such as sensing nutrients, cell movement and interaction with the surrounding environment, depend on a myriad of transmembrane proteins and their associated proteins and lipids (collectively termed "cargoes"). To successfully perform their tasks, cargo must be sorted and delivered to the right place, at the right time, and in the right amount. To achieve this, eukaryotic cells have evolved a highly organized sorting platform, the endosomal network. Here, a variety of specialized multiprotein complexes sort cargo into itineraries leading to either their degradation or their recycling to various organelles for further rounds of reuse. A key sorting complex is the Endosomal SNX‐BAR Sorting Complex for Promoting Exit (ESCPE‐1) that promotes the recycling of an array of cargos to the plasma membrane and/or the trans‐Golgi network. ESCPE‐1 recognizes a hydrophobic‐based sorting motif in numerous cargoes and orchestrates their packaging into tubular carriers that pinch off from the endosome and travel to the target organelle. A wide range of pathogens mimic this sorting motif to hijack ESCPE‐1 transport to promote their invasion and survival within infected cells. In other instances, ESCPE‐1 exerts restrictive functions against pathogens by limiting their replication and infection. In this review, we discuss ESCPE‐1 assembly and functions, with a particular focus on recent advances in the understanding of its role in membrane trafficking, cellular homeostasis and host–pathogen interaction. [ABSTRACT FROM AUTHOR]

Published

2023

15. The autophagy adaptor NDP52 and the FIP200 coiled-coil allosterically activate ULK1 complex membrane recruitment.

Author

Shi, Xiaoshan, Chang, Chunmei, Yokom, Adam L, Jensen, Liv E, and Hurley, James H

Subjects

HDX-MS, autophagy, biochemistry, cell biology, chemical biology, coiled-coil, electron microscopy, human, mitophagy, xenophagy, Biochemistry and Cell Biology

Abstract

The selective autophagy pathways of xenophagy and mitophagy are initiated when the adaptor NDP52 recruits the ULK1 complex to autophagic cargo. Hydrogen-deuterium exchange coupled to mass spectrometry (HDX-MS) was used to map the membrane and NDP52 binding sites of the ULK1 complex to unique regions of the coiled coil of the FIP200 subunit. Electron microscopy of the full-length ULK1 complex shows that the FIP200 coiled coil projects away from the crescent-shaped FIP200 N-terminal domain dimer. NDP52 allosterically stimulates membrane-binding by FIP200 and the ULK1 complex by promoting a more dynamic conformation of the membrane-binding portion of the FIP200 coiled coil. Giant unilamellar vesicle (GUV) reconstitution confirmed that membrane recruitment by the ULK1 complex is triggered by NDP52 engagement. These data reveal how the allosteric linkage between NDP52 and the ULK1 complex could drive the first membrane recruitment event of phagophore biogenesis in xenophagy and mitophagy.

Published

2020

16. The versatile defender: exploring the multifaceted role of p62 in intracellular bacterial infection.

Author

Yuhao Zhou, Shucheng Hua, and Lei Song

Subjects

BACTERIAL diseases, PROTEIN domains, SYNTHETIC drugs, BACTERIAL proteins, AUTOPHAGY

Abstract

As a highly conserved, multifunctional protein with multiple domains, p62/SQSTM1 plays a crucial role in several essential cellular activities, particularly selective autophagy. Recent research has shown that p62 is crucial in eradicating intracellular bacteria by xenophagy, a selective autophagic process that identifies and eliminates such microorganisms. This review highlights the various roles of p62 in intracellular bacterial infections, including both direct and indirect, antibacterial and infection-promoting aspects, and xenophagy-dependent and independent functions, as documented in published literature. Additionally, the potential applications of synthetic drugs targeting the p62-mediated xenophagy mechanism and unresolved questions about p62's roles in bacterial infections are also discussed. [ABSTRACT FROM AUTHOR]

Published

2023

17. Molecular mechanism of Streptococcus pneumoniae–targeting xenophagy recognition and evasion: Reinterpretation of pneumococci as intracellular bacteria.

Author

Ogawa, Michinaga, Shizukuishi, Sayaka, Akeda, Yukihiro, and Ohnishi, Makoto

Subjects

STREPTOCOCCUS pneumoniae, STREPTOCOCCUS, VACCINE effectiveness, COMMUNITY-acquired pneumonia, BACTERIA, THERAPEUTICS

Abstract

Streptococcus pneumoniae is a major, encapsulated Gram‐positive pathogen that causes diseases including community‐acquired pneumonia, meningitis, and sepsis. This pathogen colonizes the nasopharyngeal epithelia asymptomatically but can often migrate to sterile tissues and cause life‐threatening invasive infections (invasive pneumococcal disease). Although multivalent pneumococcal polysaccharides and conjugate vaccines are available and effective, they also have major shortcomings with respect to the emergence of vaccine‐resistant serotypes. Therefore, alternative therapeutic approaches are needed, and the molecular analysis of host–pathogen interactions and their applications to pharmaceutical development and clinical practice has recently received increased attention. In this review, we introduce pneumococcal surface virulence factors involved in pathogenicity and highlight recent advances in our understanding of host autophagy recognition mechanisms against intracellular S. pneumoniae and pneumococcal evasion from autophagy. [ABSTRACT FROM AUTHOR]

Published

2023

18. Membrane Curvature: The Inseparable Companion of Autophagy.

Author

Liu, Lei, Tang, Yu, Zhou, Zijuan, Huang, Yuan, Zhang, Rui, Lyu, Hao, Xiao, Shuai, Guo, Dong, Ali, Declan William, Michalak, Marek, Chen, Xing-Zhen, Zhou, Cefan, and Tang, Jingfeng

Subjects

*CURVATURE, *AUTOPHAGY, *MEMBRANE proteins, *ENDOPLASMIC reticulum, *WASTE recycling, *BILAYER lipid membranes

Abstract

Autophagy is a highly conserved recycling process of eukaryotic cells that degrades protein aggregates or damaged organelles with the participation of autophagy-related proteins. Membrane bending is a key step in autophagosome membrane formation and nucleation. A variety of autophagy-related proteins (ATGs) are needed to sense and generate membrane curvature, which then complete the membrane remodeling process. The Atg1 complex, Atg2-Atg18 complex, Vps34 complex, Atg12-Atg5 conjugation system, Atg8-phosphatidylethanolamine conjugation system, and transmembrane protein Atg9 promote the production of autophagosomal membranes directly or indirectly through their specific structures to alter membrane curvature. There are three common mechanisms to explain the change in membrane curvature. For example, the BAR domain of Bif-1 senses and tethers Atg9 vesicles to change the membrane curvature of the isolation membrane (IM), and the Atg9 vesicles are reported as a source of the IM in the autophagy process. The amphiphilic helix of Bif-1 inserts directly into the phospholipid bilayer, causing membrane asymmetry, and thus changing the membrane curvature of the IM. Atg2 forms a pathway for lipid transport from the endoplasmic reticulum to the IM, and this pathway also contributes to the formation of the IM. In this review, we introduce the phenomena and causes of membrane curvature changes in the process of macroautophagy, and the mechanisms of ATGs in membrane curvature and autophagosome membrane formation. [ABSTRACT FROM AUTHOR]

Published

2023

19. DRAM1 Promotes Lysosomal Delivery of Mycobacterium marinum in Macrophages.

Author

Banducci-Karp, Adrianna, Xie, Jiajun, Engels, Sem A. G., Sarantaris, Christos, van Hage, Patrick, Varela, Monica, Meijer, Annemarie H., and van der Vaart, Michiel

Subjects

*MYCOBACTERIUM, *MACROPHAGES, *MYCOBACTERIAL diseases, *LYSOSOMES, *DISEASE resistance of plants, *MEMBRANE proteins, *MYCOBACTERIUM bovis, *MYCOBACTERIA

Abstract

Damage-Regulated Autophagy Modulator 1 (DRAM1) is an infection-inducible membrane protein, whose function in the immune response is incompletely understood. Based on previous results in a zebrafish infection model, we have proposed that DRAM1 is a host resistance factor against intracellular mycobacterial infection. To gain insight into the cellular processes underlying DRAM1-mediated host defence, here we studied the interaction of DRAM1 with Mycobacterium marinum in murine RAW264.7 macrophages. We found that, shortly after phagocytosis, DRAM1 localised in a punctate pattern to mycobacteria, which gradually progressed to full DRAM1 envelopment of the bacteria. Within the same time frame, DRAM1-positive mycobacteria colocalised with the LC3 marker for autophagosomes and LysoTracker and LAMP1 markers for (endo)lysosomes. Knockdown analysis revealed that DRAM1 is required for the recruitment of LC3 and for the acidification of mycobacteria-containing vesicles. A reduction in the presence of LAMP1 further suggested reduced fusion of lysosomes with mycobacteria-containing vesicles. Finally, we show that DRAM1 knockdown impairs the ability of macrophages to defend against mycobacterial infection. Together, these results support that DRAM1 promotes the trafficking of mycobacteria through the degradative (auto)phagolysosomal pathway. Considering its prominent effect on host resistance to intracellular infection, DRAM1 is a promising target for therapeutic modulation of the microbicidal capacity of macrophages. [ABSTRACT FROM AUTHOR]

Published

2023

20. Xenophagy as a Strategy for Mycobacterium leprae Elimination during Type 1 or Type 2 Leprosy Reactions: A Systematic Review

Author

Débora Dantas Nucci Cerqueira, Ana Letícia Silva Pereira, Ana Elisa Coelho da Costa, Tarcísio Joaquim de Souza, Matheus Santos de Sousa Fernandes, Fabrício Oliveira Souto, and Patrícia d’Emery Alves Santos

Subjects

Mycobacterium leprae, leprosy reactions, autophagy, xenophagy, Medicine

Abstract

Background: Mycobacterium leprae is an intracellular bacillus that causes leprosy, a neglected disease that affects macrophages and Schwann cells. Leprosy reactions are acute inflammatory responses to mycobacterial antigens, classified as type1 (T1R), a predominant cellular immune response, or type2 (T2R), a humoral phenomenon, leading to a high number of bacilli in infected cells and nerve structures. Xenophagy is a type of selective autophagy that targets intracellular bacteria for lysosomal degradation; however, its immune mechanisms during leprosy reactions are still unclear. This review summarizes the relationship between the autophagic process and M. leprae elimination during leprosy reactions. Methods: Three databases, PubMed/Medline (n = 91), Scopus (n = 73), and ScienceDirect (n = 124), were searched. After applying the eligibility criteria, articles were selected for independent peer reviewers in August 2023. Results: From a total of 288 studies retrieved, eight were included. In multibacillary (MB) patients who progressed to T1R, xenophagy blockade and increased inflammasome activation were observed, with IL-1β secretion before the reactional episode occurrence. On the other hand, recent data actually observed increased IL-15 levels before the reaction began, as well as IFN-γ production and xenophagy induction. Conclusion: Our search results showed a dichotomy in the T1R development and their relationship with xenophagy. No T2R studies were found.

Published

2023

21. Editorial: Emerging mechanistic insights of selective and Nonselective Autophagy in liver and gut diseases and their treatment strategies in the era of COVID-19

Author

Md. Abdul Alim Al-Bari, Manoj B. Menon, and Nabil Eid

Subjects

autophagy, lipophagy, mitophagy, liver diseases, COVID-19, xenophagy, Therapeutics. Pharmacology, RM1-950

Published

2023

22. The Role of Nucleases Cleaving TLR3, TLR7/8 and TLR9 Ligands, Dicer RNase and miRNA/piRNA Proteins in Functional Adaptation to the Immune Escape and Xenophagy of Prostate Cancer Tissue.

Author

Kocic, Gordana, Hadzi-Djokic, Jovan, Colic, Miodrag, Veljkovic, Andrej, Tomovic, Katarina, Roumeliotis, Stefanos, Smelcerovic, Andrija, and Liakopoulos, Vassilios

Subjects

*NUCLEASES, *TOLL-like receptors, *PYRIMIDINE nucleotides, *PROTEINS, *PROSTATE cancer, *ANDROGEN receptors, *NUCLEIC acids

Abstract

The prototypic sensors for the induction of innate and adaptive immune responses are the Toll-like receptors (TLRs). Unusually high expression of TLRs in prostate carcinoma (PC), associated with less differentiated, more aggressive and more propagating forms of PC, changed the previous paradigm about the role of TLRs strictly in immune defense system. Our data reveal an entirely novel role of nucleic acids-sensing Toll-like receptors (NA-TLRs) in functional adaptation of malignant cells for supply and digestion of surrounding metabolic substrates from dead cells as specific mechanism of cancer cells survival, by corresponding ligands accelerated degradation and purine/pyrimidine salvage pathway. The spectrophotometric measurement protocols used for the determination of the activity of RNases and DNase II have been optimized in our laboratory as well as the enzyme-linked immunosorbent method for the determination of NF-κB p65 in prostate tissue samples. The protocols used to determine Dicer RNase, AGO2, TARBP2 and PIWIL4 were based on enzyme-linked immunosorbent assay. The amount of pre-existing acid-soluble oligonucleotides was measured and expressed as coefficient of absorbance. The activities of acid DNase II and RNase T2, and the activities of nucleases cleaving TLR3, TLR7/8 and TLR9 ligands (Poly I:C, poly U and unmethylated CpG), increased several times in PC, compared to the corresponding tumor adjacent and control tissue, exerting very high sensitivity and specificity of above 90%. Consequently higher levels of hypoxanthine and NF-κB p65 were reported in PC, whereas the opposite results were observed for miRNA biogenesis enzyme (Dicer RNase), miRNA processing protein (TARB2), miRNA-induced silencing complex protein (Argonaute-AGO) and PIWI-interacting RNAs silence transposon. Considering the crucial role of purine and pyrimidine nucleotides as energy carriers, subunits of nucleic acids and nucleotide cofactors, future explorations will be aimed to design novel anti-cancer immune strategies based on a specific acid endolysosomal nuclease inhibition. [ABSTRACT FROM AUTHOR]

Published

2023

23. Multifaceted roles of TAX1BP1 in autophagy.

Author

White, Jesse, Suklabaidya, Sujit, Vo, Mai Tram, Choi, Young Bong, and Harhaj, Edward W.

Subjects

ZINC-finger proteins, MYELOID differentiation factor 88, HTLV, HTLV-I, TUMOR necrosis factor receptors, GABA receptors, AUTOPHAGY

Abstract

TAX1BP1 is a selective macroautophagy/autophagy receptor that plays a central role in host defense to pathogens and in regulating the innate immune system. TAX1BP1 facilitates the xenophagic clearance of pathogenic bacteria such as Salmonella typhimurium and Mycobacterium tuberculosis and regulates TLR3 (toll-like receptor 3)-TLR4 and DDX58/RIG-I-like receptor (RLR) signaling by targeting TICAM1 and MAVS for autophagic degradation respectively. In addition to these canonical autophagy receptor functions, TAX1BP1 can also exert multiple accessory functions that influence the biogenesis and maturation of autophagosomes. In this review, we will discuss and integrate recent findings related to the autophagy function of TAX1BP1 and highlight outstanding questions regarding its functions in autophagy and regulation of innate immunity and host defense. Abbreviations: ATG: autophagy related; CALCOCO: calcium binding and coiled-coil domain; CC: coiled-coil; CHUK/IKKα: conserved helix-loop-helix ubiquitous kinase; CLIR: noncanonical LC3-interacting region; GABARAP: gamma-aminobutyric acid receptor associated protein; HTLV-1: human T-lymphotropic virus 1; IFN: interferon; IL1B/IL1β: interleukin 1 beta; LIR: LC3-interacting region; LPS: lipopolysaccharide; MAP1LC3/LC3: microtubule-associated protein 1 light chain 3; MAPK/JNK: mitogen-activated protein kinase; mATG8: mammalian Atg8 homolog; MAVS: mitochondrial antiviral signaling protein; MEF: mouse embryonic fibroblast; MTB: Mycobacterium tuberculosis; MYD88: myeloid differentiation primary response gene 88; NBR1: NBR1, autophagy cargo receptor; NFKB/NF-κB: nuclear factor of kappa light polypeptide gene enhancer in B cells; OPTN: optineurin; Poly(I:C): polyinosinic:polycytidylic acid; PTM: post-translational modification; RB1CC1: RB1-inducible coiled-coil 1; RIPK: receptor (TNFRSF)-interacting serine-threonine kinase; RLR: DDX58/RIG-I-like receptor; RSV: respiratory syncytia virus; SKICH: SKIP carboxyl homology; SLR: SQSTM1 like receptor; SQSTM1: sequestosome 1; TAX1BP1: Tax1 (human T cell leukemia virus type I) binding protein 1; TBK1: TANK-binding kinase 1; TICAM1: toll-like receptor adaptor molecule 1; TLR: toll-like receptor; TNF: tumor necrosis factor; TNFAIP3: TNF alpha induced protein 3; TNFR: tumor necrosis factor receptor; TOM1: target of myb1 trafficking protein; TRAF: TNF receptor-associated factor; TRIM32: tripartite motif-containing 32; UBD: ubiquitin binding domain; ZF: zinc finger. [ABSTRACT FROM AUTHOR]

Published

2023

24. The exploitation of host autophagy and ubiquitin machinery by Mycobacterium tuberculosis in shaping immune responses and host defense during infection.

Author

Shariq, Mohd, Quadir, Neha, Alam, Anwar, Zarin, Sheeba, Sheikh, Javaid A., Sharma, Neha, Samal, Jasmine, Ahmad, Uzair, Kumari, Indu, Hasnain, Seyed E., and Ehtesham, Nasreen Z.

Subjects

UBIQUITIN ligases, INTERFERON receptors, MYCOBACTERIUM tuberculosis, UBIQUITIN, TUBULINS, NF-kappa B, MITOGEN-activated protein kinases

Abstract

Intracellular pathogens have evolved various efficient molecular armaments to subvert innate defenses. Cellular ubiquitination, a normal physiological process to maintain homeostasis, is emerging one such exploited mechanism. Ubiquitin (Ub), a small protein modifier, is conjugated to diverse protein substrates to regulate many functions. Structurally diverse linkages of poly-Ub to target proteins allow enormous functional diversity with specificity being governed by evolutionarily conserved enzymes (E3-Ub ligases). The Ub-binding domain (UBD) and LC3-interacting region (LIR) are critical features of macroautophagy/autophagy receptors that recognize Ub-conjugated on protein substrates. Emerging evidence suggests that E3-Ub ligases unexpectedly protect against intracellular pathogens by tagging poly-Ub on their surfaces and targeting them to phagophores. Two E3-Ub ligases, PRKN and SMURF1, provide immunity against Mycobacterium tuberculosis (M. tb). Both enzymes conjugate K63 and K48-linked poly-Ub to M. tb for successful delivery to phagophores. Intriguingly, M. tb exploits virulence factors to effectively dampen host-directed autophagy utilizing diverse mechanisms. Autophagy receptors contain LIR-motifs that interact with conserved Atg8-family proteins to modulate phagophore biogenesis and fusion to the lysosome. Intracellular pathogens have evolved a vast repertoire of virulence effectors to subdue host-immunity via hijacking the host ubiquitination process. This review highlights the xenophagy-mediated clearance of M. tb involving host E3-Ub ligases and counter-strategy of autophagy inhibition by M. tb using virulence factors. The role of Ub-binding receptors and their mode of autophagy regulation is also explained. We also discuss the co-opting and utilization of the host Ub system by M. tb for its survival and virulence. Abbreviations: APC: anaphase promoting complex/cyclosome; ATG5: autophagy related 5; BCG: bacille Calmette-Guerin; C2: Ca2+-binding motif; CALCOCO2: calcium binding and coiled-coil domain 2; CUE: coupling of ubiquitin conjugation to ER degradation domains; DUB: deubiquitinating enzyme; GABARAP: GABA type A receptor-associated protein; HECT: homologous to the E6-AP carboxyl terminus; IBR: in-between-ring fingers; IFN: interferon; IL1B: interleukin 1 beta; KEAP1: kelch like ECH associated protein 1; LAMP1: lysosomal associated membrane protein 1; LGALS: galectin; LIR: LC3-interacting region; MAPK11/p38: mitogen-activated protein kinase 11; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; MAP3K7/TAK1: mitogen-activated protein kinase kinase kinase 7; MAPK8/JNK: mitogen-activated protein kinase 8; MHC-II: major histocompatibility complex-II; MTOR: mechanistic target of rapamycin kinase; NBR1: NBR1 autophagy cargo receptor; NFKB1/p50: nuclear factor kappa B subunit 1; OPTN: optineurin; PB1: phox and bem 1; PE/PPE: proline-glutamic acid/proline-proline-glutamic acid; PknG: serine/threonine-protein kinase PknG; PRKN: parkin RBR E3 ubiquitin protein ligase; RBR: RING-in between RING; RING: really interesting new gene; RNF166: RING finger protein 166; ROS: reactive oxygen species; SMURF1: SMAD specific E3 ubiquitin protein ligase 1; SQSTM1: sequestosome 1; STING1: stimulator of interferon response cGAMP interactor 1; TAX1BP1: Tax1 binding protein 1; TBK1: TANK binding kinase 1; TNF: tumor necrosis factor; TRAF6: TNF receptor associated factor 6; Ub: ubiquitin; UBA: ubiquitin-associated; UBAN: ubiquitin-binding domain in ABIN proteins and NEMO; UBD: ubiquitin-binding domain; UBL: ubiquitin-like; ULK1: unc-51 like autophagy activating kinase 1. [ABSTRACT FROM AUTHOR]

Published

2023

25. Invasive Pathobionts Contribute to Colon Cancer Initiation by Counterbalancing Epithelial Antimicrobial ResponsesSummary

Author

Linda Chia-Hui Yu, Shu-Chen Wei, Yi-Hsuan Li, Po-Yu Lin, Xin-Yu Chang, Jui-Ping Weng, Yin-Wen Shue, Liang-Chuan Lai, Jin-Town Wang, Yung-Ming Jeng, and Yen-Hsuan Ni

Subjects

Colon Carcinoma, Gut Microbiome, Intracellular Microbes, Xenophagy, Reactive Oxygen Species, Organoids and Spheroids, Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Background & Aims: Microbiota dysbiosis and mucosa-associated bacteria are involved in colorectal cancer progression. We hypothesize that an interaction between virulent pathobionts and epithelial defense promotes tumorigenesis. Methods: Chemical-induced CRC mouse model was treated with antibiotics at various phases. Colonic tissues and fecal samples were collected in a time-serial mode and analyzed by gene microarray and 16S rRNA sequencing. Intraepithelial bacteria were isolated using a gentamicin resistance assay, and challenged in epithelial cultures. Results: Our study showed that antibiotic treatment at midphase but not early or late phase reduced mouse tumor burden, suggesting a time-specific host–microbe interplay. A unique antimicrobial transcriptome profile showing an inverse relationship between autophagy and oxidative stress genes was correlated with a transient surge in microbial diversity and virulence emergence in mouse stool during cancer initiation. Gavage with fimA/fimH/htrA-expressing invasive Escherichia coli isolated from colonocytes increased tumor burden in recipient mice, whereas inoculation of bacteria deleted of htrA or triple genes did not. The invasive E. coli suppressed epithelial autophagy activity through reduction of microtubule-associated protein 1 light-chain 3 transcripts and caused dual oxidase 2–dependent free radical overproduction and tumor cell hyperproliferation. A novel alternating spheroid culture model was developed for sequential bacterial challenge to address the long-term changes in host–microbe interaction for chronic tumor growth. Epithelial cells with single bacterial encounter showed a reduction in transcript levels of autophagy genes while those sequentially challenged with invasive E. coli showed heightened autophagy gene expression to eliminate intracellular microbes, implicating that bacteria-dependent cell hyperproliferation could be terminated at late phases. Finally, the presence of bacterial htrA and altered antimicrobial gene expression were observed in human colorectal cancer specimens. Conclusions: Invasive pathobionts contribute to cancer initiation during a key time frame by counterbalancing autophagy and oxidative stress in the colonic epithelium. Monitoring gut microbiota and antimicrobial patterns may help identify the window of opportunity for intervention with bacterium-targeted precision medicine.

Published

2022

26. Actin-based motility allows Listeria monocytogenes to avoid autophagy in the macrophage cytosol.

Author

Cheng, Mandy I, Chen, Chen, Engström, Patrik, Portnoy, Daniel A, and Mitchell, Gabriel

Subjects

Cytosol, Macrophages, Listeria monocytogenes, Actins, Bacterial Proteins, Membrane Proteins, Microscopy, Fluorescence, DNA Mutational Analysis, Motion, Autophagy, Mutant Proteins, Host-Pathogen Interactions, Protein Multimerization, Immune Evasion, Time-Lapse Imaging, ActA, PLCs, bacteria, ubiquitin, xenophagy, Microscopy, Fluorescence, Microbiology, Medical Microbiology

Abstract

Listeria monocytogenes grows in the host cytosol and uses the surface protein ActA to promote actin polymerisation and mediate actin-based motility. ActA, along with two secreted bacterial phospholipases C, also mediates avoidance from autophagy, a degradative process that targets intracellular microbes. Although it is known that ActA prevents autophagic recognition of L. monocytogenes in epithelial cells by masking the bacterial surface with host factors, the relative roles of actin polymerisation and actin-based motility in autophagy avoidance are unclear in macrophages. Using pharmacological inhibition of actin polymerisation and a collection of actA mutants, we found that actin polymerisation prevented the colocalisation of L. monocytogenes with polyubiquitin, the autophagy receptor p62, and the autophagy protein LC3 during macrophage infection. In addition, the ability of L. monocytogenes to stimulate actin polymerisation promoted autophagy avoidance and growth in macrophages in the absence of phospholipases C. Time-lapse microscopy using green fluorescent protein-LC3 macrophages and a probe for filamentous actin showed that bacteria undergoing actin-based motility moved away from LC3-positive membranes. Collectively, these results suggested that although actin polymerisation protects the bacterial surface from autophagic recognition, actin-based motility allows escape of L. monocytogenes from autophagic membranes in the macrophage cytosol.

Published

2018

27. The role of ATG16L2 in autophagy and disease.

Author

Don Wai Luu, Laurence, Kaakoush, Nadeem O., and Castaño-Rodríguez, Natalia

Subjects

INFLAMMATORY bowel diseases, AUTOPHAGY, TUBULINS, CROHN'S disease, SYSTEMIC lupus erythematosus

Abstract

Macroautophagy/autophagy, a fundamental cell process for nutrient recycling and defense against pathogens (termed xenophagy), is crucial to human health. ATG16L2 (autophagy related 16 like 2) is an autophagic protein and a paralog of ATG16L1. Both proteins are implicated in similar diseases such as cancer and other chronic diseases; however, most autophagy studies to date have primarily focused on the function of ATG16L1, with ATG16L2 remaining uncharacterized and understudied. Overexpression of ATG16L2 has been reported in various cancers including colorectal, gastric, and prostate carcinomas, whereas altered methylation of ATG16L2 has been associated with lung cancer formation and poorer response to therapy in leukemia. In addition, ATG16L2 polymorphisms have been implicated in a range of other diseases including inflammatory bowel diseases and neurodegenerative disorders. Despite this likely role in human health, the function of this enigmatic protein in autophagy remains unknown. Here, we review current studies on ATG16L2 and collate evidence that suggests that this protein is a potential modulator of autophagy as well as the implications this has on pathogenesis. Abbreviations: ATG5: autophagy related 5; ATG12: autophagy related 12; ATG16L1: autophagy related 16 like 1; ATG16L2: autophagy related 16 like 2; CD: Crohn disease; IBD: inflammatory bowel diseases; IRGM: immunity related GTPase M; MAP1LC3/LC3: microtubule associated protein 1 light chain 3; PE: phosphatidylethanolamine; RB1CC1: RB1 inducible coiled-coil 1; SLE: systemic lupus erythematosus; WIPI2B: WD repeat domain, phosphoinositide interacting 2B [ABSTRACT FROM AUTHOR]

Published

2022

28. Cargo receptors and adaptors for selective autophagy in plant cells.

Author

Luong, Ai My, Koestel, Jérôme, Bhati, Kaushal Kumar, and Batoko, Henri

Subjects

*AUTOPHAGY, *PLANT physiology, *CELL physiology, *SCAFFOLD proteins, *EUKARYOTIC cells, *DOCKS, *HOMEOSTASIS

Abstract

Plant selective (macro)autophagy is a highly regulated process where eukaryotic cells spatiotemporally degrade some of their constituents that have become superfluous or harmful. The identification and characterization of the factors determining this selectivity make it possible to integrate selective (macro)autophagy into plant cell physiology and homeostasis. The specific cargo receptors and/or scaffold proteins involved in this pathway are generally not structurally conserved, as are the biochemical mechanisms underlying recognition and integration of a given cargo into the autophagosome in different cell types. This review discusses the few specific cargo receptors described in plant cells to highlight key features of selective autophagy in the plant kingdom and its integration with plant physiology, aiming to identify evolutionary convergence and knowledge gaps to be filled by future research. [ABSTRACT FROM AUTHOR]

Published

2022

29. Autophagy controls Wolbachia infection upon bacterial damage and in aging Drosophila

Author

Dávid Hargitai, Lili Kenéz, Muna Al-Lami, Győző Szenczi, Péter Lőrincz, and Gábor Juhász

Subjects

autophagy, xenophagy, Drosophila, Wolbachia, wolbophagy, Biology (General), QH301-705.5

Abstract

Autophagy is a conserved catabolic process in eukaryotic cells that degrades intracellular components in lysosomes, often in an organelle-specific selective manner (mitophagy, ERphagy, etc). Cells also use autophagy as a defense mechanism, eliminating intracellular pathogens via selective degradation known as xenophagy. Wolbachia pipientis is a Gram-negative intracellular bacterium, which is one of the most common parasites on Earth affecting approximately half of terrestrial arthropods. Interestingly, infection grants the host resistance against other pathogens and modulates lifespan, so this bacterium resembles an endosymbiont. Here we demonstrate that Drosophila somatic cells normally degrade a subset of these bacterial cells, and autophagy is required for selective elimination of Wolbachia upon antibiotic damage. In line with these, Wolbachia overpopulates in autophagy-compromised animals during aging while its presence fails to affect host lifespan unlike in case of control flies. The autophagic degradation of Wolbachia thus represents a novel antibacterial mechanism that controls the propagation of this unique bacterium, behaving both as parasite and endosymbiont at the same time.

Published

2022

30. Autophagy in Crohn’s Disease: Converging on Dysfunctional Innate Immunity

Author

Kibrom M. Alula and Arianne L. Theiss

Subjects

Crohn’s disease, innate immunity, mitophagy, xenophagy, ER stress, mitochondria, Cytology, QH573-671

Abstract

Crohn’s disease (CD) is a chronic inflammatory bowel disease marked by relapsing, transmural intestinal inflammation driven by innate and adaptive immune responses. Autophagy is a multi-step process that plays a critical role in maintaining cellular homeostasis by degrading intracellular components, such as damaged organelles and invading bacteria. Dysregulation of autophagy in CD is revealed by the identification of several susceptibility genes, including ATG16L1, IRGM, NOD2, LRRK2, ULK1, ATG4, and TCF4, that are involved in autophagy. In this review, the role of altered autophagy in the mucosal innate immune response in the context of CD is discussed, with a specific focus on dendritic cells, macrophages, Paneth cells, and goblet cells. Selective autophagy, such as xenophagy, ERphagy, and mitophagy, that play crucial roles in maintaining intestinal homeostasis in these innate immune cells, are discussed. As our understanding of autophagy in CD pathogenesis evolves, the development of autophagy-targeted therapeutics may benefit subsets of patients harboring impaired autophagy.

Published

2023

31. Locally generated C3 regulates the clearance of Toxoplasma gondii by IFN-γ-primed macrophage through regulation of xenophagy.

Author

Bo Liu, Yan Yan, Xiaoreng Wang, and Nannan Chen

Subjects

PARASITES, PERITONEAL macrophages, TOXOPLASMA gondii, CELL survival, NATURAL immunity, TRANSMISSION electron microscopy, MACROPHAGES, LASER microscopy

Abstract

Exogenous pathogen infection can induce autophagy in cells. Autophagy is essential for cell survival, development, and homeostasis. It not only regulates cell defense and stress, but also has a close relationship with innate and adaptive immunity. Complement is an important part of innate immunity, which could be activated by three approaches, including classic, alternative, and lectin pathways. All the three pathways result in the activation of C3, and generate anaphylatoxin fragments C3a and C5a, and formation of the membrane attack complex. Either C3a or C5a induces the inflammatory cytokines through binding to C3aR or C5aR, respectively. However, it is still unknown whether the complement could regulate the autophagy of intracellular microorganisms or not. In this study, we constructed a Toxoplasma gondii (T. gondii) and macrophages co-culture experimental model using T. gondii expressing enhanced green fluorescence protein (EGFP) fluorescence and C3-/-C57BL/6J mice for that T. gondii invaded peritoneal macrophages in mice. Western blot, laser confocal microscopy (LCM), and transmission electron microscopy (TEM) were used to observe the changes of autophagy between the macrophages from wild-type (WT) and C3-/-mice. Flow cytometry and LCM were used to investigate the effect of autophagy on the killing ability of macrophages against T. gondii. Here, we found that local C3 could suppress not only the canonical autophagy of macrophage, but also the xenophagy to T. gondii. Interestingly, the inhibition of C3 on host cell autophagy could significantly suppress the clearance of T. gondii by the IFN-γ-primed macrophage. Finally, we investigated the mechanism of the autophagy regulation of C3 that the effect of C3 on the macrophage-specific autophagy against T. gondii depends on mTOR. And, there is C3a but not C5a/C5aR involved in regulating macrophage xenophagy against T. gondii. Collectively, our findings suggest locally generated C3 regulates the clearance of T. gondii by Macrophage through the regulation of the non-canonical IFN-γ-dependent autophagy pathway, and paint a clearer picture in the regulation of autophagy by innate immune components. [ABSTRACT FROM AUTHOR]

Published

2022

32. Immunity-related GTPase IRGM at the intersection of autophagy, inflammation, and tumorigenesis.

Author

Goswami, Apeksha Bharatgiri, Karadarević, Dimitrije, and Castaño-Rodríguez, Natalia

Subjects

*AUTOPHAGY, *GUANOSINE triphosphatase, *G proteins, *CROSS reactions (Immunology), *NEOPLASTIC cell transformation

Abstract

The human immunity-related GTPase M (IRGM) is a GTP-binding protein that regulates selective autophagy including xenophagy and mitophagy. IRGM impacts autophagy by (1) affecting mitochondrial fusion and fission, (2) promoting the co-assembly of ULK1 and Beclin 1, (3) enhancing Beclin 1 interacting partners (AMBRA1, ATG14L1, and UVRAG), (4) interacting with other key proteins (ATG16L1, p62, NOD2, cGAS, TLR3, and RIG-I), and (5) regulating lysosomal biogenesis. IRGM also negatively regulates NLRP3 inflammasome formation and therefore, maturation of the important pro-inflammatory cytokine IL-1β, impacting inflammation and pyroptosis. Ultimately, this affords protection against chronic inflammatory diseases. Importantly, ten IRGM polymorphisms (rs4859843, rs4859846, rs4958842, rs4958847, rs1000113, rs10051924, rs10065172, rs11747270, rs13361189, and rs72553867) have been associated with human inflammatory disorders including cancer, which suggests that these genetic variants are functionally relevant to the autophagic and inflammatory responses. The current review contextualizes IRGM, its modulation of autophagy, and inflammation, and emphasizes the role of IRGM as a cross point of immunity and tumorigenesis. [ABSTRACT FROM AUTHOR]

Published

2022

33. Induction of Autophagy by Ursolic Acid Promotes the Elimination of Trypanosoma cruzi Amastigotes From Macrophages and Cardiac Cells.

Author

Cristina Vanrell, María, José Martinez, Santiago, Ibel Muñoz, Lucila, Nebaí Salassa, Betiana, Gambarte Tudela, Julián, and Silvia Romano, Patricia

Subjects

TRYPANOSOMA cruzi, HEART cells, URSOLIC acid, AMASTIGOTES, AUTOPHAGY, CHAGAS' disease, PERITONEAL macrophages

Abstract

Chagas disease, caused by the parasite Trypanosoma cruzi, is an infectious illness endemic to Latin America and still lacks an effective treatment for the chronic stage. In a previous study in our laboratory, we established the protective role of host autophagy in vivo during T. cruzi infection in mice and proposed this process as one of the mechanisms involved in the innate immune response against this parasite. In the search for an autophagy inducer that increases the anti-T. cruzi response in the host, we found ursolic acid (UA), a natural pentacyclic triterpene with many biological actions including autophagy induction. The aim of this work was to study the effect of UA on T. cruzi infection in vitro in the late infection stage, when the nests of intracellular parasites are forming, in both macrophages and cardiac cells. To test this effect, the cells were infected with T. cruzi for 24 h and then treated with UA (5-10 µM). The data showed that UA significantly decreased the number of amastigotes found in infected cells in comparison with non-treated cells. UA also induced the autophagy response in both macrophages and cardiac cells under the studied conditions, and the inhibition of this pathway during UA treatment restored the level of infection. Interestingly, LC3 protein, the main marker of autophagy, was recruited around amastigotes and the acidic probe LysoTracker localized with them, two key features of xenophagy. A direct cytotoxic effect of UA was also found on trypomastigotes of T. cruzi, whereas epimastigotes and amastigotes displayed more resistance to this drug at the studied concentrations. Taken together, these data showed that this natural compound reduces T. cruzi infection in the later stages by promoting parasite damage through the induction of autophagy. This action, in addition to the effect of this compound on trypomastigotes, points to UA as an interesting lead for Chagas disease treatment in the future. [ABSTRACT FROM AUTHOR]

Published

2022

34. A bacterial effector counteracts host autophagy by promoting degradation of an autophagy component.

Author

Leong, Jia Xuan, Raffeiner, Margot, Spinti, Daniela, Langin, Gautier, Franz‐Wachtel, Mirita, Guzman, Andrew R, Kim, Jung‐Gun, Pandey, Pooja, Minina, Alyona E, Macek, Boris, Hafrén, Anders, Bozkurt, Tolga O, Mudgett, Mary Beth, Börnke, Frederik, Hofius, Daniel, and Üstün, Suayib

Subjects

*XANTHOMONAS campestris, *AUTOPHAGY, *BACTERIAL proteins, *INTRACELLULAR pathogens, *XANTHOMONAS

Abstract

Beyond its role in cellular homeostasis, autophagy plays anti‐ and promicrobial roles in host–microbe interactions, both in animals and plants. One prominent role of antimicrobial autophagy is to degrade intracellular pathogens or microbial molecules, in a process termed xenophagy. Consequently, microbes evolved mechanisms to hijack or modulate autophagy to escape elimination. Although well‐described in animals, the extent to which xenophagy contributes to plant–bacteria interactions remains unknown. Here, we provide evidence that Xanthomonas campestris pv. vesicatoria (Xcv) suppresses host autophagy by utilizing type‐III effector XopL. XopL interacts with and degrades the autophagy component SH3P2 via its E3 ligase activity to promote infection. Intriguingly, XopL is targeted for degradation by defense‐related selective autophagy mediated by NBR1/Joka2, revealing a complex antagonistic interplay between XopL and the host autophagy machinery. Our results implicate plant antimicrobial autophagy in the depletion of a bacterial virulence factor and unravel an unprecedented pathogen strategy to counteract defense‐related autophagy in plant–bacteria interactions. Synopsis: A bacterial effector protein degrades autophagy component SH3P2. This counteracts the host cell's NBR1‐mediated defensive autophagy. Xanthomonas campestis pv. vesicatoria suppresses autophagic turnover in the host cell.Type‐III effector XopL was identified as the cause of this suppression.XopL functions by ubiquitinating host autophagy component SH3P2, which is then degraded in a proteasome‐dependent manner.XopL is itself degraded by NBR1‐mediated selective autophagy. We term this "effectorphagy".Suppression of autophagy counteracts defense‐related selective autophagy in plant‐bacteria interactions. [ABSTRACT FROM AUTHOR]

Published

2022

35. Interaction Between Autophagy and Porphyromonas gingivalis-Induced Inflammation.

Author

Sen Kang, Anna Dai, Huiming Wang, and Pei-Hui Ding

Subjects

PORPHYROMONAS gingivalis, PORPHYROMONAS gingivalis infections, AUTOPHAGY, INFLAMMATION

Abstract

Autophagy is an immune homeostasis process induced by multiple intracellular and extracellular signals. Inflammation is a protective response to harmful stimuli such as pathogen microbial infection and body tissue damage. Porphyromonas gingivalis infection elicits both autophagy and inflammation, and dysregulation of autophagy and inflammation promotes pathology. This review focuses on the interaction between autophagy and inflammation caused by Porphyromonas gingivalis infection, aiming to elaborate on the possible mechanism involved in the interaction. [ABSTRACT FROM AUTHOR]

Published

2022

36. Mycobacterium bovis induces mitophagy to suppress host xenophagy for its intracellular survival.

Author

Song, Yinjuan, Ge, Xin, Chen, Yulan, Hussain, Tariq, Liang, Zhengmin, Dong, Yuhui, Wang, Yuanzhi, Tang, Chengyuan, and Zhou, Xiangmei

Subjects

MYCOBACTERIUM bovis, LISTERIA monocytogenes, HEPATITIS C virus, HEPATITIS B virus, MYCOBACTERIUM tuberculosis, TRANSMISSION electron microscopy, CARRIER proteins

Abstract

Mitophagy is a selective autophagy mechanism for eliminating damaged mitochondria and plays a crucial role in the immune evasion of some viruses and bacteria. Here, we report that Mycobacterium bovis (M. bovis) utilizes host mitophagy to suppress host xenophagy to enhance its intracellular survival. M. bovis is the causative agent of animal tuberculosis and human tuberculosis. In the current study, we show that M. bovis induces mitophagy in macrophages, and the induction of mitophagy is impaired by PINK1 knockdown, indicating the PINK1-PRKN/Parkin pathway is involved in the mitophagy induced by M. bovis. Moreover, the survival of M. bovis in macrophages and the lung bacterial burden of mice are restricted by the inhibition of mitophagy and are enhanced by the induction of mitophagy. Confocal microscopy analysis reveals that induction of mitophagy suppresses host xenophagy by competitive utilization of p-TBK1. Overall, our results suggest that induction of mitophagy enhances M. bovis growth while inhibition of mitophagy improves growth restriction. The findings provide a new insight for understanding the intracellular survival mechanism of M. bovis in the host. Abbreviations: BMDM: mouse bone marrow-derived macrophage; BNIP3: BCL2/adenovirus E1B interacting protein 3; BNIP3L/NIX: BCL2/adenovirus E1B interacting protein 3-like; BCL2L13: BCL2-like 13 (apoptosis facilitator); CCCP: carbonyl cyanide m-cholorophenyl hydrazone; FUNDC1: FUN14 domain-containing 1; FKBP8: FKBP506 binding protein 8; HCV: hepatitis C virus; HBV: hepatitis B virus; IFN: interferon; L. monocytogenes: Listeria monocytogenes; M. bovis: Mycobacterium bovis; Mtb: Mycobacterium tuberculosis; Mdivi-1: mitochondrial division inhibitor 1; PINK1: PTEN-induced putative kinase 1; TBK1: TANK-binding kinase 1; TUFM: Tu translation elongation factor, mitochondrial; TEM: transmission electron microscopy [ABSTRACT FROM AUTHOR]

Published

2022

37. Autophagy receptors as viral targets

Author

Päivi Ylä-Anttila

Subjects

Autophagy, Infection, Receptor, Viruses, Cargo, Xenophagy, Cytology, QH573-671

Abstract

Abstract Activation of autophagy is part of the innate immune response during viral infections. Autophagy involves the sequestration of endogenous or foreign components from the cytosol within double-membraned vesicles and the delivery of their content to the lysosomes for degradation. As part of innate immune responses, this autophagic elimination of foreign components is selective and requires specialized cargo receptors that function as links between a tagged foreign component and the autophagic machinery. Pathogens have evolved ways to evade their autophagic degradation to promote their replication, and recent research has shown autophagic receptors to be an important and perhaps previously overlooked target of viral autophagy inhibition. This is a brief summary of the recent progress in knowledge of virus-host interaction in the context of autophagy receptors.

Published

2021

38. Editorial: Emerging mechanistic insights of selective and Nonselective Autophagy in liver and gut diseases and their treatment strategies in the era of COVID-19.

Author

Al-Bari, Md. Abdul Alim, Menon, Manoj B., and Eid, Nabil

Subjects

COVID-19 pandemic, LIVER diseases, THERAPEUTICS, AUTOPHAGY

Published

2023

39. Molecular definitions of autophagy and related processes

Author

Galluzzi, Lorenzo, Baehrecke, Eric H, Ballabio, Andrea, Boya, Patricia, Pedro, José Manuel Bravo‐San, Cecconi, Francesco, Choi, Augustine M, Chu, Charleen T, Codogno, Patrice, Colombo, Maria Isabel, Cuervo, Ana Maria, Debnath, Jayanta, Deretic, Vojo, Dikic, Ivan, Eskelinen, Eeva‐Liisa, Fimia, Gian Maria, Fulda, Simone, Gewirtz, David A, Green, Douglas R, Hansen, Malene, Harper, J Wade, Jäättelä, Marja, Johansen, Terje, Juhasz, Gabor, Kimmelman, Alec C, Kraft, Claudine, Ktistakis, Nicholas T, Kumar, Sharad, Levine, Beth, Lopez‐Otin, Carlos, Madeo, Frank, Martens, Sascha, Martinez, Jennifer, Melendez, Alicia, Mizushima, Noboru, Münz, Christian, Murphy, Leon O, Penninger, Josef M, Piacentini, Mauro, Reggiori, Fulvio, Rubinsztein, David C, Ryan, Kevin M, Santambrogio, Laura, Scorrano, Luca, Simon, Anna Katharina, Simon, Hans‐Uwe, Simonsen, Anne, Tavernarakis, Nektarios, Tooze, Sharon A, Yoshimori, Tamotsu, Yuan, Junying, Yue, Zhenyu, Zhong, Qing, and Kroemer, Guido

Subjects

Animals, Autophagy, Caenorhabditis elegans, Drosophila melanogaster, Gene Regulatory Networks, Mice, Saccharomyces cerevisiae, Terminology as Topic, chaperone-mediated autophagy, LC3-associated phagocytosis, microautophagy, mitophagy, xenophagy, LC3‐associated phagocytosis, chaperone‐mediated autophagy, Biological Sciences, Information and Computing Sciences, Medical and Health Sciences, Developmental Biology

Abstract

Over the past two decades, the molecular machinery that underlies autophagic responses has been characterized with ever increasing precision in multiple model organisms. Moreover, it has become clear that autophagy and autophagy-related processes have profound implications for human pathophysiology. However, considerable confusion persists about the use of appropriate terms to indicate specific types of autophagy and some components of the autophagy machinery, which may have detrimental effects on the expansion of the field. Driven by the overt recognition of such a potential obstacle, a panel of leading experts in the field attempts here to define several autophagy-related terms based on specific biochemical features. The ultimate objective of this collaborative exchange is to formulate recommendations that facilitate the dissemination of knowledge within and outside the field of autophagy research.

Published

2017

40. Bacterial Pathogens versus Autophagy: Implications for Therapeutic Interventions

Author

Kimmey, Jacqueline M and Stallings, Christina L

Subjects

Biological Sciences, Biomedical and Clinical Sciences, Health Sciences, Infectious Diseases, Infection, Animals, Anti-Bacterial Agents, Autophagy, Autophagy-Related Proteins, Bacteria, Bacterial Infections, Bacterial Physiological Phenomena, Drug Discovery, Host-Pathogen Interactions, Humans, Immunity, Innate, Mycobacterium tuberculosis, Tuberculosis, autophagy, bacterial pathogens, host-directed therapies, xenophagy, Medical and Health Sciences, Immunology, Biological sciences, Biomedical and clinical sciences, Health sciences

Abstract

Research in recent years has focused significantly on the role of selective macroautophagy in targeting intracellular pathogens for lysosomal degradation, a process termed xenophagy. In this review we evaluate the proposed roles for xenophagy in controlling bacterial infection, highlighting the concept that successful pathogens have evolved ways to subvert or exploit this defense, minimizing the actual effectiveness of xenophagy in innate immunity. Instead, studies in animal models have revealed that autophagy-associated proteins often function outside of xenophagy to influence bacterial pathogenesis. In light of current efforts to manipulate autophagy and the development of host-directed therapies to fight bacterial infections, we also discuss the implications stemming from the complicated relationship that exists between autophagy and bacterial pathogens.

Published

2016

41. Editorial: Xenophagy: Its role in pathogen infections

Author

Xiaona Zhao, Yongxia Liu, Hongwei Wang, Wentao Li, and Jianzhu Liu

Subjects

Viruses, bacteria, infection, xenophagy, pathogen, Microbiology, QR1-502

Published

2022

42. Induction of Autophagy by Ursolic Acid Promotes the Elimination of Trypanosoma cruzi Amastigotes From Macrophages and Cardiac Cells

Author

María Cristina Vanrell, Santiago José Martinez, Lucila Ibel Muñoz, Betiana Nebaí Salassa, Julián Gambarte Tudela, and Patricia Silvia Romano

Subjects

Chagas disease, Trypanosoma cruzi, amastigotes, autophagy, xenophagy, ursolic acid, Microbiology, QR1-502

Abstract

Chagas disease, caused by the parasite Trypanosoma cruzi, is an infectious illness endemic to Latin America and still lacks an effective treatment for the chronic stage. In a previous study in our laboratory, we established the protective role of host autophagy in vivo during T. cruzi infection in mice and proposed this process as one of the mechanisms involved in the innate immune response against this parasite. In the search for an autophagy inducer that increases the anti-T. cruzi response in the host, we found ursolic acid (UA), a natural pentacyclic triterpene with many biological actions including autophagy induction. The aim of this work was to study the effect of UA on T. cruzi infection in vitro in the late infection stage, when the nests of intracellular parasites are forming, in both macrophages and cardiac cells. To test this effect, the cells were infected with T. cruzi for 24 h and then treated with UA (5–10 µM). The data showed that UA significantly decreased the number of amastigotes found in infected cells in comparison with non-treated cells. UA also induced the autophagy response in both macrophages and cardiac cells under the studied conditions, and the inhibition of this pathway during UA treatment restored the level of infection. Interestingly, LC3 protein, the main marker of autophagy, was recruited around amastigotes and the acidic probe LysoTracker localized with them, two key features of xenophagy. A direct cytotoxic effect of UA was also found on trypomastigotes of T. cruzi, whereas epimastigotes and amastigotes displayed more resistance to this drug at the studied concentrations. Taken together, these data showed that this natural compound reduces T. cruzi infection in the later stages by promoting parasite damage through the induction of autophagy. This action, in addition to the effect of this compound on trypomastigotes, points to UA as an interesting lead for Chagas disease treatment in the future.

Published

2022

43. Membrane Curvature: The Inseparable Companion of Autophagy

Author

Lei Liu, Yu Tang, Zijuan Zhou, Yuan Huang, Rui Zhang, Hao Lyu, Shuai Xiao, Dong Guo, Declan William Ali, Marek Michalak, Xing-Zhen Chen, Cefan Zhou, and Jingfeng Tang

Subjects

autophagy, membrane curvature, Atg proteins, ER-phagy, nucleophagy, xenophagy, Cytology, QH573-671

Abstract

Autophagy is a highly conserved recycling process of eukaryotic cells that degrades protein aggregates or damaged organelles with the participation of autophagy-related proteins. Membrane bending is a key step in autophagosome membrane formation and nucleation. A variety of autophagy-related proteins (ATGs) are needed to sense and generate membrane curvature, which then complete the membrane remodeling process. The Atg1 complex, Atg2-Atg18 complex, Vps34 complex, Atg12-Atg5 conjugation system, Atg8-phosphatidylethanolamine conjugation system, and transmembrane protein Atg9 promote the production of autophagosomal membranes directly or indirectly through their specific structures to alter membrane curvature. There are three common mechanisms to explain the change in membrane curvature. For example, the BAR domain of Bif-1 senses and tethers Atg9 vesicles to change the membrane curvature of the isolation membrane (IM), and the Atg9 vesicles are reported as a source of the IM in the autophagy process. The amphiphilic helix of Bif-1 inserts directly into the phospholipid bilayer, causing membrane asymmetry, and thus changing the membrane curvature of the IM. Atg2 forms a pathway for lipid transport from the endoplasmic reticulum to the IM, and this pathway also contributes to the formation of the IM. In this review, we introduce the phenomena and causes of membrane curvature changes in the process of macroautophagy, and the mechanisms of ATGs in membrane curvature and autophagosome membrane formation.

Published

2023

44. The crosstalk between bacteria and host autophagy: host defense or bacteria offense.

Author

Zheng, Lin, Wei, Fang, and Li, Guolin

Abstract

Xenophagy is a specific selective autophagy for the elimination of intracellular bacteria. Current evidence suggests that the processes for host autophagy system to recognize and eliminate invading bacteria are complex, and vary according to different pathogens. Although both ubiquitin-dependent and ubiquitin-independent autophagy exist in host to defense invading bacteria, successful pathogens have evolved diverse strategies to escape from or paralyze host autophagy system. In this review, we discuss the mechanisms of host autophagy system to recognize and eliminate intracellular pathogens and the mechanisms of different pathogens to escape from or paralyze host autophagy system, with a particular focus on the most extensively studied bacteria. [ABSTRACT FROM AUTHOR]

Published

2022

45. Mechanisms underlying ubiquitin-driven selective mitochondrial and bacterial autophagy.

Author

Goodall, Ellen A., Kraus, Felix, and Harper, J. Wade

Subjects

*LYSOSOMES, *AUTOPHAGY, *MITOCHONDRIA, *FREIGHT & freightage, *UBIQUITIN, *PROTEINS

Abstract

Selective autophagy specifically eliminates damaged or superfluous organelles, maintaining cellular health. In this process, a double membrane structure termed an autophagosome captures target organelles or proteins and delivers this cargo to the lysosome for degradation. The attachment of the small protein ubiquitin to cargo has emerged as a common mechanism for initiating organelle or protein capture by the autophagy machinery. In this process, a suite of ubiquitin-binding cargo receptors function to initiate autophagosome assembly in situ on the target cargo, thereby providing selectivity in cargo capture. Here, we review recent efforts to understand the biochemical mechanisms and principles by which cargo are marked with ubiquitin and how ubiquitin-binding cargo receptors use conserved structural modules to recruit the autophagosome initiation machinery, with a particular focus on mitochondria and intracellular bacteria as cargo. These emerging mechanisms provide answers to long-standing questions in the field concerning how selectivity in cargo degradation is achieved. Goodall et al. examine recent advances in understanding the players in selective autophagy, focusing on common themes among different targets for degradation. These similarities illustrate that additional components likely remain to be discovered and expand the set of overlapping interactions driving de novo autophagosome biogenesis at targets of degradation. [ABSTRACT FROM AUTHOR]

Published

2022

46. When the Phagosome Gets Leaky: Pore-Forming Toxin-Induced Non-Canonical Autophagy (PINCA).

Author

Herb, Marc, Gluschko, Alexander, Farid, Alina, and Krönke, Martin

Subjects

BACTERIAL diseases, PHAGOCYTOSIS, BACTERIAL growth, MACROPHAGES, CYTOSOL, AUTOPHAGY

Abstract

Macrophages remove bacteria from the extracellular milieu via phagocytosis. While most of the engulfed bacteria are degraded in the antimicrobial environment of the phagolysosome, several bacterial pathogens have evolved virulence factors, which evade degradation or allow escape into the cytosol. To counter this situation, macrophages activate LC3-associated phagocytosis (LAP), a highly bactericidal non-canonical autophagy pathway, which destroys the bacterial pathogens in so called LAPosomes. Moreover, macrophages can also target intracellular bacteria by pore-forming toxin-induced non-canonical autophagy (PINCA), a recently described non-canonical autophagy pathway, which is activated by phagosomal damage induced by bacteria-derived pore-forming toxins. Similar to LAP, PINCA involves LC3 recruitment to the bacteria-containing phagosome independently of the ULK complex, but in contrast to LAP, this process does not require ROS production by Nox2. As last resort of autophagic targeting, macrophages activate xenophagy, a selective form of macroautophagy, to recapture bacteria, which evaded successful targeting by LAP or PINCA through rupture of the phagosome. However, xenophagy can also be hijacked by bacterial pathogens for their benefit or can be completely inhibited resulting in intracellular growth of the bacterial pathogen. In this perspective, we discuss the molecular differences and similarities between LAP, PINCA and xenophagy in macrophages during bacterial infections. [ABSTRACT FROM AUTHOR]

Published

2022

47. Inflammatory Bowel Disease at the Intersection of Autophagy and Immunity: Insights from Human Genetics

Author

Nedelsky, Natalia, Kuballa, Petric, Castoreno, Adam B., Xavier, Ramnik J., Hedin, Charlotte, editor, Rioux, John D., editor, and D'Amato, Mauro, editor

Published

2019

48. When the Phagosome Gets Leaky: Pore-Forming Toxin-Induced Non-Canonical Autophagy (PINCA)

Author

Marc Herb, Alexander Gluschko, Alina Farid, and Martin Krönke

Subjects

non-canonical autophagy, macrophages, ULK complex, pore-forming toxins, macroautophagy, xenophagy, Microbiology, QR1-502

Abstract

Macrophages remove bacteria from the extracellular milieu via phagocytosis. While most of the engulfed bacteria are degraded in the antimicrobial environment of the phagolysosome, several bacterial pathogens have evolved virulence factors, which evade degradation or allow escape into the cytosol. To counter this situation, macrophages activate LC3-associated phagocytosis (LAP), a highly bactericidal non-canonical autophagy pathway, which destroys the bacterial pathogens in so called LAPosomes. Moreover, macrophages can also target intracellular bacteria by pore-forming toxin-induced non-canonical autophagy (PINCA), a recently described non-canonical autophagy pathway, which is activated by phagosomal damage induced by bacteria-derived pore-forming toxins. Similar to LAP, PINCA involves LC3 recruitment to the bacteria-containing phagosome independently of the ULK complex, but in contrast to LAP, this process does not require ROS production by Nox2. As last resort of autophagic targeting, macrophages activate xenophagy, a selective form of macroautophagy, to recapture bacteria, which evaded successful targeting by LAP or PINCA through rupture of the phagosome. However, xenophagy can also be hijacked by bacterial pathogens for their benefit or can be completely inhibited resulting in intracellular growth of the bacterial pathogen. In this perspective, we discuss the molecular differences and similarities between LAP, PINCA and xenophagy in macrophages during bacterial infections.

Published

2022

49. Perturbation of ATG16L1 function impairs the biogenesis of Salmonella and Coxiella replication vacuoles.

Author

Lau, Nicole, Thomas, David R., Yi Wei Lee, Knodler, Leigh A., and Newton, Hayley J.

Subjects

*COXIELLA burnetii, *SALMONELLA enterica serovar typhimurium, *SALMONELLA enterica, *SALMONELLA, *BACTERIAL proteins

Abstract

Anti-bacterial autophagy, known as xenophagy, is a host innate immune response that targets invading pathogens for degradation. Some intracellular bacteria, such as the enteric pathogen Salmonella enterica serovar Typhimurium (S. Typhimurium), utilize effector proteins to interfere with autophagy. One such S. Typhimurium effector, SopF, inhibits recruitment of ATG16L1 to damaged Salmonella-containing vacuoles (SCVs), thereby inhibiting the host xenophagic response. SopF is also required to maintain the integrity of the SCV during the early stages of infection. Here we show disruption of the SopF-ATG16L1 interaction leads to an increased proportion of cytosolic S. Typhimurium. Furthermore, SopF was utilized as a molecular tool to examine the requirement for ATG16L1 in the intracellular lifestyle of Coxiella burnetii, a bacterium that requires a functional autophagy pathway to replicate efficiently and form a single, spacious vacuole called the Coxiella-Containing vacuole (CCV). ATG16L1 is required for CCV expansion and fusion but does not influence C. burnetii replication. In contrast, SopF did not affect CCV formation or replication, demonstrating that the contribution of ATG16L1 to CCV biogenesis is via its role in autophagy, not xenophagy. This study highlights the diverse capabilities of bacterial effector proteins to dissect the molecular details of host--pathogen interactions. [ABSTRACT FROM AUTHOR]

Published

2022

50. Autophagy in the control and pathogenesis of parasitic infections

Author

George Ghartey-Kwansah, Frank Adu-Nti, Benjamin Aboagye, Amandus Ankobil, Edward Eyipe Essuman, Yeboah Kwaku Opoku, Samuel Abokyi, Emmanuel Kwasi Abu, and Johnson Nyarko Boampong

Subjects

Autophagy, Autophagosome, Parasitophorous vacuole, Xenophagy, PAAR, Biotechnology, TP248.13-248.65, Biology (General), QH301-705.5, Biochemistry, QD415-436

Abstract

Abstract Background Autophagy has a crucial role in the defense against parasites. The interplay existing between host autophagy and parasites has varied outcomes due to the kind of host cell and microorganism. The presence of autophagic compartments disrupt a significant number of pathogens and are further cleared by xenophagy in an autolysosome. Another section of pathogens have the capacity to outwit the autophagic pathway to their own advantage. Result To comprehend the interaction between pathogens and the host cells, it is significant to distinguish between starvation-induced autophagy and other autophagic pathways. Subversion of host autophagy by parasites is likely due to differences in cellular pathways from those of ‘classical’ autophagy and that they are controlled by parasites in a peculiar way. In xenophagy clearance at the intracellular level, the pathogens are first ubiquitinated before autophagy receptors acknowledgement, followed by labeling with light chain 3 (LC3) protein. The LC3 in LC3-associated phagocytosis (LAP) is added directly into vacuole membrane and functions regardless of the ULK, an initiation complex. The activation of the ULK complex composed of ATG13, FIP200 and ATG101causes the initiation of host autophagic response. Again, the recognition of PAMPs by conserved PRRs marks the first line of defense against pathogens, involving Toll-like receptors (TLRs). These all important immune-related receptors have been reported recently to regulate autophagy. Conclusion In this review, we sum up recent advances in autophagy to acknowledge and understand the interplay between host and parasites, focusing on target proteins for the design of therapeutic drugs. The target host proteins on the initiation of the ULK complex and PRRs-mediated recognition of PAMPs may provide strong potential for the design of therapeutic drugs against parasitic infections.

Published

2020