Literature DB >> 26829985

Dectin-1 Controls TLR9 Trafficking to Phagosomes Containing β-1,3 Glucan.

Nida S Khan1, Pia V Kasperkovitz2, Allison K Timmons3, Michael K Mansour4, Jenny M Tam3, Michael W Seward3, Jennifer L Reedy4, Sravanthi Puranam3, Marianela Feliu5, Jatin M Vyas6.   

Abstract

Dectin-1 and TLR9 play distinct roles in the recognition and induction of innate immune responses to Aspergillus fumigatus and Candida albicans. Dectin-1 is a receptor for the major fungal cell wall carbohydrate β-1,3 glucan that induces inflammatory cytokines and controls phagosomal maturation through spleen tyrosine kinase activation. TLR9 is an endosomal TLR that also modulates the inflammatory cytokine response to fungal pathogens. In this study, we demonstrate that β-1,3 glucan beads are sufficient to induce dynamic redistribution and accumulation of cleaved TLR9 to phagosomes. Trafficking of TLR9 to A. fumigatus and C. albicans phagosomes requires Dectin-1 recognition. Inhibition of phagosomal acidification blocks TLR9 accumulation on phagosomes containing β-1,3 glucan beads. Dectin-1-mediated spleen tyrosine kinase activation is required for TLR9 trafficking to β-1,3 glucan-, A. fumigatus-, and C. albicans-containing phagosomes. In addition, Dectin-1 regulates TLR9-dependent gene expression. Collectively, our study demonstrates that recognition of β-1,3 glucan by Dectin-1 triggers TLR9 trafficking to β-1,3 glucan-containing phagosomes, which may be critical in coordinating innate antifungal defense.
Copyright © 2016 by The American Association of Immunologists, Inc.

Entities:  

Mesh:

Substances:

Year:  2016        PMID: 26829985      PMCID: PMC4761466          DOI: 10.4049/jimmunol.1401545

Source DB:  PubMed          Journal:  J Immunol        ISSN: 0022-1767            Impact factor:   5.422


  61 in total

Review 1.  Emerging opportunistic yeast infections.

Authors:  Marisa H Miceli; José A Díaz; Samuel A Lee
Journal:  Lancet Infect Dis       Date:  2011-02       Impact factor: 25.071

2.  Bacterial LPS and CpG DNA differentially induce gene expression profiles in mouse macrophages.

Authors:  Jian Jun Gao; Veronica Diesl; Tatiana Wittmann; David C Morrison; John L Ryan; Stefanie N Vogel; Maximillian T Follettie
Journal:  J Endotoxin Res       Date:  2003

3.  Granulin is a soluble cofactor for toll-like receptor 9 signaling.

Authors:  Boyoun Park; Ludovico Buti; Sungwook Lee; Takashi Matsuwaki; Eric Spooner; Melanie M Brinkmann; Masugi Nishihara; Hidde L Ploegh
Journal:  Immunity       Date:  2011-04-14       Impact factor: 31.745

Review 4.  Infectious diseases in patients with IRAK-4, MyD88, NEMO, or IκBα deficiency.

Authors:  Capucine Picard; Jean-Laurent Casanova; Anne Puel
Journal:  Clin Microbiol Rev       Date:  2011-07       Impact factor: 26.132

5.  Toll-like receptor 9 modulates macrophage antifungal effector function during innate recognition of Candida albicans and Saccharomyces cerevisiae.

Authors:  Pia V Kasperkovitz; Nida S Khan; Jenny M Tam; Michael K Mansour; Peter J Davids; Jatin M Vyas
Journal:  Infect Immun       Date:  2011-09-26       Impact factor: 3.441

6.  TLR9 is actively recruited to Aspergillus fumigatus phagosomes and requires the N-terminal proteolytic cleavage domain for proper intracellular trafficking.

Authors:  Pia V Kasperkovitz; Michael L Cardenas; Jatin M Vyas
Journal:  J Immunol       Date:  2010-11-08       Impact factor: 5.422

7.  Recognition of yeast nucleic acids triggers a host-protective type I interferon response.

Authors:  Carmelo Biondo; Giacomo Signorino; Alessandro Costa; Angelina Midiri; Elisabetta Gerace; Roberta Galbo; Antonella Bellantoni; Antonio Malara; Concetta Beninati; Giuseppe Teti; Giuseppe Mancuso
Journal:  Eur J Immunol       Date:  2011-07       Impact factor: 5.532

8.  A promiscuous lipid-binding protein diversifies the subcellular sites of toll-like receptor signal transduction.

Authors:  Kevin S Bonham; Megan H Orzalli; Kachiko Hayashi; Amaya I Wolf; Christoph Glanemann; Wolfgang Weninger; Akiko Iwasaki; David M Knipe; Jonathan C Kagan
Journal:  Cell       Date:  2014-02-13       Impact factor: 41.582

Review 9.  Primary immunodeficiencies underlying fungal infections.

Authors:  Fanny Lanternier; Sophie Cypowyj; Capucine Picard; Jacinta Bustamante; Olivier Lortholary; Jean-Laurent Casanova; Anne Puel
Journal:  Curr Opin Pediatr       Date:  2013-12       Impact factor: 2.856

10.  Phagocytosis-dependent activation of a TLR9-BTK-calcineurin-NFAT pathway co-ordinates innate immunity to Aspergillus fumigatus.

Authors:  Susanne Herbst; Anand Shah; Maria Mazon Moya; Vanessa Marzola; Barbara Jensen; Anna Reed; Mark A Birrell; Shinobu Saijo; Serge Mostowy; Sunil Shaunak; Darius Armstrong-James
Journal:  EMBO Mol Med       Date:  2015-03       Impact factor: 12.137
View more
  20 in total

1.  Protective effect of fungal extracellular vesicles against murine candidiasis.

Authors:  Gabriele Vargas; Leandro Honorato; Allan Jefferson Guimarães; Marcio L Rodrigues; Flavia C G Reis; André M Vale; Anjana Ray; Joshua Daniel Nosanchuk; Leonardo Nimrichter
Journal:  Cell Microbiol       Date:  2020-07-22       Impact factor: 3.715

Review 2.  The first line of defense: effector pathways of anti-fungal innate immunity.

Authors:  Rebecca A Ward; Jatin M Vyas
Journal:  Curr Opin Microbiol       Date:  2020-11-17       Impact factor: 7.934

3.  Integrin-based diffusion barrier separates membrane domains enabling the formation of microbiostatic frustrated phagosomes.

Authors:  Michelle E Maxson; Xenia Naj; Teresa R O'Meara; Jonathan D Plumb; Leah E Cowen; Sergio Grinstein
Journal:  Elife       Date:  2018-03-19       Impact factor: 8.140

Review 4.  It takes a village: Phagocytes play a central role in fungal immunity.

Authors:  Michael B Feldman; Jatin M Vyas; Michael K Mansour
Journal:  Semin Cell Dev Biol       Date:  2018-06-12       Impact factor: 7.727

5.  MDA5 Is an Essential Sensor of a Pathogen-Associated Molecular Pattern Associated with Vitality That Is Necessary for Host Resistance against Aspergillus fumigatus.

Authors:  Xi Wang; Alayna K Caffrey-Carr; Ko-Wei Liu; Vanessa Espinosa; Walburga Croteau; Sourabh Dhingra; Amariliz Rivera; Robert A Cramer; Joshua J Obar
Journal:  J Immunol       Date:  2020-10-21       Impact factor: 5.422

Review 6.  Aspergillosis and stem cell transplantation: An overview of experimental pathogenesis studies.

Authors:  Nadia Al-Bader; Donald C Sheppard
Journal:  Virulence       Date:  2016-09-29       Impact factor: 5.882

7.  Aspergillus fumigatus Induces the Release of IL-8 and MCP-1 by Activating Nuclear Transcription Through Dectin-1 and CR3 Receptors in Alveolar Epithelial Cells.

Authors:  Yanxi Liu; Zhiqian Li; Shuo Wang; Changjian Zhang; Li Han; Qun Sun; Xuelin Han
Journal:  Curr Microbiol       Date:  2021-07-16       Impact factor: 2.188

Review 8.  Sensing the threat posed by Aspergillus infection.

Authors:  Joshua J Obar
Journal:  Curr Opin Microbiol       Date:  2020-09-06       Impact factor: 7.934

9.  CD82 controls CpG-dependent TLR9 signaling.

Authors:  Nida S Khan; Daniel P Lukason; Marianela Feliu; Rebecca A Ward; Allison K Lord; Jennifer L Reedy; Zaida G Ramirez-Ortiz; Jenny M Tam; Pia V Kasperkovitz; Paige E Negoro; Tammy D Vyas; Shuying Xu; Melanie M Brinkmann; Mridu Acharaya; Katerina Artavanis-Tsakonas; Eva-Maria Frickel; Christine E Becker; Zeina Dagher; You-Me Kim; Eicke Latz; Hidde L Ploegh; Michael K Mansour; Cindy K Miranti; Stuart M Levitz; Jatin M Vyas
Journal:  FASEB J       Date:  2019-08-13       Impact factor: 5.191

10.  Efficacy of SPG-ODN 1826 Nanovehicles in Inducing M1 Phenotype through TLR-9 Activation in Murine Alveolar J774A.1 Cells: Plausible Nano-Immunotherapy for Lung Carcinoma.

Authors:  Mohammed F Aldawsari; Ahmed Alalaiwe; El-Sayed Khafagy; Ahmed Al Saqr; Saad M Alshahrani; Bader B Alsulays; Sultan Alshehri; Amr S Abu Lila; Syed Mohd Danish Rizvi; Wael A H Hegazy
Journal:  Int J Mol Sci       Date:  2021-06-25       Impact factor: 5.923
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.