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      • Record: found
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      Mycobacteria employ two different mechanisms to cross the blood–brain barrier

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          Abstract

          Central nervous system (CNS) infection by Mycobacterium tuberculosis is one of the most devastating complications of tuberculosis, in particular in early childhood. In order to induce CNS infection, M. tuberculosis needs to cross specialised barriers protecting the brain. How M. tuberculosis crosses the blood–brain barrier (BBB) and enters the CNS is not well understood. Here, we use transparent zebrafish larvae and the closely related pathogen Mycobacterium marinum to answer this question. We show that in the early stages of development, mycobacteria rapidly infect brain tissue, either as free mycobacteria or within circulating macrophages. After the formation of a functionally intact BBB, the infiltration of brain tissue by infected macrophages is delayed, but not blocked, suggesting that crossing the BBB via phagocytic cells is one of the mechanisms used by mycobacteria to invade the CNS. Interestingly, depletion of phagocytic cells did not prevent M. marinum from infecting the brain tissue, indicating that free mycobacteria can independently cause brain infection. Detailed analysis showed that mycobacteria are able to cause vasculitis by extracellular outgrowth in the smaller blood vessels and by infecting endothelial cells. Importantly, we could show that this second mechanism is an active process that depends on an intact ESX‐1 secretion system, which extends the role of ESX‐1 secretion beyond the macrophage infection cycle.

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          The role of the granuloma in expansion and dissemination of early tuberculous infection.

          J. Muse Davis, Lalita Ramakrishnan (2009)
          Granulomas, organized aggregates of immune cells, form in response to persistent stimuli and are hallmarks of tuberculosis. Tuberculous granulomas have long been considered host-protective structures formed to contain infection. However, work in zebrafish infected with Mycobacterium marinum suggests that granulomas contribute to early bacterial growth. Here we use quantitative intravital microscopy to reveal distinct steps of granuloma formation and assess their consequence for infection. Intracellular mycobacteria use the ESX-1/RD1 virulence locus to induce recruitment of new macrophages to, and their rapid movement within, nascent granulomas. This motility enables multiple arriving macrophages to efficiently find and phagocytose infected macrophages undergoing apoptosis, leading to rapid, iterative expansion of infected macrophages and thereby bacterial numbers. The primary granuloma then seeds secondary granulomas via egress of infected macrophages. Our direct observations provide insight into how pathogenic mycobacteria exploit the granuloma during the innate immune phase for local expansion and systemic dissemination.
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            Liposome mediated depletion of macrophages: mechanism of action, preparation of liposomes and applications.

            N van Rooijen, A. Sanders (1994)
            Selective depletion of macrophages from tissues in vivo can be used to investigate whether these cells are playing a role in defined biological processes. This question is particularly relevant to various host defense mechanisms. We have developed a macrophage 'suicide' technique, using the liposome mediated intracellular delivery of dichloromethylene-bisphosphonate (Cl2MBP or clodronate). The method is specific with respect to phagocytic cells of the mononuclear phagocyte system (MPS) for the following reasons: (1) The natural fate of liposomes is phagocytosis. (2) Once ingested by macrophages, the phospholipid bilayers of the liposomes are disrupted under the influence of lysosomal phospholipases. (3) Cl2MBP intracellularly released in this way does not easily escape from the cell by crossing the cell membranes. (4) Cl2MBP released in the circulation from dead macrophages or by leakage from liposomes, will not easily enter non-phagocytic cells and has an extremely short half life in the circulation and body fluids. In the present review, the preparation of Cl2MBP-liposomes has been described in detail. Furthermore, the mechanism of action of the new approach and its applicabilities are discussed.
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              Ontogeny and behaviour of early macrophages in the zebrafish embryo.

              Philippe Herbomel, Christine Thisse, B Thisse (1999)
              In the zebrafish embryo, the only known site of hemopoieisis is an intra-embryonic blood island at the junction between trunk and tail that gives rise to erythroid cells. Using video-enhanced differential interference contrast microscopy, as well as in-situ hybridization for the expression of two new hemopoietic marker genes, draculin and leucocyte-specific plastin, we show that macrophages appear in the embryo at least as early as erythroid cells, but originate from ventro-lateral mesoderm situated at the other end of the embryo, just anterior to the cardiac field. These macrophage precursors migrate to the yolksac, and differentiate. From the yolksac, many invade the mesenchyme of the head, while others join the blood circulation. Apart from phagocytosing apoptotic corpses, these macrophages were observed to engulf and destroy large amounts of bacteria injected intravenously; the macrophages also sensed the presence of bacteria injected into body cavities that are isolated from the blood, migrated into these cavities and eradicated the microorganisms. Moreover, we observed that although only a fraction of the macrophage population goes to the site of infection, the entire population acquires an activated behaviour, similar to that of activated macrophages in mammals. Our results support the notion that in vertebrate embryos, macrophages endowed with proliferative capacity arise early from the hemopoietic lineage through a non-classical, rapid differentiation pathway, which bypasses the monocytic series that is well-documented in adult hemopoietic organs.
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                Author and article information

                Contributors
                Wilbert Bitter:
                ORCID: http://orcid.org/0000-0001-8347-6511
                w.bitter@vumc.nl
                Journal
                Journal ID (nlm-ta): Cell Microbiol
                Journal ID (iso-abbrev): Cell. Microbiol
                Journal ID (doi): 10.1111/(ISSN)1462-5822
                Journal ID (publisher-id): CMI
                Title: Cellular Microbiology
                Publisher: John Wiley and Sons Inc. (Hoboken )
                ISSN (Print): 1462-5814
                ISSN (Electronic): 1462-5822
                Publication date (Electronic): 30 May 2018
                Publication date (Print): September 2018
                Volume: 20
                Issue: 9 ( doiID: 10.1111/cmi.v20.9 )
                Electronic Location Identifier: e12858
                Affiliations
                [ 1 ] Medical Microbiology and Infection Control VU Medical Center Amsterdam The Netherlands
                [ 2 ] Paediatric Infectious Diseases and Immunology VU Medical Center Amsterdam The Netherlands
                [ 3 ] Cell Biology and Histology, Electron Microscopy Centre Amsterdam Academic Medical Centre Amsterdam The Netherlands
                [ 4 ] Molecular Cell Biology and Immunology, Amsterdam Neuroscience VU Medical Center Amsterdam The Netherlands
                Author notes
                [*] [* ] Correspondence

                Wilbert Bitter, Medical Microbiology and Infection Control, VU Medical Center, Amsterdam, The Netherlands.

                Email: w.bitter@ 123456vumc.nl

                Author information
                http://orcid.org/0000-0002-0500-5439
                http://orcid.org/0000-0001-8347-6511
                Article
                Publisher ID: CMI12858 Other ID: CMI-18-0007.R2
                DOI: 10.1111/cmi.12858
                PMC ID: 6175424
                PubMed ID: 29749044
                SO-VID: a747ae05-e54e-4e43-865a-efc0f451f92a
                Copyright © © 2018 The Authors Cellular Microbiology Published by John Wiley & Sons Ltd
                License:

                This is an open access article under the terms of the http://creativecommons.org/licenses/by-nc/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes.

                History
                Date received : 14 January 2018
                Date revision received : 27 March 2018
                Date accepted : 23 April 2018
                Page count
                Figures: 8, Tables: 0, Pages: 17, Words: 8922
                Funding
                Funded by: ESPID/Wyeth fellowship 2010–2012 (awarded to M.v.d.K.)
                Funded by: Innovative Medicines Initiative Joint Undertaking Grant Agreement
                Award ID: 115337
                Categories
                Subject: Editor's Choice
                Subject: Editor's Choice
                Custom metadata
                source-schema-version-number 2.0
                component-id cmi12858
                cover-date September 2018
                details-of-publishers-convertor Converter:WILEY_ML3GV2_TO_NLMPMC version:version=5.5.0 mode:remove_FC converted:08.10.2018

                ScienceOpen disciplines: Microbiology & Virology
                Keywords: blood–brain barrier,esx‐1 secretion,trojan horse mechanism,tuberculosis,tuberculous meningitis,zebrafish
                Data availability:
                ScienceOpen disciplines: Microbiology & Virology
                Keywords: blood–brain barrier, esx‐1 secretion, trojan horse mechanism, tuberculosis, tuberculous meningitis, zebrafish

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