Mycobacteria–host interactions in human bronchiolar airway organoids
Iakobachvili, Nino; Leon-Icaza, Stephen Adonai; Knoops, Kèvin; Sachs, Norman; Mazères, Serge; Simeone, Roxane; Peixoto, Antonio; Bernard, Célia; Murris-Espin, Marlène; Mazières, Julien; Cam, Kaymeuang; Chalut, Christian; Guilhot, Christophe; López-Iglesias, Carmen; Ravelli, Raimond B.G.; Neyrolles, Olivier; Meunier, Etienne; Lugo-Villarino, Geanncarlo; Clevers, Hans; Cougoule, Céline; Peters, Peter J.
(2022) Molecular Microbiology, volume 117, issue 3, pp. 682 - 692
(Article)
Abstract
Respiratory infections remain a major global health concern. Tuberculosis is one of the top 10 causes of death worldwide, while infections with Non-Tuberculous Mycobacteria are rising globally. Recent advances in human tissue modeling offer a unique opportunity to grow different human “organs” in vitro, including the human airway, that faithfully
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recapitulates lung architecture and function. Here, we have explored the potential of human airway organoids (AOs) as a novel system in which to assess the very early steps of mycobacterial infection. We reveal that Mycobacterium tuberculosis (Mtb) and Mycobacterium abscessus (Mabs) mainly reside as extracellular bacteria and infect epithelial cells with very low efficiency. While the AO microenvironment was able to control, but not eliminate Mtb, Mabs thrives. We demonstrate that AOs responded to infection by modulating cytokine, antimicrobial peptide, and mucin gene expression. Given the importance of myeloid cells in mycobacterial infection, we co-cultured infected AOs with human monocyte-derived macrophages and found that these cells interact with the organoid epithelium. We conclude that adult stem cell (ASC)-derived AOs can be used to decipher very early events of mycobacteria infection in human settings thus offering new avenues for fundamental and therapeutic research.
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Keywords: airways, infection, mycobacteria, organoids, tuberculosis, Molecular Biology, Microbiology, Journal Article
ISSN: 0950-382X
Publisher: Wiley-Blackwell
Note: Funding Information: Authors acknowledge C. Kuo (Stanford University, USA) for the stable expressing Rspo1‐Fc cell line, and the Hubrecht Institute for the stable expressing Noggin cell line; Genotoul TRI‐IPBS core facility for flow cytometry and imaging, in particular E. Näser and E. Vega; IPBS BSL‐3 facilities, in particular C. Verollet for technical support. Authors also acknowledge the Microscopy CORE lab and PLUC facility at Maastricht University. This work was supported by grants from Campus France PHC Van Gogh (40577ZE to GL‐V), the Agence Nationale de la Recherche (ANR‐15‐CE15‐0012 (MMI‐TB)) to GL‐V, FRM “Amorçage Jeunes Equipes” (AJE20151034460 to EM), ERC StG 693 (INFLAME 804249 to EM), ATIP to EM, ZonMW 3R’s (114021005) to PJP, the Nuffic Van Gogh Programme (VGP.17/10 to NI), and by the LINK program from the Province of Limburg, the Netherlands. Funding Information: Authors acknowledge C. Kuo (Stanford University, USA) for the stable expressing Rspo1-Fc cell line, and the Hubrecht Institute for the stable expressing Noggin cell line; Genotoul TRI-IPBS core facility for flow cytometry and imaging, in particular E. Näser and E. Vega; IPBS BSL-3 facilities, in particular C. Verollet for technical support. Authors also acknowledge the Microscopy CORE lab and PLUC facility at Maastricht University. This work was supported by grants from Campus France PHC Van Gogh (40577ZE to GL-V), the Agence Nationale de la Recherche (ANR-15-CE15-0012 (MMI-TB)) to GL-V, FRM “Amorçage Jeunes Equipes” (AJE20151034460 to EM), ERC StG 693 (INFLAME 804249 to EM), ATIP to EM, ZonMW 3R’s (114021005) to PJP, the Nuffic Van Gogh Programme (VGP.17/10 to NI), and by the LINK program from the Province of Limburg, the Netherlands. Publisher Copyright: © 2021 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.
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