Rationale: Macrophages are the most abundant immune cell in the alveoli and small airways and are traditionally viewed as a homogeneous population during health. Whether distinct subsets of airspace macrophages are present in healthy humans is unknown. Single-cell RNA sequencing allows for examination of transcriptional heterogeneity between cells and between individuals. Understanding the conserved repertoire of airspace macrophages during health is essential to understanding cellular programing during disease. Objectives: We sought to determine the transcriptional heterogeneity of human cells obtained from BAL of healthy adults. Methods: Ten subjects underwent bronchoscopy with BAL. Cells from lavage were subjected to single-cell RNA sequencing. Unique cell populations and putative functions were identified. Transcriptional profiles were compared across individuals.Measurements and Main Results: We identify two novel subgroups of resident airspace macrophages-defined by proinflammatory and metallothionein gene expression profiles. We define subsets of monocyte-like cells and compare them with peripheral blood mononuclear cells. Finally, we compare global macrophage and monocyte programing between males and females.Conclusions: Healthy human airspaces contain multiple populations of myeloid cells that are highly conserved between individuals and between sexes. Resident macrophages make up the largest population and include novel subsets defined by inflammatory and metal-binding profiles. Monocyte-like cells within the airspaces are transcriptionally aligned with circulating blood cells and include a rare population defined by expression of cell-matrix interaction genes. This study is the first to delineate the conserved heterogeneity of airspace immune cells during health and identifies two previously unrecognized macrophage subsets.
Rationale: Macrophages are the most abundant immune cell in the alveoli and small airways and are traditionally viewed as a homogeneous population during health. Whether distinct subsets of airspace macrophages are present in healthy humans is unknown. Single-cell RNA sequencing allows for examination of transcriptional heterogeneity between cells and between individuals. Understanding the conserved repertoire of airspace macrophages during health is essential to understanding cellular programing during disease. Objectives: We sought to determine the transcriptional heterogeneity of human cells obtained from BAL of healthy adults. Methods: Ten subjects underwent bronchoscopy with BAL. Cells from lavage were subjected to single-cell RNA sequencing. Unique cell populations and putative functions were identified. Transcriptional profiles were compared across individuals.Measurements and Main Results: We identify two novel subgroups of resident airspace macrophages-defined by proinflammatory and metallothionein gene expression profiles. We define subsets of monocyte-like cells and compare them with peripheral blood mononuclear cells. Finally, we compare global macrophage and monocyte programing between males and females.Conclusions: Healthy human airspaces contain multiple populations of myeloid cells that are highly conserved between individuals and between sexes. Resident macrophages make up the largest population and include novel subsets defined by inflammatory and metal-binding profiles. Monocyte-like cells within the airspaces are transcriptionally aligned with circulating blood cells and include a rare population defined by expression of cell-matrix interaction genes. This study is the first to delineate the conserved heterogeneity of airspace immune cells during health and identifies two previously unrecognized macrophage subsets.
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Authors: N P O'Grady; H L Preas; J Pugin; C Fiuza; M Tropea; D Reda; S M Banks; A F Suffredini Journal: Am J Respir Crit Care Med Date: 2001-06 Impact factor: 21.405
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Authors: I S Cheon; C Li; Y M Son; N P Goplen; Y Wu; T Cassmann; Z Wang; X Wei; J Tang; Y Li; H Marlow; S Hughes; L Hammel; T M Cox; E Goddery; K Ayasoufi; D Weiskopf; J Boonyaratanakornkit; H Dong; H Li; R Chakraborty; A J Johnson; E Edell; J J Taylor; M H Kaplan; A Sette; B J Bartholmai; R Kern; R Vassallo; J Sun Journal: Sci Immunol Date: 2021-11-12
Authors: Carolyn R Morris; Aida Habibovic; Christopher M Dustin; Caspar Schiffers; Miao-Chong Lin; Jennifer L Ather; Yvonne M W Janssen-Heininger; Matthew E Poynter; Olaf Utermohlen; Martin Krönke; Albert van der Vliet Journal: Mucosal Immunol Date: 2022-06-02 Impact factor: 8.701
Authors: Thomas R Martin; Rachel L Zemans; Lorraine B Ware; Eric P Schmidt; David W H Riches; Lisa Bastarache; Carolyn S Calfee; Tushar J Desai; Susanne Herold; Catherine L Hough; Mark R Looney; Michael A Matthay; Nuala Meyer; Samir M Parikh; Troy Stevens; B Taylor Thompson Journal: Am J Respir Cell Mol Biol Date: 2022-09 Impact factor: 7.748
Authors: Shu-Yi Liao; Shaikh M Atif; Kara Mould; Iain R Konigsberg; Rui Fu; Elizabeth Davidson; Li Li; Andrew P Fontenot; Lisa A Maier; Ivana V Yang Journal: Eur Respir J Date: 2021-06-17 Impact factor: 16.671