In vitro culture of aberrant basal-like cells from fibrotic lung tissue

ABSTRACTRationaleIn idiopathic pulmonary fibrosis (IPF) atypical epithelial cells are present in the alveolar compartment. Their origin and contribution to IPF pathogenesis is unknown. We recently cultured a distinct population of cells, which readily grew from fibrotic lung tissue, but only rarely from non-fibrotic tissue. Here we aimed to characterize these fibrosis-enriched cells and determine transcriptomic differences between cells derived from IPF and patients with other interstitial lung diseases (ILD).MethodsCells were cultured from peripheral lung tissue of ILD patients and analysed by bulk or single cell RNA sequencing (scRNA-seq), TaqMan-PCR, immunofluorescence (IF), immunoblotting or electron microscopy (EM).ResultsscRNA-seq demonstrated an overall homogeneity and epithelial origin of the cells. The majority of cells expressed basal cell markers (Cytokeratin (KRT) 5 and 17, TP63), of which a fraction co-expressed mesenchymal cell markers (VIM, FN1, CDH2), alveolar (SLC34A2, ABCA3, LPCAT1, EMP2, HOPX) and/or secretory epithelial cell markers (SCGB1A1, MUC4). Interestingly, most of the cells showed closest transcriptomic similarity to recently described aberrant basal-like cells. Cells derived from IPF versus other ILD patients revealed significant transcriptomic differences with an up-regulation of fibrosis-associated and a down-regulation of inflammatory pathways in IPF cells.ConclusionWe here confirm the presence of aberrant basal-like cells in fibrotic lung tissue and, importantly, are the first to describe their in vitro characteristics and a way of culturing these cells in vitro. Cultured basal-like cells co-express epithelial and mesenchymal markers, suggesting a partial epithelial to mesenchymal transition (EMT). A subset of cells co-express alveolar, ciliated or secretory epithelial cell markers, possibly indicating differentiation towards these cell linages. Furthermore, cultured basal-like cells display a disease-specific transcriptome, possibly induced by their specific microenvironment. Our findings will contribute to a better understanding of the cells origin and their potential contribution to IPF pathogenesis.

Endocycles support tissue growth and regeneration of the adult Drosophila accessory gland

The Drosophila melanogaster accessory gland is a functional analog of the mammalian prostate made up of two secretory epithelial cell types, termed main and secondary cells. This tissue is responsible for making and secreting seminal fluid proteins and other molecules that contribute to successful reproduction. Here we show that similar to the mammalian prostate, this tissue grows with age. We find that the adult accessory gland grows in part via endocycles to increase DNA content and cell size, independent of mating status. The differentiated, bi-nucleated main cells remain poised to endocycle in the adult gland and upregulation of signals that promote endocycling and tissue growth are sufficient to trigger dramatic endocycling leading to increases in cell size and ploidy. The main cells of this tissue remain poised to enter the cell cycle and endocycling of main cells increases during recovery from severe tissue damage. Our data establish that the adult accessory gland is not quiescent, but instead uses endocycles to maintain the accessory gland’s critical function throughout the fruit fly’s lifespan.

Mtgr1 Is a Transcriptional Corepressor That Is Required for Maintenance of the Secretory Cell Lineage in the Small Intestine

ABSTRACT Two members of the MTG/ETO family of transcriptional corepressors, MTG8 and MTG16, are disrupted by chromosomal translocations in up to 15% of acute myeloid leukemia cases. The third family member, MTGR1, was identified as a factor that associates with the t(8;21) fusion protein RUNX1-MTG8. We demonstrate that Mtgr1 associates with mSin3A, N-CoR, and histone deacetylase 3 and that when tethered to DNA, Mtgr1 represses transcription, suggesting that Mtgr1 also acts as a transcriptional corepressor. To define the biological function of Mtgr1, we created Mtgr1-null mice. These mice are proportionally smaller than their littermates during embryogenesis and throughout their life span but otherwise develop normally. However, these mice display a progressive reduction in the secretory epithelial cell lineage in the small intestine. This is not due to the loss of small intestinal progenitor cells expressing Gfi1, which is required for the formation of goblet and Paneth cells, implying that loss of Mtgr1 impairs the maturation of secretory cells in the small intestine.