Sfrp1 inhibits lung fibroblast invasion during transition to injury-induced myofibroblasts.

BACKGROUND: Fibroblast-to-myofibroblast conversion is a major driver of tissue remodelling in organ fibrosis. Distinct lineages of fibroblasts support homeostatic tissue niche functions, yet their specific activation states and phenotypic trajectories during injury and repair have remained unclear. METHODS: We combined spatial transcriptomics, multiplexed immunostainings, longitudinal single-cell RNA-sequencing and genetic lineage tracing to study fibroblast fates during mouse lung regeneration. Our findings were validated in idiopathic pulmonary fibrosis patient tissues in situ as well as in cell differentiation and invasion assays using patient lung fibroblasts. Cell differentiation and invasion assays established a function of SFRP1 in regulating human lung fibroblast invasion in response to transforming growth factor (TGF)ß1. MEASUREMENTS AND MAIN RESULTS: We discovered a transitional fibroblast state characterised by high Sfrp1 expression, derived from both Tcf21-Cre lineage positive and negative cells. Sfrp1 + cells appeared early after injury in peribronchiolar, adventitial and alveolar locations and preceded the emergence of myofibroblasts. We identified lineage-specific paracrine signals and inferred converging transcriptional trajectories towards Sfrp1 + transitional fibroblasts and Cthrc1 + myofibroblasts. TGFß1 downregulated SFRP1 in noninvasive transitional cells and induced their switch to an invasive CTHRC1+ myofibroblast identity. Finally, using loss-of-function studies we showed that SFRP1 modulates TGFß1-induced fibroblast invasion and RHOA pathway activity. CONCLUSIONS: Our study reveals the convergence of spatially and transcriptionally distinct fibroblast lineages into transcriptionally uniform myofibroblasts and identifies SFRP1 as a modulator of TGFß1-driven fibroblast phenotypes in fibrogenesis. These findings are relevant in the context of therapeutic interventions that aim at limiting or reversing fibroblast foci formation.

A comparison of airway pressures for inflation fixation of developing mouse lungs for stereological analyses.

The morphometric analysis of lung structure using the principles of stereology has emerged as a powerful tool to describe the structural changes in lung architecture that accompany the development of lung disease that is experimentally modelled in adult mice. These stereological principles are now being applied to the study of the evolution of the lung architecture over the course of prenatal and postnatal lung development in mouse neonates and adolescents. The immature lung is structurally and functionally distinct from the adult lung, and has a smaller volume than does the adult lung. These differences have raised concerns about whether the inflation fixation of neonatal mouse lungs with the airway pressure (Paw) used for the inflation fixation of adult mouse lungs may cause distortion of the neonatal mouse lung structure, leading to the generation of artefacts in subsequent analyses. The objective of this study was to examine the impact of a Paw of 10, 20 and 30 cmH2O on the estimation of lung volumes and stereologically assessed parameters that describe the lung structure in developing mouse lungs. The data presented demonstrate that low Paw (10 cmH2O) leads to heterogeneity in the unfolding of alveolar structures within the lungs, and that high Paw (30 cmH2O) leads to an overestimation of the lung volume, and thus, affects the estimation of volume-dependent parameters, such as total alveoli number and gas-exchange surface area. Thus, these data support the use of a Paw of 20 cmH2O for inflation fixation in morphometric studies on neonatal mouse lungs.

Implication of in vivo circulating fibrocytes ablation in experimental pulmonary hypertension murine model.

BACKGROUND AND PURPOSE: Recruitment and involvement of bone-/blood-derived circulating fibrocytes (CF) in the promotion of fibrotic tissue remodelling processes have been shown. However, their direct contribution to pathological changes is not clear. The present study investigates the causal role of CF in the pathogenesis of pulmonary hypertension (PH). EXPERIMENTAL APPROACH: For selective ablation of CF, we applied the suicidal gene strategy with herpes simplex virus thymidine kinase (HSV-TK) and ganciclovir. The transgenic mice were generated, having HSV-TK-GFP transgene under the collagen 1 promoter. To selectively target CF, HSV-TK-GFP+ bone marrow transplanted into irradiated wild type mice. These chimera mice were subjected to hypoxia for PH induction and ganciclovir for CF ablation. KEY RESULTS: In vivo CF ablation reduced right ventricular hypertrophy and vascular remodelling with reduced total collagen content. We quantified the CF recruited in the perivascular area and arterial wall of small pulmonary arteries. There was significant recruitment of CF in the lung in response to hypoxia. The characterization of CF showed the expression of CD45 and collagen1 (GFP) along with α-smooth muscle actin (αSMA). CONCLUSION AND IMPLICATIONS: Our data demonstrated that CF ablation has a potential impact on right ventricular hypertrophy and vascular remodelling in the setting of experimental pulmonary hypertension induced by hypoxia. The beneficial effects may be related to the direct contribution of fibrocytes or its paracrine effect on other resident cell types. Thus, clinical manipulation of CF may represent a novel therapeutic approach to ameliorate the disease state in pulmonary hypertension.

Estimation of absolute number of alveolar epithelial type 2 cells in mouse lungs: a comparison between stereology and flow cytometry.

Accurate estimation of the absolute number of a particular cell-type in whole organs is increasingly important in studies on organogenesis, and the remodelling and repair of diseased tissues. The unbiased estimation of the absolute number of cells in an organ is complicated, and design-based stereology remains the method of choice. This has led investigators to explore alternative approaches - such as flow cytometry - as a faster and less labour-intensive replacement for stereology. To address whether flow cytometry might substitute stereology, design-based stereology was compared with microfluorosphere-controlled flow cytometry, for estimation of the absolute number of alveolar epithelial type 2 cells (AEC2) in the lungs of two mouse strains: wild-type C57BL/6J mice and Sftpc-YFP mice. Using design-based stereology, ≈10.7 million and ≈9.0 million AEC2 were estimated in the lungs of wild-type C57BL/6J mice and Sftpc-YFP mice, respectively. Substantially fewer AEC2 were estimated using flow cytometry. In wild-type C57/BL6J mouse lungs, 59% of the AEC2 estimated by design-based stereology were estimated by flow cytometry (≈6.3 million), using intracellular staining for pro-surfactant protein C. Similarly, in Sftpc-YFP mouse lungs, 23% of the AEC2 estimated by design-based stereology were estimated by flow cytometry (≈2.1 million), using yellow fluorescent protein fluorescence. Our data suggest that flow cytometry underestimates AEC2 number, possibly due to impaired recoverability of AEC2 from dissociated lung tissue. These data suggest design-based stereology as the method of choice for the unbiased estimation of the absolute number of cells in an organ. LAY DESCRIPTION: There is much interest in studies on the pathological changes that accompany disease, to be able to count or estimate the number of a particular cell-type in solid tissue, such as an organ. The easiest way to do this is to make liquid suspensions of single cells from solid tissue, and then to count the number of cells of interest, using either a microscope, or automated cell counting (for example, a flow cytometer). Alternatively, solid tissue may be examined microscopically, where the cell-type of interest might also be counted 'by eye' or in an automated manner using software (called planimetry). All of these approaches to counting cells in solid organs come with serious drawbacks, and estimation of the cell number may thus be inaccurate. To overcome this, we have employed a combination of mathematical tools and statistical principles together with microscopy (called 'design-based stereology') that permits the unbiased counting of cells in microscopic fields, which can then be extrapolated to the entire solid tissue volume, to accurately estimate the number of a cell-type of interest in the solid tissue. We have compared this method with the estimation of cell number using a flow cytometer. Our data reveal that flow cytometry appreciably underestimates the total number of cells in solid tissue, where we used the lung as an example of solid tissue, and estimated the number of a unique cell-type in the lung: the alveolar epithelial type 2 cell, to compare stereology with flow cytometry. We believe that flow cytometry underestimates the cell number due to the difficulty of breaking up solid tissue into single cells, and being able to recover all of those single cells for analysis. Our data supports the recommendation to use stereology, not flow cytometry, to accurately estimate the number of a particular cell-type in solid tissue. Accurate estimation of the absolute number of a particular cell-type in whole organs is increasingly important in studies on organogenesis, and the remodelling and repair of diseased tissues. Although estimation of the relative number of cells might be straightforward, unbiased estimation of the absolute number of cells in an organ is complicated, and design-based stereology remains the method of choice. This has led investigators to explore alternative approaches - such as flow cytometry - as a faster and less labour-intensive replacement for stereology. To address whether flow cytometry might substitute stereology, design-based stereology was compared with microfluorosphere-controlled flow cytometry, for estimation of the absolute number of alveolar epithelial type 2 cells (AEC2) in the lungs of two mouse strains: wild-type C57BL/6J mice and Sftpc-YFP mice. Using design-based stereology, ≈10.7 million and ≈9.0 million AEC2 were estimated in the lungs of wild-type C57BL/6J mice and Sftpc-YFP mice, respectively. Substantially fewer AEC2 were estimated using flow cytometry. In wild-type C57/BL6J mouse lungs, 59% of the AEC2 estimated by design-based stereology were estimated by flow cytometry (≈6.3 million), using intracellular staining for pro-surfactant protein C. Similarly, in Sftpc-YFP mouse lungs, 23% of the AEC2 estimated by design-based stereology were estimated by flow cytometry (≈2.1 million), using yellow fluorescent protein fluorescence. Our data suggest that flow cytometry underestimates AEC2 number, possibly due to impaired recoverability of AEC2 from dissociated lung tissue. These data suggest design-based stereology as the method of choice for the unbiased estimation of the absolute number of cells in an organ.

Targeting miR-34a/Pdgfra interactions partially corrects alveologenesis in experimental bronchopulmonary dysplasia.

Bronchopulmonary dysplasia (BPD) is a common complication of preterm birth characterized by arrested lung alveolarization, which generates lungs that are incompetent for effective gas exchange. We report here deregulated expression of miR-34a in a hyperoxia-based mouse model of BPD, where miR-34a expression was markedly increased in platelet-derived growth factor receptor (PDGFR)α-expressing myofibroblasts, a cell type critical for proper lung alveolarization. Global deletion of miR-34a; and inducible, conditional deletion of miR-34a in PDGFRα+ cells afforded partial protection to the developing lung against hyperoxia-induced perturbations to lung architecture. Pdgfra mRNA was identified as the relevant miR-34a target, and using a target site blocker in vivo, the miR-34a/Pdgfra interaction was validated as a causal actor in arrested lung development. An antimiR directed against miR-34a partially restored PDGFRα+ myofibroblast abundance and improved lung alveolarization in newborn mice in an experimental BPD model. We present here the first identification of a pathology-relevant microRNA/mRNA target interaction in aberrant lung alveolarization and highlight the translational potential of targeting the miR-34a/Pdgfra interaction to manage arrested lung development associated with preterm birth.

The Tcf21 lineage constitutes the lung lipofibroblast population.

Transcription factor 21 (Tcf21) is a basic helix-loop-helix transcription factor required for mesenchymal development in several organs. Others have demonstrated that Tcf21 is expressed in embryonic lung mesenchyme and that loss of Tcf21 results in a pulmonary hypoplasia phenotype. Although recent single-cell transcriptome analysis has described multiple mesenchymal cell types in the lung, few have characterized the Tcf21 expressing population. To explore the Tcf21 mesenchymal lineage, we traced Tcf21-expressing cells during embryogenesis and in the adult. Our results showed that Tcf21 progenitor cells at embryonic day (E)11.5 generated a subpopulation of fibroblasts and lipofibroblasts and a limited number of smooth muscle cells. After E15.5, Tcf21 progenitor cells exclusively become lipofibroblasts and interstitial fibroblasts. Lipid metabolism genes were highly expressed in perinatal and adult Tcf21 lineage cells. Overexpression of Tcf21 in primary neonatal lung fibroblasts led to increases in intracellular neutral lipids, suggesting a regulatory role for Tcf21 in lipofibroblast function. Collectively, our results reveal that Tcf21 expression after E15.5 delineates the lipofibroblast and a population of interstitial fibroblasts. The Tcf21 inducible Cre mouse line provides a novel method for identifying and manipulating the lipofibroblast.

Understanding alveolarization to induce lung regeneration.

BACKGROUND: Gas exchange represents the key physiological function of the lung, and is dependent upon proper formation of the delicate alveolar structure. Malformation or destruction of the alveolar gas-exchange regions are key histopathological hallmarks of diseases such as bronchopulmonary dysplasia (BPD), chronic obstructive pulmonary disease (COPD), and pulmonary fibrosis; all of which are characterized by perturbations to the alveolo-capillary barrier structure. Impaired gas-exchange is the primary initial consequence of these perturbations, resulting in severe clinical symptoms, reduced quality of life, and death. The pronounced morbidity and mortality associated with malformation or destruction of alveoli underscores a pressing need for new therapeutic concepts. The re-induction of alveolarization in diseased lungs is a new and exciting concept in a regenerative medicine approach to manage pulmonary diseases that are characterized by an absence of alveoli. MAIN TEXT: Mechanisms of alveolarization first need to be understood, to identify pathways and mediators that may be exploited to drive the induction of alveolarization in the diseased lung. With this in mind, a variety of candidate cell-types, pathways, and molecular mediators have recently been identified. Using lineage tracing approaches and lung injury models, new progenitor cells for epithelial and mesenchymal cell types - as well as cell lineages which are able to acquire stem cell properties - have been discovered. However, the underlying mechanisms that orchestrate the complex process of lung alveolar septation remain largely unknown. CONCLUSION: While important progress has been made, further characterization of the contributing cell-types, the cell type-specific molecular signatures, and the time-dependent chemical and mechanical processes in the developing, adult and diseased lung is needed in order to implement a regenerative therapeutic approach for pulmonary diseases.

Recent advances in our understanding of the mechanisms of late lung development and bronchopulmonary dysplasia.

The objective of lung development is to generate an organ of gas exchange that provides both a thin gas diffusion barrier and a large gas diffusion surface area, which concomitantly generates a steep gas diffusion concentration gradient. As such, the lung is perfectly structured to undertake the function of gas exchange: a large number of small alveoli provide extensive surface area within the limited volume of the lung, and a delicate alveolo-capillary barrier brings circulating blood into close proximity to the inspired air. Efficient movement of inspired air and circulating blood through the conducting airways and conducting vessels, respectively, generates steep oxygen and carbon dioxide concentration gradients across the alveolo-capillary barrier, providing ideal conditions for effective diffusion of both gases during breathing. The development of the gas exchange apparatus of the lung occurs during the second phase of lung development-namely, late lung development-which includes the canalicular, saccular, and alveolar stages of lung development. It is during these stages of lung development that preterm-born infants are delivered, when the lung is not yet competent for effective gas exchange. These infants may develop bronchopulmonary dysplasia (BPD), a syndrome complicated by disturbances to the development of the alveoli and the pulmonary vasculature. It is the objective of this review to update the reader about recent developments that further our understanding of the mechanisms of lung alveolarization and vascularization and the pathogenesis of BPD and other neonatal lung diseases that feature lung hypoplasia.

A novel mouse Cre-driver line targeting Perilipin 2-expressing cells in the neonatal lung.

Pulmonary diseases such as chronic obstructive pulmonary disease, lung fibrosis, and bronchopulmonary dysplasia are characterized by the destruction or malformation of the alveolar regions of the lung. The underlying pathomechanisms at play are an area of intense interest since these mechanisms may reveal pathways suitable for interventions to drive reparative processes. Lipid-laden fibroblasts (lipofibroblasts) express the Perilipin 2 (Plin2) gene-product, PLIN2, commonly called adipose-differentiation related protein (ADRP). These cells are also thought to play a role in alveolarization and repair after injury to the alveolus. Progress in defining the functional contribution of lipofibroblasts to alveolar generation and repair is hampered by a lack of in vivo tools. The present study reports the generation of an inducible mouse Cre-driver line to target cells of the ADRP lineage. Robust Cre-mediated recombination in this mouse line was detected in mesenchymal cells of the postnatal lung, and in additional organs including the heart, liver, and spleen. The generation and validation of this valuable new tool to genetically target, manipulate, and trace cells of the ADRP lineage is critical for assessing the functional contribution of lipofibroblasts to lung development and repair.