Christina E. Barkauskas

Multiple stromal populations contribute to pulmonary fibrosis without evidence for epithelial to mesenchymal transition

There are currently few treatment options for pulmonary fibrosis. Innovations may come from a better understanding of the cellular origin of the characteristic fibrotic lesions. We have analyzed normal and fibrotic mouse and human lungs by confocal microscopy to define stromal cell populations with respect to several commonly used markers. In both species, we observed unexpected heterogeneity of stromal cells. These include numerous cells with molecular and morphological characteristics of pericytes, implicated as a source of myofibroblasts in other fibrotic tissues. We used mouse genetic tools to follow the fates of specific cell types in the bleomcyin-induced model of pulmonary fibrosis. Using inducible transgenic alleles to lineage trace pericyte-like cells in the alveolar interstitium, we show that this population proliferates in fibrotic regions. However, neither these cells nor their descendants express high levels of the myofibroblast marker alpha smooth muscle actin (Acta2, aSMA). We then used a Surfactant protein C-CreERT2 knock-in allele to follow the fate of Type II alveolar cells (AEC2) in vivo. We find no evidence at the cellular or molecular level for epithelial to mesenchymal transition of labeled cells into myofibroblasts. Rather, bleomycin accelerates the previously reported conversion of AEC2 into AEC1 cells. Similarly, epithelial cells labeled with our Scgb1a1-CreER allele do not give rise to fibroblasts but generate both AEC2 and AEC1 cells in response to bleomycin-induced lung injury. Taken together, our results show a previously unappreciated heterogeneity of cell types proliferating in fibrotic lesions and exclude pericytes and two epithelial cell populations as the origin of myofibroblasts.

Repair and regeneration of the respiratory system: complexity, plasticity, and mechanisms of lung stem cell function

Respiratory disease is the third leading cause of death in the industrialized world. Consequently, the trachea, lungs, and cardiopulmonary vasculature have been the focus of extensive investigations. Recent studies have provided new information about the mechanisms driving lung development and differentiation. However, there is still much to learn about the ability of the adult respiratory system to undergo repair and to replace cells lost in response to injury and disease. This Review highlights the multiple stem/progenitor populations in different regions of the adult lung, the plasticity of their behavior in injury models, and molecular pathways that support homeostasis and repair.

Pulmonary fibrosis: patterns and perpetrators.

Pulmonary fibrosis occurs in a variety of clinical settings, constitutes a major cause of morbidity and mortality, and represents an enormous unmet medical need. However, the disease is heterogeneous, and the failure to accurately discern between forms of fibrosing lung diseases leads to inaccurate treatments. Pulmonary fibrosis occurring in the context of connective tissue diseases is often characterized by a distinct pattern of tissue pathology and may be amenable to immunosuppressive therapies. In contrast, idiopathic pulmonary fibrosis (IPF) is a progressive and lethal form of fibrosing lung disease that is recalcitrant to therapies that target the immune system. Although animal models of fibrosis imperfectly recapitulate IPF, they have yielded numerous targets for therapeutic intervention. Understanding the heterogeneity of these diseases and elucidating the final common pathways of fibrogenesis are critical for the development of efficacious therapies for severe fibrosing lung diseases.

Telomere dysfunction causes alveolar stem cell failure

Significance Idiopathic pulmonary fibrosis and emphysema are leading causes of mortality, but there are no effective therapies. Mutations in telomerase are the most common identifiable risk factor for idiopathic pulmonary fibrosis. They also predispose to severe emphysema in smokers, occurring at a frequency similar to α-1 antitrypsin deficiency. The work shown here points to alveolar stem cell senescence as a driver of these pathologies. Epithelial stem cell failure was associated with secondary inflammatory recruitment and exquisite susceptibility to injury from “second hits.” The findings suggest that efforts to reverse the stem cell failure state directly, rather than its secondary consequences, may be an effective therapy approach in telomere-mediated lung disease. Telomere syndromes have their most common manifestation in lung disease that is recognized as idiopathic pulmonary fibrosis and emphysema. In both conditions, there is loss of alveolar integrity, but the underlying mechanisms are not known. We tested the capacity of alveolar epithelial and stromal cells from mice with short telomeres to support alveolar organoid colony formation and found that type 2 alveolar epithelial cells (AEC2s), the stem cell-containing population, were limiting. When telomere dysfunction was induced in adult AEC2s by conditional deletion of the shelterin component telomeric repeat-binding factor 2, cells survived but remained dormant and showed all the hallmarks of cellular senescence. Telomere dysfunction in AEC2s triggered an immune response, and this was associated with AEC2-derived up-regulation of cytokine signaling pathways that are known to provoke inflammation in the lung. Mice uniformly died after challenge with bleomycin, underscoring an essential role for telomere function in AEC2s for alveolar repair. Our data show that alveoloar progenitor senescence is sufficient to recapitulate the regenerative defects, inflammatory responses, and susceptibility to injury that are characteristic of telomere-mediated lung disease. They suggest alveolar stem cell failure is a driver of telomere-mediated lung disease and that efforts to reverse it may be clinically beneficial.

Plasticity of Hopx+ Type I alveolar cells to regenerate Type II cells in the lung

The plasticity of differentiated cells in adult tissues undergoing repair is an area of intense research. Pulmonary alveolar Type II cells produce surfactant and function as progenitors in the adult, demonstrating both self-renewal and differentiation into gas exchanging Type I cells. In vivo, Type I cells are thought to be terminally differentiated and their ability to give rise to alternate lineages has not been reported. Here, we show that Hopx becomes restricted to Type I cells during development. However, unexpectedly, lineage-labeled Hopx+ cells both proliferate and generate Type II cells during adult alveolar regrowth following partial pneumonectomy. In clonal 3D culture, single Hopx+ Type I cells generate organoids composed of Type I and Type II cells, a process modulated by TGFβ signaling. These findings demonstrate unanticipated plasticity of Type I cells and a bi-directional lineage relationship between distinct differentiated alveolar epithelial cell types in vivo and in single cell culture.

Cellular Mechanisms of Tissue Fibrosis. 7. New insights into the cellular mechanisms of pulmonary fibrosis

Idiopathic pulmonary fibrosis (IPF) is a devastating disease characterized by severe and progressive scar formation in the gas-exchange regions of the lung. Despite years of research, therapeutic treatments remain elusive and there is a pressing need for deeper mechanistic insights into the pathogenesis of the disease. In this article, we review our current knowledge of the triggers and/or perpetuators of pulmonary fibrosis with special emphasis on the alveolar epithelium and the underlying mesenchyme. In doing so, we raise a number of questions highlighting critical voids and limitations in our current understanding and study of this disease.

Stem cells of the adult lung: their development and role in homeostasis, regeneration, and disease.

The lung has vital functions in gas exchange and immune defense. To fulfill these functions the cellular composition and complex three‐dimensional organization of the organ must be maintained for a lifetime. Cell turnover in the adult lung is normally low. However, in response to cellular injury by agents such as infection, toxic compounds, and irradiation there is rapid proliferation and differentiation of endogenous stem and progenitor cells to repair and regenerate the damaged tissue. In the mouse, different populations of epithelial progenitor cells have been identified in different regions of the respiratory system: basal cells in the proximal tracheobronchial region and submucosal glands, and secretory cells in the conducting airways and bronchioalveolar duct junction. The identification of the long‐term stem cells in the alveolar region is still under debate, and little is known about resident stem and progenitor cells for the many mesodermal populations. Within this framework information is provided about the origin of lung progenitor cells during development, the microenvironment in which they reside, the experimental injury and repair systems used to promote their regenerative response, and some of the mechanisms regulating their behavior. WIREs Dev Biol 2013, 2:131–148. doi: 10.1002/wdev.58

Lung organoids: current uses and future promise

ABSTRACT Lungs are composed of a system of highly branched tubes that bring air into the alveoli, where gas exchange takes place. The proximal and distal regions of the lung contain epithelial cells specialized for different functions: basal, secretory and ciliated cells in the conducting airways and type II and type I cells lining the alveoli. Basal, secretory and type II cells can be grown in three-dimensional culture, with or without supporting stromal cells, and under these conditions they give rise to self-organizing structures known as organoids. This Review summarizes the different methods for generating organoids from cells isolated from human and mouse lungs, and compares their final structure and cellular composition with that of the airways or alveoli of the adult lung. We also discuss the potential and limitations of organoids for addressing outstanding questions in lung biology and for developing new drugs for disorders such as cystic fibrosis and asthma. Summary: This Review article explores the latest advances in both adult and embryonic stem cell-derived lung organoid culture, and discusses how these systems can be used to understand homeostasis and regeneration.

Sec63 and Xbp1 regulate IRE1α activity and polycystic disease severity

The HSP40 cochaperone SEC63 is associated with the SEC61 translocon complex in the ER. Mutations in the gene encoding SEC63 cause polycystic liver disease in humans; however, it is not clear how altered SEC63 influences disease manifestations. In mice, loss of SEC63 induces cyst formation both in liver and kidney as the result of reduced polycystin-1 (PC1). Here we report that inactivation of SEC63 induces an unfolded protein response (UPR) pathway that is protective against cyst formation. Specifically, using murine genetic models, we determined that SEC63 deficiency selectively activates the IRE1α-XBP1 branch of UPR and that SEC63 exists in a complex with PC1. Concomitant inactivation of both SEC63 and XBP1 exacerbated the polycystic kidney phenotype in mice by markedly suppressing cleavage at the G protein-coupled receptor proteolysis site (GPS) in PC1. Enforced expression of spliced XBP1 (XBP1s) enhanced GPS cleavage of PC1 in SEC63-deficient cells, and XBP1 overexpression in vivo ameliorated cystic disease in a murine model with reduced PC1 function that is unrelated to SEC63 inactivation. Collectively, the findings show that SEC63 function regulates IRE1α/XBP1 activation, SEC63 and XBP1 are required for GPS cleavage and maturation of PC1, and activation of XBP1 can protect against polycystic disease in the setting of impaired biogenesis of PC1.

Diabetes on a cardiovascular ward: adherence to current recommendations.

Objectives: Improving diabetes and blood pressure control decreases the incidence and progression of microvascular disease. Likewise, screening for microvascular complications is beneficial in the early detection and treatment of these disorders. However, adherence to practice guidelines for screening and treatment in patients with diabetes is suboptimal. This study describes a group of patients with diabetes who were admitted to a cardiology service at an academic medical center. Methods: Patient interview and chart review were used to determine glycemic control and compliance with practice guidelines. Results: The mean hemoglobin A1c was 8.3%. Only 69% of patients received ophthalmologic examinations, and fewer were screened for nephropathy. Thirty-five percent of patients monitored home blood glucoses less than daily. Nearly 17% had no hemoglobin A1c or lipid checks during the 3 months before admission. Conclusions: For a group of poorly controlled patients with diabetes who are at high risk for cardiovascular disease, adherence to practice guidelines and the level of diabetes control is inadequate.