Functional analysis of two distinct bronchiolar progenitors during lung injury and repair.

Air spaces of the mammalian lung are lined by a specialized epithelium that is maintained by endogenous progenitor cells. Within bronchioles, the abundance and distribution of progenitor cells that contribute to epithelial homeostasis change as a function of maintenance versus repair. It is unclear whether functionally distinct progenitor pools or a single progenitor cell type maintain the epithelium and how the behavior is regulated in normal or disease states. To address these questions, we applied fractionation methods for the enrichment of distal airway progenitors. We show that bronchiolar progenitor cells can be subdivided into two functionally distinct populations that differ in their susceptibility to injury and contribution to repair. The proliferative capacity of these progenitors is confirmed in a novel in vitro assay. We show that both populations give rise to colonies with a similar dependence on stromal cell interactions and regulation by TGF-ß. These findings provide additional insights into mechanisms of epithelial remodeling in the setting of chronic lung disease and offer hope that pharmacologic interventions may be developed to mitigate tissue remodeling.

Prospective isolation of bronchiolar stem cells based upon immunophenotypic and autofluorescence characteristics.

Bronchiolar stem cells have been functionally defined in vivo on the basis of their resistance to chemical (naphthalene) injury, their infrequent proliferation relative to other progenitor cell types, and their coexpression of the airway and alveolar secretory cell markers Clara cell secretory protein and pro-surfactant protein C, respectively. Cell surface markers that have previously been used for their prospective isolation included Sca-1 and CD34. Using transgenic animal models associated with stem cell expansion, ablation, and lineage tracing, we demonstrate that CD34(pos) cells do not belong to the airway epithelial lineage and that cell surface Sca-1 immunoreactivity does not distinguish between bronchiolar stem and facultative transit-amplifying (Clara) cell populations. Furthermore, we show that high autofluorescence (AF(high)) is a distinguishing characteristic of Clara cells allowing for the fractionation of AF(low) bronchiolar stem cells. On the basis of these data we show that the defining phenotype of the bronchiolar stem cell is CD45(neg) CD31(neg) CD34(neg) Sca-l(low) AF(low). This refinement in the definition of bronchiolar stem cells provides a critical tool by which to assess functional and molecular distinctions between bronchiolar stem cells and the more abundant pool of facultative transit-amplifying (Clara) cells.

beta-Catenin is not necessary for maintenance or repair of the bronchiolar epithelium.

Signaling by Wnt/beta-catenin regulates self-renewal of tissue stem cells in the gut and, when activated in the embryonic bronchiolar epithelium, leads to stem cell expansion. We have used transgenic and cell type-specific knockout strategies to determine roles for beta-catenin-regulated gene expression in normal maintenance and repair of the bronchiolar epithelium. Analysis of TOPGal transgene activity detected beta-catenin signaling in the steady-state and repairing bronchiolar epithelium. However, the broad distribution and phenotype of signaling cells precluded establishment of a clear role for beta-catenin in the normal or repairing state. Necessity of beta-catenin signaling was tested through Cre-mediated deletion of Catnb exons 2-6 in airway epithelial cells. Functional knockout of beta-catenin had no impact on expression of Clara cell differentiation markers, mitotic index, or sensitivity of these cells to the Clara cell-specific toxicant, naphthalene. Repair of the naphthalene-injured airway proceeded with establishment of focal regions of beta-catenin-null epithelium. The size of regenerative epithelial units, mitotic index, and restoration of the ciliated cell population did not vary between wild-type and genetically modified mice. Thus, beta-catenin was not necessary for maintenance or efficient repair of the bronchiolar epithelium.

Conditional stabilization of beta-catenin expands the pool of lung stem cells.

Maintenance of classic stem cell hierarchies is dependent upon stem cell self-renewal mediated in part by Wnt/beta-catenin regulation of the cell cycle. This function is critical in rapidly renewing tissues due to the obligate role played by the tissue stem cell. However, the stem cell hierarchy responsible for maintenance of the conducting airway epithelium is distinct from classic stem cell hierarchies. The epithelium of conducting airways is maintained by transit-amplifying cells in the steady state; rare bronchiolar stem cells are activated to participate in epithelial repair only following depletion of transit-amplifying cells. Here, we investigate how signaling through beta-catenin affects establishment and maintenance of the stem cell hierarchy within the slowly renewing epithelium of the lung. Conditional potentiation of beta-catenin signaling in the embryonic lung results in amplification of airway stem cells through attenuated differentiation rather than augmented proliferation. Our data demonstrate that the differentiation-modulating activities of stabilized beta-catenin account for expansion of tissue stem cells.