Li C.,Los Angeles CountyUniversity of Southern California Medical Center |
Bellusci S.,Excellence Cluster Cardio Pulmonary System ECCPS |
Bellusci S.,Universities of Giessen and Marburg Lung Center |
Bellusci S.,Saban Research Institute |
And 2 more authors.
Journal of Biochemistry | Year: 2015
The role of WNT signalling in metazoan organogenesis has been a topic of widespread interest. In the lung, while the role of canonical WNT signalling has been examined in some detail by multiple studies, the non-canonical WNT signalling has received limited attention. Reliable evidence shows that this important signalling mechanism constitutes a major regulatory pathway in lung development. In addition, accumulating evidence has also shown that the non-canonical WNT pathway is critical for maintaining lung homeostasis and that aberrant activation of this pathway may underlie several debilitating lung diseases. Functional analyses have further revealed that the non-canonical WNT pathway regulates multiple cellular activities in the lung that are dependent on the specific cellular context. In most cell types, non-canonical WNT signalling regulates canonical WNT activity, which is also critical for many aspects of lung biology. This review will summarize what is currently known about the role of non-canonical WNT signalling in lung development, homeostasis and pathogenesis of disease. © The Authors 2015. Published by Oxford University Press on behalf of the Japanese Biochemical Society. All rights reserved.
El Agha E.,Excellence Cluster Cardio Pulmonary System ECCPS |
El Agha E.,Universities of Giessen and Marburg Lung Center |
Herold S.,Excellence Cluster Cardio Pulmonary System ECCPS |
Herold S.,Universities of Giessen and Marburg Lung Center |
And 16 more authors.
Development (Cambridge) | Year: 2014
The lung mesenchyme consists of a widely heterogeneous population of cells that play crucial roles during development and homeostasis after birth. These cells belong to myogenic, adipogenic, chondrogenic, neuronal and other lineages. Yet, no clear hierarchy for these lineages has been established. We have previously generated a novel Fgf10iCreknock-in mouse line that allows lineage tracing of Fgf10-positive cells during development and postnatally. Using these mice, we hereby demonstrate the presence of two waves of Fgf10 expression during embryonic lung development: the first wave, comprising Fgf10-positive cells residing in the submesothelial mesenchyme at early pseudoglandular stage (as well as their descendants); and the second wave, comprising Fgf10- positive cells from late pseudoglandular stage (as well as their descendants). Our lineage-tracing data reveal that the first wave contributes to the formation of parabronchial and vascular smooth muscle cells as well as lipofibroblasts at later developmental stages, whereas the second wave does not give rise to smooth muscle cells but to lipofibroblasts as well as an Nkx2.1- E-Cad- Epcam+ Pro-Spc+ lineage that requires further in-depth analysis. During alveologenesis, Fgf10-positive cells give rise to lipofibroblasts rather than alveolar myofibroblasts, and during adult life, a subpopulation of Fgf10- expressing cells represents a pool of resident mesenchymal stromal (stem) cells (MSCs) (Cd45- Cd31- Sca-1+). Taken together, we show for the first time that Fgf10-expressing cells represent a pool of mesenchymal progenitors in the embryonic and postnatal lung. Our findings suggest that Fgf10-positive cells could be useful for developing stem cell-based therapies for treating interstitial lung diseases. © 2014. Published by The Company of Biologists Ltd.