Your search keyword '"Ahlbrecht, Katrin"' showing total 5 results

1. Origin and characterization of alpha smooth muscle actin‐positive cells during murine lung development

Author

Moiseenko, Alena, Kheirollahi, Vahid, Chao, Cho‐Ming, Ahmadvand, Negah, Quantius, Jennifer, Wilhelm, Jochen, Herold, Susanne, Ahlbrecht, Katrin, Morty, Rory E., Rizvanov, Albert A., Minoo, Parviz, El Agha, Elie, and Bellusci, Saverio

Abstract

ACTA2 expression identifies pulmonary airway and vascular smooth muscle cells (SMCs) as well as alveolar myofibroblasts (MYF). Mesenchymal progenitors expressing fibroblast growth factor 10 (Fgf10), Wilms tumor 1 (Wt1), or glioma‐associated oncogene 1 (Gli1) contribute to SMC formation from early stages of lung development. However, their respective contribution and specificity to the SMC and/or alveolar MYF lineages remain controversial. In addition, the contribution of mesenchymal cells undergoing active WNT signaling remains unknown. Using Fgf10CreERT2, Wt1CreERT2, Gli1CreERT2, and Axin2CreERT2inducible driver lines in combination with a tdTomatofloxreporter line, the respective differentiation of each pool of labeled progenitor cells along the SMC and alveolar MYF lineages was quantified. The results revealed that while FGF10+and WT1+cells show a minor contribution to the SMC lineage, GLI1+and AXIN2+cells significantly contribute to both the SMC and alveolar MYF lineages, but with limited specificity. Lineage tracing using the Acta2‐CreERT2transgenic line showed that ACTA2+cells labeled at embryonic day (E)11.5 do not expand significantly to give rise to new SMCs at E18.5. However, ACTA2+cells labeled at E15.5 give rise to the majority (85%–97%) of the SMCs in the lung at E18.5 as well as alveolar MYF progenitors in the lung parenchyma. Fluorescence‐activated cell sorting‐based isolation of different subpopulations of ACTA2+lineage‐traced cells followed by gene arrays, identified transcriptomic signatures for alveolar MYF progenitors versus airway and vascular SMCs at E18.5. Our results establish a new transcriptional landscape for further experiments addressing the function of signaling pathways in the formation of different subpopulations of ACTA2+cells. StemCells2017;35:1566–1578 Model summarizing the impact of different progenitor populations on the SMC lineage. Mesothelial WT1+and FGF10+cells contribute in a minor fashion to the SMC lineage, while GLI1+and AXIN2+significantly contribute to this lineage. Sub‐mesoth. –sub‐mesothelial, sub‐epith. –sub‐epith

Published

2017

2. Quantitative Proteome Analysis of Alveolar Type-II Cells Reveals a Connection of Integrin Receptor Subunits Beta 2/6 and WNT Signaling.

Author

Mukhametshina, Regina T., Ruhs, Aaron, Singh, Indrabahadur, Hasan, Diya, Contreras, Adriana, Mehta, Aditi, Nikam, Vandana S., Ahlbrecht, Katrin, Carraro, Gianni, Cabrera-Fuentes, Hector A., Dongsheng Jiang, Voswinckel, Robert, Seeger, Werner, Bellusci, Saverio, Scharffetter-Kochanek, Karin, Bagaeva, Tatyana V., Preissner, Klaus T., Boettger, Thomas, Braun, Thomas, and Krüger, Marcus

Published

2013

3. Quantitative Proteome Analysis of Alveolar Type-II Cells Reveals a Connection of Integrin Receptor Subunits Beta 2/6 and WNT Signaling

Author

Mukhametshina, Regina T., Ruhs, Aaron, Singh, Indrabahadur, Hasan, Diya, Contreras, Adriana, Mehta, Aditi, Nikam, Vandana S., Ahlbrecht, Katrin, Carraro, Gianni, Cabrera-Fuentes, Hector A., Jiang, Dongsheng, Voswinckel, Robert, Seeger, Werner, Bellusci, Saverio, Scharffetter-Kochanek, Karin, Bagaeva, Tatyana V., Preissner, Klaus T., Boettger, Thomas, Braun, Thomas, Krüger, Marcus, and Barreto, Guillermo

Abstract

Alveolar type-II cells (ATII cells) are lung progenitor cells responsible for regeneration of alveolar epithelium during homeostatic turnover and in response to injury. Characterization of ATII cells will have a profound impact on our understanding and treatment of lung disease. The identification of novel ATII cell-surface proteins can be used for sorting and enrichment of these cells for further characterization. Here we combined a high-resolution mass spectrometry-based membrane proteomic approach using lungs of the SILAC mice with an Affymetrix microarray-based transcriptome analysis of ATII cells. We identified 16 proteins that are enriched in the membrane fraction of ATII cells and whose genes are highly expressed in these cells. Interestingly, we confirmed our data for two of these genes, integrin beta 2 and 6 (Itgb2and Itgb6), by qRT-PCR expression analysis and Western blot analysis of protein extracts. Moreover, flow cytometry and immunohistochemistry in adult lung revealed that ITGB2 and ITGB6 are present in subpopulations of surfactant-associated-protein-C-positive cells, suggesting the existence of different types of ATII cells. Furthermore, analysis of the Itgb2–/–mice showed that Itgb2is required for proper WNT signaling regulation in the lung.

Published

2013

4. Two-Way Conversion between Lipogenic and Myogenic Fibroblastic Phenotypes Marks the Progression and Resolution of Lung Fibrosis

Author

El Agha, Elie, Moiseenko, Alena, Kheirollahi, Vahid, De Langhe, Stijn, Crnkovic, Slaven, Kwapiszewska, Grazyna, Szibor, Marten, Kosanovic, Djuro, Schwind, Felix, Schermuly, Ralph T., Henneke, Ingrid, MacKenzie, BreAnne, Quantius, Jennifer, Herold, Susanne, Ntokou, Aglaia, Ahlbrecht, Katrin, Braun, Thomas, Morty, Rory E., Günther, Andreas, Seeger, Werner, and Bellusci, Saverio

Published

2017

5. Two-Way Conversion between Lipogenic and Myogenic Fibroblastic Phenotypes Marks the Progression and Resolution of Lung Fibrosis

Author

El Agha, Elie, Moiseenko, Alena, Kheirollahi, Vahid, De Langhe, Stijn, Crnkovic, Slaven, Kwapiszewska, Grazyna, Szibor, Marten, Kosanovic, Djuro, Schwind, Felix, Schermuly, Ralph T., Henneke, Ingrid, MacKenzie, BreAnne, Quantius, Jennifer, Herold, Susanne, Ntokou, Aglaia, Ahlbrecht, Katrin, Braun, Thomas, Morty, Rory E., Günther, Andreas, Seeger, Werner, and Bellusci, Saverio

Abstract

Idiopathic pulmonary fibrosis (IPF) is a form of progressive interstitial lung disease with unknown etiology. Due to a lack of effective treatment, IPF is associated with a high mortality rate. The hallmark feature of this disease is the accumulation of activated myofibroblasts that excessively deposit extracellular matrix proteins, thus compromising lung architecture and function and hindering gas exchange. Here we investigated the origin of activated myofibroblasts and the molecular mechanisms governing fibrosis formation and resolution. Genetic engineering in mice enables the time-controlled labeling and monitoring of lipogenic or myogenic populations of lung fibroblasts during fibrosis formation and resolution. Our data demonstrate a lipogenic-to-myogenic switch in fibroblastic phenotype during fibrosis formation. Conversely, we observed a myogenic-to-lipogenic switch during fibrosis resolution. Analysis of human lung tissues and primary human lung fibroblasts indicates that this fate switching is involved in IPF pathogenesis, opening potential therapeutic avenues to treat patients.

Published

2017