Resident fibroblast lineages mediate pressure overload–induced cardiac fibrosis
Thomas Moore-Morris, … , Ju Chen, Sylvia M. Evans
Thomas Moore-Morris, … , Ju Chen, Sylvia M. Evans
Published June 17, 2014
Citation Information: J Clin Invest. 2014;124(7):2921-2934. https://doi.org/10.1172/JCI74783.
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Resident fibroblast lineages mediate pressure overload–induced cardiac fibrosis

Abstract

Activation and accumulation of cardiac fibroblasts, which result in excessive extracellular matrix deposition and consequent mechanical stiffness, myocyte uncoupling, and ischemia, are key contributors to heart failure progression. Recently, endothelial-to-mesenchymal transition (EndoMT) and the recruitment of circulating hematopoietic progenitors to the heart have been reported to generate substantial numbers of cardiac fibroblasts in response to pressure overload–induced injury; therefore, these processes are widely considered to be promising therapeutic targets. Here, using multiple independent murine Cre lines and a collagen1a1-GFP fusion reporter, which specifically labels fibroblasts, we found that following pressure overload, fibroblasts were not derived from hematopoietic cells, EndoMT, or epicardial epithelial-to-mesenchymal transition. Instead, pressure overload promoted comparable proliferation and activation of two resident fibroblast lineages, including a previously described epicardial population and a population of endothelial origin. Together, these data present a paradigm for the origins of cardiac fibroblasts during development and in fibrosis. Furthermore, these data indicate that therapeutic strategies for reducing pathogenic cardiac fibroblasts should shift from targeting presumptive EndoMT or infiltrating hematopoietically derived fibroblasts, toward common pathways upregulated in two endogenous fibroblast populations.

Authors

Thomas Moore-Morris, Nuno Guimarães-Camboa, Indroneal Banerjee, Alexander C. Zambon, Tatiana Kisseleva, Aurélie Velayoudon, William B. Stallcup, Yusu Gu, Nancy D. Dalton, Marta Cedenilla, Rafael Gomez-Amaro, Bin Zhou, David A. Brenner, Kirk L. Peterson, Ju Chen, Sylvia M. Evans

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Figure 3

Complementary distribution patterns of Wt1-Cre and Tie2-Cre CF lineages.

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Complementary distribution patterns of Wt1-Cre and Tie2-Cre CF lineages....
(A) Representative 4-chamber view of adult Wt1-Cre+/– collagen1a1-GFP+/– Rosa-tdT+/– heart. IVS (A1, A1′) contained few lineage-traced fibroblasts, whereas fibroblasts in the LVFW (A2, A2′) were predominantly lineage traced (lineage traced, arrows; nonlineage traced, arrowheads). Labeled myocytes were abundant in the IVS (asterisks). (B) Representative Tie2-Cre+/– collagen1a1-GFP+/– Rosa-tdT+/– heart showing Tie2-Cre lineage-traced fibroblasts were predominant in the IVS (B1, B1′), but most fibroblasts were nonlineage traced in the LVFW (B2, B2′) (lineage traced, arrows; nonlineage traced, arrowheads). (C) Flow cytometry plots of dissociated LV and IVS from Tie2-Cre, Wt1-Cre, Wt1-Cre + Tie2-Cre, and Vav-Cre lineage-traced mice. Tie2-Cre and Wt1-Cre, but not Vav-Cre, labeled collagen1a1-GFP+ CF populations. (D) Quantification of the relative numbers of lineage-traced fibroblasts (n = 3 per group). Combining Wt1-Cre and Tie2-Cre resulted in labeling of approximately 95% of fibroblasts. Histograms represent average ± SD. Data from Wt1-Cre and Wt1-Cre + Tie2-Cre groups were compared using unpaired Student’s t test. Scale bars: 1 mm (A and B); 250 μm (A1, A2, B1, B2); and 20 μm (A1′, A2′, B1′, B2′).