FOXC2 and fluid shear stress stabilize postnatal lymphatic vasculature
Amélie Sabine, … , Naoyuki Miura, Tatiana V. Petrova
Amélie Sabine, … , Naoyuki Miura, Tatiana V. Petrova
Published September 21, 2015
Citation Information: J Clin Invest. 2015;125(10):3861-3877. https://doi.org/10.1172/JCI80454.
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Research Article Vascular biology

FOXC2 and fluid shear stress stabilize postnatal lymphatic vasculature

Abstract

Biomechanical forces, such as fluid shear stress, govern multiple aspects of endothelial cell biology. In blood vessels, disturbed flow is associated with vascular diseases, such as atherosclerosis, and promotes endothelial cell proliferation and apoptosis. Here, we identified an important role for disturbed flow in lymphatic vessels, in which it cooperates with the transcription factor FOXC2 to ensure lifelong stability of the lymphatic vasculature. In cultured lymphatic endothelial cells, FOXC2 inactivation conferred abnormal shear stress sensing, promoting junction disassembly and entry into the cell cycle. Loss of FOXC2-dependent quiescence was mediated by the Hippo pathway transcriptional coactivator TAZ and, ultimately, led to cell death. In murine models, inducible deletion of Foxc2 within the lymphatic vasculature led to cell-cell junction defects, regression of valves, and focal vascular lumen collapse, which triggered generalized lymphatic vascular dysfunction and lethality. Together, our work describes a fundamental mechanism by which FOXC2 and oscillatory shear stress maintain lymphatic endothelial cell quiescence through intercellular junction and cytoskeleton stabilization and provides an essential link between biomechanical forces and endothelial cell identity that is necessary for postnatal vessel homeostasis. As FOXC2 is mutated in lymphedema-distichiasis syndrome, our data also underscore the role of impaired mechanotransduction in the pathology of this hereditary human disease.

Authors

Amélie Sabine, Esther Bovay, Cansaran Saygili Demir, Wataru Kimura, Muriel Jaquet, Yan Agalarov, Nadine Zangger, Joshua P. Scallan, Werner Graber, Elgin Gulpinar, Brenda R. Kwak, Taija Mäkinen, Inés Martinez-Corral, Sagrario Ortega, Mauro Delorenzi, Friedemann Kiefer, Michael J. Davis, Valentin Djonov, Naoyuki Miura, Tatiana V. Petrova

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Figure 4

FOXC2 and OSS control adherens cell-cell junction integrity.

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FOXC2 and OSS control adherens cell-cell junction integrity. (A) Stainin...
(A) Staining of control and FOXC2KD cells for FOXC2 (green) and VE-cadherin (pink). The arrow indicates an overlapping junction induced by OSS; the arrowhead indicates a zigzag-like junction induced by FOXC2 depletion. Cell nuclei are outlined by white lines. (B) High-magnification images of VE-cadherin junctions (black) show the formation of reticular structures (red arrow) in control cells under OSS, while FOXC2KD cells have mostly discontinuous and thin cell-cell contacts (red arrowhead). (C) Quantification of adherens cell-cell junction types in control and FOXC2KD cells. VE-cadherin+ junctions were classified as linear (exemplified by control/static image in B), overlapping (exemplified by control/oscillatory image in B), or discontinuous (exemplified by FOXC2KD/oscillatory image in B). The proportion of each junction type was determined for the entire cell periphery. (D) OSS increases VE-cadherin+ junctional area in control but not in FOXC2KD LECs. (E) Increased junction complexity in FOXC2KD cells, as indicated by increased fractal dimension of the VE-cadherin organization. (F) Increased number of VE-cadherin gaps in FOXC2KD LECs. (G) FOXC2-dependent cell-cell junction remodeling is cell autonomous. The isolated FOXC2+ cell has continuous junctions (arrows), while the neighboring FOXC2KD cells have zigzag junctions (arrowheads). Staining for FOXC2 (green) and VE-cadherin (pink). Cell nuclei are outlined with dashed white lines. Scale bars: 10 μm (A and G); 5 μm (B). n = 3; more than 50 cells scored per condition; 2-tailed unpaired Student’s t test; #P < 0.05 (static vs. OSS), *P < 0.05 (control vs. FOXC2KD) (see also Supplemental Figure 3, A and B).