Rapamycin reversal of VEGF-C–driven lymphatic anomalies in the respiratory tract
Peter Baluk, Li-Chin Yao, Julio C. Flores, Dongwon Choi, Young-Kwon Hong, Donald M. McDonald
Peter Baluk, Li-Chin Yao, Julio C. Flores, Dongwon Choi, Young-Kwon Hong, Donald M. McDonald
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Research Article Vascular biology

Rapamycin reversal of VEGF-C–driven lymphatic anomalies in the respiratory tract

Abstract

Lymphatic malformations are serious but poorly understood conditions that present therapeutic challenges. The goal of this study was to compare strategies for inducing regression of abnormal lymphatics and explore underlying mechanisms. CCSP-rtTA/tetO-VEGF-C mice, in which doxycycline regulates VEGF-C expression in the airway epithelium, were used as a model of pulmonary lymphangiectasia. After doxycycline was stopped, VEGF-C expression returned to normal, but lymphangiectasia persisted for at least 9 months. Inhibition of VEGFR-2/VEGFR-3 signaling, Notch, β-adrenergic receptors, or autophagy and antiinflammatory steroids had no noticeable effect on the amount or severity of lymphangiectasia. However, rapamycin inhibition of mTOR reduced lymphangiectasia by 76% within 7 days without affecting normal lymphatics. Efficacy of rapamycin was not increased by coadministration with the other agents. In prevention trials, rapamycin suppressed VEGF-C–driven mTOR phosphorylation and lymphatic endothelial cell sprouting and proliferation. However, in reversal trials, no lymphatic endothelial cell proliferation was present to block in established lymphangiectasia, and rapamycin did not increase caspase-dependent apoptosis. However, rapamycin potently suppressed Prox1 and VEGFR-3. These experiments revealed that lymphangiectasia is remarkably resistant to regression but is responsive to rapamycin, which rapidly reduces and normalizes the abnormal lymphatics without affecting normal lymphatics.

Authors

Peter Baluk, Li-Chin Yao, Julio C. Flores, Dongwon Choi, Young-Kwon Hong, Donald M. McDonald

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Figure 6

Effect of rapamycin on lymphatic sprouting and proliferation in tracheas of CCSP/VEGF-C mice.

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Effect of rapamycin on lymphatic sprouting and proliferation in tracheas...
(A) Lymphatic sprouts after doxycycline (left) but not after doxycycline plus rapamycin (right) (2d, P21–P23). (B) Measurements of lymphatic sprouts. Baseline, single-transgenic mice (P21). *P < 0.05 vs. vehicle, ANOVA. (C) Lymphangiogenesis after doxycycline (left) but not after doxycycline plus rapamycin (right) (7d, P21–P28). (D) Measurements of lymphatic density. *P < 0.05 vs. vehicle, ANOVA. (E) No BrdU uptake by lymphatics in control mouse, compared with (F) BrdU-labeled lymphatics (arrowheads) after doxycycline (3d). Dividing lymphatic endothelial cell (arrow). (G) BrdU labeling of lymphatics after doxycycline for 1–7 days (P21–P28). *P < 0.05 vs. baseline, ANOVA. (H) Rapamycin suppression of BrdU labeling after doxycycline for 3 or 7 days (P24 or P28), expressed as a percentage of Prox1-positive cells. (I) Reduction in Prox1-positive cells after doxycycline plus rapamycin for 3 days (87% reduction, P24) or 7 days (52% reduction, P28). (J) No activated caspase-3 staining in control lymphatics, compared with (K) staining of fragmented Prox1-positive cells (arrows) after doxycycline plus rapamycin (3d, P21 to P24). n = 5 mice/group. Scale bar: 100 μm (A); 200 μm (C); 20 μm (E, F, J, and K). Box and whisker plots show the median, first and third quartiles, and maximum and minimum.