Therapeutic lymphangiogenesis ameliorates established acute lung allograft rejection
Ye Cui, Kaifeng Liu, Maria E. Monzon-Medina, Robert F. Padera, Hao Wang, Gautam George, Demet Toprak, Elie Abdelnour, Emmanuel D’Agostino, Hilary J. Goldberg, Mark A. Perrella, Rosanna Malbran Forteza, Ivan O. Rosas, Gary Visner, Souheil El-Chemaly
Ye Cui, Kaifeng Liu, Maria E. Monzon-Medina, Robert F. Padera, Hao Wang, Gautam George, Demet Toprak, Elie Abdelnour, Emmanuel D’Agostino, Hilary J. Goldberg, Mark A. Perrella, Rosanna Malbran Forteza, Ivan O. Rosas, Gary Visner, Souheil El-Chemaly
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Research Article Angiogenesis Cardiology Inflammation Oncology Vascular biology

Therapeutic lymphangiogenesis ameliorates established acute lung allograft rejection

Abstract

Lung transplantation is the only viable option for patients suffering from otherwise incurable end-stage pulmonary diseases such as chronic obstructive pulmonary disease and idiopathic pulmonary fibrosis. Despite aggressive immunosuppression, acute rejection of the lung allograft occurs in over half of transplant recipients, and the factors that promote lung acceptance are poorly understood. The contribution of lymphatic vessels to transplant pathophysiology remains controversial, and data that directly address the exact roles of lymphatic vessels in lung allograft function and survival are limited. Here, we have shown that there is a marked decline in the density of lymphatic vessels, accompanied by accumulation of low-MW hyaluronan (HA) in mouse orthotopic allografts undergoing rejection. We found that stimulation of lymphangiogenesis with VEGF-C156S, a mutant form of VEGF-C with selective VEGFR-3 binding, alleviates an established rejection response and improves clearance of HA from the lung allograft. Longitudinal analysis of transbronchial biopsies from human lung transplant recipients demonstrated an association between resolution of acute lung rejection and decreased HA in the graft tissue. Taken together, these results indicate that lymphatic vessel formation after lung transplantation mediates HA drainage and suggest that treatments to stimulate lymphangiogenesis have promise for improving graft outcomes.

Authors

Ye Cui, Kaifeng Liu, Maria E. Monzon-Medina, Robert F. Padera, Hao Wang, Gautam George, Demet Toprak, Elie Abdelnour, Emmanuel D’Agostino, Hilary J. Goldberg, Mark A. Perrella, Rosanna Malbran Forteza, Ivan O. Rosas, Gary Visner, Souheil El-Chemaly

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Figure 3

VEGF-C156S treatment inhibits the downward shift of HA molecular mass in lung allograft rejection.

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VEGF-C156S treatment inhibits the downward shift of HA molecular mass in...
Left panel: agarose gel electrophoresis was conducted to analyze HA size in mouse left lungs. From left to right: mega (6100, 4570, 3050, and 1520 kDa), high (1510, 1090, 966, 572, and 495 kDa), and low (495, 310, 214, 110, and 27 kDa) HA ladders were used to determine the molecular mass of HA in tissue samples. HA samples per lane were pooled from the upper portions of mouse left lungs in each group. Right panel: quantitative analysis of HA profiles in mouse left lungs. Animals receiving allogeneic left lung grafts were treated with PBS (n = 5 mice) or VEGF-C156S (VEGF-C) (n = 6 mice) or were concomitantly treated with VEGF-C156S and LYVE-1 function–blocking antibody (VEGF-C + LYVE-1 Ab) (n = 6 mice) from day 20 to day 30 after transplantation. Age-matched untransplanted animals were used as controls (n = 6 mice).