Pathogenesis of persistent lymphatic vessel hyperplasia in chronic airway inflammation
Peter Baluk, … , Kari Alitalo, Donald M. McDonald
Peter Baluk, … , Kari Alitalo, Donald M. McDonald
Published February 1, 2005
Citation Information: J Clin Invest. 2005;115(2):247-257. https://doi.org/10.1172/JCI22037.
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Article Angiogenesis

Pathogenesis of persistent lymphatic vessel hyperplasia in chronic airway inflammation

Abstract

Edema occurs in asthma and other inflammatory diseases when the rate of plasma leakage from blood vessels exceeds the drainage through lymphatic vessels and other routes. It is unclear to what extent lymphatic vessels grow to compensate for increased leakage during inflammation and what drives the lymphangiogenesis that does occur. We addressed these issues in mouse models of (a) chronic respiratory tract infection with Mycoplasma pulmonis and (b) adenoviral transduction of airway epithelium with VEGF family growth factors. Blood vessel remodeling and lymphangiogenesis were both robust in infected airways. Inhibition of VEGFR-3 signaling completely prevented the growth of lymphatic vessels but not blood vessels. Lack of lymphatic growth exaggerated mucosal edema and reduced the hypertrophy of draining lymph nodes. Airway dendritic cells, macrophages, neutrophils, and epithelial cells expressed the VEGFR-3 ligands VEGF-C or VEGF-D. Adenoviral delivery of either VEGF-C or VEGF-D evoked lymphangiogenesis without angiogenesis, whereas adenoviral VEGF had the opposite effect. After antibiotic treatment of the infection, inflammation and remodeling of blood vessels quickly subsided, but lymphatic vessels persisted. Together, these findings suggest that when lymphangiogenesis is impaired, airway inflammation may lead to bronchial lymphedema and exaggerated airflow obstruction. Correction of defective lymphangiogenesis may benefit the treatment of asthma and other inflammatory airway diseases.

Authors

Peter Baluk, Tuomas Tammela, Erin Ator, Natalya Lyubynska, Marc G. Achen, Daniel J. Hicklin, Michael Jeltsch, Tatiana V. Petrova, Bronislaw Pytowski, Steven A. Stacker, Seppo Ylä-Herttuala, David G. Jackson, Kari Alitalo, Donald M. McDonald

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Figure 2

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VEGF receptor distribution and inhibition in tracheal vessels. (A) Stron...
VEGF receptor distribution and inhibition in tracheal vessels. (A) Strong VEGFR-2 immunoreactivity on blood vessels (arrowheads) and weaker staining of lymphatic vessels (arrows) in pathogen-free mouse. (B) Immunoreactivities for VEGFR-3 and LYVE-1 colocalize on lymphatic vessels (arrows) in pathogen-free mouse. (C and D) Lymphatic vessels in mice infected with M. pulmonis for 7 days, either untreated (C) or pretreated with soluble VEGFR-3–Ig (D). Sprouts (arrows) emerge from enlarged lymphatic vessels after infection (C) but not if pretreated with soluble VEGFR-3–Ig (D). (E) Number of lymphatic sprouts in tracheas from pathogen-free mice, or from mice after 7 days of infection, with or without soluble VEGFR-3–Ig pretreatment. (F and G) After 14 days of infection, lymphangiogenesis is not affected by concurrent treatment with antibody against VEGFR-1 (F) but is blocked by antibody against VEGFR-3 (G). (H) Area density of lymphatic vessels (red) and blood vessels (green) showing inhibition of infection-induced lymphangiogenesis by anti–VEGFR-3 (R3) antibody but not by anti–VEGFR-1 (R1) or anti–VEGFR-2 (R2). Anti–VEGFR-2 did not augment the effect of anti–VEGFR-3 (R2 + R3). None of the antibodies reduced angiogenesis. *P < 0.05 vs. pathogen-free group; P < 0.05 vs. infected control group. Scale bar in G applies to all figures: 100 μm in A and B and 50 μm in C, D, F, and G.