Go to The Journal of Clinical Investigation
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
  • Physician-Scientist Development
  • Current issue
  • Past issues
  • By specialty
    • COVID-19
    • Cardiology
    • Immunology
    • Metabolism
    • Nephrology
    • Oncology
    • Pulmonology
    • All ...
  • Videos
  • Collections
    • In-Press Preview
    • Resource and Technical Advances
    • Clinical Research and Public Health
    • Research Letters
    • Editorials
    • Perspectives
    • Physician-Scientist Development
    • Reviews
    • Top read articles

  • Current issue
  • Past issues
  • Specialties
  • In-Press Preview
  • Resource and Technical Advances
  • Clinical Research and Public Health
  • Research Letters
  • Editorials
  • Perspectives
  • Physician-Scientist Development
  • Reviews
  • Top read articles
  • About
  • Editors
  • Consulting Editors
  • For authors
  • Publication ethics
  • Publication alerts by email
  • Transfers
  • Advertising
  • Job board
  • Contact
Pathological MAPK activation–mediated lymphatic basement membrane disruption causes lymphangiectasia that is treatable with ravoxertinib
Harish P. Janardhan, Karen Dresser, Lloyd Hutchinson, Chinmay M. Trivedi
Harish P. Janardhan, Karen Dresser, Lloyd Hutchinson, Chinmay M. Trivedi
View: Text | PDF
Research Article Development Vascular biology

Pathological MAPK activation–mediated lymphatic basement membrane disruption causes lymphangiectasia that is treatable with ravoxertinib

  • Text
  • PDF
Abstract

Lymphangiectasia, an anomalous dilation of lymphatic vessels first described in the 17th century, is frequently associated with chylous effusion, respiratory failure, and high mortality in young patients, yet the underlying molecular pathogenesis and effective treatments remain elusive. Here, we identify an unexpected causal link between MAPK activation and defective development of the lymphatic basement membrane that drives lymphangiectasia. Human pathological tissue samples from patients diagnosed with lymphangiectasia revealed sustained MAPK activation within lymphatic endothelial cells. Endothelial KRASG12D–mediated sustained MAPK activation in newborn mice caused severe pulmonary and intercostal lymphangiectasia, accumulation of chyle in the pleural space, and complete lethality. Pathological activation of MAPK in murine vasculature inhibited the Nfatc1-dependent genetic program required for laminin interactions, collagen crosslinking, and anchoring fibril formation, driving defective development of the lymphatic basement membrane. Treatment with ravoxertinib, a pharmacological inhibitor of MAPK, reverses nuclear-to-cytoplasmic localization of Nfatc1, basement membrane development defects, lymphangiectasia, and chyle accumulation, ultimately improving survival of endothelial KRAS mutant neonatal mice. These results reveal defective lymphatic basement membrane assembly and composition as major causes of thoracic lymphangiectasia and provide a potential treatment.

Authors

Harish P. Janardhan, Karen Dresser, Lloyd Hutchinson, Chinmay M. Trivedi

×

Figure 2

Lymphatic endothelial KRASG12D mutation drives lymphangiectasia.

Options: View larger image (or click on image) Download as PowerPoint
Lymphatic endothelial KRASG12D mutation drives lymphangiectasia.
(A–C) H...
(A–C) H&E-stained (upper row), Pdpn (green) and Lyve1 (red) immunofluorescently stained (middle row), and Vegfr3 (green) and Prox1 (red) immunofluorescently stained (lower row) sections of intercostal spaces (A), lungs (B), and skin (C) from control and KrasG12D fl/+; Cdh5CreERT2; R26RmTmG+/– mice treated with tamoxifen at P12. White arrows show normal lymphatic vessels. Red arrows show pathological dilation of lymphatic vessels. Black arrows show dilated intercostal vessels. Hoechst nuclear counterstain (blue). Scale bar: 100 μm (top row, middle row [left 2 panels], and middle row [right 2 panels]), 10 μm (middle row [middle 2 panels] and bottom row). (D) Lyve1, GFP, and Ki67 immunofluorescently stained sections of intercostal spaces (upper panels) and lungs (lower panels) from control and KrasG12D fl/+; Cdh5CreERT2; R26RmTmG+/– mice treated with tamoxifen at P12. White arrows show proliferating lymphatic endothelial cells. Hoechst nuclear counterstain (blue). Scale bar: 10 μm. (E and F) Quantitation of proliferating intercostal (E) and pulmonary (F) lymphatic endothelial cells (Lyve1+, GFP+, and Ki67+) in control and KrasG12D fl/+; Cdh5CreERT2; R26RmTmG+/– mice treated with tamoxifen (n = 3) at P12. Unpaired nonparametric Mann-Whitney U test; P > 0.3. Data represent the mean ± SEM. (G) SMA, Lyve1, and GFP immunofluorescently stained sections of intercostal spaces (upper panels) and lungs (lower panels) from control and KrasG12D fl/+; Prox1CreERT2; R26RmTmG+/– mice treated with tamoxifen at P12. White arrows show normal lymphatic vessels. Red arrows show aberrant dilation of lymphatic vessels. Lymphatic vessels lack smooth muscle coverage (green staining). Hoechst nuclear counterstain (blue). Scale bar: 10 μm. All experimental data were verified in at least 3 independent experiments. L, Lymphatic vessel; B, Bronchus; R, Rib.

Copyright © 2026 American Society for Clinical Investigation
ISSN 2379-3708

Sign up for email alerts