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
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Research Article Development Vascular biology

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

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

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Figure 4

Pathological MAPK activation represses Nfatc1-dependent transcription of lymphatic basement membrane genes.

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Pathological MAPK activation represses Nfatc1-dependent transcription of...
(A) Top consensus lymphatic endothelial motif enriched in phosphorylated-MAPK CUT&Tag DNA fragments isolated from KRASG12D mutant lungs compared with controls. n = 3, P < 1 × 10–9 (known motif), P < 1 × 10–310 (de novo motif). (B and C) CUT&Tag analyses of Nfatc1 showing enrichment at transcriptional start sites (B) and basement membrane genes Col4a1, Nid1, and Lama4 regulatory loci (C) in P12 WT mice. Blue peaks (tracks) represent Nfatc1-occupied DNA sequences. Red boxes represent consensus Nfatc1 binding sites identified by ChIP-Seq (HOMER). (D) Immunofluorescent staining for Col4a (green)/Nid1 (green) or Lama4 (red) expression in intercostal lymphatic vessels marked by Pdpn (green) or Lyve1 (red) in P10 WT mice (n = 3) treated with vehicle (top row) or Nfatc1 inhibitor (bottom row). Scale bar: 10 μm. (E) Immunofluorescent staining of human lymphangiectasia tissue samples (n = 7) show decreased nuclear localization of NFATC1 (red arrows) and reduced LAMA4 expression (yellow arrows) compared with nonpathological areas (white arrows). Scale bar: 10 μm.