KRAS-driven model of Gorham-Stout disease effectively treated with trametinib
Nassim Homayun-Sepehr, Anna L. McCarter, Raphaël Helaers, Christine Galant, Laurence M. Boon, Pascal Brouillard, Miikka Vikkula, Michael T. Dellinger
Nassim Homayun-Sepehr, Anna L. McCarter, Raphaël Helaers, Christine Galant, Laurence M. Boon, Pascal Brouillard, Miikka Vikkula, Michael T. Dellinger
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Research Article Angiogenesis Vascular biology

KRAS-driven model of Gorham-Stout disease effectively treated with trametinib

Abstract

Gorham-Stout disease (GSD) is a sporadically occurring lymphatic disorder. Patients with GSD develop ectopic lymphatics in bone, gradually lose bone, and can have life-threatening complications, such as chylothorax. The etiology of GSD is poorly understood, and current treatments for this disease are inadequate for most patients. To explore the pathogenesis of GSD, we performed targeted high-throughput sequencing with samples from a patient with GSD and identified an activating somatic mutation in KRAS (p.G12V). To characterize the effect of hyperactive KRAS signaling on lymphatic development, we expressed an active form of KRAS (p.G12D) in murine lymphatics (iLECKras mice). We found that iLECKras mice developed lymphatics in bone, which is a hallmark of GSD. We also found that lymphatic valve development and maintenance was altered in iLECKras mice. Because most iLECKras mice developed chylothorax and died before they had significant bone disease, we analyzed the effect of trametinib (an FDA-approved MEK1/2 inhibitor) on lymphatic valve regression in iLECKras mice. Notably, we found that trametinib suppressed this phenotype in iLECKras mice. Together, our results demonstrate that somatic activating mutations in KRAS can be associated with GSD and reveal that hyperactive KRAS signaling stimulates the formation of lymphatics in bone and impairs the development of lymphatic valves. These findings provide insight into the pathogenesis of GSD and suggest that trametinib could be an effective treatment for GSD.

Authors

Nassim Homayun-Sepehr, Anna L. McCarter, Raphaël Helaers, Christine Galant, Laurence M. Boon, Pascal Brouillard, Miikka Vikkula, Michael T. Dellinger

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Figure 4

iLECKras mice have fewer lymphatic valves compared with iLECCtrl mice.

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iLECKras mice have fewer lymphatic valves compared with iLECCtrl mice. ...
(A) Schematic showing when mice were fed tamoxifen (2 μl of 25 mg/ml solution). Tissues were collected on P20. (B–E) Representative images of GFP-stained ear skin whole mounts from iLECCtrl;mT/mG mice (B and C) and iLECKras;mT/mG mice (D and E). (C) A higher-magnification view of the boxed region in B, showing a lymphatic valve with a normal V-shaped morphology in an iLECCtrl;mT/mG mouse. (E) A higher-magnification view of the boxed region in D, showing a lymphatic in an iLECKras;mT/mG mouse. This lymphatic does not have a valve with a normal V-shaped morphology. (F) iLECCtrl;mT/mG mice had significantly more lymphatic branch points per 4× field (52 ± 3.845; n = 8) than iLECKras;mT/mG mice (29.71 ± 2.775; n = 7). (G) iLECCtrl;mT/mG mice had significantly skinnier lymphatics (49.91 ± 1.232 μm; n = 7) than iLECKras;mT/mG mice (82.59 ± 6.178 μm; n = 6). (H) iLECCtrl;mT/mG mice had significantly more lymphatic valves per 4× field (27.25 ± 2.25; n = 8) than iLECKras;mT/mG mice (0.8571 ± 0.3401; n = 7). Data are presented as mean ± SEM. ***P < 0.001, ****P < 0.0001; unpaired Student’s t tests. Scale bar: 200 μm (B and D); 100 μm (C and E).