Insights into KIF11 pathogenesis in microcephaly-lymphedema-chorioretinopathy syndrome from a lymphatic perspective
Kazim Ogmen, Sara E. Dobbins, Rose Yinghan Behncke, Ines Martinez-Corral, Ryan C.S. Brown, Michelle Meier, Sascha Ulferts, Nils Rouven Hansmeier, Ege Sackey, Ahlam Alqahtani, Christina Karapouliou, Dionysios Grigoriadis, Juan C. Del Rey Jimenez, Michael Oberlin, Denise Williams, Arzu Ekici, Kadri Karaer, Steve Jeffery, Peter Mortimer, Kristiana Gordon, Kazuhide S. Okuda, Benjamin M. Hogan, Taija Mäkinen, René Hägerling, Sahar Mansour, Silvia Martin-Almedina, Pia Ostergaard
Kazim Ogmen, Sara E. Dobbins, Rose Yinghan Behncke, Ines Martinez-Corral, Ryan C.S. Brown, Michelle Meier, Sascha Ulferts, Nils Rouven Hansmeier, Ege Sackey, Ahlam Alqahtani, Christina Karapouliou, Dionysios Grigoriadis, Juan C. Del Rey Jimenez, Michael Oberlin, Denise Williams, Arzu Ekici, Kadri Karaer, Steve Jeffery, Peter Mortimer, Kristiana Gordon, Kazuhide S. Okuda, Benjamin M. Hogan, Taija Mäkinen, René Hägerling, Sahar Mansour, Silvia Martin-Almedina, Pia Ostergaard
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Research Article Clinical Research Genetics Vascular biology

Insights into KIF11 pathogenesis in microcephaly-lymphedema-chorioretinopathy syndrome from a lymphatic perspective

Abstract

Pathogenic variants in kinesin KIF11 underlie microcephaly-lymphedema-chorioretinopathy (MLC) syndrome. Although well known for regulating spindle dynamics ensuring successful cell division, the association of KIF11 (encoding EG5) with development of the lymphatic system and how KIF11 pathogenic variants lead to lymphatic dysfunction and lymphedema remain unknown. Using patient-derived lymphoblastoid cells, we demonstrated that patients with MLC carrying pathogenic stop-gain variants in KIF11 have reduced mRNA and protein levels. Lymphoscintigraphy showed reduced tracer absorption, and intestinal lymphangiectasia was detected in one patient, pointing to impairment of lymphatic function caused by KIF11 haploinsufficiency. We revealed that KIF11 is expressed in early human and mouse development with the lymphatic markers VEGFR3, podoplanin, and PROX1. In zebrafish, single-cell RNA-Seq identified kif11 specifically expressed in endothelial precursors. In human lymphatic endothelial cells, EG5 inhibition with ispinesib reduced VEGFC-driven AKT phosphorylation, migration, and spheroid sprouting. KIF11 knockdown reduced PROX1 and VEGFR3 expression, providing for the first time to our knowledge a link between KIF11 and drivers of lymphangiogenesis and lymphatic identity.

Authors

Kazim Ogmen, Sara E. Dobbins, Rose Yinghan Behncke, Ines Martinez-Corral, Ryan C.S. Brown, Michelle Meier, Sascha Ulferts, Nils Rouven Hansmeier, Ege Sackey, Ahlam Alqahtani, Christina Karapouliou, Dionysios Grigoriadis, Juan C. Del Rey Jimenez, Michael Oberlin, Denise Williams, Arzu Ekici, Kadri Karaer, Steve Jeffery, Peter Mortimer, Kristiana Gordon, Kazuhide S. Okuda, Benjamin M. Hogan, Taija Mäkinen, René Hägerling, Sahar Mansour, Silvia Martin-Almedina, Pia Ostergaard

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Figure 4

Kif11 coexpression with Flt4-positive lymphatic vessels during mouse embryonic development.

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Kif11 coexpression with Flt4-positive lymphatic vessels during mouse em...
Mouse embryonic sections from developmental stages (A) E10.5, (B) E11.5, (C) E12.5 and (D) E13.5 were processed by H&E staining, immunofluorescence staining, or RNA hybridization. Selected magnified (framed) areas highlight embryonic regions containing dermal lymphatics and the thoracic duct. These regions were imaged using DAPI staining (blue; channel 2) as well as for Kif11 (red; channel 3) and Flt4 (white; channel 4) mRNA expression; merged images are also shown. Arrowheads indicate areas with coexpression of Kif11 and Flt4 mRNA. Additional labeling was added to facilitate the understanding of the embryonic anatomy: A, artery; DLV, dermal lymphatic vessel; LEC, lymphatic endothelial cell; NC, notochord; NT, neural tube; O, esophagus; PLV, peripheral lymphatic vessel; PTD, primordial thoracic duct; T, trachea; V, vein. Scale bars: 100 μm. (E) Quantification of Kif11 and Flt4 mRNA signals from dermal (purple) and thoracic duct (light green) of different stages of mouse embryo development. RNAscope signals were measured from 6–8 different areas of 25 μm2. (F) Bar chart represents Kif11 (red) and Flt4 (VEGFR3) (white) mRNA signal ratio in dermal versus thoracic duct (Td) during different stages of mouse embryo development.