Kinesin motors play a fundamental role in development by controlling intracellular transport, spindle assembly, and microtubule organization. In humans, patients carrying mutations in KIF11 suffer from an autosomal dominant inheritable disease called microcephaly with or without chorioretinopathy, lymphoedema, or mental retardation (MCLMR). While mitotic functions of KIF11 proteins have been well documented in centrosome separation and spindle assembly, cellular mechanisms underlying KIF11 dysfunction and MCLMR remain unclear. In this study, we generate KIF11-inhibition chick and zebrafish models and find that KIF11 inhibition results in microcephaly, chorioretinopathy, and severe developmental defects in vivo. Notably, loss-of-function of KIF11 causes the formation of monopolar spindle and chromosome misalignment, which finally contribute to cell cycle arrest, chromosome instability, and cell death. Our results demonstrate that KIF11 is crucial for spindle assembly, chromosome alignment, and cell cycle progression of progenitor stem cells, indicating a potential link between polyploidy and MCLMR. Our data have revealed that KIF11 inhibition cause microcephaly, chorioretinopathy, and development disorders through the formation of monopolar spindle, polyploid, and cell cycle arrest.

Microcephaly with or without chorioretinopathy, lymphedema, or mental retardation (MCLMR) is an inherited disorder characterized by severe microcephaly and abnormal facial features. Kinesin family member 11 (KIF11) mutations have been reported closely related to microcephaly in different cases, while the pathogenicity was still unclear. Here, we report a de novo heterozygous mutation in exon 20 of the KIF11 (c.2922G>T; p.Pro974=) from a microcephaly patient through whole-exome sequencing. Further studies identified that this variant affected the normal splicing of KIF11 pre-mRNA, thus leading to the c.2815_2922 deletion of exon 20 through PBMC-derived pre-mRNA splicing assay and minigene experiment. Moreover, c.2815_2922 deletion would produce a shortened KIF11 protein, which may competitively bind to the normal KIF11 protein, suggesting a dominant negative effect mechanism in c.2922G>T mutation-induced MCLMR.

Oculodentodigitaldysplasia (ODDD; MIM no. 164200) is a rare hereditary disorder caused by mutations in the gene GJA1.Ocular disorders included microcornea, cornea opacity and glaucoma. However, few studies described fundus findings.
Ophthalmic examination included visual acuity measurement, intraocular pressure (IOP) measurements, slit-lamp biomicroscopy, B-scan ultrasonography, Ultrasound biomicroscopy (UBM), spectral-domain optical coherence tomography (SD-OCT), ERG and retcam fluorescein angiogram. In addition, blood samples were taken from this patient for mutation analyze of GJA1.
The ophthalmic features of this patient were microcornea, cornea opacity, glaucoma as expected. Interestingly, the patient had a normal axial length with refractive status of emmetropia, but extremely retinal dysplasia and severe choroid thinning was noted. Flash electroretinogram (ERG) was extinguished in both eyes. This study identified a novel mutation c.91A>T in the GJA1 gene associated with fundus abnormalities. Bioinformatics and structural modeling suggested the mutation to be pathogenic.
Our research expanded not only the mutation spectrum, but also the clinical characteristics of ODDD. To the best of our knowledge, this is the first report on anatomical and functional chorioretinal changes in ODDD patients. These novel ocular features highlight the importance of fundus morphological and functional evaluation in ODDD.
ODDD: oculodentodigital dysplasia; OCT: optical coherence tomography; ERG: electroretinogram; TACT: teller acuity card test; UBM: ultrasound biomicroscopy; MW: molecular weights; AL: axial length; Cx43: connexin 43; RPE: retinal pigment epithelium; RGCs: retinal ganglion cells; FEVR: familial exudative vitreoretinopathy; ROP: retinopathy of prematurity.

Microphthalmia is characterized by abnormally small eyes and usually retinal dysplasia, accounting for up to 11% of the blindness in children. Right now there is no effective treatment for the disease, and the underlying mechanisms, especially how retinal dysplasia develops from microphthalmia and whether it depends on the signals from lens ectoderm are still unclear. Mutations in genes of the TGF-β superfamily have been noted in patients with microphthalmia. Using conditional knockout mice, here we address the question that whether ocular surface ectoderm-derived Smad4 modulates retinal development. We found that loss of Smad4 specifically on surface lens ectoderm leads to microphthalmia and dysplasia of retina. Retinal dysplasia in the knockout mice is caused by the delayed or failed differentiation and apoptosis of retinal cells. Microarray analyses revealed that members of Hedgehog and Wnt signaling pathways are affected in the knockout retinas, suggesting that ocular surface ectoderm-derived Smad4 can regulate Hedgehog and Wnt signaling in the retina. Our studies suggest that defective of ocular surface ectoderm may affect retinal development.

The retina is one of the most essential elements of vision pathway in vertebrate. The dysplasia of retina cause congenital blindness or vision disability in individuals, and the misbalance in adult retinal vascular homeostasis leads to neovascularization-associated diseases in adults, such as diabetic retinopathy or age-related macular degeneration. Many developmental signaling pathways are involved in the process of retinal development and vascular homeostasis. Among them, Notch signaling pathway has long been studied, and Notch signaling-interfered mouse models show both neural retina dysplasia and vascular abnormality. In this review, we discuss the roles of Notch signaling in the maintenance of retinal progenitor cells, specification of retinal neurons and glial cells, and the sustaining of retina vascular homeostasis, especially from the aspects of conditional knockout mouse models. The potential of Notch signal manipulation may provide a powerful cell fate- and neovascularization-controlling tool that could have important applications in treatment of retinal diseases.