Wdr26 insufficiency causes Skraban-Deardorff syndrome–like neurodevelopmental deficits in mice
Xingyun Xu, Yaohui Zhou, Shiyao Xu, Hongjie Zhou, Xuexia Lin, Yuhao Luo, Yu Xu, Zhigang Miao, Wei Ge, Hao Yang, Xingshun Xu
Xingyun Xu, Yaohui Zhou, Shiyao Xu, Hongjie Zhou, Xuexia Lin, Yuhao Luo, Yu Xu, Zhigang Miao, Wei Ge, Hao Yang, Xingshun Xu
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Research Article Development Neuroscience

Wdr26 insufficiency causes Skraban-Deardorff syndrome–like neurodevelopmental deficits in mice

Abstract

Skraban-Deardorff syndrome, a rare neurodevelopmental disorder caused by WD repeat domain 26 (WDR26) haploinsufficiency, is characterized by intellectual disability, seizures, autistic-like behaviors, and craniofacial anomalies. Despite its genetic association with variants disrupting the C-terminal to LisH (CTLH) E3 ubiquitin ligase complex, the molecular mechanisms linking WDR26 dysfunction to neurodevelopmental deficits remain unclear. Here, we demonstrate that Wdr26 heterozygous-KO mice (Wdr26+/–) recapitulated core clinical features of the syndrome, including learning and memory impairments, social dysfunction, heightened seizure susceptibility, and motor deficits, alongside rare craniofacial and dental abnormalities. Mechanistically, Wdr26 haploinsufficiency stabilized RUNX1 translocation partner 1 (RUNX1T1), a transcriptional coactivator critical for neuronal differentiation, by impairing its ubiquitination and proteasomal degradation, consequently disrupting the level of microtubule-associated protein 2 (MAP2), a key regulator of dendritic architecture and synaptic plasticity. Early intervention in neonatal Wdr26+/– mice (P0.5) using AAV-shRNA–mediated Runx1t1 knockdown reversed MAP2 overexpression and behavioral deficits. Notably, the antipsychotic risperidone ameliorated cognitive and social impairments in Wdr26+/– mice by upregulating WDR26 levels, suggesting a potential therapeutic avenue. Our findings not only establish the animal model as a robust preclinical tool but also define the WDR26/RUNX1T1/MAP2 regulatory axis as pivotal to the syndrome’s pathogenesis, while identifying actionable therapeutic targets.

Authors

Xingyun Xu, Yaohui Zhou, Shiyao Xu, Hongjie Zhou, Xuexia Lin, Yuhao Luo, Yu Xu, Zhigang Miao, Wei Ge, Hao Yang, Xingshun Xu

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Figure 5

Wdr26+/– mice show developmental abnormalities, with a small proportion exhibiting dental malformations and cranial abnormalities.

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Wdr26+/– mice show developmental abnormalities, with a small proportion...
(A and B) Images of Wdr26+/+ and Wdr26+/– mice at 6–8 weeks of age. (A) Wdr26+/– mice exhibited tooth deformities (8 of 132). (B) Skeletal staining shows cranial misalignment in Wdr26+/– mice (8 of 132). (C) Wdr26+/+, Wdr26+/–, and Wdr26–/– embryos at E12.5, E14.5, and E16.5. Images are representative of 3 independent experiments (AC). (D) Images of brains from 2-month-old Wdr26+/+ and Wdr26+/– mice and a schematic outline of the corresponding right cerebral cortex and tectum. The arrow indicates the tectum. (E) Quantitative analysis of the tectum size in D (n = 10). Tectum size ratio (percentage) = (tectum area/total brain area) × 100%. (F) H&E staining of brain sections in Wdr26+/+ and Wdr26+/– mice. (G) Quantitative analysis of ventricular sizes in F (n = 6). The ventricular size ratio refers to the average percentage of the ventricular area relative to the total brain area, calculated as the average of area ratios in the 3 sections (F). Scale bars: 2 mm (A), 1 cm (B, left), 2 mm (B, right), 2 mm (C), 1 mm (D), and 2 mm (F).