Investigation of a Novel Mouse Model of Prader-Willi Syndrome with Invalidation of Necdin and Magel2

Pierre-Yves Barelle, Alicia Sicardi, Fabienne Schaller, Julie Buron, Denis Becquet, Felix Omnes, Francoise Watrin, Catarina Santos, Clement Menuet, Anne-Marie Francois-Bellan, Emilie Caron, Jessica Klucznik, Vincent Prevot, Sebastien G Bouret, Francoise Muscatelli
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Abstract

Prader-Willi syndrome (PWS) is a multigenic disorder caused by the loss of seven contiguous paternally expressed genes. Mouse models with inactivation of all PWS genes are lethal. Knockout (KO) mouse models for each candidate gene were generated, but they lack the functional interactions between PWS genes. Here, we revealed an interplay between Necdin and Magel2 PWS genes and generated a novel mouse model (named Madin) with a deletion including both genes. A subset of Madin KO mice showed neonatal lethality. Behaviorally, surviving mutant mice exhibited sensory delays during infancy and alterations in social exploration at adulthood. Madin KO mice had a lower body weight before weaning, persisting after weaning in males only, with reduced fat mass and improved glucose tolerance. Delayed sexual maturation and altered timing of puberty onset were observed in mutant mice. Adult Madin KO mice displayed increased ventilation and a persistent increase in apneas following a hypercapnic challenge. Transcriptomics analyses revealed a dysregulation of key circadian genes and alterations of genes associated with axonal function that were also found in the hypothalamus of patients with PWS. At neuroanatomical levels, we report an impaired maturation of oxytocin neurons and a disrupted development of melanocortin circuits. Together, these data indicate that the Madin KO mouse is a reliable and more genetically relevant model for the study of PWS.
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研究一种新型的普拉德-威利综合征小鼠模型,并对 Necdin 和 Magel2 进行验证
普拉德-威利综合征(Prader-Willi Syndrome,PWS)是一种由父系表达的七个连续基因缺失引起的多基因疾病。所有PWS基因失活的小鼠模型都是致死的。针对每个候选基因的基因敲除(KO)小鼠模型已经产生,但它们缺乏 PWS 基因之间的功能性相互作用。在这里,我们揭示了Necdin和Magel2 PWS基因之间的相互作用,并生成了一个同时缺失这两个基因的新型小鼠模型(命名为Madin)。一部分Madin KO小鼠表现出新生儿致死性。在行为上,存活的突变小鼠在婴儿期表现出感官发育迟缓,成年后社会探索能力发生改变。Madin KO小鼠断奶前体重较轻,断奶后仅雄性小鼠体重持续较轻,脂肪量减少,葡萄糖耐量改善。在突变小鼠中观察到性成熟延迟和青春期开始时间的改变。成年的Madin KO小鼠通气量增加,高碳酸血症挑战后呼吸暂停持续增加。转录组学分析揭示了关键昼夜节律基因的失调以及与轴突功能相关的基因的改变,这些在PWS患者的下丘脑中也有发现。在神经解剖学层面,我们发现催产素神经元的成熟受到影响,黑皮质素回路的发育也受到破坏。这些数据共同表明,Madin KO小鼠是研究PWS的一个可靠且更具遗传相关性的模型。
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