Tan Senwei, Zhang Qiumeng, Zhan Rui, Luo Si, Han Yaoling, Yu Bin, Muss Candace, Pingault Veronique, Marlin Sandrine, Delahaye Andrée, Peters Sophia, Perne Claudia, Kreiß Martina, Spataro Nino, Trujillo-Quintero Juan Pablo, Racine Caroline, Tran-Mau-Them Frederic, Phornphutkul Chanika, Besterman Aaron D, Martinez Julian, Wang Xiuxia, Tian Xiaoyu, Srivastava Siddharth, Urion David K, Madden Jill A, Saif Hind Al, Morrow Michelle M, Begtrup Amber, Li Xing, Jurgensmeyer Sarah, Leahy Peter, Zhou Shimin, Li Faxiang, Hu Zhengmao, Tan Jieqiong, Xia Kun, Guo Hui
Center for Medical Genetics & MOE Key Lab of Rare Pediatric Diseases, School of Life Sciences, Central South University, Changsha, Hunan, China.
Department of Genetics, Nemours Children's Hospital, Wilmington, DE, USA.
Mol Psychiatry. 2025 May;30(5):1952-1965. doi: 10.1038/s41380-024-02806-z. Epub 2024 Oct 29.
De novo variants adjacent to the canonical splicing sites or in the well-defined splicing-related regions are more likely to impair splicing but remain under-investigated in autism spectrum disorder (ASD). By analyzing large, recent ASD genome sequencing cohorts, we find a significant burden of de novo potential splicing-disrupting variants (PSDVs) in 5048 probands compared to 4090 unaffected siblings. We identified 55 genes with recurrent de novo PSDVs that were highly intolerant to variation. Forty-six of these genes have not been strongly implicated in ASD or other neurodevelopmental disorders previously, including GSK3B. Through international, multicenter collaborations, we assembled genotype and phenotype data for 15 individuals with GSK3B variants and identified common phenotypes including developmental delay, ASD, sleeping disturbance, and aggressive behavior. Using available single-cell transcriptomic data, we show that GSK3B is enriched in dorsal progenitors and intermediate forms of excitatory neurons in the developing brain. We showed that Gsk3b knockdown in mouse excitatory neurons interferes with dendrite arborization and spine maturation which could not be rescued by de novo missense variants identified from affected individuals. In summary, our findings suggest that PSDVs may play an important role in the genetic etiology of ASD and allow for the prioritization of new ASD candidate genes. Importantly, we show that genetic variation resulting in GSK3B loss-of-function can lead to a neurodevelopmental disorder with core features of ASD and developmental delay.
位于经典剪接位点附近或明确的剪接相关区域的新生变异更有可能破坏剪接,但在自闭症谱系障碍(ASD)中仍未得到充分研究。通过分析近期大型的ASD基因组测序队列,我们发现5048名先证者中新生潜在剪接破坏变异(PSDV)的负担显著高于4090名未受影响的同胞。我们鉴定出55个具有复发性新生PSDV且对变异高度不耐受的基因。其中46个基因此前未被强烈认为与ASD或其他神经发育障碍有关,包括GSK3B。通过国际多中心合作,我们收集了15名携带GSK3B变异个体的基因型和表型数据,并确定了常见表型,包括发育迟缓、ASD、睡眠障碍和攻击性行为。利用现有的单细胞转录组数据,我们表明GSK3B在发育中的大脑背侧祖细胞和兴奋性神经元的中间形式中富集。我们发现,在小鼠兴奋性神经元中敲低Gsk3b会干扰树突分支和棘突成熟,而从受影响个体中鉴定出的新生错义变异无法挽救这种情况。总之,我们的研究结果表明,PSDV可能在ASD的遗传病因中起重要作用,并有助于确定新的ASD候选基因的优先级。重要的是,我们表明导致GSK3B功能丧失的遗传变异可导致一种具有ASD和发育迟缓核心特征的神经发育障碍。
