Andrew C Liu, Yang Shen, Carolyn R Serbinski, Hongzhi He, Destino Roman, Mehari Endale, Lindsey Aschbacher-Smith, Katherine A King, Jorge L Granadillo, Isabel López, Darcy A Krueger, Thomas J Dye, David F Smith, John B Hogenesch, Carlos E Prada
{"title":"史密斯-金斯莫尔综合征 MTOR 变体的临床和功能研究揭示了昼夜节律和睡眠-觉醒行为的缺陷。","authors":"Andrew C Liu, Yang Shen, Carolyn R Serbinski, Hongzhi He, Destino Roman, Mehari Endale, Lindsey Aschbacher-Smith, Katherine A King, Jorge L Granadillo, Isabel López, Darcy A Krueger, Thomas J Dye, David F Smith, John B Hogenesch, Carlos E Prada","doi":"10.1016/j.xhgg.2024.100333","DOIUrl":null,"url":null,"abstract":"<p><p>Heterozygous de novo or inherited gain-of-function mutations in the MTOR gene cause Smith-Kingsmore syndrome (SKS). SKS is a rare autosomal dominant condition, and individuals with SKS display macrocephaly/megalencephaly, developmental delay, intellectual disability, and seizures. A few dozen individuals are reported in the literature. Here, we report a cohort of 28 individuals with SKS that represent nine MTOR pathogenic variants. We conducted a detailed natural history study and found pathophysiological deficits among individuals with SKS in addition to the common neurodevelopmental symptoms. These symptoms include sleep-wake disturbance, hyperphagia, and hyperactivity, indicative of homeostatic imbalance. To characterize these variants, we developed cell models and characterized their functional consequences. We showed that these SKS variants display a range of mechanistic target of rapamycin (mTOR) activities and respond to the mTOR inhibitor, rapamycin, differently. For example, the R1480_C1483del variant we identified here and the previously known C1483F are more active than wild-type controls and less responsive to rapamycin. Further, we showed that SKS mutations dampened circadian rhythms and low-dose rapamycin improved the rhythm amplitude, suggesting that optimal mTOR activity is required for normal circadian function. As SKS is caused by gain-of-function mutations in MTOR, rapamycin was used to treat several patients. While higher doses of rapamycin caused delayed sleep-wake phase disorder in a subset of patients, optimized lower doses improved sleep. Our study expands the clinical and molecular spectrum of SKS and supports further studies for mechanism-guided treatment options to improve sleep-wake behavior and overall health.</p>","PeriodicalId":34530,"journal":{"name":"HGG Advances","volume":null,"pages":null},"PeriodicalIF":3.3000,"publicationDate":"2024-10-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11342114/pdf/","citationCount":"0","resultStr":"{\"title\":\"Clinical and functional studies of MTOR variants in Smith-Kingsmore syndrome reveal deficits of circadian rhythm and sleep-wake behavior.\",\"authors\":\"Andrew C Liu, Yang Shen, Carolyn R Serbinski, Hongzhi He, Destino Roman, Mehari Endale, Lindsey Aschbacher-Smith, Katherine A King, Jorge L Granadillo, Isabel López, Darcy A Krueger, Thomas J Dye, David F Smith, John B Hogenesch, Carlos E Prada\",\"doi\":\"10.1016/j.xhgg.2024.100333\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Heterozygous de novo or inherited gain-of-function mutations in the MTOR gene cause Smith-Kingsmore syndrome (SKS). 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For example, the R1480_C1483del variant we identified here and the previously known C1483F are more active than wild-type controls and less responsive to rapamycin. Further, we showed that SKS mutations dampened circadian rhythms and low-dose rapamycin improved the rhythm amplitude, suggesting that optimal mTOR activity is required for normal circadian function. As SKS is caused by gain-of-function mutations in MTOR, rapamycin was used to treat several patients. While higher doses of rapamycin caused delayed sleep-wake phase disorder in a subset of patients, optimized lower doses improved sleep. 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引用次数: 0
摘要
MTOR 基因中的异卵新生突变或遗传性功能增益突变会导致史密斯-金斯莫尔综合征(SKS)。SKS 是一种罕见的常染色体显性遗传病,SKS 患者会出现巨脑畸形/巨脑症、发育迟缓、智力障碍和癫痫发作。文献中仅报道了几十例患者。在此,我们报告了一个由 28 名 SKS 患者组成的队列,这些患者代表了 9 种 MTOR 致病变异。我们进行了详细的自然史研究,发现除了常见的神经发育症状外,SKS 患者还存在病理生理缺陷。这些症状包括睡眠-觉醒障碍、多食和多动,表明体内平衡失调。为了描述这些变体的特征,我们开发了细胞模型,并描述了它们的功能后果。我们发现,这些 SKS 变体显示出一系列 mTOR 活性,并对 mTOR 抑制剂雷帕霉素做出不同的反应。例如,我们在此发现的 R1480_C1483del 变异和之前已知的 C1483F 变异比野生型对照更活跃,对雷帕霉素的反应更弱。此外,我们发现 SKS 突变抑制了昼夜节律,而低剂量雷帕霉素改善了节律幅度,这表明正常的昼夜节律功能需要最佳的 mTOR 活性。由于 SKS 是由 MTOR 功能增益突变引起的,因此雷帕霉素被用于治疗几名患者。虽然高剂量雷帕霉素会导致部分患者出现睡眠觉醒期延迟紊乱,但优化后的低剂量雷帕霉素却能改善睡眠。我们的研究扩展了SKS的临床和分子谱,支持进一步研究以机制为导向的治疗方案,以改善睡眠-觉醒行为和整体健康。
Clinical and functional studies of MTOR variants in Smith-Kingsmore syndrome reveal deficits of circadian rhythm and sleep-wake behavior.
Heterozygous de novo or inherited gain-of-function mutations in the MTOR gene cause Smith-Kingsmore syndrome (SKS). SKS is a rare autosomal dominant condition, and individuals with SKS display macrocephaly/megalencephaly, developmental delay, intellectual disability, and seizures. A few dozen individuals are reported in the literature. Here, we report a cohort of 28 individuals with SKS that represent nine MTOR pathogenic variants. We conducted a detailed natural history study and found pathophysiological deficits among individuals with SKS in addition to the common neurodevelopmental symptoms. These symptoms include sleep-wake disturbance, hyperphagia, and hyperactivity, indicative of homeostatic imbalance. To characterize these variants, we developed cell models and characterized their functional consequences. We showed that these SKS variants display a range of mechanistic target of rapamycin (mTOR) activities and respond to the mTOR inhibitor, rapamycin, differently. For example, the R1480_C1483del variant we identified here and the previously known C1483F are more active than wild-type controls and less responsive to rapamycin. Further, we showed that SKS mutations dampened circadian rhythms and low-dose rapamycin improved the rhythm amplitude, suggesting that optimal mTOR activity is required for normal circadian function. As SKS is caused by gain-of-function mutations in MTOR, rapamycin was used to treat several patients. While higher doses of rapamycin caused delayed sleep-wake phase disorder in a subset of patients, optimized lower doses improved sleep. Our study expands the clinical and molecular spectrum of SKS and supports further studies for mechanism-guided treatment options to improve sleep-wake behavior and overall health.