Ectopic transcription due to inappropriately inherited histone methylation may interfere with the ongoing function of terminally differentiated cells.

Juan D Rodriguez, Monica N Reeves, Hsiao-Lin V Wang, Jaely Z Chavez, Rhea Rastogi, Sindy R Chavez, Elicia A Preston, Madhav S Chadha, Liyang I Sun, Emily J Hill, Victor G Corces, Karen L Schmeichel, John I Murray, David J Katz
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Abstract

How mutations in histone modifying enzymes lead to neurodevelopmental disorders is unknown. We took advantage of the invariant embryonic lineage and adult nervous system in C. elegans to investigate a double mutant between spr-5/Lsd1/Kdm1a (H3K4me1/2 demethylase) and met-2/Setdb1 (H3K9 methyltransferase). We demonstrate that spr-5; met-2 double mutant worms have a severe chemotaxis defect caused by the ectopic expression of germline genes in somatic tissues. Despite this behavioral defect, we observe few embryonic lineage alterations and an intact adult nervous system. This raises the possibility that the abnormal chemotaxis behavior may be due to ongoing defects in terminally differentiated cells rather than alterations in development. Remarkably, we found that shutting off the ectopic germline expression rescues normal chemotaxis in the same spr-5; met-2 adult worms that had a chemotaxis defect earlier. This suggests that ongoing inappropriate transcription can block normal behavior in an intact nervous system. Based on these data, it is possible that the intellectual disability and altered behavior observed in human neurodevelopmental syndromes caused by mutations in histone modifying enzymes could be due to ongoing ectopic transcription and may be reversible.

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不适当遗传组蛋白甲基化导致的异位转录可能会干扰终末分化细胞的持续功能。
许多人类神经发育障碍是由组蛋白修饰酶的新生突变引起的。这些患者有颅面缺陷、发育迟缓、智力残疾和行为异常,但目前尚不清楚这些突变是如何导致这些发育缺陷的。在这里,我们利用不变的秀丽隐杆线虫谱系以及H3K4me1/2去甲基化酶SPR-5/LSD1/KDM1A和H3K9甲基转移酶MET-2/SETDB1的独特双突变来解决这个问题。我们证明了spr-5;Met-2双突变虫具有严重的趋化性缺陷,这取决于体细胞组织中种系基因的异位表达。此外,通过执行单细胞RNAseq,我们发现种系基因开始在spr-5中广泛异位表达;met-2胚胎。然而,令人惊讶的是,我们发现spr-5;在胚胎发生的200个细胞阶段之前,Met-2突变体没有体细胞谱系缺陷。这表明趋化性行为的改变可能是由于终末分化细胞的持续缺陷,而不是发育缺陷。为了直接验证这一点,我们使用RNAi关闭L2 spr-5中种系基因的异位表达;Met-2幼虫,有完全形成的神经系统。值得注意的是,我们发现,关闭异位种系表达可以恢复以前在L2阶段具有趋化性缺陷的成虫的正常趋化行为。这表明持续的异位转录可以阻断完全完整的神经系统的正常行为。这些数据提出了一种可能性,即由组蛋白修饰酶突变引起的神经发育综合征中的智力残疾和行为改变可能是由于正在进行的异位转录,并且可能是可逆的。
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