小鼠SCN2A缺乏模型

Jacob Paulaskas
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引用次数: 0

摘要

由SCN2A基因(小鼠中为SCN2A)编码的Nav1.2钠通道作为大脑中主要的通信形式传播动作电位,特别是在发育过程中。当SCN2A基因因突变而中断时,人类的表型结果从癫痫到自闭症不等。选择一只小鼠来模拟scn2a相关神经发育障碍的影响,并检查潜在治疗方法的疗效。与完全敲除Scn2a不同,基因诱捕降低了Scn2a基因的表达,提高了围产期后的存活率。在纯合子(homs)基因诱捕小鼠中,Scn2a转录物的表达水平为29±4%,而在野生型(WT)小鼠中,Scn2a的表达水平为100%。HOM小鼠没有交配,因此必须使用杂合(HET)小鼠进行繁殖。孟德尔遗传学表明,杂交两个HET的后代可能是HOM、HET或WT的概率为1:2:1。因此,用PCR对每只小鼠幼仔进行基因分型,并计算最终的孟德尔比例,以确定幼崽是否遵循理论的1:2:1模式。进行卡方拟合优度检验,结果不显著(p = 0.0676),表明数据在>95%的置信区间内遵循理论1:2:1的比例。为了减少基因分型不一致造成的偏倚,只纳入至少有一个HOM的窝鼠。最常见的基因分型问题是在提取和电泳凝胶上划线过程中保持一致的DNA/洗脱缓冲液浓度。总的来说,HOM基因诱捕小鼠将继续作为测试scn2a相关神经发育障碍新疗法的模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Modeling SCN2A Deficiency in Mice
Encoded by the gene SCN2A (Scn2a in mice), Nav1.2 sodium channels propagate action potentials as the main form of communication in the brain, especially during development. When the SCN2A gene becomes disrupted by mutation, the phenotypic results range from epilepsy to autism in humans. A mouse was selected to model the effects of SCN2A-related neurodevelopmental disorders and examine the efficacy of potential therapies. A gene trap reduced Scn2a gene expression and increased survivability past the perinatal state, unlike a complete Scn2a knockout. A functional Scn2a transcript was produced at levels of 29 ± 4% in homozygous (HOM) gene-trap mice, compared to 100% expression in wild-type (WT) mice. HOM mice did not mate, so heterozygous (HET) mice had to be used for breeding. Mendelian genetics dictates crossing two HETs gives a 1:2:1 probability that offspring could be either HOM, HET, or WT. Therefore, each mouse pup was genotyped with PCR, and a final Mendelian ratio was calculated to determine if the litters followed the theoretical 1:2:1 pattern. A chi-square goodness of fit test was performed and concluded the results were not significant (p = 0.0676), showing the data followed the theoretical 1:2:1 ratio at a >95% confidence interval. Only litters with at least one HOM were included to reduce bias from inconsistent genotyping. The most frequent genotyping issues were maintaining consistent DNA/elution buffer concentrations during extraction and streaking on the electrophoresis gel. Overall, the HOM gene-trap mice will continue to serve as a model for testing new therapies for SCN2A-related neurodevelopmental disorders.
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