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一个鉴定 VSX2 型眼发育迟缓 J 小鼠早期视网膜发育障碍相关功能互作因子的框架。

A framework to identify functional interactors that contribute to disrupted early retinal development in Vsx2 ocular retardation J mice.

机构信息

Department of Cell and Developmental Biology, Vanderbilt University, Nashville, Tennessee, USA.

Department of Ophthalmology and Visual Sciences, Vanderbilt University Medical Center, Nashville, Tennessee, USA.

出版信息

Dev Dyn. 2023 Nov;252(11):1338-1362. doi: 10.1002/dvdy.629. Epub 2023 Jun 1.

DOI:10.1002/dvdy.629
PMID:37259952
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10689574/
Abstract

BACKGROUND

A goal of developmental genetics is to identify functional interactions that underlie phenotypes caused by mutations. We sought to identify functional interactors of Vsx2, which when mutated, disrupts early retinal development. We utilized the Vsx2 loss-of-function mouse, ocular retardation J (orJ), to assess interactions based on principles of positive and negative epistasis as applied to bulk transcriptome data. This was first tested in vivo with Mitf, a target of Vsx2 repression, and then to cultures of orJ retina treated with inhibitors of Retinoid-X Receptors (RXR) to target Rxrg, an up-regulated gene in the orJ retina, and gamma-Secretase, an enzyme required for Notch signaling, a key mediator of retinal proliferation and neurogenesis.

RESULTS

Whereas Mitf exhibited robust positive epistasis with Vsx2, it only partially accounts for the orJ phenotype, suggesting other functional interactors. RXR inhibition yielded minimal evidence for epistasis between Vsx2 and Rxrg. In contrast, gamma-Secretase inhibition caused hundreds of Vsx2-dependent genes associated with proliferation to deviate further from wild-type, providing evidence for convergent negative epistasis with Vsx2 in regulating tissue growth.

CONCLUSIONS

Combining in vivo and ex vivo testing with transcriptome analysis revealed quantitative and qualitative characteristics of functional interaction between Vsx2, Mitf, RXR, and gamma-Secretase activities.

摘要

背景

发育遗传学的目标是确定导致突变引起的表型的功能相互作用。我们试图确定 Vsx2 的功能相互作用物,当突变时,它会破坏早期视网膜发育。我们利用 Vsx2 功能丧失型小鼠,眼部发育迟缓 J(或 J),根据正和负上位性的原则,基于大量转录组数据来评估相互作用。这首先在体内用 Mitf 进行了测试,Mitf 是 Vsx2 抑制的靶标,然后用视黄酸受体(RXR)抑制剂处理 J 视网膜培养物,以靶向 J 视网膜中上调的基因 Rxrg 和 Notch 信号传导所需的γ-分泌酶, Notch 信号传导是视网膜增殖和神经发生的关键介质。

结果

尽管 Mitf 与 Vsx2 表现出强烈的正上位性,但它仅部分解释了 J 表型,表明存在其他功能相互作用物。RXR 抑制在 Vsx2 和 Rxrg 之间几乎没有表现出上位性。相比之下,γ-分泌酶抑制导致数百个与增殖相关的依赖于 Vsx2 的基因进一步偏离野生型,为调节组织生长的与 Vsx2 之间的收敛性负上位性提供了证据。

结论

将体内和体外测试与转录组分析相结合,揭示了 Vsx2、Mitf、RXR 和γ-分泌酶活性之间功能相互作用的定量和定性特征。

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Neuron. 2023 Jan 4;111(1):49-64.e5. doi: 10.1016/j.neuron.2022.10.025. Epub 2022 Nov 8.
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Timed Notch Inhibition Drives Photoreceptor Fate Specification in Human Retinal Organoids.时间门控 Notch 抑制促进人视网膜类器官中光感受器命运特化。
Invest Ophthalmol Vis Sci. 2022 Sep 1;63(10):12. doi: 10.1167/iovs.63.10.12.
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Functional analysis of the Vsx2 super-enhancer uncovers distinct cis-regulatory circuits controlling Vsx2 expression during retinogenesis.功能分析揭示了 Vsx2 超级增强子在视发生过程中控制 Vsx2 表达的独特顺式调控回路。
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