Fluorescent In Situ Hybridization Chain Reaction for RNA in the Drosophila Embryonic and Larval Central Nervous System.

Jake E Henderson, Chris C Wreden, Ellie S Heckscher
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Abstract

In the Drosophila nerve cord, much is known about the generation of neurons from neuronal stem cells. Over the lifetime of a neuron, the cumulative expression of genes within that neuron determines its fate. Furthermore, gene expression in mature neurons determines their functional characteristics. It is therefore useful to visualize neural gene expression, which is often done via staining with antibodies to a protein of interest. In cases where there is no antibody to a desired gene product, or when it is useful to detect RNA rather than protein products, fluorescent in situ hybridization chain reaction for RNA (HCR RNA-FISH, or HCR for this protocol) can be used to detect and quantify RNA expression. RNA molecules reside predominantly in the cell soma, so HCR can facilitate determining neuron identity because somata position within the nerve cord is stereotyped across animals. HCR provides high-amplitude, high-fidelity signals. In principle, HCR can be broken down into a detection/hybridization stage and an amplification stage. During detection/hybridization, a probe set hybridizes to multiple sequences within a target gene. In the amplification step, concatemerized fluorescent hairpins bind to the hybridized probes. This two-step process increases the specificity of the fluorescent signal and helps reduce the likelihood of background fluorescence compared to traditional in situ hybridization techniques where the hybridizing probe itself contains the fluorescent signal. Here, we describe a protocol for using HCR to study gene expression in the Drosophila embryonic and larval nerve cord. We also describe how to combine HCR with immunofluorescence staining.

果蝇胚胎和幼虫中枢神经系统 RNA 的荧光原位杂交连锁反应。
在果蝇神经索中,人们对神经元干细胞产生神经元的过程了解甚多。在神经元的整个生命周期中,神经元内基因的累积表达决定了神经元的命运。此外,成熟神经元的基因表达决定了其功能特征。因此,对神经基因表达进行可视化是非常有用的,这通常是通过对相关蛋白进行抗体染色来实现的。如果没有所需的基因产物抗体,或者需要检测 RNA 而不是蛋白质产物,则可以使用 RNA 荧光原位杂交链反应(HCR RNA-FISH,或本方案中的 HCR)来检测和量化 RNA 表达。RNA 分子主要存在于细胞体内,因此 HCR 可以帮助确定神经元的身份,因为神经元在神经索内的体节位置在不同动物中是定型的。HCR 可提供高振幅、高保真信号。原则上,HCR 可分为检测/杂交阶段和放大阶段。在检测/杂交阶段,探针组与目标基因内的多个序列杂交。在扩增阶段,荧光发夹与杂交探针结合。与杂交探针本身就含有荧光信号的传统原位杂交技术相比,这两步过程提高了荧光信号的特异性,并有助于降低背景荧光的可能性。在这里,我们介绍了使用 HCR 研究果蝇胚胎和幼虫神经索基因表达的方案。我们还介绍了如何将 HCR 与免疫荧光染色相结合。
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来源期刊
Cold Spring Harbor protocols
Cold Spring Harbor protocols Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)
CiteScore
3.00
自引率
0.00%
发文量
163
期刊介绍: Cold Spring Harbor Laboratory is renowned for its teaching of biomedical research techniques. For decades, participants in its celebrated, hands-on courses and users of its laboratory manuals have gained access to the most authoritative and reliable methods in molecular and cellular biology. Now that access has moved online. Cold Spring Harbor Protocols is an interdisciplinary journal providing a definitive source of research methods in cell, developmental and molecular biology, genetics, bioinformatics, protein science, computational biology, immunology, neuroscience and imaging. Each monthly issue details multiple essential methods—a mix of cutting-edge and well-established techniques.
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