Whole mount in situ hybridization techniques for analysis of the spatial distribution of mRNAs in sea urchin embryos and early larvae

• Published in: Methods in cell biology Vol. 151; pp. 177 - 196
• Main Authors: Erkenbrack, Eric M, Croce, Jenifer C, Miranda, Esther, Gautam, Sujan, Martinez-Bartolome, Marina, Yaguchi, Shunsuke, Range, Ryan C
• Format: Journal Article
• Language: English
• Published: United States 2019
• Subjects: Animals; Embryo, Nonmammalian - cytology; Embryonic Development - genetics; Gene Expression Regulation, Developmental - genetics; Gene Regulatory Networks - genetics; In Situ Hybridization - methods; Larva - genetics; Larva - growth & development; RNA, Messenger - genetics; Sea Urchins - genetics; Sea Urchins - growth & development; Strongylocentrotus purpuratus; Gene regulatory networks; Lytechinus variegatus; Paracentrotus lividus; RNA; Eucidaris tribuloides; Hemicentrotus pulcherrimus; In situ hybridization; Sea urchin
• ISSN: 0091-679X
• DOI: 10.1016/bs.mcb.2019.01.003

A critical process in embryonic development is the activation and spatial localization of mRNAs to specific cells and territories of the embryo. Revealing the spatial distribution of mRNAs and how it changes during development is a vital piece of information that aids in understanding the signaling and regulatory genes driving specific gene regulatory networks. In the laboratory, a cost-efficient, reliable method to determine the spatial distribution of mRNAs in embryos is in situ hybridization. This sensitive and straightforward method employs exogenous antisense RNA probes to find specific and complementary sequences in fixed embryos. Antigenic moieties conjugated to the ribonucleotides incorporated in the probe cross-react with antibodies, and numerous staining methods can be subsequently employed to reveal the spatial distribution of the targeted mRNA. The quality of the data produced by this method is equivalent to the experience of the researcher, and thus a thorough understanding of the numerous steps comprising this method is important for obtaining high quality data. Here we compile and summarize several protocols that have been employed chiefly on five sea urchin species in numerous laboratories around the world. Whereas the protocols can vary for the different species, the overarching steps are similar and can be readily mastered. When properly and carefully undertaken, in situ hybridization is a powerful tool providing unambiguous data for which there currently is no comparable substitute and will continue to be an important method in the era of big data and beyond.