Abstract
BackgroundIn rice, the cortex and outer tissues play a key role in submergence tolerance. The cortex differentiates into aerenchyma, which are air-containing cavities that allow the flow of oxygen from shoots to roots, whereas exodermis suberification and sclerenchyma lignification limit oxygen loss from the mature parts of roots by forming a barrier to root oxygen loss (ROL). The genes and their networks involved in the cellular identity and differentiation of these tissues remain poorly understood. Identification and characterization of key regulators of aerenchyma and ROL barrier formation require determination of the specific expression profiles of these tissues.ResultsWe optimized an approach combining laser microdissection (LM) and droplet digital RT-PCR (ddRT-PCR) for high-throughput identification of tissue-specific expression profiles. The developed protocol enables rapid (within 3 days) extraction of high-quality RNA from root tissues with a low contamination rate. We also demonstrated the possibility of extracting RNAs from paraffin blocks stored at 4 °C without any loss of quality. We included a detailed troubleshooting guide that should allow future users to adapt the proposed protocol to other tissues and/or species. We demonstrated that our protocol, which combines LM with ddRT-PCR, can be used as a complementary tool to in situ hybridization for tissue-specific characterization of gene expression even with a low RNA concentration input. We illustrated the efficiency of the proposed approach by validating three of four potential tissue-specific candidate genes detailed in the RiceXpro database.ConclusionThe detailed protocol and the critical steps required to optimize its use for other species will democratize tissue-specific transcriptome approaches combining LM with ddRT-PCR for analyses of plants.
Highlights
In rice, the cortex and outer tissues play a key role in submergence tolerance
Three main technologies have been developed for the isolation of RNA from specific tissues, and these can be grouped into two groups: technology involving laser microdissection (LM) [1] and Fluorescence-activated Cell Sorting (FACS) [2] and INTACT [3, 4] technologies
High-throughput protocol involving the use of LM and droplet digital PCR (ddPCR) to extract highquality RNA, control intertissue contamination, and analyze gene expression
Summary
The cortex differentiates into aerenchyma, which are air-containing cavities that allow the flow of oxygen from shoots to roots, whereas exodermis suberification and sclerenchyma lignification limit oxygen loss from the mature parts of roots by forming a barrier to root oxygen loss (ROL). The genes and their networks involved in the cellular identity and differentiation of these tissues remain poorly understood. RNAseq or microarray is used to obtain an expression profile of the labeled cell populations These technologies have mainly been used for the analysis of A. thaliana For A. thaliana, the development of FACS technology has made it possible to produce a map of the expression profiles of most root cell types [2] and to analyze tissue-specific responses to salt stress [7]
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