Strand‐Specific Transcriptome Sequencing Using SMART Technology

Current Protocols in Molecular Biology2016Vol. 116(1), pp. 4.27.1–4.27.18

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Magnolia Bostick, Nathalie Bolduc, Alisa P. Lehman, Andrew Farmer

Abstract

Next-generation sequencing is empowering a deeper understanding of biology by enabling RNA expression analysis over the entire transcriptome with high sensitivity and a wide dynamic range. One powerful application within this field is stranded RNA sequencing (RNA-seq), which is necessary to distinguish overlapping genes and to conduct comprehensive annotation and quantification of long non-coding RNAs. Commonly used methods for generating strand-specific RNA-seq libraries are often complicated by protocols that require several rounds of enzymatic treatments and clean-up steps, making them time-intensive, insensitive, and unsuitable for processing several samples simultaneously. An additional challenge in the generation of RNA-seq libraries from total RNA involves the high amount of ribosomal RNA (rRNA) in the starting material. This unit presents streamlined workflows for generating strand-specific RNA-seq libraries from 10 ng to 1 µg total RNA, representing a minimum of 1000 cells, in less than 7 hr with minimal carryover rRNA. These methods allow scientists to evaluate the expression of all transcripts, including non-polyadenylated long non-coding RNAs, even in limited biological samples. Combination of the RNase H-based RiboGone rRNA removal system and SMARTer Stranded RNA-seq technology enables depletion of over 95% of rRNA from mammalian samples, and direct production of Illumina-ready libraries that maintain strand-of-origin information. An alternate method for low input of highly degraded samples is also presented. © 2016 by John Wiley & Sons, Inc.

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Abstract

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