Abstract
RNA sequencing techniques have enabled the systematic elucidation of gene expression (RNA-Seq), transcription start sites (differential RNA-Seq), transcript 3′ ends (Term-Seq), and post-transcriptional processes (ribosome profiling). The main challenge of transcriptomic studies is to remove ribosomal RNAs (rRNAs), which comprise more than 90% of the total RNA in a cell. Here, we report a low-cost and robust bacterial rRNA depletion method, RiboRid, based on the enzymatic degradation of rRNA by thermostable RNase H. This method implemented experimental considerations to minimize nonspecific degradation of mRNA and is capable of depleting pre-rRNAs that often comprise a large portion of RNA, even after rRNA depletion. We demonstrated the highly efficient removal of rRNA up to a removal efficiency of 99.99% for various transcriptome studies, including RNA-Seq, Term-Seq, and ribosome profiling, with a cost of approximately $10 per sample. This method is expected to be a robust method for large-scale high-throughput bacterial transcriptomic studies.
Highlights
Genetic information encoded in the genome is transferred to proteins via messenger RNAs
Removal of ribosomal RNAs, a major constituent of cellular RNA is a critical experimental step for transcriptomic studies that deal with messenger RNAs
We validate the method on various types of transcriptomic studies for seven diverse bacterial species
Summary
Genetic information encoded in the genome is transferred to proteins via messenger RNAs (mRNAs). Investigating mRNAs is a central approach to elucidating the fundamentals of cellular functions Multiple techniques such as quantitative polymerase chain reaction (qPCR), microarray, and RNA sequencing (RNA-Seq) have been developed to quantitatively measure mRNAs inside a cell or their changes in response to a variety of environmental and genetic perturbations [1,2]. Exonucleolytic digestion of processed RNA with monophosphate at the 50 end has been devised for transcriptomics [8] This method has relatively low efficiency and is limited by the fact that primary transcripts protected by triphosphate from 50phosphate-dependent terminator exonuclease (TEX) may not be a precise representation of mRNA levels in a cell, because a considerable amount of mRNA exists as a processed form. Several methods have been proposed for rRNA removal based on duplex-specific nucleasebased digestion, electrophoretic size selection, and sequence-specific blockage of reverse transcription, they are not as efficient as commercial systems [9,10,11,12]
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