A survey of best practices for RNA-seq data analysis
Genome biology, 2016•Springer
Abstract RNA-sequencing (RNA-seq) has a wide variety of applications, but no single
analysis pipeline can be used in all cases. We review all of the major steps in RNA-seq data
analysis, including experimental design, quality control, read alignment, quantification of
gene and transcript levels, visualization, differential gene expression, alternative splicing,
functional analysis, gene fusion detection and eQTL mapping. We highlight the challenges
associated with each step. We discuss the analysis of small RNAs and the integration of …
analysis pipeline can be used in all cases. We review all of the major steps in RNA-seq data
analysis, including experimental design, quality control, read alignment, quantification of
gene and transcript levels, visualization, differential gene expression, alternative splicing,
functional analysis, gene fusion detection and eQTL mapping. We highlight the challenges
associated with each step. We discuss the analysis of small RNAs and the integration of …
Abstract
RNA-sequencing (RNA-seq) has a wide variety of applications, but no single analysis pipeline can be used in all cases. We review all of the major steps in RNA-seq data analysis, including experimental design, quality control, read alignment, quantification of gene and transcript levels, visualization, differential gene expression, alternative splicing, functional analysis, gene fusion detection and eQTL mapping. We highlight the challenges associated with each step. We discuss the analysis of small RNAs and the integration of RNA-seq with other functional genomics techniques. Finally, we discuss the outlook for novel technologies that are changing the state of the art in transcriptomics.
Springer
