Abstract
Transcriptomes are one of the first sources of high-throughput genomic data that have benefitted from the introduction of Next-Gen Sequencing. As sequencing technology becomes more accessible, transcriptome sequencing is applicable to multiple organisms for which genome sequences are unavailable. Currently all methods for de novo assembly are based on the concept of matching the nucleotide context overlapping between short fragments-reads. However, even short reads may still contain biologically relevant information which can be used as hints in guiding the assembly process. We propose a computational workflow for the reconstruction and functional annotation of expressed gene transcripts that does not require a reference genome sequence and can be tolerant to low coverage, high error rates and other issues that often lead to poor results of de novo assembly in studies of non-model organisms. We start with either raw sequences or the output of a context-based de novo transcriptome assembly. Instead of mapping reads to a reference genome or creating a completely unsupervised clustering of reads, we assemble the unknown transcriptome using nearest homologs from a public database as seeds. We consider even distant relations, indirectly linking protein-coding fragments to entire gene families in multiple distantly related genomes. The intended application of the proposed method is an additional step of semantic (based on relations between protein-coding fragments) scaffolding following traditional (i.e. based on sequence overlap) de novo assembly. The method we developed was effective in analysis of the jellyfish Cyanea capillata transcriptome and may be applicable in other studies of gene expression in species lacking a high quality reference genome sequence. Our algorithms are implemented in C and designed for parallel computation using a high-performance computer. The software is available free of charge via an open source license.
Highlights
Transcriptome sequencing is arguably the first truly high-throughput technology, allowing for the creation of large-scale genomic databases
Next-Generation Sequencing technology (NGS) transcriptome studies allow quantitative estimation of gene expression by counting the number of reads aligned to each transcript or gene sequence
This study was motivated by the challenge of analyzing a MiSeq (Illumina Inc., San Diego) project on the mRNA of the peri-rhopalial tissue of jellyfish Cyanea capillata, an important model for analysis of the molecular mechanisms of cellular excitability and evolution of the nervous system
Summary
Transcriptome sequencing is arguably the first truly high-throughput technology, allowing for the creation of large-scale genomic databases. NGS transcriptome studies allow quantitative estimation of gene expression by counting the number of reads aligned to each transcript or gene sequence.
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