Bridger: a new framework for de novo transcriptome assembly using RNA-seq data

Chang, Zheng; Li, Guojun; Liu, Juntao; Zhang, Yu; Ashby, Cody; Liu, De Li; Cramer, Carole L.; Huang, Xiuzhen

doi:10.1186/s13059-015-0596-2

Cited by 277 publications

(226 citation statements)

References 34 publications

(64 reference statements)

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“…Transcripts expressed at extremely low levels can also cause noise because they may not be reliably assembled (http://cole-trapnell-lab.github.io/cufflinks/cufflinks/). Furthermore, it is difficult to distinguish between isoforms of one gene versus the existence of more gene copies as a consequence of duplications (Chang et al 2015).…”

Section: Transcriptome Sequencing and Assemblymentioning

confidence: 99%

Mechanisms of vegetative propagation in bulbs : a molecular approach

Moreno-Pachon

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Section: Transcriptome Sequencing and Assemblymentioning

confidence: 99%

Mechanisms of vegetative propagation in bulbs : a molecular approach

Moreno-Pachon

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“…However, de Bruijn graph-based strategy between de novo genome and transcriptome assembly is slightly modiied because of the following reasons: (i) while the DNA sequencing depth is expected to be uniform across the genome (except in repetitive regions), the sequencing depth of transcripts can vary considerably, (ii) Genome assembly graph is considered as linear (theoretically one graph for each chromosome), but due to alternative splicing, transcriptome assembly is more complex than genome and requires a graph to represent the multiple alternative transcripts per locus [1,21]. By considering these challenges, several de novo assembly tools such as Trinity [1], SOAPdenovo-Trans [22], Trans-AbySS [23], Oases [24], IDBA-Tran [25], BinPacker [26] and Bridger [27] have been developed so far (Box 1). Most of these tools, which are initially developed for de novo genome assembly (except for Trinity) use de Bruijn graph-based assembly strategy and have their own pros and cons in transcript reconstruction.…”

Section: A Brief Glance At De Novo Transcript Assemblersmentioning

confidence: 99%

Transcriptome Analysis for Non-Model Organism: Current Status and Best-Practices

Eldem¹,

Zararsız²,

Taşçi³

et al. 2017

Applications of RNA-Seq and Omics Strategies - From Microorganisms to Human Health

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Since transcriptome analysis provides genome-wide sequence and gene expression information, transcript reconstruction using RNA-Seq sequence reads has become popular during recent years. For non-model organism, as distinct from the reference genome-based mapping, sequence reads are processed via de novo transcriptome assembly approaches to produce large numbers of contigs corresponding to coding or non-coding, but expressed, part of genome. In spite of immense potential of RNA-Seq-based methods, particularly in recovering full-length transcripts and spliced isoforms from short-reads, the accurate results can be only obtained by the procedures to be taken in a step-by-step manner. In this chapter, we aim to provide an overview of the state-of-the-art methods including (i) quality check and pre-processing of raw reads, (ii) the pros and cons of de novo transcriptome assemblers, (iii) generating non-redundant transcript data, (iv) current quality assessment tools for de novo transcriptome assemblies, (v) approaches for transcript abundance and diferential expression estimations and inally (vi) further mining of transcriptomic data for particular biological questions. Our intention is to provide an overview and practical guidance for choosing the appropriate approaches to best meet the needs of researchers in this area and also outline the strategies to improve on-going projects.

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“…A method called Bridge which combines the de novo assembler Trinity with the reference-based assembler Cufflinks has been proposed [28] to tackle the transcriptome assembly problem. Bridge builds splicing graphs for all genes from the reference genome.…”

Section: Reference-based Transcriptome Assembly Strategymentioning

confidence: 99%

Transcriptome assembly strategies for precision medicine

Wang

Acharya²,

Bai

et al. 2017

Quant. Biol.

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Background: Precision medicine approach holds great promise to tailored diagnosis, treatment and prevention. Individuals can be vastly different in their genomic information and genetic mechanisms hence having unique transcriptomic signatures. The development of precision medicine has demanded moving beyond DNA sequencing (DNA-Seq) to much more pointed RNA-sequencing (RNA-Seq) [Cell, 2017, 168: 584-599]. Results: Here we conduct a brief survey on the recent methodology development of transcriptome assembly approach using RNA-Seq. Conclusions: Since transcriptomes in human disease are highly complex, dynamic and diverse, transcriptome assembly is playing an increasingly important role in precision medicine research to dissect the molecular mechanisms of the human diseases.

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Bridger: a new framework for de novo transcriptome assembly using RNA-seq data

Cited by 277 publications

References 34 publications

Mechanisms of vegetative propagation in bulbs : a molecular approach

Mechanisms of vegetative propagation in bulbs : a molecular approach

Transcriptome Analysis for Non-Model Organism: Current Status and Best-Practices

Transcriptome assembly strategies for precision medicine

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