The complex task of choosing a de novo assembly: Lessons from fungal genomes
Selecting the values of parameters used by de novo genomic assembly programs, or choosing an optimal de novo assembly from several runs obtained with different parameters or programs, are tasks that can require complex decision-making. A key parameter that must be supplied to typical next generation...
- Autores:
- Tipo de recurso:
- Fecha de publicación:
- 2014
- Institución:
- Universidad del Rosario
- Repositorio:
- Repositorio EdocUR - U. Rosario
- Idioma:
- eng
- OAI Identifier:
- oai:repository.urosario.edu.co:10336/23761
- Acceso en línea:
- https://doi.org/10.1016/j.compbiolchem.2014.08.014
https://repository.urosario.edu.co/handle/10336/23761
- Palabra clave:
- Complex task
De novo assemblies
Genome assembly
Next-generation sequencing
Spacer DNA
Algorithm
Contig mapping
DNA sequence
Fungal genome
Genetics
High throughput sequencing
Nucleotide repeat
Open reading frame
Paracoccidioides
Quality control
Statistics and numerical data
Algorithms
Benchmarking
Contig Mapping
High-Throughput Nucleotide Sequencing
Open Reading Frames
Paracoccidioides
Genome assembly methods
Next-generation sequencing
Repetitive DNA
Nucleic Acid
DNA
Fungal
Intergenic
DNA
Genome
Repetitive Sequences
Sequence Analysis
- Rights
- License
- Abierto (Texto Completo)
Summary: | Selecting the values of parameters used by de novo genomic assembly programs, or choosing an optimal de novo assembly from several runs obtained with different parameters or programs, are tasks that can require complex decision-making. A key parameter that must be supplied to typical next generation sequencing (NGS) assemblers is the k-mer length, i.e., the word size that determines which de Bruijn graph the program should map out and use. The topic of assembly selection criteria was recently revisited in the Assemblathon 2 study (Bradnam et al., 2013). Although no clear message was delivered with regard to optimal k-mer lengths, it was shown with examples that it is sometimes important to decide if one is most interested in optimizing the sequences of protein-coding genes (the gene space) or in optimizing the whole genome sequence including the intergenic DNA, as what is best for one criterion may not be best for the other. In the present study, our aim was to better understand how the assembly of unicellular fungi (which are typically intermediate in size and complexity between prokaryotes and metazoan eukaryotes) can change as one varies the k-mer values over a wide range. We used two different de novo assembly programs (SOAPdenovo2 and ABySS), and simple assembly metrics that also focused on success in assembling the gene space and repetitive elements. A recent increase in Illumina read length to around 150 bp allowed us to attempt de novo assemblies with a larger range of k-mers, up to 127 bp. We applied these methods to Illumina paired-end sequencing read sets of fungal strains of Paracoccidioides brasiliensis and other species. By visualizing the results in simple plots, we were able to track the effect of changing k-mer size and assembly program, and to demonstrate how such plots can readily reveal discontinuities or other unexpected characteristics that assembly programs can present in practice, especially when they are used in a traditional molecular microbiology laboratory with a 'genomics corner'. Here we propose and apply a component of a first pass validation methodology for benchmarking and understanding fungal genome de novo assembly processes. © 2014 Elsevier Ltd. All rights reserved. |
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