Mapping single molecule sequencing reads using basic local alignment with successive refinement (BLASR): application and theory

Recent methods have been developed to perform high-throughput sequencing of DNA by Single Molecule Sequencing (SMS). While Next-Generation sequencing methods may produce reads up to several hundred bases long, SMS sequencing produces reads up to tens of kilobases long. Existing alignment methods are...

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Bibliographic Details
Published in:BMC bioinformatics 2012-09, Vol.13 (1), p.238-238, Article 238
Main Authors: Chaisson, Mark J, Tesler, Glenn
Format: Article
Language:English
Subjects:
Algorithms
Base Sequence
Bioinformatics
DNA
DNA - genetics
DNA sequencing
Gene deletion
Gene mapping
Genome
Genomes
Genomics
Insertion
Methodology
Methods
Nucleotide sequencing
Sample variance
Sequence Alignment - methods
Sequence Analysis, DNA - methods
Software
Studies
Theory
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Summary:Recent methods have been developed to perform high-throughput sequencing of DNA by Single Molecule Sequencing (SMS). While Next-Generation sequencing methods may produce reads up to several hundred bases long, SMS sequencing produces reads up to tens of kilobases long. Existing alignment methods are either too inefficient for high-throughput datasets, or not sensitive enough to align SMS reads, which have a higher error rate than Next-Generation sequencing. We describe the method BLASR (Basic Local Alignment with Successive Refinement) for mapping Single Molecule Sequencing (SMS) reads that are thousands of bases long, with divergence between the read and genome dominated by insertion and deletion error. The method is benchmarked using both simulated reads and reads from a bacterial sequencing project. We also present a combinatorial model of sequencing error that motivates why our approach is effective. The results indicate that it is possible to map SMS reads with high accuracy and speed. Furthermore, the inferences made on the mapability of SMS reads using our combinatorial model of sequencing error are in agreement with the mapping accuracy demonstrated on simulated reads.
ISSN:1471-2105
1471-2105
DOI:10.1186/1471-2105-13-238