Compressed Full-Text Indexes for Highly Repetitive Collections (Jouni Sirén)

Readers may find GCSA framework mentioned by Paul Melsted useful. The context is mapping of reads into an assembly graph and the results came from Jouni Sirn’s PhD thesis (available from the website).

GCSA Website

GCSA [2, 3] is a compressed suffix array for finite languages. The implementation now supports general alphabet and multiple automata. The most up-to-date description of GCSA can be found in [3].

See README in the package for further information.

The implementation is available for download under the MIT / X11 License. Our implementation of RLCSA [1, 3] is required for compiling GCSA. (The current version of GCSA should always work with the current version of RLCSA.)

Return to the SuDS homepage.

References

1. Veli Mkinen, Gonzalo Navarro, Jouni Sirn, and Niko Vlimki: Storage and Retrieval of Highly Repetitive Sequence Collections.

Journal of Computational Biology 17(3):281-308, 2010.

[Article] [Preprint]

2. Jouni Sirn, Niko Vlimki, and Veli Mkinen: Indexing Finite Language Representation of Population Genotypes.

Proc. WABI 2011, Springer LNCS 6833, pp. 270-281, Saarbrcken, Germany, September 5-7, 2011.

[Article] [Preprint] [Full version]

3. Jouni Sirn: Compressed Full-Text Indexes for Highly Repetitive Collections (PhD Thesis).

Department of Computer Science, Series of Publications A, Report A-2012-5, University of Helsinki, June 2012. [Thesis]

The second reference can be downloaded from here.

Indexing Finite Language Representation of Population Genotypes

Abstract. With the recent advances in DNA sequencing, it is now possible to have complete genomes of individuals sequenced and assembled. This rich and focused genotype information can be used to do diff erent population-wide studies, now rst time directly on whole genome level. We propose a way to index population genotype information together with the complete genome sequence, so that one can use the index to eciently align a given sequence to the genome with all plausible genotype recombinations taken into account. This is achieved through converting a multiple alignment of individual genomes into a nite automaton recognizing all strings that can be read from the alignment by switching the sequence at any time. The nite automaton is indexed with an extension of Burrows-Wheeler transform to allow pattern search inside the plausible recombinant sequences. The size of the index stays limited, because of the high similarity of individual genomes. The index fi nds applications in variation calling and in primer design. On a variation calling experiment, we found about 1.0% of matches to novel recombinants just with exact matching, and up to 2.4% with approximate matching.

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On a related topic, readers may look at

Short Read Alignment with Populations of Genomes