论文信息 - Genomic distance under gene substitutions

Genomic distance under gene substitutions

BackgroundThe distance between two genomes is often computed by comparing only the common markers between them. Some approaches are also able to deal with non-common markers, allowing the insertion or the deletion of such markers. In these models, a deletion and a subsequent insertion that occur at the same position of the genome count for two sorting steps.ResultsHere we propose a new model that sorts non-common markers with substitutions, which are more powerful operations that comprehend insertions and deletions. A deletion and an insertion that occur at the same position of the genome can be modeled as a substitution, counting for a single sorting step.ConclusionsComparing genomes with unequal content, but without duplicated markers, we give a linear time algorithm to compute the genomic distance considering substitutions and double-cut-and-join (DCJ) operations. This model provides a parsimonious genomic distance to handle genomes free of duplicated markers, that is in practice a lower bound to the real genomic distances. The method could also be used to refine orthology assignments, since in some cases a substitution could actually correspond to an unannotated orthology.

[1] D. Page,et al. Four evolutionary strata on the human X chromosome. , 1999, Science.

[2] Jens Stoye,et al. Double Cut and Join with Insertions and Deletions , 2011, J. Comput. Biol..

[3] Jens Stoye,et al. On the weight of indels in genomic distances , 2011, BMC Bioinformatics.

[4] Pavel A. Pevzner,et al. Transforming men into mice (polynomial algorithm for genomic distance problem) , 1995, Proceedings of IEEE 36th Annual Foundations of Computer Science.

[5] Richard Friedberg,et al. Efficient sorting of genomic permutations by translocation, inversion and block interchange , 2005, Bioinform..

[6] Dr. Susumu Ohno. Sex Chromosomes and Sex-Linked Genes , 1967, Monographs on Endocrinology.

[7] Richard Friedberg,et al. DCJ Path Formulation for Genome Transformations which Include Insertions, Deletions, and Duplications , 2009, J. Comput. Biol..

[8] Jens Stoye,et al. The Solution Space of Sorting by DCJ , 2010, J. Comput. Biol..

[9] R. W. C. Stevens,et al. Sex chromosomes and sex-linked genes. , 1968 .

[10] Jens Stoye,et al. A Unifying View of Genome Rearrangements , 2006, WABI.

[11] J. Boore. The duplication/random loss model for gene rearrangement exemplified by mitochondrial genomes of deu , 2000 .

[12] David L. Steffen,et al. The DNA sequence of the human X chromosome , 2005, Nature.

[13] W. Brown,et al. EVOLUTION OF ANIMAL MITOCHONDRIAL DNA: RELEVANCE FOR POPULATION BIOLOGY AND SYSTEMATICS , 1987 .