DocumentCode
1755734
Title
Extending the Algebraic Formalism for Genome Rearrangements to Include Linear Chromosomes
Author
Feijao, Pedro ; Meidanis, Joao
Author_Institution
Inst. of Comput., Univ. of Campinas, Campinas, Brazil
Volume
10
Issue
4
fYear
2013
fDate
July-Aug. 2013
Firstpage
819
Lastpage
831
Abstract
Algebraic rearrangement theory, as introduced by Meidanis and Dias, focuses on representing the order in which genes appear in chromosomes, and applies to circular chromosomes only. By shifting our attention to genome adjacencies, we introduce the adjacency algebraic theory, extending the original algebraic theory to linear chromosomes in a very natural way, also allowing the original algebraic distance formula to be used to the general multichromosomal case, with both linear and circular chromosomes. The resulting distance, which we call algebraic distance here, is very similar to, but not quite the same as, double-cut-and-join distance. We present linear time algorithms to compute it and to sort genomes. We show how to compute the rearrangement distance from the adjacency graph, for an easier comparison with other rearrangement distances. A thorough discussion on the relationship between the chromosomal and adjacency representation is also given, and we show how all classic rearrangement operations can be modeled using the algebraic theory.
Keywords
algebra; cellular biophysics; genomics; adjacency algebraic theory; algebraic distance; algebraic formalism; algebraic rearrangement theory; double-cut-and-join distance; general multichromosomal case; genome adjacencies; genome rearrangements; linear chromosomes; linear time algorithms; Bioinformatics; Biological cells; Computational biology; Extremities; Genomics; IEEE transactions; Sorting; Biology and genetics; combinatorial algorithms;
fLanguage
English
Journal_Title
Computational Biology and Bioinformatics, IEEE/ACM Transactions on
Publisher
ieee
ISSN
1545-5963
Type
jour
DOI
10.1109/TCBB.2012.161
Filename
6378360
Link To Document