Abstract
BackgroundFinding sequences of evolutionary operations that transform one genome into another is a classic problem in comparative genomics. While most of the genome rearrangement algorithms assume that there is exactly one copy of each gene in both genomes, this does not reflect the biological reality very well – most of the studied genomes contain duplicated gene content, which has to be removed before applying those algorithms. However, dealing with unequal gene content is a very challenging task, and only few algorithms allow operations like duplications and deletions. Almost all of these algorithms restrict these operations to have a fixed size.ResultsIn this paper, we present a heuristic algorithm to sort an ancestral genome (with unique gene content) into a genome of a descendant (with arbitrary gene content) by reversals, block interchanges, tandem duplications, and deletions, where tandem duplications and deletions are of arbitrary size.ConclusionExperimental results show that our algorithm finds sorting sequences that are close to an optimal sorting sequence when the ancestor and the descendant are closely related. The quality of the results decreases when the genomes get more diverged or the genome size increases. Nevertheless, the calculated distances give a good approximation of the true evolutionary distances.
Highlights
Finding sequences of evolutionary operations that transform one genome into another is a classic problem in comparative genomics
Genomes are subject to genome rearrangements, which are large scale mutations that can alter the ordering and orientation of the genes on the chromosomes or even change the genome content by inserting, deleting, or duplicating genes
We will restrict the set of operations to reversals, deletions, tandem duplications, and block interchanges, as defined in the subsection
Summary
Finding sequences of evolutionary operations that transform one genome into another is a classic problem in comparative genomics. Dealing with unequal gene content is a very challenging task, and only few algorithms allow operations like duplications and deletions. Genomes are subject to genome rearrangements, which are large scale mutations that can alter the ordering and orientation (strandedness) of the genes on the chromosomes or even change the genome content by inserting, deleting, or duplicating genes. Because these events are rare compared to point mutations, they can give us valuable information about ancient events in the evolutionary history of organisms. These "classical operations" are nowadays a well-studied subject, where the most important operations are reversals (page number not for citation purposes)
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