The study of genomic inversions (or reversals) has been a mainstay of computational genomics for nearly 20 years. After the initial breakthrough of Hannenhalli and Pevzner, who gave the first polynomial-time algorithm for sorting signed permutations by inversions, improved algorithms have been designed, culminating with an optimal linear-time algorithm for computing the inversion distance and a subquadratic algorithm for providing a shortest sequence of inversions-also known as sorting by inversions. Remaining open was the question of whether sorting by inversions Could be done in O(n log n) time
Gu et al. gave a 2-approximation for computing the minimal number of inversions and transpositions n...
Abstract. In comparative genomics studies, finding a minimum length sequences of reversals, so calle...
Hannenhalli and Pevzner gave the first polynomial-time algorithm for computing the inversion distanc...
The rearrangement distance between single-chromosome genomes can be estimated as the minimum number ...
Sorting signed permutations by reversals is a fundamental problem in computationial molecular biolog...
The problem of estimating evolutionary distance from differences in gene order has been distilled to...
Motivated by the problem in computational biology of reconstructing the series of chromosome inversi...
During evolution, genomes are subject to genome rearrangements that alter the ordering and orientati...
AbstractGenome rearrangement algorithms are powerful tools to analyze gene orders in molecular evolu...
During evolution, global mutations may modify the gene order in a genome. Such mutations are commonl...
AbstractSorting permutations by reversals is one of the most challenging problems related with the a...
International audienceThis paper proposes new algorithms for computing pairwise rearrangement scenar...
Abstract. Genome rearrangement algorithms are powerful tools to analyze gene orders in molecular evo...
AbstractThe problem of sorting signed permutations by reversals is inspired by genome rearrangement ...
In comparative genomics studies, finding a minimum length sequences of reversals, so-called sorting ...
Gu et al. gave a 2-approximation for computing the minimal number of inversions and transpositions n...
Abstract. In comparative genomics studies, finding a minimum length sequences of reversals, so calle...
Hannenhalli and Pevzner gave the first polynomial-time algorithm for computing the inversion distanc...
The rearrangement distance between single-chromosome genomes can be estimated as the minimum number ...
Sorting signed permutations by reversals is a fundamental problem in computationial molecular biolog...
The problem of estimating evolutionary distance from differences in gene order has been distilled to...
Motivated by the problem in computational biology of reconstructing the series of chromosome inversi...
During evolution, genomes are subject to genome rearrangements that alter the ordering and orientati...
AbstractGenome rearrangement algorithms are powerful tools to analyze gene orders in molecular evolu...
During evolution, global mutations may modify the gene order in a genome. Such mutations are commonl...
AbstractSorting permutations by reversals is one of the most challenging problems related with the a...
International audienceThis paper proposes new algorithms for computing pairwise rearrangement scenar...
Abstract. Genome rearrangement algorithms are powerful tools to analyze gene orders in molecular evo...
AbstractThe problem of sorting signed permutations by reversals is inspired by genome rearrangement ...
In comparative genomics studies, finding a minimum length sequences of reversals, so-called sorting ...
Gu et al. gave a 2-approximation for computing the minimal number of inversions and transpositions n...
Abstract. In comparative genomics studies, finding a minimum length sequences of reversals, so calle...
Hannenhalli and Pevzner gave the first polynomial-time algorithm for computing the inversion distanc...