Abstract
In this paper we present several lower bounds on the approximation of the exemplar conserved interval distance problem of genomes. We first prove that the exemplar conserved interval distance problem cannot be approximated within a factor of clogn for some constant c>0 in polynomial time, unless P=NP. We then prove that it is NP-complete to decide whether the exemplar conserved interval distance between any two sets of genomes is zero or not. This result implies that the exemplar conserved interval distance problem does not admit any approximation in polynomial time, unless P=NP. In fact, this result holds even when a gene appears in each of the given genomes at most three times. Finally, we strengthen the second result under a weaker definition of approximation (which we call weak approximation). We show that the exemplar conserved interval distance problem does not admit a weak approximation within a factor of m, where m is the maximum length of the given genomes.
This research is supported in part by FIPSE Congressional Award P116Z020159, NSF CNS-0521585, Louisiana Board of Regents under contract number LEQSF(2004-07)-RD-A-35 and MSU-Bozeman’s Short-term Professional Development Leave Program.
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Chen, Z., Fowler, R.H., Fu, B., Zhu, B. (2006). Lower Bounds on the Approximation of the Exemplar Conserved Interval Distance Problem of Genomes. In: Chen, D.Z., Lee, D.T. (eds) Computing and Combinatorics. COCOON 2006. Lecture Notes in Computer Science, vol 4112. Springer, Berlin, Heidelberg. https://doi.org/10.1007/11809678_27
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DOI: https://doi.org/10.1007/11809678_27
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