Years and Authors of Summarized Original Work
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2001; Blanchette, Schwikowski, Tompa
Problem Definition
The Substring Parsimony Problem, introduced by Blanchette et al. [1] in the context of motif discovery in biological sequences, can be described in a more general framework:
Input:
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A discrete space \( { \mathcal{S} } \) on which an integral distanced is defined (i.e., \( { d(x,y) \in \mathbb{N} \ \forall x,} \)\( {y \in \mathcal{S} } \) ).
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A rooted binary tree \( { T=(V,E) } \) with n leaves. Vertices are labeled \( { \{1,2, \dots,n,} \)\( {\dots,|V|\} } \), where the leaves are vertices \( { \{1,2, \dots,n\} } \).
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Finite sets \( { S_1,S_2, \dots, S_n } \), where set \( { S_i \subseteq \mathcal{S} } \) is assigned to leaf i, for all \( { i=1 \dots n } \).
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A non-negative integer t
Output: All solutions of the form \( { (x_1,x_2, \dots,} \)\( {x_n, \dots,x_{|V|}) } \) such that:
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\( { x_i \in \mathcal{S} } \) for all \( { i =1 \dots |V| } \)
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\( { x_i \in S_i } \) for all \( { i=1 \dots n...
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Recommended Reading
Blanchette M (2001) Algorithms for phylogenetic footprinting. In: RECOMB01: proceedings of the fifth annual international conference on computational molecular biology, Montreal. ACM, pp 49–58
Blanchette M (2002) Algorithms for phylogenetic footprinting. PhD thesis, University of Washington
Blanchette M, Schwikowski B, Tompa M (2002) Algorithms for phylogenetic footprinting. J Comput Biol 9(2):211–223
Blanchette M, Tompa M (2002) Discovery of regulatory elements by a computational method for phylogenetic footprinting. Genome Res 12:739–748
Blanchette M, Tompa M (2003) Footprinter: a program designed for phylogenetic footprinting. Nucleic Acids Res 31(13):3840–3842
Buhler J, Tompa M (2001) Finding motifs using random projections. In: RECOMB01: proceedings of the fifth annual international conference on computational molecular biology, pp 69–76
Elias I (2006) Settling the intractability of multiple alignment. J Comput Biol 13:1323–1339
Fang F, Blanchette M (2006) Footprinter3: phylogenetic footprinting in partially alignable sequences. Nucleic Acids Res 34(2):617–620
Fitch WM (1971) Toward defining the course of evolution: minimum change for a specified tree topology. Syst Zool 20:406–416
Huson DH, Bryant D (2006) Application of phylogenetic networks in evolutionary studies. Mol Biol Evol 23(2):254–267
Sankoff D, Rousseau P (1975) Locating the vertices of a Steiner tree in arbitrary metric space. Math Program 9:240–246
Sankoff DD (1975) Minimal mutation trees of sequences. SIAM J Appl Math 28:35–42
Shigemizu D, Maruyama O (2004) Searching for regulatory elements of alternative splicing events using phylogenetic footprinting. In: Proceedings of the fourth workshop on algorithms for bioinformatics. Lecture notes in computer science. Springer, Berlin, pp 147–158
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Blanchette, M. (2016). Substring Parsimony. In: Kao, MY. (eds) Encyclopedia of Algorithms. Springer, New York, NY. https://doi.org/10.1007/978-1-4939-2864-4_409
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DOI: https://doi.org/10.1007/978-1-4939-2864-4_409
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