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A double combinatorial approach to discovering patterns in biological sequences

  • Marie -France Sagot
  • Alain Viari
Conference paper
Part of the Lecture Notes in Computer Science book series (LNCS, volume 1075)

Abstract

We present in this paper an algorithm for finding degenerated common features by multiple comparison of a set of biological sequences (nucleic acids or proteins). The features that are of interest to us are words in the sequences. The algorithm uses the concept of a model we introduced earlier for locating these features. A model can be seen as a generalization of a consensus pattern as defined by Waterman [42]. It is an object against which the words in the sequences are compared and which serves as an identifier for the groups of similar ones. The algorithm given here innovates in relation to our previous work in that the models are defined over what we call a weighted combinatorial cover. This is a collection of sets among all possible subsets of the alphabet Σ of nucleotides or amino acids, including the wild card {Σ}, with a weight attached to each of these sets indicating the number of times it may appear in a model. In this way, we explore both the space of models and that of alphabets. The words that are related to a model defined over such a combinatorial cover, and thus considered to be similar, are then the ones that either belong to the model or present at most a certain number of errors with a nearest element of it. We use two algorithmic ideas that allow us to deal with such double combinatorics, one concerns a left-to-right minimality of the sets composing a model, the other involves making a sketch of the solution space before exploring it in detail.

Keywords

multiple comparison weighted combinatorial cover wild card model degenerated feature left-to-right minimality of sets sketch of solution space DNA protein 

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Copyright information

© Springer-Verlag Berlin Heidelberg 1996

Authors and Affiliations

  • Marie -France Sagot
    • 1
    • 2
  • Alain Viari
    • 1
  1. 1.Atelier de BioInformatiqueCPASO - URA CNRS 448, Section de Recherche de l'Institut CurieParisFrance
  2. 2.Institut Gaspard MongeUniversité de Marne la ValléeNoisy le Grand

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