DocumentCode
1426887
Title
Biological Information as Set-Based Complexity
Author
Galas, David J. ; Nykter, Matti ; Carter, Gregory W. ; Price, Nathan D. ; Shmulevich, Ilya
Author_Institution
Inst. for Syst. Biol., Seattle, WA, USA
Volume
56
Issue
2
fYear
2010
Firstpage
667
Lastpage
677
Abstract
The significant and meaningful fraction of all the potential information residing in the molecules and structures of living systems is unknown. Sets of random molecular sequences or identically repeated sequences, for example, would be expected to contribute little or no useful information to a cell. This issue of quantitation of information is important since the ebb and flow of biologically significant information is essential to our quantitative understanding of biological function and evolution. Motivated specifically by these problems of biological information, a class of measures is proposed to quantify the contextual nature of the information in sets of objects, based on Kolmogorov´s intrinsic complexity. Such measures discount both random and redundant information and are inherent in that they do not require a defined state space to quantify the information. The maximization of this new measure, which can be formulated in terms of the universal information distance, appears to have several useful and interesting properties, some of which we illustrate with examples.
Keywords
bioinformatics; information theory; large-scale systems; molecular biophysics; Kolmogorov intrinsic complexity; biological information; molecular sequences; random molecular sequences; set-based complexity; universal information distance; Bioinformatics; Biological systems; Chemicals; DNA; Evolution (biology); Heart; RNA; Sequences; State-space methods; Systems biology; Complexity; criticality; information distance; networks; set complexity;
fLanguage
English
Journal_Title
Information Theory, IEEE Transactions on
Publisher
ieee
ISSN
0018-9448
Type
jour
DOI
10.1109/TIT.2009.2037046
Filename
5420290
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