Birth of scale-free molecular networks and the number of  distinct DNA and protein domains per genome

doi:10.1093/bioinformatics/17.10.988

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Bioinformatics Vol. 17 no. 10 2001
Pages 988-996
© 2001 Oxford University Press

Birth of scale-free molecular networks and the number of distinct DNA and protein domains per genome

Andrey Rzhetsky ¹^,2^,* and Shawn M. Gomez ¹

¹ Columbia Genome Center
² Department of Medical Informatics, Columbia University, New York, NY 10032, USA

Received on April 20, 2001 ; revised on July 13, 2001 ; accepted on July 13, 2001

Motivation: Current growth in the field of genomics has provided a number of exciting approaches to the modeling of evolutionary mechanisms within the genome. Separately, dynamical and statistical analyses of networks such as the World Wide Web and the social interactions existing between humans have shown that thesenetworks can exhibit common fractal properties—includingthe property of being scale-free. This work attempts to bridgethese two fields and demonstrate that the fractal propertiesof molecular networks are linked to the fractal propertiesof their underlying genomes.

Results: We suggest a stochastic model capable of describingthe evolutionary growth of metabolic or signal-transductionnetworks. This model generates networks that share importantstatistical properties (so-called scale-free behavior) withreal molecular networks. In particular, the frequency ofvertices connected to exactly k other vertices follows apower-law distribution. The shape of this distribution remainsinvariant to changes in network scale: a small subgraph hasthe same distribution as the complete graph from which itis derived. Furthermore, the model correctly predicts thatthe frequencies of distinct DNA and protein domains alsofollow a power-law distribution. Finally, the model leads toa simple equation linking the total number of different DNAand protein domains in a genome with both the total numberof genes and the overall network topology.

Availability: MatLab (MathWorks, Inc.) programs described inthis manuscript are available on request from the authors.

Contact: ar345{at}columbia.edu

^* To whom correspondence should be addressed.

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