DocumentCode
757094
Title
Systems-level insights into cellular regulation: inferring, analysing, and modelling intracellular networks
Author
Christensen, C. ; Thakar, J. ; Albert, R.
Author_Institution
Dept. of Phys., Pennsylvania State Univ., University Park
Volume
1
Issue
2
fYear
2007
fDate
3/1/2007 12:00:00 AM
Firstpage
61
Lastpage
77
Abstract
Genes and gene products interact on several levels, forming transcriptional regulatory-, protein interaction-, metabolic- and signal transduction networks. Genetic, biochemical and molecular biology techniques have been used for decades to identify biological interactions; newly developed high-throughput methods now allow for the construction of genome-level interaction maps. In parallel, high-throughput expression data paired with computational algorithms can be used to infer networks of interactions and causal relationships capable of producing the observed experimental data. Graph-theoretical measures and network models are more and more frequently used to discern functional and evolutionary constraints in the organisation of biological networks. Perhaps most importantly, the combination of interaction and expression information allows the formulation of quantitative and predictive dynamic models. Some of the dominant experimental and computational methods used for the reconstruction or inference of cellular networks are reviewed, also the biological insights that have been obtained from graph-theoretical analysis of these networks, and the extension of static networks into various dynamic models capable of providing a new layer of insight into the functioning of cellular systems is discussed.
Keywords
biochemistry; biology computing; cellular biophysics; genetics; graph theory; molecular biophysics; physiological models; proteins; reviews; biochemical techniques; cellular regulation; evolutionary constraints; functional constraints; gene products; genes; genetic techniques; genome-level interaction maps; graph-theoretical analysis; intracellular networks; metabolic networks; molecular biology techniques; predictive dynamic models; protein interaction networks; quantitative dynamic models; review; signal transduction networks; systems-level insights; transcriptional regulatory networks;
fLanguage
English
Journal_Title
Systems Biology, IET
Publisher
iet
ISSN
1751-8849
Type
jour
DOI
10.1049/iet-syb:20060071
Filename
4140670
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