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Exploring Complexity in Biological Systems: Building Blocks, Modules, and Network Connections

This article provides an overview of the complexity in biological systems, discussing the components, functional modules, and network connections. It explores the concept of a "bio-system" and its properties, as well as the importance of reverse engineering and quantitative modeling in understanding these systems.

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Exploring Complexity in Biological Systems: Building Blocks, Modules, and Network Connections

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  1. System-Biophysik Überblick Life‘s Complexity Pyramid(Oltvai-Barabasi, Science 10/25/02) System Functional Modules Building Blocks Components

  2. Out- put Input Zum Begriff „Bio-System“ Eigenschaften * Komponenten (Spezien) * Netzwerkartige Verknüpfungen (kinetische Raten) * Substrukturen (Knoten,Module, Motive) * Funktionelle Input => Output Relation Ziel * Erforschung der „Bauprinzipen“ (reverse engineering) Vorsicht : Bauprinzip nicht „rational“ sondern Ergebnis eines Evolutionprozesses * Erstellung quantitativer Modelle zur Beschreibung des Systems

  3. Boehring-Mennheim Large Metabolic Networks: the „usual“ view

  4. Network Measures

  5. Network Measures

  6. Network Measures

  7. Network Measures

  8. Network Types Random Scale-Free Hierarchical

  9. Network Types Random Scale-Free Hierarchical

  10. Network Types Random Scale-Free Hierarchical

  11. Metabolic networksat different levels of description

  12. Metabolic networks:Rather Hierarchical than Scale-free

  13. g=2.2 g=2.2 Jeong et al Nature Oct 00

  14. Scale-free complex networks

  15. Highly clustered „small worlds“ Nature June 4, 1998 Aug 1999 http://smallworld.sociology.columbia.edu

  16. 19 degrees  Finite size scaling: create a network with N nodes with Pin(k) and Pout(k) < l > = 0.35 + 2.06 log(N) 19 degrees of separation R. Albert et al Nature (99) based on 800 million webpages [S. Lawrence et al Nature (99)] nd.edu < l > IBM A. Broder et al WWW9 (00) 19 degrees of separation: “The WWW is very big but not very wide” 3 l15=2 [1,2,5] l17=4 [1,3,4,6,7] … < l > = ?? 6 1 4 7 5 2

  17. Nature July 27, 2000

  18. Yeast protein interaction network Topological robustness 10% proteins with k<5 are lethal BUT 60% proteins with k>15 are lethal red = lethal, green = non-lethal orange = slow growth yellow = unknown

  19. Construction of Scale-free networks These scale-free networks do not arise by chance alone. Erdős and Renyi (1960) studied a model of growth for graphs in which, at each step, two nodes are chosen uniformly at random and a link is inserted between them. The properties of these random graphs are not consistent with the properties observed in scale-free networks, and therefore a model for this growth process is needed. The scale-free properties of the Web have been studied, and its distribution of links is very close to a power law, because there are a few Web sites with huge numbers of links, which benefit from a good placement in search engines and an established presence on the Web. Those sites are the ones that attract more of the new links. This has been called the winners take all phenomenon. The mostly widely accepted generative model is Barabasi and Albert's (1999) rich get richer generative model in which each new Web page creates links to existent Web pages with a probability distribution which is not uniform, but proportional to the current in-degree of Web pages. This model was originally discovered by Derek de Solla Price in 1965 under the term cumulative advantage, but did not reach popularity until Barabasi rediscovered the results under its current name. According to this process, a page with many in-links will attract more in-links than a regular page. This generates a power-law but the resulting graph differs from the actual Web graph in other properties such as the presence of small tightly connected communities. More general models and networks characteristics have been proposed and studied (for a review see the book by Dorogovtsev and Mendes). A different generative model is the copy model studied by Kumar et al. (2000), in which new nodes choose an existent node at random and copy a fraction of the links of the existent node. This also generates a power law. However, if we look at communities of interests in a specific topic, discarding the major hubs of the Web, the distribution of links is no longer a power law but resembles more a normal distribution, as observed by Pennock et al. (2002) in the communities of the home pages of universities, public companies, newspapers and scientists. Based on these observations, the authors propose a generative model that mixes preferential attachment with a baseline probability of gaining a link. en.wikipedia.org

  20. The origin of the scale-free topology and hubsin biological networks Evolutionary origin of scale-free networks

  21. The origin of the scale-free topology and hubsin biological networks Evolutionary origin of scale-free networks

  22. http://www.genome.jp/kegg/pathway.html#cellular -> MCP, CheY

  23. ZusammenfassungBiologische Netzwerke Netzwerke haben eine hierachische Struktur - Komponenten, Blöcke, funktionelle Module, System Universelle Eigenschaften komplexer Netzwerke * „small world property“ (kurze Verbindungswege) * skaleninvarianz (Verteilung der „connectivity“) * Starke Tendenz zu Clustern Große Zahl und inhomogene Komponenten Experimenteller Input durch: * Hochdurchsatztechniken / Datenbanken * Systematische Literaturanalyse (data-mining)

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