Network motifs that recur across species, including gene regulatory and protein–protein interaction networks
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- 作者:Robert Borotkanics ; Harold Lehmann
- 关键词:Network motif ; Subgraph ; Cancer ; Toxicology
- 刊名:Archives of Toxicology
- 出版年:2015
- 出版时间:April 2015
- 年:2015
- 卷:89
- 期:4
- 页码:489-499
- 全文大小:1,409 KB
- 参考文献:1. Albert, R, Barabasi, AL (2002) Statistical mechanics of complex networks. Rev Mod Phys 74: pp. 47-97 CrossRef
2. Alon, U (2007) An introduction to systems biology: design principles of biological circuits. Taylor and Francis, Boca Raton
3. Alon, U (2007) Network motifs: theory and experimental approaches. Nat Genet 8: pp. 450-461 CrossRef
4. Barabasi, AL, Albert, R (1999) Emergence of scaling in random networks. Science 286: pp. 509-512 CrossRef
5. Barabasi, AL, Oltvai, ZN (2004) Network biology: understanding the cell’s functional organization. Nat Genet 5: pp. 101-113 CrossRef
6. Davidson, EH, Rast, JP, Oliveri, P, Ransick, A, Calestani, C, Yuh, CH, Minokawa, T, Amore, G, Hinman, V, Arenas-Mena, C, Otim, O, Brown, CT, Livi, CB, Lee, PY, Revilla, R, Rust, AG, Pan, ZJ, Schilstra, MJ, Clarke, PJC, Arnone, MI, Rowen, L, Cameron, RA, McClay, DR, Hood, L, Bolouri, H (2002) A genomic regulatory network for development. Science 295: pp. 1669-1678 CrossRef
7. Dorbin R, Beg QK, Barabasi AL, Oltvai ZN (2004) Aggregation of topological motifs in the / Escherichia coli transcriptional regulatory network. BMC Bioinform 5
8. Duarte, NC, Herrg?rd, MJ, Palsson, B? (2004) Reconstruction and validation of Saccharomyces cerevisiae iND750, a fully compartmentalized genome-scale metabolic model. Genome Res 14: pp. 1298-1309 CrossRef
9. Duarte, NC, Becker, SA, Jamshidi, N, Thiele, I, Mo, ML, Vo, TD, Srivas, R, Palsson, B? (2007) Global reconstruction of the human metabolic network based on genomic and bibliomic data. Proc Natl Acad Sci 104: pp. 1777-1782 CrossRef
10. Eom, Y, Lee, S, Jeong, H (2006) Exploring local structural organization of metabolic networks using subgraph patterns. J Theor Biol 241: pp. 823-829 CrossRef
11. Feist, AM, Scholten, JCM, Palsson, B?, Brockman, FJ, Ideker, T (2006) Modeling methanogenesis with a genome-scale metabolic reconstruction of Methanosarcina barkeri. Mol Syst Biol 2: pp. 0004
12. Gavin, AC, Bosche, M, Krause, R, Grandi, P, Marzioch, M, Bauer, A, Schultz, J, Rick, JM, Michon, AM, Cruciat, CM (2002) Functional organization of the yeast proteome by systematic analysis of protein complexes. Nature 415: pp. 141-147 CrossRef
13. Gonzalez, O, Gronau, S, Falb, M, Pfeiffer, F, Mendoza, E, Zimmerb, R, Oesterhelta, D (2008) Reconstruction, modeling and analysis of Halobacterium salinarum R-1 metabolism. Mol BioSyst 4: pp. 148-159 CrossRef
14. Guelzim, N, Bottani, S, Bourgine, P, Képès, F (2002) Topological and causal structure of the yeast transcriptional regulatory network. Nat Genet 31: pp. 60-63 CrossRef
15. Halbeisen, RE, Gerber, AP (2009) Stress-dependent coordination of transcriptome and translatome in yeast. PLoS Biol 7: pp. e1000105 CrossRef
16. Harbison, CT, Gordon, DB, Lee, TI, Rinaldi, NJ, Macisaac, KD, Danford, TW, Hannett, NM, Tagne, JB, Reynolds, DB, Yoo, J, Jennings, EG, Zeitlinger, J, Pokholok, DK, Kellis, M, Rolfe, PA, Takusagawa, KT, Lander, ES, Gifford, DK, Fraenkel, E, Young, RA (2004) Transcriptional regulatory code of a eukaryotic genome. Nature 431: pp. 99-104 CrossRef
17. Ho, Y, Gruhler, A, Heilbut, A, Bader, GD, Moore, L, Adams, SL, Millar, A, Taylor, P, Bennett, K, Boutilier, K (2002) Systematic identification of protein complexes in Saccharomyces cerevisiae by mass spectrometry. Nature 415: pp. 180-183
文摘
Cellular molecules interact in complex ways, giving rise to a cell’s functional outcomes. Conscientious efforts have been made in recent years to better characterize these patterns of interactions. It has been learned that many of these interactions can be represented abstractly as a network and within a network there in many instances are network motifs. Network motifs are subgraphs that are statistically overrepresented within networks. To date, specific network motifs have been experimentally identified across various species and also within specific, intracellular networks; however, motifs that recur across species and major network types have not been systematically characterized. We reason that recurring network motifs could potentially have important implications and applications for toxicology and, in particular, toxicity testing. Therefore, the goal of this study was to determine the set of intracellular, network motifs found to recur across species of both gene regulatory and protein–protein interaction networks. We report the recurrence of 13 intracellular, network motifs across species. Ten recurring motifs were found across both protein–protein interaction networks and gene regulatory networks. The significant pair motif was found to recur only in gene regulatory networks. The diamond and one-way cycle reversible step motifs were found to recur only in protein–protein interaction networks. This study is the first formal review of recurring, intracellular network motifs across species. Within toxicology, combining our understanding of recurring motifs with mechanism and mode of action knowledge could result in more robust and efficient toxicity testing models. We are sure that our results will support research in applying network motifs to toxicity testing.