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Bridging the gaps in systems biology

: Cvijovic, M.; Almquist, J.; Hagmar, J.; Hohmann, S.; Kaltenbach, H.-M.; Klipp, E.; Krantz, M.; Mendes, P.; Nelander, S.; Nielsen, J.; Pagnani, A.; Przulj, N.; Raue, A.; Stelling, J.; Stoma, S.; Tobin, F.; Wodke, J.A.H.; Zecchina, R.; Jirstrand, M.


Molecular genetics and genomics : MGG 289 (2014), No.5, pp.727-734
ISSN: 1617-4615 (Print)
ISSN: 1617-4623 (Online)
Journal Article
Fraunhofer FCC ()

Systems biology aims at creating mathematical models, i.e., computational reconstructions of biological systems and processes that will result in a new level of understanding-the elucidation of the basic and presumably conserved "design" and "engineering" principles of biomolecular systems. Thus, systems biology will move biology from a phenomenological to a predictive science. Mathematical modeling of biological networks and processes has already greatly improved our understanding of many cellular processes. However, given the massive amount of qualitative and quantitative data currently produced and number of burning questions in health care and biotechnology needed to be solved is still in its early phases. The field requires novel approaches for abstraction, for modeling bioprocesses that follow different biochemical and biophysical rules, and for combining different modules into larger models that still allow realistic simulation with the computational power availa ble today. We have identified and discussed currently most prominent problems in systems biology: (1) how to bridge different scales of modeling abstraction, (2) how to bridge the gap between topological and mechanistic modeling, and (3) how to bridge the wet and dry laboratory gap. The future success of systems biology largely depends on bridging the recognized gaps.