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Leveraging Biological Robustness to Improve Engineered Systems

Leveraging Biological Robustness to Improve Engineered Systems. Michael Mayo, PhD. Research Physicist Environmental Genomics and Systems Biology Team Environmental Laboratory US Army Engineer Research & Development Center (ERDC) VCU Computer Science Department 9 October 2012.

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Leveraging Biological Robustness to Improve Engineered Systems

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  1. Leveraging Biological Robustness to Improve Engineered Systems Michael Mayo, PhD Research Physicist Environmental Genomics and Systems Biology Team Environmental Laboratory US Army Engineer Research & Development Center (ERDC) VCU Computer Science Department 9 October 2012

  2. Leveraging Biological Robustness to Improve Engineered Systems Robustness “The behavior of a system is termed robust if that behavior is qualitatively normal in the face of substantial changes to the system components.” J.W. Little et al., EMBO J. 18, 4299 (1999). “…the preservation of particular characteristics despite uncertainty in system components.” M.E. Csets and J.C. Doyle Science 295, 1664 (2002). “…biological circuits are not fine-tuned to exercise their functions only for precise values of their biochemical parameters. Instead, they must be able to function under a rangeof different parameters.” A. Wagner Proc. Natl. Acad. Sci. USA 102, 11775 (2005).

  3. Leveraging Biological Robustness to Improve Engineered Systems Example – Circadian oscillator R = mRNA concentration (transcription) P = protein concentration (translation) P’ = post-translational modification (dimerization/phosphorylation) P = fraction of parameter space that yield oscillating solutions. A. Wagner Proc. Natl. Acad. Sci. USA 102, 11775 (2005). Main Result “Changing parameters at random in a topology with high P is more likely to yield a parameter combination leading to circadian oscillations than in a topology with low P.” In certain topologies, oscillations robust against parameter fluctuations.

  4. Leveraging Biological Robustness to Improve Engineered Systems Why use mathematical modeling? • Translates the problem into unambiguous language of mathematics. • Mathematical model is a laboratory to conduct simulated experiments, where it is too expensive or otherwise unethical to acquire experimental data. • Hypotheses or other “scenarios” (like oscillator topology) can be tested or assessed more easily and rapidly. Drawback: Models are only as good as what go into them.

  5. Leveraging Biological Robustness to Improve Engineered Systems Case Study Mammalian Gas-Exchange

  6. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Branching point at which velocity from convection = 0.

  7. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange M. Mayo et al., Phys. Rev. E 85, 011115 (2012).

  8. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Cayley tree: Main Idea Leaves/canopy Using conservation principles, solve for current entering branch, across the branching point. Root M. Mayo et al., Phys. Rev. E 85, 011115 (2012).

  9. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Current into the tree 2r = diameter of branch D = diffusion coefficient of O2 in air C0 = concentration of O2 at entrance to acinar airways m = number of branching at each branch point (m=2 in lungs) n = depth of tree/orders of branching points L = length of a branch Λ = D/W = exploration length

  10. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Current into the tree M. Mayo et al., Phys. Rev. E 85, 011115 (2012).

  11. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Diffusional screening and current plateaus M. Mayo et al., Phys. Rev. E 85, 011115 (2012). J.S Andrade, Jr. et al., Europhys. Lett. 55, 573 (2001).

  12. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Mammalian gas-exchange Experimental validation of model predictions M. Mayo, P. Pfeifer, and C. Hou*. 2012. Reverse engineering the robustness of mammalian lung. Reverse Engineering, ed. A.C. Telea. InTech Publisher, Boston, pp.243-262

  13. Leveraging Biological Robustness to Improve Engineered Systems Summary • Competition between the O2 transport across the alveolar membranes and its screening from surface sites generates plateaus. • Plateaus represent regions of maximum insensitivity (i.e. robustness) of the O2 current to “changes” in the Thiele modulus (i.e. changes to D or W, or both). • Plateaus emerge independent of any feedback loop. • Experimental values for current lie in the plateau, but next to the “no screening” (NS) regime, providing flexibility of the O2 current to moderate surface “damage.”

  14. Leveraging Biological Robustness to Improve Engineered Systems Case Study Teleost Reproductive Axis

  15. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis Chemical FSH/LH Hypothalamus-Pituitary VTG Liver Ovary Fecundity E2/T Population http://www.tpwd.state.tx.us/fishboat/fish/images/inland_species/fathead1.jpg Time Hypothalamus-Pituitary-Gonadal (HPG) axis – synthesis and regulation of reproductive the hormones 17β-estradiol (E2) and testosterone (T).

  16. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis G.T. Ankley et al., Aquat. Toxicol. 92, 168 (2009).

  17. Leveraging Biological Robustness to Improve Engineered Systems D.L. Villeneuve et al., Environ. HealthPerspect.117, 624 (2009). Network inference reveals that Androgen Receptor regulation may lead to compensation of E2 in lower doses. G. Ankley et al., Toxicol. Sci. 67, 121 (2002). Control 2 10 50 Fadrozole (ng/ml) GRANULOSA T. Habib, M. Mayo, E.J. Perkins et al., (in preparation). THECA

  18. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis The conceptual and mathematical model Built from equations of the type: Creation flux Elimination flux (i.e. turnover, degradation etc) M. Mayo et al., (in preparation)

  19. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis M. Mayo et al., (in preparation)

  20. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis Mathematical model: relative error to parameter variation M. Mayo et al., (in preparation)

  21. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Teleost Reproductive Axis Mathematical model: predictive capability M. Mayo et al., (in preparation) K=19.53 nM n=1.75

  22. Leveraging Biological Robustness to Improve Engineered Systems Summary • Relative error analysis reveals that only a few components of HPG axis are “fragile,” but these fragilities are at critical regulation points of the network (i.e. cholesterol transport). • Compensation arises from feedback through androgen receptor complex, which activates key steroidogenic genes. • Competition between aromatase creation and sequestration results in long-term robustness of E2 profile when these effects are balanced.

  23. Leveraging Biological Robustness to Improve Engineered Systems Case Study Coupling Among Motifs in Transcriptional Networks

  24. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Motif Coupling in Gene Networks S. Mangan and U. Alon, Proc. Natl. Acad. Sci. USA 21, 11980 (2003). R. Milo et al., Science 298, 824 (2002). Feed-forward loops are one of the most common three-node motifs, but mostly only studied before in isolation.

  25. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Motif Coupling in Gene Networks Maximally coupled Sparse connectivity Null model Each link can act as either an activator or an inhibitor of transcriptional activity. Other work in progress demonstrates that transcription factors play the role of nodes 1,2,4 and 5 justifying the study of coupling among the TFs only.

  26. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Motif Coupling in Gene Networks Mathematical model activation repression Maximum transcriptional activity Degradation rate Affinity of inhibitor (activator) to repress (induce) transcriptional activity Parameter space will be searched using a log-uniform distribution with sufficient point density

  27. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Motif Coupling in Gene Networks Experimental design Black line Blue line Timing is measured and correlated with network topology

  28. Leveraging Biological Robustness to Improve Engineered Systems Case Study: Motif Coupling in Gene Networks Experimental design http://openwetware.org/wiki/Biomolecular_Breadboards Feed-forward loops will be constructed experimentally to determine the primary variables that control correlations between robustness and topology.

  29. Leveraging Biological Robustness to Improve Engineered Systems Connection with Engineered Systems

  30. Leveraging Biological Robustness to Improve Engineered Systems http://nice.che.rpi.edu/Research/fuel_cells.htm S. Kjelstrup, M.-O. Coppens, J. G. Phaoroah, and P. Pfeifer,Energy Fuels 24, 5097 (2010).

  31. Leveraging Biological Robustness to Improve Engineered Systems Acknowledgements Case Study: Mammalian gas-exchange Stefan Gheorghiu – Center for Complexity Studies, Bucharest Romania. Peter Pfeifer – Chair and Professor of Physics, University of Missouri. Chen Hou – Associate Professor, Missouri University of Science & Technology. Case Study: Teleost Reproductive Axis Ed Perkins – Senior Scientist, Environmental Laboratory ERDC. Karen Watanabe – Associate Professor, Oregon Health & Science University (OHSU). Natalia Garcia-Reyero – Associate Research Professor, Mississippi State University. TanwirHabib – Staff Scientist, Badger Technical Services. Dan Villeneuve – Research Biologist, Environmental Protection Agency (EPA) Gary Ankley – Senior Scientist, Environmental Protection Agency (EPA) Case Study: Coupling Among Motifs and Transcriptional Netowrks PreetamGhosh – Assistant Professor, Department of Computer Science, VCU. VijenderChaitankar, Ahmed Abdelzaher, BhanuKishore– Department of Computer Science, VCU.

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