A control theoretic framework for modular analysis and design of biomolecular networks

Abstract Control theory has been instrumental for the analysis and design of a number of engineering systems, including aerospace and transportation systems, robotics and intelligent machines, manufacturing chains, electrical, power, and information networks. In the past several years, the ability of de novo creating biomolecular networks and of measuring key physical quantities has come to a point in which quantitative analysis and design of biological systems is possible. While a modular approach to analyze and design complex systems has proven critical in most control theory applications, it is still subject of debate whether a modular approach is viable in biomolecular networks. In fact, biomolecular networks display context-dependent behavior, that is, the input/output dynamical properties of a module change once this is part of a network. One cause of context dependence, similar to what found in many engineering systems, is retroactivity, that is, the effect of loads applied on a module by downstream systems. In this paper, we focus on retroactivity and review techniques, based on nonlinear control and dynamical systems theory, that we have developed to quantify the extent of modularity of biomolecular systems and to establish modular analysis and design techniques.

[1]  Domitilla Del Vecchio,et al.  Retroactivity Attenuation in Bio-Molecular Systems Based on Timescale Separation , 2011, IEEE Transactions on Automatic Control.

[2]  Thierry Emonet,et al.  Understanding Modularity in Molecular Networks Requires Dynamics , 2009, Science Signaling.

[3]  H. Sauro,et al.  MAPK Cascades as Feedback Amplifiers , 2007, 0710.5195.

[4]  Max Donath,et al.  American Control Conference , 1993 .

[5]  Ron Weiss,et al.  Engineering life: building a fab for biology. , 2006, Scientific American.

[6]  Jeff Hasty,et al.  Translational cross talk in gene networks. , 2013, Biophysical journal.

[7]  L. Serrano,et al.  Engineering stability in gene networks by autoregulation , 2000, Nature.

[8]  Donald L. Schilling,et al.  Electronic Circuits: Discrete and Integrated , 1980 .

[9]  J. C Willems Behaviors, Latent Variables, and Interconnections (Special Issue on Mathematical Approaches to System Engineering Expository Articles) , 1999 .

[10]  U. Alon Network motifs: theory and experimental approaches , 2007, Nature Reviews Genetics.

[11]  Christiaan Heij,et al.  Introduction to mathematical systems theory , 1997 .

[12]  Domitilla Del Vecchio,et al.  Engineering principles in bio-molecular systems: From retroactivity to modularity , 2009, 2009 European Control Conference (ECC).

[13]  J. Stelling,et al.  Modular analysis of biological networks. , 2012, Advances in experimental medicine and biology.

[14]  D. Fell Metabolic control analysis: a survey of its theoretical and experimental development. , 1992, The Biochemical journal.

[15]  R. Murray,et al.  Timing molecular motion and production with a synthetic transcriptional clock , 2011, Proceedings of the National Academy of Sciences.

[16]  H. Sauro,et al.  Quantitative analysis of signaling networks. , 2004, Progress in biophysics and molecular biology.

[17]  J. Keasling,et al.  Design of a dynamic sensor-regulator system for production of chemicals and fuels derived from fatty acids , 2012, Nature Biotechnology.

[18]  D. Lauffenburger Cell signaling pathways as control modules: complexity for simplicity? , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[19]  M. Khammash,et al.  Stochastic Modeling and Analysis of Genetic Networks , 2005, Proceedings of the 44th IEEE Conference on Decision and Control.

[20]  N. Kampen,et al.  Stochastic processes in physics and chemistry , 1981 .

[21]  D. Gillespie The chemical Langevin equation , 2000 .

[22]  R. Weiss,et al.  Multi-input Rnai-based Logic Circuit for Identification of Specific , 2022 .

[23]  Domitilla Del Vecchio,et al.  How slaves affect a master module in gene transcription networks , 2013, 52nd IEEE Conference on Decision and Control.

[24]  Julio Saez-Rodriguez,et al.  Dissecting the puzzle of life: modularization of signal transduction networks , 2005, Comput. Chem. Eng..

[25]  W. Bentley,et al.  Plasmid‐encoded protein: The principal factor in the “metabolic burden” associated with recombinant bacteria , 1990, Biotechnology and bioengineering.

[26]  Eduardo D Sontag,et al.  The energy costs of insulators in biochemical networks. , 2013, Biophysical journal.

[27]  T. Hwa,et al.  Interdependence of Cell Growth and Gene Expression: Origins and Consequences , 2010, Science.

[28]  Eduardo Sontag,et al.  Load-Induced Modulation of Signal Transduction Networks , 2011, Science Signaling.

[29]  A. Ninfa,et al.  Development of Genetic Circuitry Exhibiting Toggle Switch or Oscillatory Behavior in Escherichia coli , 2003, Cell.

[30]  E. Krebs,et al.  The MAPK signaling cascade , 1995, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[31]  Richard M. Murray,et al.  Design of insulating devices for in vitro synthetic circuits , 2009, Proceedings of the 48h IEEE Conference on Decision and Control (CDC) held jointly with 2009 28th Chinese Control Conference.

[32]  J. Collins,et al.  Programmable cells: interfacing natural and engineered gene networks. , 2004, Proceedings of the National Academy of Sciences of the United States of America.

[33]  Ruth J. Williams,et al.  Queueing up for Enzymatic Processing: Correlated Signaling through Coupled Degradation , 2022 .

[34]  Jan C. Willems,et al.  Introduction to mathematical systems theory: a behavioral approach, Texts in Applied Mathematics 26 , 1999 .

[35]  Eduardo Sontag,et al.  Optimal Length and Signal Amplification in Weakly Activated Signal Transduction Cascades , 2003, math/0311357.

[36]  D. Gillespie Exact Stochastic Simulation of Coupled Chemical Reactions , 1977 .

[37]  B. Alberts,et al.  Molecular Biology of the Cell (Fifth Edition) , 2008 .

[38]  M. Bennett,et al.  A fast, robust, and tunable synthetic gene oscillator , 2008, Nature.

[39]  Ruth E Baker,et al.  Mathematical models of morphogen gradients and their effects on gene expression , 2012, Wiley interdisciplinary reviews. Developmental biology.

[40]  Domitilla Del Vecchio,et al.  Retroactivity to the input in complex gene transcription networks , 2012, 2012 IEEE 51st IEEE Conference on Decision and Control (CDC).

[41]  Domitilla Del Vecchio,et al.  Design and Analysis of an Activator-Repressor Clock in E. Coli , 2007, 2007 American Control Conference.

[42]  Daniel M. Stoebel,et al.  The Cost of Expression of Escherichia coli lac Operon Proteins Is in the Process, Not in the Products , 2008, Genetics.

[43]  R. Weiss,et al.  Foundations for the design and implementation of synthetic genetic circuits , 2012, Nature Reviews Genetics.

[44]  J. C. Willems Behaviors,Latent Variables,and lnterconnections (システム工学への数理的アプローチ特集) , 1999 .

[45]  A. Kremling,et al.  Modular analysis of signal transduction networks , 2004, IEEE Control Systems.

[46]  J. Keasling,et al.  Microbial engineering for the production of advanced biofuels , 2012, Nature.

[47]  Zhen Xie,et al.  Molecular Systems Biology Peer Review Process File Synthetic Incoherent Feed-forward Circuits Show Adaptation to the Amount of Their Genetic Template. Transaction Report , 2022 .

[48]  Leif H. Finkel,et al.  BIOENGINEERING MODELS OF CELL SIGNALING , 2007 .

[49]  Domitilla Del Vecchio,et al.  Long signaling cascades tend to attenuate retroactivity. , 2011, Biophysical journal.

[50]  Domitilla Del Vecchio,et al.  Optimal design of phosphorylation-based insulation devices , 2013, 2013 American Control Conference.

[51]  F. Bruggeman,et al.  Introduction to systems biology. , 2007, EXS.

[52]  Anant Agarwal,et al.  Foundations of Analog and Digital Electronic Circuits , 2005 .

[53]  P. Olver Nonlinear Systems , 2013 .

[54]  D. Koshland,et al.  An amplified sensitivity arising from covalent modification in biological systems. , 1981, Proceedings of the National Academy of Sciences of the United States of America.

[55]  Antonis Papachristodoulou,et al.  Model decomposition and reduction tools for large-scale networks in systems biology , 2011, Autom..

[56]  Yoosik Kim,et al.  Substrate-dependent control of MAPK phosphorylation in vivo , 2011, Molecular systems biology.

[57]  Eduardo Sontag,et al.  Modular cell biology: retroactivity and insulation , 2008, Molecular systems biology.

[58]  Christopher A. Voigt,et al.  Genetic programs constructed from layered logic gates in single cells , 2012, Nature.

[59]  Singiresu S Rao,et al.  A Comparative Study of Evidence Theories in the Modeling, Analysis, and Design of Engineering Systems , 2013 .

[60]  R. Heinrich,et al.  The Regulation of Cellular Systems , 1996, Springer US.

[61]  W. Ebeling Stochastic Processes in Physics and Chemistry , 1995 .

[62]  Domitilla Del Vecchio,et al.  Retroactivity controls the temporal dynamics of gene transcription. , 2013, ACS synthetic biology.

[63]  Vadim I. Utkin,et al.  A singular perturbation analysis of high-gain feedback systems , 1977 .

[64]  Domitilla Del Vecchio,et al.  On the compromise between retroactivity attenuation and noise amplification in gene regulatory networks , 2009, Proceedings of the 48h IEEE Conference on Decision and Control (CDC) held jointly with 2009 28th Chinese Control Conference.

[65]  L. Tsimring,et al.  A synchronized quorum of genetic clocks , 2009, Nature.

[66]  Richard M. Murray,et al.  Resource competition as a source of non-minimum phase behavior in transcription-translation systems , 2013, 52nd IEEE Conference on Decision and Control.

[67]  Miles Miller,et al.  Modular Design of Artificial Tissue Homeostasis: Robust Control through Synthetic Cellular Heterogeneity , 2012, PLoS Comput. Biol..

[68]  Reinhart Heinrich,et al.  Mathematical models of protein kinase signal transduction. , 2002, Molecular cell.

[69]  J. Hopfield,et al.  From molecular to modular cell biology , 1999, Nature.

[70]  J. Blenis,et al.  ERK and p38 MAPK-Activated Protein Kinases: a Family of Protein Kinases with Diverse Biological Functions , 2004, Microbiology and Molecular Biology Reviews.

[71]  A. Arkin,et al.  Contextualizing context for synthetic biology – identifying causes of failure of synthetic biological systems , 2012, Biotechnology journal.

[72]  Edda Klipp,et al.  Systems Biology in Practice , 2005 .

[73]  J. Collins,et al.  Construction of a genetic toggle switch in Escherichia coli , 2000, Nature.

[74]  Christopher C. Moser,et al.  Natural engineering principles of electron tunnelling in biological oxidation–reduction , 1999, Nature.

[75]  Rolf Müller,et al.  Crosstalk of oncogenic and prostanoid signaling pathways , 2004, Journal of Cancer Research and Clinical Oncology.

[76]  Soha Hassoun,et al.  Identification of Biochemical Network Modules Based on Shortest Retroactive Distances , 2011, PLoS Comput. Biol..

[77]  P. Wolynes,et al.  Abduction , 2021, A Logical Theory of Causality.

[78]  Domitilla Del Vecchio,et al.  Tuning Genetic Clocks Employing DNA Binding Sites , 2012, PloS one.

[79]  E. Andrianantoandro,et al.  Synthetic biology: new engineering rules for an emerging discipline , 2006, Molecular systems biology.

[80]  Priscilla E. M. Purnick,et al.  The second wave of synthetic biology: from modules to systems , 2009, Nature Reviews Molecular Cell Biology.

[81]  Domitilla Del Vecchio,et al.  Signaling properties of a covalent modification cycle are altered by a downstream target , 2010, Proceedings of the National Academy of Sciences.

[82]  M. Elowitz,et al.  A synthetic oscillatory network of transcriptional regulators , 2000, Nature.