TY - JOUR
T1 - Engineering Translational Resource Allocation Controllers
T2 - Mechanistic Models, Design Guidelines, and Potential Biological Implementations
AU - Darlington, Alexander P.S.
AU - Kim, Juhyun
AU - Jiménez, José I.
AU - Bates, Declan G.
N1 - Publisher Copyright:
© 2018 American Chemical Society.
PY - 2018/11/16
Y1 - 2018/11/16
N2 - The use of orthogonal ribosomes in combination with dynamic resource allocation controllers is a promising approach for relieving the negative effects of cellular resource limitations on the modularity of synthetic gene circuits. Here, we develop a detailed mechanistic model of gene expression and resource allocation, which when simplified to a tractable level of complexity, allows the rational design of translational resource allocation controllers. Analysis of this model reveals a fundamental design trade-off: that reducing coupling acts to decrease gene expression. Through a sensitivity analysis of the experimentally tunable controller parameters, we identify how each controller design parameter affects the overall closed-loop behavior of the system, leading to a detailed set of design guidelines for optimally managing this trade-off. On the basis of our designs, we evaluated a number of alternative potential experimental implementations of the proposed system using commonly available biological components. Finally, we show that the controller is capable of dynamically allocating ribosomes as needed to restore modularity in a number of more complex synthetic circuits, such as the repressilator, and activation cascades composed of multiple interacting modules.
AB - The use of orthogonal ribosomes in combination with dynamic resource allocation controllers is a promising approach for relieving the negative effects of cellular resource limitations on the modularity of synthetic gene circuits. Here, we develop a detailed mechanistic model of gene expression and resource allocation, which when simplified to a tractable level of complexity, allows the rational design of translational resource allocation controllers. Analysis of this model reveals a fundamental design trade-off: that reducing coupling acts to decrease gene expression. Through a sensitivity analysis of the experimentally tunable controller parameters, we identify how each controller design parameter affects the overall closed-loop behavior of the system, leading to a detailed set of design guidelines for optimally managing this trade-off. On the basis of our designs, we evaluated a number of alternative potential experimental implementations of the proposed system using commonly available biological components. Finally, we show that the controller is capable of dynamically allocating ribosomes as needed to restore modularity in a number of more complex synthetic circuits, such as the repressilator, and activation cascades composed of multiple interacting modules.
KW - feedback control
KW - modularity
KW - orthogonal ribosomes
KW - resource competition
UR - http://www.scopus.com/inward/record.url?scp=85055498274&partnerID=8YFLogxK
U2 - 10.1021/acssynbio.8b00029
DO - 10.1021/acssynbio.8b00029
M3 - Article
C2 - 30346148
AN - SCOPUS:85055498274
SN - 2161-5063
VL - 7
SP - 2485
EP - 2496
JO - ACS Synthetic Biology
JF - ACS Synthetic Biology
IS - 11
ER -