Engineering synthetic regulatory circuits in plants

Tessema K. Kassaw; Alberto J. Donayre-Torres; Mauricio S. Antunes; Kevin J. Morey; June I. Medford

doi:10.1016/j.plantsci.2018.04.005

Engineering synthetic regulatory circuits in plants

Tessema K. Kassaw
, Alberto J. Donayre-Torres
, Mauricio S. Antunes
, Kevin J. Morey
, June I. Medford

Research output: Contribution to journal › Article › peer-review

33 Scopus citations

Abstract

Plant synthetic biology is a rapidly emerging field that aims to engineer genetic circuits to function in plants with the same reliability and precision as electronic circuits. These circuits can be used to program predictable plant behavior, producing novel traits to improve crop plant productivity, enable biosensors, and serve as platforms to synthesize chemicals and complex biomolecules. Herein we introduce the importance of developing orthogonal plant parts and the need for quantitative part characterization for mathematical modeling of complex circuits. In particular, transfer functions are important when designing electronic-like genetic controls such as toggle switches, positive/negative feedback loops, and Boolean logic gates. We then discuss potential constraints and challenges in synthetic regulatory circuit design and integration when using plants. Finally, we highlight current and potential plant synthetic regulatory circuit applications.

Original language	English
Pages (from-to)	13-22
Number of pages	10
Journal	Plant Science
Volume	273
DOIs	https://doi.org/10.1016/j.plantsci.2018.04.005
State	Published - Aug 2018
Externally published	Yes

Keywords

Genetic circuit
Mathematical modeling
Orthogonal
Plant synthetic biology
Synthetic biology
Transfer function

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10.1016/j.plantsci.2018.04.005

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title = "Engineering synthetic regulatory circuits in plants",

abstract = "Plant synthetic biology is a rapidly emerging field that aims to engineer genetic circuits to function in plants with the same reliability and precision as electronic circuits. These circuits can be used to program predictable plant behavior, producing novel traits to improve crop plant productivity, enable biosensors, and serve as platforms to synthesize chemicals and complex biomolecules. Herein we introduce the importance of developing orthogonal plant parts and the need for quantitative part characterization for mathematical modeling of complex circuits. In particular, transfer functions are important when designing electronic-like genetic controls such as toggle switches, positive/negative feedback loops, and Boolean logic gates. We then discuss potential constraints and challenges in synthetic regulatory circuit design and integration when using plants. Finally, we highlight current and potential plant synthetic regulatory circuit applications.",

keywords = "Genetic circuit, Mathematical modeling, Orthogonal, Plant synthetic biology, Synthetic biology, Transfer function",

author = "Kassaw, \{Tessema K.\} and Donayre-Torres, \{Alberto J.\} and Antunes, \{Mauricio S.\} and Morey, \{Kevin J.\} and Medford, \{June I.\}",

note = "Publisher Copyright: {\textcopyright} 2018 Elsevier B.V.",

year = "2018",

month = aug,

doi = "10.1016/j.plantsci.2018.04.005",

language = "English",

volume = "273",

pages = "13--22",

journal = "Plant Science",

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AU - Kassaw, Tessema K.

AU - Donayre-Torres, Alberto J.

AU - Antunes, Mauricio S.

AU - Morey, Kevin J.

AU - Medford, June I.

PY - 2018/8

Y1 - 2018/8

N2 - Plant synthetic biology is a rapidly emerging field that aims to engineer genetic circuits to function in plants with the same reliability and precision as electronic circuits. These circuits can be used to program predictable plant behavior, producing novel traits to improve crop plant productivity, enable biosensors, and serve as platforms to synthesize chemicals and complex biomolecules. Herein we introduce the importance of developing orthogonal plant parts and the need for quantitative part characterization for mathematical modeling of complex circuits. In particular, transfer functions are important when designing electronic-like genetic controls such as toggle switches, positive/negative feedback loops, and Boolean logic gates. We then discuss potential constraints and challenges in synthetic regulatory circuit design and integration when using plants. Finally, we highlight current and potential plant synthetic regulatory circuit applications.

AB - Plant synthetic biology is a rapidly emerging field that aims to engineer genetic circuits to function in plants with the same reliability and precision as electronic circuits. These circuits can be used to program predictable plant behavior, producing novel traits to improve crop plant productivity, enable biosensors, and serve as platforms to synthesize chemicals and complex biomolecules. Herein we introduce the importance of developing orthogonal plant parts and the need for quantitative part characterization for mathematical modeling of complex circuits. In particular, transfer functions are important when designing electronic-like genetic controls such as toggle switches, positive/negative feedback loops, and Boolean logic gates. We then discuss potential constraints and challenges in synthetic regulatory circuit design and integration when using plants. Finally, we highlight current and potential plant synthetic regulatory circuit applications.

KW - Genetic circuit

KW - Mathematical modeling

KW - Orthogonal

KW - Plant synthetic biology

KW - Synthetic biology

KW - Transfer function

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DO - 10.1016/j.plantsci.2018.04.005

M3 - Article

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AN - SCOPUS:85045462969

SN - 0168-9452

VL - 273

SP - 13

EP - 22

JO - Plant Science

JF - Plant Science

ER -

Engineering synthetic regulatory circuits in plants

Abstract

Keywords

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