Designing synthetic networks in silico: a generalised evolutionary algorithm approach

Smith, Robert W.; Sluijs, Bob van; Fleck, Christian

doi:10.1186/s12918-017-0499-9

Cited by 23 publications

(20 citation statements)

References 46 publications

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“…Given that our angular metric data record the percentage of cells ON across a population, we consider a stochastic modelling approach through the implementation of our model using the We utilise global optimisation via a genetic algorithm (GA) in order to parameterise our stochastic model (Materials and Methods). Such algorithms have been widely used in mathematical model inference problems relating to, for example, synthetic oscillators and gene regulatory networks [49][50][51]. We optimise the model against the adapted angular metric of two circuits that, together, present the full range of possible dynamical responses in equal measure ([GFPmCherry GFP STOP GFP] and [GFPmCherry STOP mCherry mCherry], Table 2).…”

Section: Distributions Of Ensemble Simulations Reveal Consistent Perfmentioning

confidence: 99%

A mechanistic model of the BLADE platform predicts performance characteristics of 256 different synthetic DNA recombination circuits

Bowyer

Ding

Weinberg³

et al. 2020

Preprint

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Boolean logic and arithmetic through DNA excision (BLADE) is a recently developed platform for implementing inducible and logical control over gene expression in mammalian cells, which has the potential to revolutionise cell engineering for therapeutic applications. This 2-input 2-output platform can implement 256 different logical circuits that exploit the specificity and stability of DNA recombination. Here, we develop the first mechanistic mathematical model of the 2-input BLADE platform based on Cre-and Flp-mediated DNA excision. After calibrating the model on experimental data from two circuits, we demonstrate close agreement between model outputs and data on the other 111 circuits that have so far been experimentally constructed using the 2-input BLADE platform. Model simulations of the remaining 143 circuits that have yet to be tested experimentally predict excellent performance of the 2-input BLADE platform across the range of possible circuits.Circuits from both the tested and untested subsets that perform less well consist of a disproportionally high number of STOP sequences. Model predictions suggested that circuit performance declines with a decrease in recombinase expression and new experimental data was generated that confirms this relationship.

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Section: Distributions Of Ensemble Simulations Reveal Consistent Perfmentioning

confidence: 99%

A mechanistic model of the BLADE platform predicts performance characteristics of 256 different synthetic DNA recombination circuits

Bowyer

Ding

Weinberg³

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…1B). A variety of different approaches to designing synthetic circuits is available [18,13,26]. However, to confront many application-derived limitations, circuit designs must be often tailored to rigorous specifications.…”

Section: Introductionmentioning

confidence: 99%

“…GAs are evolution-inspired metaheuristics that allow to optimize populations of individuals [14]. Such evolutionary approaches were successfully applied to various biological questions [12], e.g., design of synthetic networks and, in particular, design of single-circuit classifiers [26,16]. Due to the high flexibility of GAs in terms of design and parameters, the algorithm may be efficiently adapted to the distributed classifier problem.…”

Section: Introductionmentioning

confidence: 99%

Designing Distributed Cell Classifier Circuits using a Genetic Algorithm

Nowicka

Siebert

2019

Preprint

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Cell classifiers are decision-making synthetic circuits that allow in vivo cell-type classification. Their design is based on finding a relationship between differential expression of miRNAs and the cell condition. Such biological devices have shown potential to become a valuable tool in cancer treatment as a new type-specific cell targeting approach. So far, only single-circuit classifiers were designed in this context. However, reliable designs come with high complexity, making them difficult to assemble in the lab. Here, we apply so-called Distributed Classifiers (DC) consisting of simple single circuits, that decide collectively according to a threshold function. Such architecture potentially simplifies the assembly process and provides design flexibility. Here, we present a genetic algorithm that allows the design and optimization of DCs. Breast cancer case studies show that DCs perform with high accuracy on realworld data. Optimized classifiers capture biologically relevant miRNAs that are cancer-type specific. The comparison to a single-circuit classifier design approach shows that DCs perform with significantly higher accuracy than individual circuits. The algorithm is implemented as an open source tool.

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“…But in their work, enzymes are available whenever needed without considering how GRN regulates this process. In [4] The author uses 6 segment of fixed length binary string to represent a gene. The dynamics of this article is extended to concentration profiles, oscillating dynamics and signal responses.…”

Section: Introductionmentioning

confidence: 99%

In silicon emergence of an autonomous artificial metabolic system

Chen

2019

Preprint

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In this work, we establish and evolve an artificial metabolic system in silicon to shed light on how the metabolic mechanism emerged. This system is composed of two subsystems: the artificial genome subsystem (AGS) and the artificial metabolite subsystem (AMS). The whole system is designed to be capable of being autonomous: the dynamics of AGS is capable of situating itself to the dynamics of AMS to provide it with enzymes in the right time and quantity; the dynamics of AMS is capable of implementing the metabolic function and harvest energy so as to pay back the energy consumption of AGS. This kind of autonomous state requires an intricate structure of the AGS. So it is almost impossible to be predetermined manually. With the help of an evolutionary computational method that has a hierarchical mutational structure, the artificial metabolic system with this kind of autonomous state eventually emerged in silicon. We find that ATP and ADP molecules have an important role in making the state of the system autonomous. We also find that the emerged structure of AGS ensemble existing biological structures in the natural cells.

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Designing synthetic networks in silico: a generalised evolutionary algorithm approach

Cited by 23 publications

References 46 publications

A mechanistic model of the BLADE platform predicts performance characteristics of 256 different synthetic DNA recombination circuits

A mechanistic model of the BLADE platform predicts performance characteristics of 256 different synthetic DNA recombination circuits

Designing Distributed Cell Classifier Circuits using a Genetic Algorithm

In silicon emergence of an autonomous artificial metabolic system

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