Your search keyword '"Rei-Hsing Hu"' showing total 3 results

1. Systematic Biological Filter Design with a Desired I/O Filtering Response Based on Promoter-RBS Libraries

Author

Rei-Hsing Hu, Che Lin, Bor-Sen Chen, Hsiao-Chun Cheng, Chih-Chun Chang, Chih-Yuan Hsu, and Zhen-Ming Pan

Subjects

Binding Sites, Computer science, Applied Mathematics, Matched filter, Detector, Topology (electrical circuits), Synthetic biology, Filter design, Band-pass filter, Cascade, Robustness (computer science), Genetics, Synthetic Biology, Promoter Regions, Genetic, Algorithm, Ribosomes, Algorithms, Biotechnology, Gene Library

Abstract

In this study, robust biological filters with an external control to match a desired input/output (I/O) filtering response are engineered based on the well-characterized promoter-RBS libraries and a cascade gene circuit topology. In the field of synthetic biology, the biological filter system serves as a powerful detector or sensor to sense different molecular signals and produces a specific output response only if the concentration of the input molecular signal is higher or lower than a specified threshold. The proposed systematic design method of robust biological filters is summarized into three steps. Firstly, several well-characterized promoter-RBS libraries are established for biological filter design by identifying and collecting the quantitative and qualitative characteristics of their promoter-RBS components via nonlinear parameter estimation method. Then, the topology of synthetic biological filter is decomposed into three cascade gene regulatory modules, and an appropriate promoter-RBS library is selected for each module to achieve the desired I/O specification of a biological filter. Finally, based on the proposed systematic method, a robust externally tunable biological filter is engineered by searching the promoter-RBS component libraries and a control inducer concentration library to achieve the optimal reference match for the specified I/O filtering response.

Published

2015

2. Systematic design methodology for robust genetic transistors based on I/O specifications via promoter- RBS libraries.

Author

Yi-Ying Lee, Chih-Yuan Hsu, Ling-Jiun Lin, Chih-Chun Chang, Hsiao-Chun Cheng, Tsung-Hsien Yeh, Rei-Hsing Hu, Che Lin, Zhen Xie, and Bor-Sen Chen

Subjects

GENETIC algorithms, RIBOSOMES, RIBOSOMAL DNA, TRANSISTORS, ELECTRONIC circuit design

Abstract

Background Synthetic genetic transistors are vital for signal amplification and switching in genetic circuits. However, it is still problematic to efficiently select the adequate promoters, Ribosome Binding Sides (RBSs) and inducer concentrations to construct a genetic transistor with the desired linear amplification or switching in the Input/Output (I/O) characteristics for practical applications. Results Three kinds of promoter-RBS libraries, i.e., a constitutive promoter-RBS library, a repressorregulated promoter-RBS library and an activator-regulated promoter-RBS library, are constructed for systematic genetic circuit design using the identified kinetic strengths of their promoter-RBS components. According to the dynamic model of genetic transistors, a design methodology for genetic transistors via a Genetic Algorithm (GA)-based searching algorithm is developed to search for a set of promoter-RBS components and adequate concentrations of inducers to achieve the prescribed I/O characteristics of a genetic transistor. Furthermore, according to design specifications for different types of genetic transistors, a look-up table is built for genetic transistor design, from which we could easily select an adequate set of promoter-RBS components and adequate concentrations of external inducers for a specific genetic transistor. Conclusion This systematic design method will reduce the time spent using trial-and-error methods in the experimental procedure for a genetic transistor with a desired I/O characteristic. We demonstrate the applicability of our design methodology to genetic transistors that have desirable linear amplification or switching by employing promoter-RBS library searching. [ABSTRACT FROM AUTHOR]

Published

2013

3. Systematic design methodology for robust genetic transistors based on I/O specifications via promoter-RBS libraries

Author

Che Lin, Yi-Ying Lee, Chih-Yuan Hsu, Rei-Hsing Hu, Ling-Jiun Lin, Tsung-Hsien Yeh, Bor-Sen Chen, Hsiao-Chun Cheng, Chih-Chun Chang, and Zhen Xie

Subjects

Systematic design methodology, Biology, law.invention, law, Structural Biology, Modelling and Simulation, Electronic engineering, Promoter Regions, Genetic, Promoter-RBS library, Design methods, Molecular Biology, Electronic circuit, Genetics, Genetic transistor, Binding Sites, Models, Genetic, Systems Biology, Applied Mathematics, Linear amplification, Transistor, Construct (python library), equipment and supplies, Computer Science Applications, Modeling and Simulation, Design specifications, Ribosomes, Input/Output (I/O) characteristics, Signal amplification, Algorithms, Research Article

Abstract

Background Synthetic genetic transistors are vital for signal amplification and switching in genetic circuits. However, it is still problematic to efficiently select the adequate promoters, Ribosome Binding Sides (RBSs) and inducer concentrations to construct a genetic transistor with the desired linear amplification or switching in the Input/Output (I/O) characteristics for practical applications. Results Three kinds of promoter-RBS libraries, i.e., a constitutive promoter-RBS library, a repressor-regulated promoter-RBS library and an activator-regulated promoter-RBS library, are constructed for systematic genetic circuit design using the identified kinetic strengths of their promoter-RBS components. According to the dynamic model of genetic transistors, a design methodology for genetic transistors via a Genetic Algorithm (GA)-based searching algorithm is developed to search for a set of promoter-RBS components and adequate concentrations of inducers to achieve the prescribed I/O characteristics of a genetic transistor. Furthermore, according to design specifications for different types of genetic transistors, a look-up table is built for genetic transistor design, from which we could easily select an adequate set of promoter-RBS components and adequate concentrations of external inducers for a specific genetic transistor. Conclusion This systematic design method will reduce the time spent using trial-and-error methods in the experimental procedure for a genetic transistor with a desired I/O characteristic. We demonstrate the applicability of our design methodology to genetic transistors that have desirable linear amplification or switching by employing promoter-RBS library searching.