Synthetic circuits offer great promise for generating insights into nature's underlying design principles or forward engineering novel biotechnology applications. However, construction of these circuits is not straightforward. Synthetic circuits generally consist of components optimized to function in their natural context, not in the context of the synthetic circuit. Combining mathematical modeling with directed evolution offers one promising means for addressing this problem. Modeling identifies mutational targets and limits the evolutionary search space for directed evolution, which alters circuit performance without the need for detailed biophysical information. This review examines strategies for integrating modeling and directed evolu...
Synthetic biology has exploited genetic engineering technology and systems theory to decipher the na...
The evolution of phenotype is often based on changes in gene expression rather than changes in prote...
Synthetic genetic regulatory networks (or genetic circuits) can operate in complex biochemical envir...
A major goal of synthetic biology is to develop a deeper understanding of biological design principl...
The construction of artificial networks of transcriptional control elements in living cells represen...
Synthetic biology emerged as an engineering discipline to design and construct artificial biological...
Cells navigate environments, communicate and build complex patterns by initiating gene expression in...
Motivation: In principle, novel genetic circuits can be engineered using standard parts with well-un...
Constructing novel biological systems that function in a robust and predictable manner requires bett...
Mathematical models and synthetic gene circuits are powerful tools to develop novel treatments for p...
The field of synthetic gene circuits is concerned with engineering novel gene expression dynamics in...
Life on Earth is incredibly diverse. Yet, underneath that diversity, there are a number of constants...
The concept of reengineering and rewiring of pathways and gene regulatory networks for novel uses, a...
Synthetic biology combines biological parts from different sources in order to engineer non-native, ...
abstract: Synthetic biology is a novel method that reengineers functional parts of natural genes of ...
Synthetic biology has exploited genetic engineering technology and systems theory to decipher the na...
The evolution of phenotype is often based on changes in gene expression rather than changes in prote...
Synthetic genetic regulatory networks (or genetic circuits) can operate in complex biochemical envir...
A major goal of synthetic biology is to develop a deeper understanding of biological design principl...
The construction of artificial networks of transcriptional control elements in living cells represen...
Synthetic biology emerged as an engineering discipline to design and construct artificial biological...
Cells navigate environments, communicate and build complex patterns by initiating gene expression in...
Motivation: In principle, novel genetic circuits can be engineered using standard parts with well-un...
Constructing novel biological systems that function in a robust and predictable manner requires bett...
Mathematical models and synthetic gene circuits are powerful tools to develop novel treatments for p...
The field of synthetic gene circuits is concerned with engineering novel gene expression dynamics in...
Life on Earth is incredibly diverse. Yet, underneath that diversity, there are a number of constants...
The concept of reengineering and rewiring of pathways and gene regulatory networks for novel uses, a...
Synthetic biology combines biological parts from different sources in order to engineer non-native, ...
abstract: Synthetic biology is a novel method that reengineers functional parts of natural genes of ...
Synthetic biology has exploited genetic engineering technology and systems theory to decipher the na...
The evolution of phenotype is often based on changes in gene expression rather than changes in prote...
Synthetic genetic regulatory networks (or genetic circuits) can operate in complex biochemical envir...