Constructing novel biological systems that function in a robust and predictable manner requires better methods for discovering new functional molecules and for optimizing their assembly in novel biological contexts. By enabling functional diversification and optimization in the absence of detailed mechanistic understanding, directed evolution is a powerful complement to ‘rational’ engineering approaches. Aided by clever selection schemes, directed evolution has generated new parts for genetic circuits, cell–cell communication systems, and non-natural metabolic pathways in bacteria
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
There are near-to-infinite combinations of possibilities for evolution to happen within nature, maki...
Conventional in vivo directed evolution methods have primarily linked the biomolecule’s activity to ...
Constructing novel biological systems that function in a robust and predictable manner requires bett...
Tailor-made: Discussed herein is the ability to adapt biology's mechanisms for innovation and optimi...
Life on Earth is incredibly diverse. Yet, underneath that diversity, there are a number of constants...
Developing technologies such as unnatural amino acid mutagenesis, non-natural cofactor engineering, ...
Directed evolution circumvents our profound ignorance of how a protein's sequence encodes its functi...
The stunning array of features and functions exhibited by proteins in nature should convince most sc...
Synthetic circuits offer great promise for generating insights into nature's underlying design princ...
Directed evolution can generate a remarkable range of new enzyme properties. Alternate substrate spe...
Protein engineering has been the most attractive strategy for biologists to redesign enzymes. As the...
Synthetic biology emerged as an engineering discipline to design and construct artificial biological...
Directed evolution is a widely-used engineering strategy for improving the stabilities or biochemica...
We will explore the work of Andrew Ellington, a biochemist focused on synthetic evolution of biomole...
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
There are near-to-infinite combinations of possibilities for evolution to happen within nature, maki...
Conventional in vivo directed evolution methods have primarily linked the biomolecule’s activity to ...
Constructing novel biological systems that function in a robust and predictable manner requires bett...
Tailor-made: Discussed herein is the ability to adapt biology's mechanisms for innovation and optimi...
Life on Earth is incredibly diverse. Yet, underneath that diversity, there are a number of constants...
Developing technologies such as unnatural amino acid mutagenesis, non-natural cofactor engineering, ...
Directed evolution circumvents our profound ignorance of how a protein's sequence encodes its functi...
The stunning array of features and functions exhibited by proteins in nature should convince most sc...
Synthetic circuits offer great promise for generating insights into nature's underlying design princ...
Directed evolution can generate a remarkable range of new enzyme properties. Alternate substrate spe...
Protein engineering has been the most attractive strategy for biologists to redesign enzymes. As the...
Synthetic biology emerged as an engineering discipline to design and construct artificial biological...
Directed evolution is a widely-used engineering strategy for improving the stabilities or biochemica...
We will explore the work of Andrew Ellington, a biochemist focused on synthetic evolution of biomole...
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
There are near-to-infinite combinations of possibilities for evolution to happen within nature, maki...
Conventional in vivo directed evolution methods have primarily linked the biomolecule’s activity to ...