Your search keyword '"Morris, Connor J"' showing total 2 results

1. Current computational methods for enzyme design.

Author

Coates, Talmage L., Young, Naomi, Jarrett, Austin J., Morris, Connor J., Moody, James D., and Corte, Dennis Della

Subjects

ENZYMES, PROTEIN engineering

Abstract

Computational enzyme design has made great strides over the last five years. Traditional methods of enzyme design require synthesis and evaluation of many mutations. Computational enzyme design has emerged as a powerful tool to predict how specific mutations modify a protein's activity, stability, and/or selectivity. Such computational approaches can evaluate many mutations and reduce the load of in vitro work by identifying mutations likely to accomplish design objectives. Computational approaches can explore mutational spaces inaccessible in traditional mutagenesis. Computational methods reduce cost and time compared with experimental approaches. We review the efficacy and key differences of computational enzyme design methods as published in recent studies. The included articles used computational methods to design enzymes, were published no earlier than 2015, met design objectives, and verified results in vitro. [ABSTRACT FROM AUTHOR]

Published

2021

2. Engineering and application of a biosensor with focused ligand specificity.

Author

Della Corte, Dennis, van Beek, Hugo L., Syberg, Falk, Schallmey, Marcus, Tobola, Felix, Cormann, Kai U., Schlicker, Christine, Baumann, Philipp T., Krumbach, Karin, Sokolowsky, Sascha, Morris, Connor J., Grünberger, Alexander, Hofmann, Eckhard, Schröder, Gunnar F., and Marienhagen, Jan

Subjects

CORYNEBACTERIUM glutamicum, CHEMICAL precursors, AMINO acids, BIOSENSORS, ENZYMES

Abstract

Cell factories converting bio-based precursors to chemicals present an attractive avenue to a sustainable economy, yet screening of genetically diverse strain libraries to identify the best-performing whole-cell biocatalysts is a low-throughput endeavor. For this reason, transcriptional biosensors attract attention as they allow the screening of vast libraries when used in combination with fluorescence-activated cell sorting (FACS). However, broad ligand specificity of transcriptional regulators (TRs) often prohibits the development of such ultra-high-throughput screens. Here, we solve the structure of the TR LysG of Corynebacterium glutamicum, which detects all three basic amino acids. Based on this information, we follow a semi-rational engineering approach using a FACS-based screening/counterscreening strategy to generate an l-lysine insensitive LysG-based biosensor. This biosensor can be used to isolate l-histidine-producing strains by FACS, showing that TR engineering towards a more focused ligand spectrum can expand the scope of application of such metabolite sensors. Transcriptional biosensors represent powerful tools for the screening of vast strain libraries, but the broad ligand specificity of some transcriptional regulators (TRs) can prohibit such applications. Here authors present the engineering of a LysG-based biosensor with a focused ligand specificity to isolate L-histidine-producing strains. [ABSTRACT FROM AUTHOR]

Published

2020