Given the explosion in human genetic data, new high-throughput genetic methods are necessary for studying variants and elucidating their role in human disease. In Chapter I, I will expand on this concept and describe current methods for genetically modifying human cells. In E. coli, Multiplex Automatable Genome Engineering (MAGE) is a powerful tool that enables the targeting of multiple genomic loci simultaneously with synthetic oligos that are recombined at high frequencies in an optimized strain. MAGE as a method has two components: organism-specific optimization of oligo recombination parameters and a protein capable of increasing recombination frequencies
Biological functions of a cell are encoded within its genome and regulated through complex genetic n...
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
Disrupting the interaction between primase and helicase in Escherichia coli increases Okazaki fragme...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Recent advances allow multiplexed genome engineering in E. coli, employing easily designed oligonucl...
A defining cellular engineering challenge is the development of high-throughput and automated method...
Disrupting the interaction between primase and helicase in Escherichia coli increases Okazaki fragme...
We present a method for identifying genomic modifications that optimize a complex phenotype through ...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Genome-scale engineering of living organisms requires precise and economical methods to effi-ciently...
The ability to introduce precise genomic modifications in human cells has profound implications for ...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Technology is a key driving force in the advancement of scientific discoveries. While DNA sequencing...
Multiplex genome engineering is a standalone recombineering tool for large-scale programming and acc...
Improving our ability to build and test DNA sequences will accelerate progress in biology. Multiplex...
Biological functions of a cell are encoded within its genome and regulated through complex genetic n...
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
Disrupting the interaction between primase and helicase in Escherichia coli increases Okazaki fragme...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Recent advances allow multiplexed genome engineering in E. coli, employing easily designed oligonucl...
A defining cellular engineering challenge is the development of high-throughput and automated method...
Disrupting the interaction between primase and helicase in Escherichia coli increases Okazaki fragme...
We present a method for identifying genomic modifications that optimize a complex phenotype through ...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Genome-scale engineering of living organisms requires precise and economical methods to effi-ciently...
The ability to introduce precise genomic modifications in human cells has profound implications for ...
Multiplex Automated Genome Engineering (MAGE) allows simultaneous mutagenesis of multiple target sit...
Technology is a key driving force in the advancement of scientific discoveries. While DNA sequencing...
Multiplex genome engineering is a standalone recombineering tool for large-scale programming and acc...
Improving our ability to build and test DNA sequences will accelerate progress in biology. Multiplex...
Biological functions of a cell are encoded within its genome and regulated through complex genetic n...
The emerging field of synthetic biology evolved from biological research much the same way synthetic...
Disrupting the interaction between primase and helicase in Escherichia coli increases Okazaki fragme...