Aaron J O Lewis scite author profile

Multiplex automated genome engineering (MAGE) is a powerful technology for in vivo genome editing that uses synthetic single-stranded DNA (ssDNA) to introduce targeted modifications directly into the Escherichia coli chromosome. MAGE is a cyclical process that involves transformation of ssDNA (by electroporation) followed by outgrowth, during which bacteriophage homologous recombination proteins mediate annealing of ssDNAs to their genomic targets. By iteratively introducing libraries of mutagenic ssDNAs targeting multiple sites, MAGE can generate combinatorial genetic diversity in a cell population. Alternatively, MAGE can introduce precise mutant alleles at many loci for genome-wide editing or for recoding projects that are not possible with other methods. In recent technological advances, MAGE has been improved by strain modifications and selection techniques that enhance allelic replacement. This protocol describes the manual execution of MAGE wherein each cycle takes ≈ 2.5 h, which, if carried out by two people, allows ≈ 10 continuous cycles of MAGE-based mutagenesis per day.

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Mechanism of an intramembrane chaperone for multipass membrane proteins

Smalinskaitė

Kim

Lewis

et al. 2022

Nature

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A unified evolutionary origin for the ubiquitous protein transporters SecY and YidC

Lewis

Hegde

2021

BMC Biol

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Background Protein transporters translocate hydrophilic segments of polypeptide across hydrophobic cell membranes. Two protein transporters are ubiquitous and date back to the last universal common ancestor: SecY and YidC. SecY consists of two pseudosymmetric halves, which together form a membrane-spanning protein-conducting channel. YidC is an asymmetric molecule with a protein-conducting hydrophilic groove that partially spans the membrane. Although both transporters mediate insertion of membrane proteins with short translocated domains, only SecY transports secretory proteins and membrane proteins with long translocated domains. The evolutionary origins of these ancient and essential transporters are not known. Results The features conserved by the two halves of SecY indicate that their common ancestor was an antiparallel homodimeric channel. Structural searches with SecY’s halves detect exceptional similarity with YidC homologs. The SecY halves and YidC share a fold comprising a three-helix bundle interrupted by a helical hairpin. In YidC, this hairpin is cytoplasmic and facilitates substrate delivery, whereas in SecY, it is transmembrane and forms the substrate-binding lateral gate helices. In both transporters, the three-helix bundle forms a protein-conducting hydrophilic groove delimited by a conserved hydrophobic residue. Based on these similarities, we propose that SecY originated as a YidC homolog which formed a channel by juxtaposing two hydrophilic grooves in an antiparallel homodimer. We find that archaeal YidC and its eukaryotic descendants use this same dimerisation interface to heterodimerise with a conserved partner. YidC’s sufficiency for the function of simple cells is suggested by the results of reductive evolution in mitochondria and plastids, which tend to retain SecY only if they require translocation of large hydrophilic domains. Conclusions SecY and YidC share previously unrecognised similarities in sequence, structure, mechanism, and function. Our delineation of a detailed correspondence between these two essential and ancient transporters enables a deeper mechanistic understanding of how each functions. Furthermore, key differences between them help explain how SecY performs its distinctive function in the recognition and translocation of secretory proteins. The unified theory presented here explains the evolution of these features, and thus reconstructs a key step in the origin of cells.

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Merlin: Computer-Aided Oligonucleotide Design for Large Scale Genome Engineering with MAGE

et al. 2016

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Genome engineering technologies now enable precise manipulation of organism genotype, but can be limited in scalability by their design requirements. Here we describe Merlin ( http://merlincad.org ), an open-source web-based tool to assist biologists in designing experiments using multiplex automated genome engineering (MAGE). Merlin provides methods to generate pools of single-stranded DNA oligonucleotides (oligos) for MAGE experiments by performing free energy calculation and BLAST scoring on a sliding window spanning the targeted site. These oligos are designed not only to improve recombination efficiency, but also to minimize off-target interactions. The application further assists experiment planning by reporting predicted allelic replacement rates after multiple MAGE cycles, and enables rapid result validation by generating primer sequences for multiplexed allele-specific colony PCR. Here we describe the Merlin oligo and primer design procedures and validate their functionality compared to OptMAGE by eliminating seven AvrII restriction sites from the Escherichia coli genome.

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Aaron J O Lewis

Rapid editing and evolution of bacterial genomes using libraries of synthetic DNA

Mechanism of an intramembrane chaperone for multipass membrane proteins

A unified evolutionary origin for the ubiquitous protein transporters SecY and YidC

Merlin: Computer-Aided Oligonucleotide Design for Large Scale Genome Engineering with MAGE

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