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Binary vector copy number engineering improves *Agrobacterium*-mediated transformation

Biology

Binary vector copy number engineering improves *Agrobacterium*-mediated transformation

M. J. Szarzanowicz, L. M. Waldburger, et al.

Discover how a team of researchers, including Matthew J. Szarzanowicz and Lucas M. Waldburger, has revolutionized plasmid functionality by enhancing *Agrobacterium*-mediated transformation (AMT) efficiency! Through innovative directed evolution, they've identified mutations that significantly boost transformation rates in various organisms. This groundbreaking framework opens new avenues for precision in prokaryotic genetic engineering.

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Playback language: English
Abstract
The copy number of a plasmid is linked to its functionality, yet there have been few attempts to optimize higher-copy-number mutants for use across diverse origins of replication in different hosts. We use a high-throughput growth-coupled selection assay and a directed evolution approach to rapidly identify origin of replication mutations that influence copy number and screen for mutants that improve *Agrobacterium*-mediated transformation (AMT) efficiency. By introducing these mutations into binary vectors within the plasmid backbone used for AMT, we observe improved transient transformation of *Nicotiana benthamiana* in four diverse tested origins (pVS1, RK2, pSa and BBR1). For the best-performing origin, pVS1, we isolate higher-copy-number variants that increase stable transformation efficiencies by 60–100% in *Arabidopsis thaliana* and 390% in the oleaginous yeast *Rhodosporidium toruloides*. Our work provides an easily deployable framework to generate plasmid copy number variants that will enable greater precision in prokaryotic genetic engineering, in addition to improving AMT efficiency.
Publisher
Nature Biotechnology
Published On
Nov 04, 2024
Authors
Matthew J. Szarzanowicz, Lucas M. Waldburger, Michael Busche, Gina M. Geiselman, Liam D. Kirkpatrick, Alexander J. Kehl, Claudine Tahmin, Rita C. Kuo, Joshua McCauley, Hamreet Pannu, Ruoming Cui, Shuying Liu, Nathan J. Hillson, Jacob O. Brunkard, Jay D. Keasling, John M. Gladden, Mitchell G. Thompson, Patrick M. Shih
Tags
plasmid
Agrobacterium
transformation efficiency
directed evolution
genetic engineering
mutations
copy number

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