Electron capture dissociation of gaseous multiply charged ions by Fourier-transform ion cyclotron resonance

SUMMARYGenetic transformation is a powerful means for the improvement of crop plants, but requires labor-and resource-intensive methods. An efficient method for identifying single-copy transgene insertion events from a population of independent transgenic lines is desirable. Currently, transgene copy number is estimated by either Southern blot hybridization analyses or quantitative polymerase chain reaction (qPCR) experiments. Southern hybridization is a convincing and reliable method, but it also is expensive, time-consuming and often requires a large amount of genomic DNA and radioactively labeled probes. Alternatively, qPCR requires less DNA and is potentially simpler to perform, but its results can lack the accuracy and precision needed to confidently distinguish between one-and two-copy events in transgenic plants with large genomes. To address this need, we developed a droplet digital PCR-based method for transgene copy number measurement in an array of crops: rice, citrus, potato, maize, tomato and wheat. The method utilizes specific primers to amplify target transgenes, and endogenous reference genes in a single duplexed reaction containing thousands of droplets. Endpoint amplicon production in the droplets is detected and quantified using sequence-specific fluorescently labeled probes. The results demonstrate that this approach can generate confident copy number measurements in independent transgenic lines in these crop species. This method and the compendium of probes and primers will be a useful resource for the plant research community, enabling the simple and accurate determination of transgene copy number in these six important crop species.

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Genetically modified crops support climate change mitigation

Kovak¹,

Blaustein-Rejto²,

Qaim³

2022

Trends in Plant Science

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Effect of Biochemical and Physiological Response to Salt Stress in Camelina Sativa

Morales

Potlakayala

Soliman

et al. 2017

Communications in Soil Science and Plant Analysis

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The climate benefits of yield increases in genetically engineered crops

Kovak

Qaim

Blaustein-Rejto

2021

Preprint

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The benefits of genetically engineered (GE) crops are systematically underestimated because previous studies did not incorporate the reduction in greenhouse gas (GHG) emissions associated with yield increases. We estimate this impact using the carbon opportunity cost of land use. Our results suggest that the GHG emissions reductions from the yield increases in GE crops are substantial and should be included in future analyses.

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Emma Kovak

Accurate measurement of transgene copy number in crop plants using droplet digital PCR

Genetically modified crops support climate change mitigation

Effect of Biochemical and Physiological Response to Salt Stress in Camelina Sativa

The climate benefits of yield increases in genetically engineered crops

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