Genome-editing techniques are promising tools in plant breeding. To facilitate a more comprehensive understanding of the use of genome editing, EU-SAGE developed an interactive, publicly accessible online database of genome-edited crop plants as described in peer-reviewed scientific publications.
The aim of the database is to inform interested stakeholder communities in a transparent manner about the latest evidence about the use of genome editing in crop plants. Different elements including the plant species, traits, techniques, and applications can be filtered in this database.
Regarding the methodology, a literature search in the bibliographic databases and web pages of governmental agencies was conducted using predefined queries in English. Identifying research articles in other languages was not possible due to language barriers. Patents were not screened.
Peer-reviewed articles were screened for relevance and were included in the database based on pre-defined criteria. The main criterium is that the research article should describe a research study of any crop plant in which a trait has been introduced that is relevant from an agricultural and/or food/feed perspective. The database does neither give information on the stage of development of the crop plant, nor on the existence of the intention to develop the described crop plants to be marketed.
This database will be regularly updated. Please contact us via the following webpage in case you would like to inform us about a new scientific study of crops developed for market-oriented agricultural production as a result of genome editing

Genome Editing Technique

Plant

Displaying 33 results

Traits related to biotic stress tolerance

Oomycete resistance: significantly reduced susceptibility to downy mildew disease (DM). DM is caused by Peronospora belbahrii, a worldwide threat to the basil industry.
(Zhang et al., 2021)
SDN1
CRISPR/Cas
The State University of New Jersey, USA
Enhanced resistance to downy mildew pathogen.
( Hasley et al., 2021 )
SDN1
CRISPR/Cas
University of Hawaii at Manoa, USA
Fungal resistance: higher resistance to Verticillium dahliae infestation. Cotton verticillium wilt/cotton cancer, is a destructive disease, leading to 250-310 million USD economic losses each year in China.
(Zhang et al., 2018)
SDN1
CRISPR/Cas
Chinese Academy of Sciences
Chinese Academy of Agricultural Sciences
Shanxi Academy of Agricultural Sciences, China
Oomycete resistance: resistance against downly mildew disease (DM). DM is caused by Peronospora belbahrii, a worldwide threat to the basil industry.
(Laura et al., 2023)
SDN1
CRISPR/Cas
Research Centre for Vegetable and Ornamental Crops
Institute of Agricultural Biology and Biotechnology
Institute for Sustainable Plant Protection
Research Centre for Olive Fruit and Citrus Crops
University of Pisa
Center for Agricultural Experimentation and Assistance
Institute of Biosciences and Bioresources, Italy
Viral resistance: reduced cotton leaf curl viral (CLCuV) load with asymptomatic plants. <br /> CLCuV causes a very devastating and prevalent disease. It causes huge losses to textile and other industries.
(Shakoor et al., 2023)
SDN1
CRISPR/Cas
University of the Punjab
University of Gujrat, Pakistan
Pacific Biosciences
CureVac Manufacturing GmbH, Germany
Insect resistance: Apolygus lucorum are less attracted to the plant.
(Teng et al., 2024)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Yunnan University
Shanxi Agricultural University
National Plant Protection Scientific Observation and Experiment Station
Biocentury Transgene (China) Co. Ltd., China
Fungal resistance: Enhanced resistance against Verticillium and Fusarium wilt, which threatens the cotton production world wide.
(Zhao et al., 2024)
SDN1
CRISPR/Cas
China Agricultural University
Xinjiang Academy of Agricultural Sciences, China
Insect-resistant plant.
( Wang et al., 2024 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Huanghuai University
Xinjiang Academy of Agricultural Sciences
School of Life Sciences, China

Traits related to improved food/feed quality

High-oleic acid content. Oleic acid has better oxidative stability than linoleic acid due to its monounsaturated nature. High levels of linoleic acid reduces the oxidative stability of cottonseed oil, which can cause rancidity, a short shelf life and production of detrimental trans-fatty acids.
( Chen et al., 2020 )
SDN1
CRISPR/Cas
Cotton Research Center of Shandong Academy of Agricultural Sciences
Huazhong Agricultural University, China
Increased vitamin C content, increased oxidation stress tolerance and increased ascorbate content.
( Zhang et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China

Traits related to increased plant yield and growth

Improved root growth under high and low nitrogen conditions.
( Wang et al., 2017 )
SDN1
CRISPR/Cas
Anhui Agricultural University
Chinese Academy of Agricultural Sciences, China
High temperature germination. Large increases in the maximum temperature for seed germination to allow for the cultivation of the crop in production areas with higher temperature.
( Bertier et al., 2018 )
SDN1
CRISPR/Cas
University of California, USA
Bushy phenotype and increased tiller production.
( Liu et al., 2017 )
SDN1
CRISPR/Cas
Iowa State University, USA
Improve biomass yield and salinity tolerance.
( Guan et al., 2020 )
SDN1
CRISPR/Cas
China Agricultural University
Shandong institute of agricultural sustainable development
Beijing Sure Academy of Biosciences, China
Oklahoma State University, USA
Enhanced photosynthesis and decreased leaf angles for improved plant architecture and high yields.
( An et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University, China
Increased leaf yield of lettuce by delaying the onset of flowering.
( Choi et al., 2022 )
SDN1
CRISPR/Cas
Korea Research Institute of Bioscience and Biotechnology
Korea University of Science and Technology, South Korea
Significantly improved photosynthesis and decreased leaf angles. The plant architecture is ideal for dense planting.
( An et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University, China
Transformation of a climbing woody perennial, developing axillary inflorescences after many years of juvenility, into a compact plant with rapid terminal flower and fruit development.
( Varkonyi-Gasic et al., 2022 )
SDN1
CRISPR/Cas
The New Zealand Institute for Plant &
Food Research Limited (Plant &
Food Research), University of Auckland, New Zealand
Delay in the appearance of flower buds and increased yield.
( Beracochea et al., 2023 )
SDN1
CRISPR/Cas
Consejo Nacional de Investigaciones Científicas Y Técnicas (CONICET)
Instituto Nacional de Tecnología Agropecuaria (INTA), Argentina
Altered branch and petiole angles.
( Kangben et al., 2023 )
SDN1
CRISPR/Cas
Clemson University
HudsonAlpha Institute for Biotechnology
United States Department of Agriculture (USDA)
Cotton incorporated, USA
Butterhead plant architecture.
( Xie et al., 2023 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Wuhan Academy of Agricultural Sciences, China
Late flowering phenotype.
( Liu et al., 2024 )
SDN1
CRISPR/Cas
China Agricultural University, China

Traits related to industrial utilization

Guidance for creating male-sterile lines to facilitate hybrid cotton production. Exploit heterosis for improvement of cotton.
( Ma et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Huanggang Normal University
Xinjiang Academy of Agricultural Sciences
Institute of Cotton Research of Chinese Academy of Agricultural Sciences, China
Bio-fuel production: Reduced lignin content and improved sugar release.
(Park et al., 2017)
SDN1
CRISPR/Cas
Noble Research Institute, USA
Reduced lignin content and S (syringyl lignin)/G (guaiacyl lignin) (S/G) ratio alteration to reduce cell wall recalcitrance and improve bioethanol production. Lignin is a major component of secondary cell walls and contributes to the recalcitrance problem during fermentation.
( Park et al., 2021 )
SDN1
CRISPR/Cas
The Samuel Roberts Noble Foundation
BioEnergy Science Center
University of Tennessee, USA

Traits related to herbicide tolerance

Glyphosate & hppd inhibitor herbicides, for example tembotrione
( D'Halluin et al., 2013 )
SDN2
CRISPR/Cas
Bayer CropScience N.V, Belgium

Traits related to product color/flavour

Color change of the taproot from orange to pink-orange and slightly higher content of α-carotene in the taproot.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Chinese Academy of Agricultural Science, China
Albino phenotype.
( Wang et al., 2018 )
SDN1
CRISPR/Cas
Provincial Key Laboratory of Applied Botany
Guangdong Provincial Key Laboratory of Applied Botany
University of Chinese Academy of Sciences, China
Purple color.
( Xu et al., 2019 )
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Crop modification: albino phenotype.
(Wang et al., 2017)
SDN1
CRISPR/Cas
Huazhong Agricultural University, China
University of Pennsylvania, USA
Color modification due to reduced anthocyanin accumulation.
( Klimek-Chodacka et al., 2018 )
SDN1
CRISPR/Cas
University of Agriculture in Krakow, Poland
East Carolina University
University of Maryland, USA
Reduced citrate content. Citrate is a common primary metabolite which often characterizes fruit flavour.
( Fu et al., 2023 )
SDN1
CRISPR/Cas
Zhejiang University, China
University of Florida, USA
The New Zealand Institute for Plant &
Food Research Limited (Plant &
Food Research) Mt Albert
University of Auckland, New Zealand
Pale purple phenotype due to dramatic decrease of anthocyanins content.
( Duan et al., 2023 )
SDN1
CRISPR/Cas
College of Horticulture, China