genome search | EU-SAGE

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

Displaying 55 results

Traits related to biotic stress tolerance

Resistance to parasitic weed: Phelipanche aegyptiaca. The obligate root parasitic plant causes great damages to important crops and represents one of the most destructive and greatest challenges for the agricultural economy.
(Bari et al., 2019)

SDN1
CRISPR/Cas

Newe Ya’ar Research Center,
Agricultural Research Organization (ARO), Israel
University of California, USA

Viral resistance: increased resistance to infection with the potato virus Y (PVY) and tolerance to salt and osmotic stress. PVY is one of the most economically important potato pathogens
(Makhotenko et al., 2019)

SDN1
CRISPR/Cas

Russia Moscow State University, Russia
Doka Gene Technologies Ltd, USA

Viral resistance: enhanced resistance against chickpea chlorotic dwarf virus (CpCDV). The range of symptoms caused by CpCDV varies from mosaic pattern to streaks to leaf curling and can include browning of the collar region and stunting, foliar chlorosis and necrosis.
(Munir Malik et al., 2022)

SDN1
CRISPR/Cas

University of the Punjab
University of Gujrat, Pakistan
Washington State University, USA

Viral resistance: reduced cassava brown streak disease (CBSD) symptom severity and incidence. CBSD threatens cassava production in West Africa and is a major constraint on cassava production in East and Central Africa.
(Gomez et al., 2019)

SDN1
CRISPR/Cas

University of California
Donald Danforth Plant Science Center, USA

Fungal resistance: Enhanced resistance to powdery mildew, a fungal disease causing great losses in soybean yield and seed quality.
(Bui et al., 2023)

SDN1
CRISPR/Cas

Institute of Biotechnology
University of Science and Technology of Hanoi
Vietnam Academy of Science and Technology
Vietnam Academy of Agriculture Science, Vietnam
Washington University in St. Louis
University of Missouri, USA

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

Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Zhou et al., 2015)

SDN1
CRISPR/Cas

Iowa State University, USA

Viral resistance: increased resistance to turnip mosaic virus (TuMV).
(Lee et al., 2023)

SDN1
CRISPR/Cas

Rural Development Administration
Advanced Institute for Science and Technology, South Korea
North Carolina State University, USA

Bacterial resistance: resistance to different pathogens including Xanthomonas spp., P. syringae and P. capsici.
(de Toledo Thomazella et al., 2016)

SDN1
CRISPR/Cas

University of California, USA

Bacterial resistance: improved resistance to Xanthomonas oryzae, which causes bacterial blight, a devastating rice disease resulting in yield losses.
(Oliva et al., 2019)

SDN1
CRISPR/Cas

International Rice Research Institute, Philippines
University of Missouri
University of Florida
Iowa State University
Donald Danforth Plant Science Center, USA
Université Montpellier, France
Heinrich Heine Universität Düsseldorf
Max Planck Institute for Plant Breeding Research
Erfurt University of Applied Sciences, Germany
Nagoya University, Japan

Visualization of the early stages of Cassava bacterial blight (CBB) infection in vivo. CBB is caused by Xanthomonas axonopodis pv. Manihotis.
( Veley et al., 2021 )

SDN2
CRISPR/Cas

Donald Danforth Plant Science Center, USA
National Root Crops Research Institute, Nigeria

Fungal resistance: broad-spectrum stress tolerance including Pseudoperonospora cubernsis (P. cubensis) resistance. P. cubensis is the causal agent of cucurbit downy mildew, responsible for devastating losses worldwide of cucumber, cantaloupe, pumpkin, watermelon and squash.
(Dong et al., 2023)

SDN1
CRISPR/Cas

Chinese Academy of Agricultural Sciences, China
University of California, USA

Bacterial resistance: Enhanced resistance against hemibiotrophic pathogens M. oryzae and Xanthomonas oryzae pv. oryzae (but increased susceptibility to Cochliobolus miyabeanus)
(Kim et al., 2022)

SDN1
CRISPR/Cas

Seoul National University
Kyung Hee University, South Korea
Pennsylvania State University, USA

Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Shan et al., 2013)

SDN1
TALENs

Chinese Academy of Sciences, University of Electronic Science and Technology of China, China
University of Minnesota, USA

Viral resistance: increased resistance to chickpea chlorotic dwarf virus (CpCDV).
(Malik et al., 2023)

SDN1
CRISPR/Cas

University of the Punjab
University of Gujrat, Pakistan
Washington State University, USA

Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Li et al., 2013)

SDN1
TALENs

Iowa State University, USA
Guangxi University, China

Effective detection of a resistance-breaking strain of tomato spotted wilt virus (TSWV). TSWV causes a great threat to various food crops globally and can cause devastating epidemics.
( Shymanovich et al., 2024 )

SDN1
CRISPR/Cas

North Carolina State University, USA

Fungal resistance: increased resistance to southern leaf blight (SLB), caused by the necrotrophic fungal pathogen Cochliobolus heterostrophus (anamorph Bipolaris maydis). SLB is a major foliar disease which causes significant yield losses in maize worldwide.
(Chen et al., 2023)

SDN1
CRISPR/Cas

Northwest A&
F University, China
Corteva AgriscienceTM
USDA-ARS
North Carolina State University, USA

Fungal resistance: increased resistance to Phytophthora tropicalis. Severe outbreaks can destroy all cacao fruit on a farm. Each year, global cacao production is destroyed with 20-30% by pathogens.
(Fister et al., 2018)

SDN1
CRISPR/Cas

Pennsylvania State University, USA

Broad-spectrum disease resistance without yield loss.
( Sha et al., 2023 )

SDN1
CRISPR/Cas

Huazhong Agricultural University
Chengdu Normal University
Jiangxi Academy of Agricultural Sciences
Anhui Agricultural University
BGI-Shenzhen
Northwest A&
F University
Shandong Academy of Agricultural Sciences, China
Université de Bordeaux, France
University of California
The Joint BioEnergy Institute, USA
University of Adelaide, Australia

Viral resistance: increased control on viral pathogen Banana streak virus (BSV). The BSV integrates in the banana host genome as endogenous BSV (eBSV). When banana plants are stressed, the eBSV produces infectious viral particles and thus the plant develops disease symptoms.
(Tripathi et al., 2019)

SDN1
CRISPR/Cas

International Institute of Tropical Agriculture (IITA), Kenya
University of California, USA

Viral resistance: Reduced viral load and symptoms after bean yellow dwarf virus (BeYDV) infection.
(Baltes et al., 2015)

SDN1
CRISPR/Cas

University of Minnesota
The Ohio State University, USA
Institute of Biophysics ASCR, Czech Republic

Viral resistance: increased resistance against Tobacco Mosaic Virus (TMV).
(Jogam et al., 2023)

SDN1
CRISPR/Cas

Kakatiya University
Center of Innovative and Applied Bioprocessing (DBT-CIAB), India
University of Minnesota
East Carolina University, USA

Bacterial resistance: Xanthomonas citri, causing citrus canker, one of the most serious diseases affecting the global citrus industry.
(Jia et al., 2020)

SDN1
CRISPR/Cas

University of Florida, USA

Bacterial resistance: resistance to Xanthomonas citri, a pathogen causing citrus canker. Citrus canker is one of the most devastating citrus diseases worldwide, causing canker symptoms. Generating disease-resistant varieties is one of the most efficient and environmentally friendly measures for controlling canker.
(Jia et al., 2021)

SDN1
CRISPR/Cas

University of Florida
Citrus Research and Education Center, USA

Fungal resistance: increased resistance against powdery mildew, a destructive disease that threatens cucumber production globally.
(Dong et al., 2023)

SDN1
CRISPR/Cas

Chinese Academy of Agricultural Sciences, China
University of California Davis, USA
Wageningen University &
Research, The Netherlands

Enhanced resistance to downy mildew pathogen.
( Hasley et al., 2021 )

SDN1
CRISPR/Cas

University of Hawaii at Manoa, USA

Viral resistance: Attenuated infection symptoms and reduced viral RNA accumulation, specific for the cucumber mosaic virus (CMV) or tobacco mosaic virus (TMV).
(Zhang et al., 2018)

SDN1
CRISPR/Cas

South China Agricultural University, China
University of Missouri, USA

Fungal resistance: improved resistance to necrotrophic fungus Botrytis cinerea.
(Jeon et al., 2020)

SDN1
CRISPR/Cas

Stanford University, UK
L’Oreal, France
Howard Hughes Medical Institute, USA

Fungal resistance: Reduced pathogenicity to the oomycete Phytophthora palmivora, a destructive pathogen that infects all parts of papaya plants. Increased papain sensitvity of in-vitro growth. Papaya fruits contain papain, a cysteine protease that mediates plant defense against pathogens and insects.
(Gumtow et al., 2018)

SDN1
CRISPR/Cas

University of Hawaii at Manoa, USA

Fungal resistance: enhanced resistance to powdery mildew (Erysiphe necator), a major fungal disease, threatening one of the most economically valuable horticular crops.
(Wan et al., 2020)

SDN1
CRISPR/Cas

Ministry of Agriculture, China
Northwest A&
F University
University of Maryland College Park, USA

Bacterial resistance: Xanthomonas citri, causing citrus canker, one of the most serious diseases affecting the global citrus industry. Citrus is the most produced fruit in the world.
(Jia et al., 2016)

SDN1
CRISPR/Cas

University of Florida, USA

Nematode resistance: resistance against soybean cyst nematode. Plant-parasitic nematode pests result in billions of dollars in realized annual losses worldwide.
(Usovsky et al., 2023)

SDN1
CRISPR/Cas

University of Missouri
University of Georgia
Beltsville Agricultural Research Center, USA

Mutants were compromised in infectivity of Phytophthora palmivora, a destructive oomycete plant pathogen with a wide host range
( Pettongkhao et al., 2022 )

SDN1
CRISPR/Cas

Prince of Songkla University, Thailand
University of Hawaii at Manoa
East-West Center, USA
Sainsbury Laboratory Cambridge University (SLCU), UK

Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Li et al., 2012)

SDN1
TALENs

Iowa State University, USA

Resistance to parasitic weed: Striga spp. The parasitic plant reduces yields of cereal crops worldwide.
(Hao et al., 2023)

SDN1
CRISPR/Cas

University of Nebraska-Lincoln
Pennsylvania State University, USA
International Maize and Wheat Improvement Center (CIMMYT), Senegal
Kenyatta University, Kenya

Traits related to industrial utilization

Generating male sterility lines (MLS). Using MLS in hybrid seed production for monoclinous crops reduces costs and ensures high purity of the varieties because it does not produce pollen and has exserted stigmas.
( Svitashev et al., 2015 )

SDN1
CRISPR/Cas

DuPont Pioneer, USA

Induction of haploid plants and a reduced seed set for rice breeding.
( Yao et al., 2018 )

SDN2
CRISPR/Cas

ZhongGuanCun Life Science Park, China
Syngenta India Limited
Technology Centre
Medchal Mandal, India
Syngenta Crop Protection
LLC
Research Triangle Park, USA

Accelerated abscission. Plant organ abscission is a process important for development and reproductive success,
( Liu et al., 2022 )

SDN1
CRISPR/Cas

Shenyang Agricultural University
Key Laboratory of Protected Horticulture of Ministry of Education, China
University of California at Davis
Crops Pathology and Genetic Research Unit, USA

Hairy root transformation. Hairy roots play a role in multiple processes, ranging from recombinant protein production and metabolic engineering to analyses of rhizosphere physiology and biochemistry.
( Ron et al., 2014 )

SDN1
CRISPR/Cas

University of California
Emory University, USA
University of Cambridge, UK

Accelerate flowering, a rare event under glasshouse conditions. Modified starch.
( Bull et al., 2018 )

SDN3
CRISPR/Cas

Institute of Molecular Plant Biology, Switzerland

Rapid generation of male sterile (MS) bread wheat. MS is an important tool in creating hybrid crop varieties that provide a yield advantage over traditional varieties by harnessing heterosis.
( Singh et al., 2021 )

SDN1
CRISPR/Cas

DuPont Pioneer, USA

Generate self-compatible diploid potato lines for the application of efficient breeding methods.
( Enciso-Rodriguez et al., 2021 )

SDN1
CRISPR/Cas

Michigan State University, USA

Rubber biosynthesis. To accelerate the domestication of Taraxacum kok-saghyz (TK), a plant notable for its ability to produce high molecular weight rubber in its roots and which might be an alternative source of natural rubber.
( Iaffaldano et al., 2016 )

SDN1
CRISPR/Cas

Ohio Agricultural Research and Development Center, 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

Accumulate low levels of alkaloids. Nicotine is the most abundant alkaloid produced in tobacco plants. Switching to cigarettes containing levels of nicotine below the level of sustaining an addiction response will smoke less and/or find it easier to quit. Possibly, the US Food and Drug Administration (FDA) may mandate such reductions in future cigarette products.
( Smith et al., 2022 )

SDN1
CRISPR/Cas

North Carolina State University, USA

Complete reproductive sterility to prevent the spread of highly domesticated, exotic or genetically modified organisms into wild populations.
( Azeez et al., 2021 )

SDN1
CRISPR/Cas

Michigan Technological University, USA

Bio-fuel production: Reduced lignin content and improved sugar release.
(Park et al., 2017)

SDN1
CRISPR/Cas

Noble Research Institute, USA

Bioethanol production: Improved saccharification efficiency without compromising biomass yield.
(Kannan et al., 2017)

SDN1
TALENs

University of Florida
Novozymes North America Inc, USA
Korea Institute of Science and Technology (KIST), South Korea

Stem wood discoloration due to lignin reduction.
( Zhou et al., 2015 )

SDN1
CRISPR/Cas

University of Georgia, USA

Modified wood composition with traits desirable for fiber pulping and lower carbon emissions. The edited wood could bring efficiencies, bioeconomic opportunities and environmental benefits.
( Sulis et al., 2023 )

SDN1
CRISPR/Cas

North Carolina State University
University of Illinois at Urbana-Champaign, USA
Beihua University
Northeast Forestry University, China

Bio-fuel production: Reduced lignin content, improves cell wall composition for production of bio-ethanol.
(Jung et al., 2016)

SDN1
TALENs

Korea University, South Korea
University of Florida, USA

Asexual propagation trough seeds. Induction of apomeiosis, mitosis instead of meiosis. This proces leads to the production of genetically identical seeds, serving many applications in plant breeding.
( Khanday et al., 2019 )

SDN1
CRISPR/Cas

University of California
Innovative Genomics Institute
Iowa State University, USA
Université Paris-Saclay, France

Enhanced biological nitrogen fixation to reduce the use of inorganic nitrogen fertilizers. Enhanced biofilm formation of soil diazotrophic bacteria by modified root microbiome structure.
( Yan et al., 2022 )

SDN1
CRISPR/Cas

University of California
Bayer Crop Science, USA

Trait stacking. Modern agriculture demands crops carrying multiple traits.
( Ainley et al., 2013 )

SDN1
ZFN

Dow AgroSciences LLC
Sangamo BioSciences, Inc., USA

Traits categories

Genome Editing Technique

Countries

Plant

Sdn Type

Traits related to biotic stress tolerance

Traits related to industrial utilization