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

Plant

Displaying 446 results

Traits related to biotic stress tolerance

Disease resistant thermosensitive genic male sterility (TGMS) with enhanced resistance to rice blast and bacterial blight.
( Li et al., 2019 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Bacterial resistance: Enhanced resistance to both blast and bacterial blight diseases, two major diseases having devastating impact on the yield of rice in most rice-growing countries.
(Zhou et al., 2021)
SDN1
CRISPR/Cas
South China Agricultural University
Huazhong Agricultural University
Yuan Longping High-Tech Agriculture Co. Ltd
Hunan Hybrid Rice Research Center
Yuan Longping High-Tech Agriculture Co. Ltd, China
Bacterial resistance: Resistance/moderately resistance against Bacterial leaf blight (BLB), caused by Xanthomonas oryzae pv oryzae (Xoo). BLB is a major constraint in rice production.
(Arulganesh et al., 2022)
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University, India
Enhanced resistance to insects, no serotonin production and higher salicylic acid levels. Rice brown planthopper (BPH; Nilaparvata lugens Stål) and striped stem borer (SSB; Chilo suppressalis) are the two most serious pests in rice production.
( Lu et al., 2018 )
SDN1
CRISPR/Cas
Zhejiang University
Jiaxing Academy of Agricultural Sciences
Wuxi Hupper Bioseed Ltd.
Hubei Collaborative Innovation Center for Grain Industry, China
Newcastle University, UK
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
Viral resistance: Partial resistance to rice black-streaked dwarf virus (RBSDV). RBSDV is a serious threat in Chinese rice production.
(Wang et al., 2021)
SDN1
CRISPR/Cas
Jiangsu Academy of Agricultural Sciences
Nanjing Agricultural University, China
Fungal resistance: Increased resistance to Phytophthora sojae, a pathogen severely impairing soybean production.
(Yu et al., 2021)
SDN1
CRISPR/Cas
Northeast Agricultural University
Chinese Academy of Agricultural Sciences
Shanghai Jiao Tong University
Jilin Academy of Agricultural Science
Jiamusi Branch Academy of Heilongjiang Academy of Agricultural Sciences
Heilongjiang Academy of Agricultural Sciences, China
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
Fungal resistance: increased resistance to both biotrophic and necrotrophic plant pathogenic fungi, Bipolaris spot blotch and Fusarium root rot.
(Galli et al., 2022)
SDN1
CRISPR/Cas
Justus Liebig University, Germany
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
High level of powdery mildew resistance while maintaining normal crop
growth and yields.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Significant resistance to bacterial blight caused by Xanthomonas oryzae pv. oryzae (Xoo), sheath blight caused by Rhizoctonia solani and rice blast caused by Magnaporthe oryzae.
( Hu et al., 2021 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Jiangxi Agricultural University
Wuhan Towin Biotechnology Company Limited, China
Robust rust resistance to pandemic stripe rust caused by Puccinia striiformis (Pst) without growth and yield penalty.
( Wang et al., 2022 )
SDN1
CRISPR/Cas
Northwest A&
F University
Chinese Academy of Sciences, China
Disease-resistant and fertile varieties.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Hubei Academy of Agricultural Sciences
Huazhong Agricultural University

Hubei Hongshan Laborator, China
Broad-spectrum bacterial blight resistance.
( Xu et al., 2019 )
SDN1
CRISPR/Cas
Shanghai Jiao Tong University, China
Viral resistance: resistance to rice tungro disease (RTD), the most important viral disease that limits rice production.
(Kumam et al., 2022)
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University
International Centre for Genetic Engineering and Biotechnology
ICAR-Indian Institute of Rice Research, India
Resistance against leaf chewing insects: leaf-chewing insects cause yield loss and reduce seed quality in soybeans
(Zhang et al., 2022)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Huazhong Agricultural University
Henan Agricultural University, China
Resistance to Phytophthora sojae, which severely impairs soybean production.
( Yu et al., 2022 )
SDN1
CRISPR/Cas
Northeast Agricultural University
Chinese Academy of Agricultural Sciences
Jilin Academy of Agricultural Science
Shanghai Jiao Tong University
Jiamusi Branch Academy of Heilongjiang Academy of Agricultural Sciences, China
Viral resistance: increased resistance against wheat yellow mosaic virus (WYMV) without yield penalty. WYMV results in severe yield losses in hexaploid wheat.
(Kan et al., 2023)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences (CAAS)
Agricultural Sciences Institute in Jiangsu Lixiahe Area, China
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
Fungal resistance: increased resistance against the fungus Pyricularia oryzae, causing rice blast, one of the most destructive diseases affecting rice worldwide.
(Távora et al., 2022)
SDN1
CRISPR/Cas
Federal University of Juiz de Fora
Embrapa Genetic Resources and Biotechnology
Catholic University of Brasilia
Catholic University of Dom Bosco, Brazil
Agricultural Research Center for International Development (CIRAD)
University of Montpellier
Montpellier SupAgro, France
Fungal resistance: increased resistance against the fungus Puccinia striiformis f. sp. tritici (Pst). Wheat stripe rust is caused by Pst and is one of the most destructive wheat diseases, resulting in significant losses to wheat production worldwide.
(He et al., 2022)
SDN1
CRISPR/Cas
Northwest A&
F University
Hebei Agri cultural University, China
Bacterial resistance: enhanced resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Kim et al., 2019)
SDN1
CRISPR/Cas
Sejong University, South Korea
Viral resistance: Increased resistance to the barley mild mosaic virus (BaMMV), which can cause yield losses as high as 50% upon infection.
(Hoffie et al., 2022)
SDN1
CRISPR/Cas
Leibniz-Institute of Plant Genetics and Crop Plant Research (IPK)
Federal Research Centre for Cultivated Plants, Germany
Bacterial resistance: Enhanced resistance to Xanthomonas oryzae pv. oryzae (Xoo) and X. oryzae pv. oryzicola (Xoc), which cause bacterial blight and bacterial leaf streak, respectively.
(Peng et al., 2022)
SDN1
CRISPR/Cas
Nanjing Agricultural University
Shandong Agricultural University
Jiangsu University of Science and Technology, China
Fungal resistance to Oidium neolycopersici, causing powdery mildew, one of the most important diseases limiting the production of wheat.
( Wang et al., 2014 )
SDN1
TALENs
Chinese Academy of Sciences, China
Fungal resistance to Oidium neolycopersici, causing powdery mildew, one of the most important diseases limiting the production of wheat.
( Zhang et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Fungal resistance: resistance to Fusarium graminearum. Fusarium head blight (FHB) is an economically important disease, affecting both yield and grain quality of maize, wheat and barley.
(Brauer et al., 2020)
SDN1
CRISPR/Cas
Ottawa Research and Development Centre, Canada
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

Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Zafar et al., 2020)
SDN1
CRISPR/Cas
Constituent College of Pakistan Institute of Engineering and Applied Sciences
University of Information Technology
Engineering and Management Sciences
Constituent College of Pakistan Institute of Engineering and Applied Sciences, Pakistan
Fungal resistance: enhanced resistance to Magnaporthe oryzae, causing rice blast, one of the most destructive diseases affecting rice worldwide.
(Wang et al., 2016)
SDN1
CRISPR/Cas
Chinese Academy of Agriculture, China
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
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Blanvillain-Baufumé et al., 2017)
SDN1
TALENs
IRD-CIRAD-Université, France
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
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Wang et al., 2017)
SDN1
TALENs
National University of Singapore, Singapore
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Xie et al., 2017)
SDN1
TALENs
Chinese Academy of Sciences, China
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Zhou et al., 2018)
SDN1
CRISPR/Cas
National Center for Plant Gene Research
Sichuan Agricultural University, China
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
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Cai et al., 2017)
SDN1
TALENs
Shanghai Jiao Tong University
Yunnan Academy of Agricultural Sciences, China
Bacterial and fungal resistance: Resistance to bacterial blight and rice blight. Also spontaneous cell death, altered seed dormancy (pre-harvest sprouting) and enhanced growth.
(Liao et al., 2018)
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
Viral resistance: resistance to rice tungro spherical virus, causing rice tungro disease (RTD). RTD is a serious threat for rice production in tropical Asia.
(Macovei et al., 2018)
SDN1
CRISPR/Cas
International Rice Research Institute (IRRI), Philippines
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease in Southeast Asia and West Africa. Bacteria enter the host and produce a toxin, which prevents the production of chlorophyl.
(Han et al., 2020)
SDN1
TALENs
Chinese Academy of Sciences
Hainan University, China
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease in Southeast Asia and West Africa.
(Wei et al., 2021)
SDN2
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Agricultural Research Center, Egypt
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease.
(Li et al., 2020)
SDN1
CRISPR/Cas
College of Life Science and Technology &
College of Horticulture &
Forestry Sciences
Huazhong Agricultural University, China
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Xu et al., 2021)
SDN1
TALENs
Shanghai Jiao Tong University, China
Crop Diseases Research Institute, Pakistan
Bacterial resistance: Strong resistance to Xanthomonas oryzae, causing bacterial blight, a devastating rice disease resulting in yield losses.
(Zeng et al., 2020)
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Enhanced blast disease resistance
( Liao et al., 2022 )
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
Fungal resistance: Enhanced resistance to blast without affecting the major agronomic traits. Rice blast caused by Magnaporthe oryzae, is a devastating disease affecting rice production globally
(Nawaz et al., 2020)
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Fungal resistance: Improved resistance to false smut, caused by Ustilaginoidea virens. False smut is one of the major fungal diseases of rice.
(Liang et al., 2018)
SDN2
CRISPR/Cas
Northwest A&
F University
Fujian Agriculture and Forestry University, China
Viral resistance: Highly efficient resistance against wheat dwarf virus (WDV), an economically important virus. WDV infect both wheat and barley causing severe yield losses. The natural resistance resources are limited.
(Kis et al., 2019)
SDN1
CRISPR/Cas
University of Pannonia
Hungarian Academy of Sciences
Eötvös Loránd University University
Szent István University, Hungary
Oomycete resistance: increased resistance against soybean root rot disease caused by Phytophthora sojae.
(Liu et al., 2023)
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Bacterial and fungal resistance: increased resistance against the bacterial pathogen Xanthomonas oryzae pv. oryzae (Xoo) and fungal pathogen Magnaporthe oryzae causing bacterial blight and rice blast, respectively.
(Liu et al., 2023)
SDN1
CRISPR/Cas
Hunan Agricultural University
Hunan Provincial Key Laboratory of Rice and Rapeseed Breeding for Disease Resistance
Hunan Academy of Agricultural Sciences
State Key Laboratory of Hybrid Rice, China
Fungal and bacterial resistance: improved resistance against Magnaporthe oryzae–caused rice blast and bacterial leaf streak caused by Xanthomonas oryzae. Rice blast and bacterial leaf streak are deadly diseases that can lead to serious damage.
(Yang et al., 2023)
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University
Guangxi Lvhai
Seed Co., China
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
Fungal resistance: broad-spectrum resistance to rice pathogens without adverse effects in terms of growth and yield.
(Chen et al., 2023)
SDN1
CRISPR/Cas
Anhui Agricultural University
Huazhong Agricultural University, China
Bacterial resistance: Plant moderately resistant against a strain of the gram-negative bacterium, Xanthomonas oryzae pv. oryzae (Xoo). Xoo severely impacts rice productivity by causing bacterial leaf blight disease.
(Bhagya Sree et al., 2023)
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University, India
Viral resistance: Strong barley yellow dwarf virusses (BYDV) resistance without negative effects on plant growth under field conditions. BYDV threatens efficient and stable production of wheat, maize, barley and oats.
(Wang et al., 2023)
SDN1
CRISPR/Cas
Henan Agricultural University
The Shennong Laboratory
Chinese Academy of Agricultural Sciences, China
Sensitive detection of two fungal pathogens (Diaporthe aspalathi and Diaporthe caulivora) that cause soybean stem canker. The method requires minimal equipment as well as training and shows potential for on-site screening.
( Sun et al., 2023 )
SDN1
CRISPR/Cas
Chinese Academy of Inspection and Quarantine
Shenyang Agricultural University
Huangpu Customs Technology Center
Technical Center of Hangzhou Customs
Dalian University, China
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

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
Fungal resistance: stripe rust resistance, caused by Puccinia striiformis f. sp. tritici. In appropriate environmental conditions and susceptible varieties, stripe rust can cause huge grain yield and quality loss.
(Li et al., 2023)
SDN1
CRISPR/Cas
Fudan University
Chinese Academy of Sciences
University of the Chinese Academy of Sciences
China Agricultural University
Guangzhou University
School of Life Science
Shandong Academy of Agricultural Sciences
Ministry of Agriculture
National Engineering Research Center for Wheat and Maize
Sichuan Agricultural University
Nanjing Agricultural University, China
Université Paris Cité
Université Paris-Saclay, France
Fungal resistance: Improved resistance to Magnaporthe oryzae.
(Lijuan et al., 2024)
SDN1
CRISPR/Cas
China National Rice Research Institute
Agricultural College of Yangzhou University, China
Enhanced resistance against rice bacterial blight (BB) and bacterial leaf streak (BLS).
( Wang et al., 2024 )
SDN1
CRISPR/Cas
Zhejiang Normal University, China
Fungal resistance: enhanced resistance against rust caused by Puccinia striiformis f. sp. tritici and powdery mildew caused by Blumeria graminis f. sp. tritici., while also increasing yield.
(Liu et al., 2024)
SDN1
CRISPR/Cas
Southwest University
Yangtze University, China
University of Cologne, Germany
University of Maryland
Bacterial resistance: Enhanced resistance to blast and bacterial blight.
(Zhang et al., 2024)
SDN1
CRISPR/Cas
China National Rice Research Institute, China
Nematode resistance: Enhanced resistance to more virulent soybean cyst nematode (SCN). SCN is the most devastating post to soybean crop yields in the US.
(Wang et al., 2024)
SDN1
CRISPR/Cas
Henan Agricultural University
University of South Carolina, China
Early on site detection of Phytophthora root rot, caused by Phytophthora sojae.
( Li et al., 2024 )
SDN1
CRISPR/Cas
Hainan University
Shanghai Jiao Tong University
China Agricultural University
Post-Entry Quarantine Center for Tropical Plant, China
Fungal resistance: Assay for rapid detection of Diaporthe aspalathi, causal agent of Southern stem canker, which causes huge losses of soybean worldwide.
(Dong et al., 2024)
SDN1
CRISPR/Cas
Hainan University
Sanya Institute of China Agricultural University, China
Rapid detection of Bacillus cereus, which is a foodborne pathogen that can cause different diseases through production of enterotoxins.
( Li et al., 2024 )
SDN1
CRISPR/Cas
China Agricultural University
Guangzhou Wanlian Biotechnology Co., China
Bacterial resistance: bacterial leaf-blight resistance, which is a destructive disease caused by Xanthomonas oryzae pv. oryzae. and threatens rice production in tropical and temperate regions.
(Kim et al., 2024)
SDN1
CRISPR/Cas
Chungbuk National University
Hankyong National University, Korea
Viral resistance: resistance against Soybean mosaic virus, which is a very common and destructive pathogenic virus.
(Gao et al., 2024)
SDN1
CRISPR/Cas
Nanjing Agricultural University
Beijing Vocational College of Agriculture
China Agricultural University
Shenyang Agricultural University, China
Sensitive on-site diagnosis of Rice bakanae disease, caused by F. fujikuroi, F. proliferatum, F. verticillioides, and F. andiyazi.
( Zhang et al., 2024 )
SDN1
CRISPR/Cas
Anhui Agricultural University, China
Bacterial resistance: broad-spectrum resistance to bacterial blight. Rice bacterial blight is caused by Xanthomonas oryzae pv. oryzae and forms a threat to rice populations in Southeast Asia and West Africa.
(Li et al., 2024)
SDN1
CRISPR/Cas
Northwest A &
F University
Chinese Academy of Agricultural Sciences, China
Viral resistance: enhanced resistance against wheat dwarf virus, which is a causal agent of wheat viral disease and can significantly impact wheat production worldwide.
(Yuan et al., 2024)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Northwest A&
F University, China

Norwegian Institute of Bioeconomy Research, Norway
Viral resistance: improved resistance against the Southern rice black-streaked dwarf virus, which can cause significant crop losses.
(Zhang et al., 2024)
SDN1
CRISPR/Cas
Shenyang Agricultural University
Ningbo University, China
Fungal resistance: Decreased susceptibility against sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Gao et al., 2018)
SDN1
CRISPR/Cas
Shenyang Agricultural University
Fuzhou University
Chinese Academy of Agricultural Sciences
Nanjing Agricultural University
Chinese Academy of Sciences
Wenzhou Agricultural Science Research Institute, China
Fungal resistance: improved sheath blight resistance. Sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Cao et al., 2021)
SDN1
CRISPR/Cas
Agricultural College of Yangzhou University
Jiangsu Yanjiang Institute of Agricultural Science
Yangzhou University
Testing Center of Yangzhou University
Ministry of Agriculture
Chinese Academy of Agricultural Sciences
Institutes of Agricultural Science and Technology Development, China
BASF, Germany
Fungal resistance: improved sheath blight resistance. Sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Xie et al., 2023)
SDN1
CRISPR/Cas
Agricultural College of Yangzhou University
Yangzhou University, China
Fungal resistance: Decreased susceptibility against sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Chen et al., 2024)
SDN1
CRISPR/Cas
Chongqing Three Gorges University
Shenyang Agricultural University
Nankai University
Northeast Forestry University, China
Fungal resistance: Decreased susceptibility against sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Wang et al., 2024)
SDN1
CRISPR/Cas
Shenyang Agricultural University
Liaoning Academy of Agricultural Sciences, China
Fungal resistance: improved sheath blight resistance. Sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Feng et al., 2023)
SDN1
CRISPR/Cas
Yangzhou University, China
Fungal resistance: Decreased susceptibility against sheath blight disease caused by Rhizoctonia solani AGI-1A and is one of the three major rice diseases. Sheath blight disease can cause severe yield losses.
(Zhao et al., 2024)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Hebei Agricultural University
Agricultural College of Yangzhou University, China
The Ohio State University, USA
Fungal resistance: Resistance against the blast fungus Mangaporthe oryzae.
(Bundó et al., 2024)
SDN1
CRISPR/Cas
Campus Universitat Autònoma de Barcelona (UAB)
Consejo Superior de Investigaciones Científcas (CSIC), Spain
Academia Sinica No 128, Taiwan
Bacterial resistance: Resistance against African Xanthomonas oryzae isolates, causing agents of bacterial blight. Bacterial blight threatens rice populations in Asia and West Africa.
(Li et al., 2024)

BE
University of Missouri
Donald Danforth Plant Science Center, USA
Department of Nanjing Agricultural University, China
Rapid detection system for Paracoccus marginatus, an insect that can cause huge crop losses.
( Chen et al., 2024 )
SDN1
CRISPR/Cas
Fujian Academy of Agricultural Sciences, China
UMR ISA, France

Traits related to abiotic stress tolerance

Increased tolerance to salinity stress. Development of lines with reduced inositol hexakisphosphate (IP6) content may enhance phosphate and mineral bioavailability. ICP6 is a major storage form of phosphate in cereal grains.
( Vicko et al., 2020 )
SDN1
CRISPR/Cas
Czech Academy of Sciences, Czech Republic
Drought tolerance and abscisic acid sensitivity.
( Lou et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Potassium deficiency tolerance and contribution to stomatal closure.
( Mao et al., 2016 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Fujian Academy of Agricultural Sciences
National Center of Rice Improvement of China
National Engineering Laboratory of Rice
South Base of National Key Laboratory of Hybrid Rice of China, China
Salt tolerance.
( Duan et al,. 2016 )
SDN1
CRISPR/Cas
Anhui Academy of Agricultural Sciences, China
Arsenic (As) tolerance. As is toxic to organisms and elevated As accumulation may pose health risks to humans.
( Duan et al., 2015 )
SDN1
CRISPR/Cas
Anhui Academy of Agricultural Sciences, China
Enhanced responses to abscisic acid (ABA), which plays an important role in drought stress responses in plants. Improved drought tolerance through stomatal regulation and increased primary root growth under non-stressed conditions.
( Ogata et al., 2020 )
SDN1
CRISPR/Cas
Japan International Research Center for Agricultural Sciences (JIRCAS)
RIKEN Center for Sustainable Resource Science
University of Tsukuba, Japan
Enhanced resistance to salt and oxidative stress and increased grain yield.
( Alfatih et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Drought tolerance.
( Kim D et al,. 2018 )
SDN1
CRISPR/Cas
Montana State University, USA
Drought and salt tolerance.
( Kumar et al., 2020 )
SDN1
CRISPR/Cas
ICAR-Indian Agricultural Research Institute
Bhartidasan University, India
Improved yield and cold tolerance. High yield and high cold tolerance were often antagonistic to each other.
( Zeng et al., 2020 )
SDN1
CRISPR/Cas
College of Life Sciences, Wuhan University, China
Drought tolerance.
( Zhao et al., 2022 )
SDN1
CRISPR/Cas
Hebei Normal University
University of Chinese Academy of Sciences, China
Curled leaf phenotype and improved drought tolerance.
( Liao et al., 2019 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Drought and salt tolerance.
( Curtin et al., 2018 )
SDN1
CRISPR/Cas
University of Minnesota, USA
The University of Newcastle, Australia
Enhanced the tolerance of plants to salt (NaCl), the stress hormone abscisic acid (ABA), dehydration and polyethylene glycol (PEG) stresses.
( Yue et al., 2020 )
SDN1
CRISPR/Cas
Zhejiang University
Hunan Agricultural University, China
Drought tolerance by modulating lignin accumulation in roots.
( Bang et al, 2021 )
SDN1
CRISPR/Cas
Seoul National University, South Korea
Salinity tolerance. Salinity stress is one of the most important abiotic stress factors affecting rice production worldwide.
( Lim et al., 2021 )
SDN1
CRISPR/Cas
Kangwon National University
Sangji University
Kyung Hee University, South Korea
Enhanced salinity tolerance.
( Zhang et al., 2019 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Shanghai Agrobiological Gene Center, China
Enhanced salinity stress tolerance.
( Wang et al., 2021 )
SDN1
CRISPR/Cas
Northeast Normal University
Jilin Academy of Agricultural Sciences
Linyi University
Chinese Academy of Sciences, China
Drought resistance.
( Zhang et al., 2022 )
SDN1
CRISPR/Cas
Jilin Agricultural University, China
Enhances adaptation to direct-seeding on wet land and tolerance to drought stress in rice. Water stress is the most important factor limiting rice agriculture by either floods or drought.
( Zhang et al., 2020 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Shanghai Agrobiological Gene Center, China
Increased tolerance to salinity stress. Improved rice yields in saline paddy fields by root angle modifications to adapt to climate change.
( Kitomi et al., 2020 )
SDN1
CRISPR/Cas
National Agriculture and Food Research Organization (NARO)
Tohoku University
Institute of Agrobiological Sciences
Japan Science and Technology Agency (JST)
Advanced Analysis Center
National Institute of Advanced Industrial Science and Technology (AIST), Japan
More tolerant to chilling stress: increased survival rate, decreased membrane permeability, and reduced lipid peroxidation.
(Xu et al., 2022)
SDN1
CRISPR/Cas
Henan University of Science and Technology
Chinese Academy of Sciences, China
Improved salt stress resistance. Significant increase in the shoot weight, the total chlorophyll content, and the chlorophyll fluorescence under salt stress. Also high antioxidant activities coincided with less reactive oxygen species (ROS).
( Shah Alam et al., 2022 )
SDN1
CRISPR/Cas
Zhejiang University, China
Taif University, Saudi Arabia
Alexandria University, Egypt
Better salinity tolerance.
( Ma et al., 2022 )
SDN1
CRISPR/Cas
Ningbo Academy of Agricultural Sciences
Nanjing Agricultural University, China
Chilling tolerance.
( Zhang et al., 2022 )
SDN1
CRISPR/Cas
Jilin University, China
Improved rice growth with increased plant height, biomass, and chlorophyll content but with a lower degree of oxidative injury and Cd accumulation.
( Cao et al., 2022 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Jiangsu Academy of Agricultural Sciences, China
Reduced cuticle permeability and enhanced drought tolerance.
( He et al., 2022 )
SDN1
CRISPR/Cas
Northwest A&
F University
USA
University of British Columbia, Canada
Salt tolerance during the seedling stage.
( Chen et al., 2022 )
SDN1
CRISPR/Cas
Hubei Academy of Agricultural Sciences
Huazhong Agriculture University
Hubei Hongshan Laboratory, China
Improved drought tolerance and yield.
( Usman et al., 2020 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Improved salinity tolerance.
( Wang et al., 2022 )
SDN1
CRISPR/Cas
National Taiwan University, Taiwan
University of North Carolina, USA
Reduced uptake of lead (Pb). Lead is one of the most toxic metals affecting human health globally and food is an important source of chronic Pb exposure in humans.
( Chang et al., 2022 )
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Increased water-deficit tolerance.
( Lv et al., 2022 )
SDN1
CRISPR/Cas
Chongqing University, China
Reduced cadmium content. Cadmium poses a health treat, as it is a highly toxic heavy metal for most living organisms.
( Hao et al., 2022 )
SDN1
CRISPR/Cas
Hunan University of Arts and Science
Hunan Normal University, China
Increased tolerance to cadmium toxicity.
( Yue et al., 2022 )
SDN1
CRISPR/Cas
Zhejiang University
Hangzhou Academy of Agricultural Sciences, China
Increased drought tolerance.
( Abdallah et al., 2022 )
SDN1
CRISPR/Cas
Cairo University, Egypt
Crop Improvement and Genetics Unit, USA
Increased tolerance to low temperatures.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Tianjin Academy of Agricultural Sciences
Nankai University
University of Electronic Science and Technology of China, China
Increased drought tolerance. Plants showed lower ion leakage and higher proline content upon abiotic stress.
( Kim et al., 2023 )
SDN1
CRISPR/Cas
Chungbuk National University
Hankyong National University

Institute of Korean Prehistory, South Korea
Reduced arsenic content and increased arsenic tolerance. Arsenic is toxic to organisms and elevated its accumulation may pose health risks to humans.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Henan Agricultural University
Chinese Academy of Sciences
Henan Agricultural University, China
Increased root length, which can restore good performance under water stress.
( Gabay et al., 2023 )
SDN1
CRISPR/Cas
University of California
Howard Hughes Medical Institute, USA
University of Haifa, Israel
Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET)
Universidad Nacional de San Martín (UNSAM), Argentina
Fudan University
China Agricultural University, China
Karolinska Institutet, Sweden
Enhanced drought tolerance.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
International Maize and Wheat Improvement Center, Mexico
Enhanced cadmium resistance with reduced cadmium accumulation in roots and shoots. Cadmium is a heavy metal, harmful for human health.
( Dang et al., 2023 )
SDN1
CRISPR/Cas
Shenyang Agricultural University/Key Laboratory of Northern geng Super Rice Breeding, China
Increased cuticular wax biosynthesis resulting in enhanced drought tolerance.
( Shim et al., 2023 )
SDN1
CRISPR/Cas
Seoul National University
Incheon National University
Kyung Hee University, South Korea
Salt-tolerant plants.
( Jingfang et al., 2023 )
SDN1
CRISPR/Cas
Lianyungang Academy of Agricultural Science
Nanjing Agricultural University
Jiangsu Academy of Agricultural Sciences, China
Enhanced rice salinity tolerance and absisic acid hypersensitivity.
( Yan et al., 2023 )
SDN1
CRISPR/Cas
Nanchang University, China
Early heading phenotype that escapes from cold stress and achieves high yield potential.
( Zhou et al., 2023 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Institute of Lianyungang Agricultural Science of Xuhuai Area/Lianyungang Institute of Agricultural Sciences
Chinese Academy of Agricultural Sciences, China
Cold tolerance.
( Park et al., 2023 )
SDN1
CRISPR/Cas
National Institute of Crop Science
Kyungpook National University, South Korea
Enhanced chilling tolerance at seedling stage without yield loss.
( Deng et al., 2024 )
SDN1
CRISPR/Cas
Hunan Agricultural University
Hunan Academy of Agricultural Sciences
Yuelushan Laboratory, China
Improved lodging resistance.
( Wakasa et al., 2024 )
SDN1
CRISPR/Cas
Institute of Agrobiological Sciences
Institute of Crop Sciences, Japan
Decreased Cadmium (Cd) accumulation. Consumption of crops that absorb Cd from the soil can cause serious health problems in humans.
( He et al., 2024 )
SDN1
CRISPR/Cas
Yunnan Agricultural University, China
Enhanced salt tolerance.
( Ly et al., 2024 )
SDN1
CRISPR/Cas
Vietnam Academy of Science and Technology
Agricultural Genetics Institute, Vietnam
Reduced arsenic content. Arsenic accumulation in rice poses a threat to human health.
( Singh et al., 2024 )
SDN1
CRISPR/Cas
Academy of Scientific and Innovative Research (AcSIR)
CSIR-National Botanical Research Institute
CSIR-National Botanical Research Institute, India
Increased salt-tolerance.
( Antonova et al., 2024 )
SDN1
CRISPR/Cas
Institute of Plant and Animal Ecology (IPAE)
N.I. Vavilov All-Russian Institute of Plant Genetic Resources (VIR)
Institute of Cytology and Genetics (ICG), Russia
Enhanced salt tolerance and alkali resistance among other resistances.
( Luo et al., 2024 )
SDN1
CRISPR/Cas
Northeast Agricultural University/Key Laboratory of Soybean Biology of the Chinese Education Ministry
Keshan Branch of Heilongjiang Academy of Agricultural Sciences
Harbin Normal University, China
Shorter internode length, reduced plant height and a thicker culm wall, which might indicate lodging resistance.
( Zhao et al., 2024 )
SDN1
CRISPR/Cas
Liaoning Academy of Agricultural Sciences, China
Reduced cadmium contamination. Cadmium is a toxic heavy metal.
( Zhu et al., 2024 )
SDN1
CRISPR/Cas
Zhejiang University
Yangzhou University, China
Improved cold tolerance.
( Park et al., 2024 )
SDN1
CRISPR/Cas
Rural Development Administration
Kyungpook National University
National Institute of Agricultural Sciences
Kyungpook National University
Jeonbuk National University, Korea
College of Marine and Bioengineering, China
Improved cold tolerance.
( Shibo et al., 2024 )
SDN1
CRISPR/Cas
Shenyang Agricultural University
Liaoning Provincial Science and Technology Innovation Service Center, China
Enhanced salt tolerance.
( Chen et al., 2024 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Chinese Academy of Agricultural Sciences
Tianjin Academy of Agricultural Sciences
Chinese Academy of Agricultural Sciences
Minzu University of China
Hebei Academy of Agriculture and Forestry Science, China
Improved salt tolerance.
( Xu et al., 2024 )
SDN1
CRISPR/Cas
Northeast Agricultural University
Heilongjiang Academy of Agricultural Sciences, China

Traits related to improved food/feed quality

Increased grain hardness and reduced grain width. Grain hardness index of hina mutants was 95.5 on average, while that of the wild type was only 53.7, indicating successful conversion of soft barley into hard barley.Grain hardness, defined as the resistance of the kernel to deformation, is the most important and defining quality of barley and wheat.
( Jiang et al., 2022 )
SDN1
CRISPR/Cas
Qinghai Normal University
Chinese Academy of Sciences, China
Low amylose content to improve the rice eating quality.
( Mao et al., 2022 )

Guangdong Academy of Agricultural Sciences
Guangdong Key Laboratory of New Technology in Rice Breeding
Guangdong Rice Engineering Laboratory, China
Fine-tuning the amylose content, one of the major contributors to the eating and cooking quality.
( Zhang et al., 2022 )
SDN1
CRISPR/Cas
Shanghai Normal University, China
Reducing polyunsaturated fatty acids content and increased content of monounsaturated fatty acids. High levels of polyunsaturated fatty acids in natural soybean oil renders the oil susceptible to the development of unpalatable flavors and trans fatty acids.
( Fu et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Fragrant glutinous hybrid rice.
( Tian et al., 2023 )
SDN1
CRISPR/Cas
Huazhong Agricultural University, China
Waxy rice which lacks amylose. Waxy rice is regarded as a high-quality rice variant, also known as glutinous rice. Due to the unique properties of waxy rice starch, it is extensively used in the chemical industry, medicine, and daily human life.
( Fu et al., 2023 )
SDN1
CRISPR/Cas
Chengdu University of Traditional Chinese Medicine
Rice Research Institute of Sichuan Agricultural University
Meishan Dongpo District Agricultural and Rural Bureau, China
Altered gliadin levels resulting in improved end-use quality and reduced gluten epitopes associated with celiac disease. Gliadins are important for wheat end-use traits.
( Liu et al., 2023 )
SDN1
CRISPR/Cas
China Agricultural University, China
Research Centre for Cereal and Industrial Crops, Italy
Increased contents of GABA, protein, crude fat, and various mineral contents. GABA-rich rice varieties can promote human nutrition, and ensure health.
( Chen et al., 2023 )
SDN1
CRISPR/Cas
Ministry of Agriculture and Rural Affairs, China
Increased amylose content in the seeds, thus a lower Glycemic Index (GI) value. Low GI rice is preferred to avoid a sudden rise in glucose in the bloodstream. Starch with a high GI threatens healthy individuals to get diabetes type II and proves extremely harmful for existing diabetes type II patients.
( Jameel et al., 2022 )
SDN1
CRISPR/Cas
Jamia Millia Islamia
International Centre for Genetic Engineering and Biotechnology, India
King Saud University, Saudi Arabia
Reduced phytic acid content in soybean seeds. Monogastric animals are unable to digest phytic acid, making phytic acid phosphorous in animal waste one of the major causes of environmental phosphorus pollution.
( Song et al., 2022 )
SDN1
CRISPR/Cas
Dong-A University
Korea Research Institute of Bioscience Biotechnology (KRIBB), South Korea
Improved seed protein content.
( Shen et al., 2022 )
SDN1
CRISPR/Cas
Corteva Agriscience
University of Arizona, USA
Enriched levels of Gamma-amino butyric acid (GABA). GABA lowers blood pressure, has anti-aging effects, and activates the liver and kidney.
( Chen et al., 2022 )
SDN1
CRISPR/Cas
Guangdong Academy of Agricultural Sciences, China
Low glutelin content in the rice germplasm: patients with chronic kidney disease (CKD) and phenylketonuria (PKU) need to eat rice with low glutelin content.
(Chen et al., 2022)
SDN1
CRISPR/Cas
Nanjing Branch of Chinese National Center for Rice Improvement
Yangzhou University
Henan Agricultural University
Jiangsu Academy of Agricultural Sciences, China
CSIRO Agriculture and Food, Australia
Reduction of phytic acid (PA) in seeds. PA has adverse effects on essential mineral absorption and thus is considered as an anti-nutritive for monogastric animals.
( Khan et al., 2019 )
SDN1
CRISPR/Cas
Zhejiang University
Yangtze University, China
Improved grain quality. The amylose content, gel consistency and pasting viscosity of grain starches are influencing the grain appearance, cooking/eating quality and starch physical characters.
( Zeng et al., 2020 )
SDN1
CRISPR/Cas
State Key Laboratory for Conservation and Utilization of Subtropical Agro‐Bioresources
Guangdong Laboratory for Lingnan Modern Agriculture
South China Agricultural University, China
Improved quality by reduced grain protein content (GPC). High GPC is negatively correlated between protein content and peak viscosity and breakdown value. High GPC is also positively correlated to protein content and hardness.
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Jiangsu Key Laboratory of Crop Genetics and Physiology/Key Laboratory of Plant Functional Genomics of the Ministry of Education/Jiangsu Key Laboratory of Crop Genomics and Molecular Breeding
Jiangsu Co-Innovation Center for Modern Production Technology of Grain Crops
Agricultural College of Yangzhou University, China
Facilitated Isoproturon Metabolism and Detoxification: Improved growth, the Isoproturon (IPU)-induced cellular damage was attenuated, and IPU accumulation was significantly repressed
(Zhai et al., 2022)
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Production of opaque seeds with depleted starch reserves. Reduced starch content and increased amylose content. Accumulation of multiple sugars, fatty acids, amino acids and phytosterols.
( Baysal et al., 2020 )
SDN1
CRISPR/Cas
University of Lleida-Agrotecnio Center
Catalan Institute for Research and Advanced Studies (ICREA), Spain
Royal Holloway University of London, UK
Enhanced soybean aroma and functional marker for improving soybean flavor.
( Qian et al., 2022 )
SDN1
CRISPR/Cas
Zhejiang Academy of Agricultural Science
Ministry of Agriculture and Rural Affairs of China
Zhejiang University of Technology
Zhejiang Academy of Agricultural Sciences, China
Specific differences in grain morphology, composition and (1,3;1,4)-β-glucan content. Barley rich in (1,3;1,4)-β-glucan, a source of fermentable dietary fibre, is useful to protect against various human health conditions. However, low grain (1,3;1,4)-β-glucan content is preferred for brewing and distilling.
( Garcia-Gimenez et al., 2020 )
SDN1
CRISPR/Cas
The James Hutton Institute
University of Dundee, UK
University of Adelaide
La Trobe University, Australia
Increased NH4+ and PO43− uptake, and photosynthetic activity under high CO2 conditions in rice. Largely increased panicle weight. Improved grain appearance quality or a decrease in the number of chalky grains.
( Iwamoto et al., 2022 )
SDN1
CRISPR/Cas
Institute of Agrobiological Sciences, Japan
Increased RS. Cereals high in RS may be beneficial to improve human health and reduce the risk of diet-related chronic diseases.
( Biswas et al., 2022 )
SDN1
CRISPR/Cas
Texas A&
M Univ.
Avance Biosciences Inc., USA
Reduced Cd accumulation.
( Chen et al., 2022 )
SDN1
CRISPR/Cas
South China Agricultural University
Guangdong Academy of Sciences, China
Carotenoid-enriched. Carotenoids, the source of pro vitamin A, are an essential component of dietary antioxidants.
( Dong et al., 2020 )
SDN3
CRISPR/Cas
University of California
Innovative Genomics Institute
The Joint Bioenergy Institute, USA
Fragrant rice. Introduction of aroma into any non-aromatic rice varieties.
( Ashokkumar et al., 2020 )
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University, India
Increased lysophospholipid content and enhanced cooking and eating quality. Lysophospholipid (LPL) is derived from the hydrolysis of phospholipids and plays an important role in rice grain quality.
( Khan et al., 2020 )
SDN1
CRISPR/Cas
Zhejiang University, China
Increased carotene accumulation in rice endosperm.
( Shao et al., 2017 )
SDN1
CRISPR/Cas
Key Laboratory of Rice Biology and Genetic Breeding, China
Biofortification: Enhanced Zinc and Manganese tolerance and increased Zinc and Manganese accumulation in rice grains.
(Qiao et al., 2019)
SDN1
CRISPR/Cas
Shenzhen University
University of Chinese Academy of Sciences, China
Aromatic three-line hybrid.
( Hui et al., 2021 )
SDN1
CRISPR/Cas
China National Rice Research Institute, China
Increased grain amylose content. Improving grain quality is one of the most important goals in rice breeding. Contribute to the breeding of rice cultivars with better eating and cooking quality, as cooking and eating quality is determined from amylose content.
( Liu et al., 2022 )
SDN1
CRISPR/Cas
Hunan Agricultural University
China National Seed Group Co., China
Reduces phytic acid (anti-nutrient) and improves iron and zinc accumulation in wheat grains. Biofortification.
( Ibrahim et al., 2021 )
SDN1
CRISPR/Cas
Quaid-i-Azam University Islamabad
National Agricultural Research Centre, Pakistan
Changing grain composition: decrease in the prolamines, an increase in the glutenins, increased starch content, amylose content, and β-glucan content. The protein matrix surrounding the starch granules was increased.
(Yang et al., 2020)
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
Norwich Research Park, UK
CSIRO Agriculture and Food, Australia
High gamma-aminobutyric acid (GABA) content. GABA plays a key role in plant stress responses, growth, development and as a nutritional component of grain can also reduce the likelihood of hypertension and diabetes. Increased amino acid content. Higher seed weight and seed protein content.
( Akama et al., 2020 )
SDN1
CRISPR/Cas
Shimane University
Institute of Agrobiological Sciences
National Agriculture and Food Research Organization
Yokohama City University, Japan
Increased flavonoid content, functioning as allelochemicals and insect deterrents.
( Lam et al., 2019 )
SDN1
CRISPR/Cas
The University of Hong Kong
The Chinese University of Hong Kong
Shenzhen
Zhejiang Academy of Agricultural Sciences
Nanjing Forestry University, China
Kyoto University, Japan
Low Cadmium (Cd) accumulating. Cadmium (Cd) is a non-essential heavy metal that is toxic to virtually all living organisms, including plants.
( Songmei et al., 2019 )
SDN1
CRISPR/Cas
Zhejiang University
Hubei Collaborative Innovation Center for Grain Industry
Zhejiang University
Jiaxing Academy of Agricultural Sciences, China
Lowering phytate synthesis in seeds. Phytate is an anti-nutritient.
( Vlčko and Ohnoutková, 2020 )
SDN1
CRISPR/Cas
Czech Academy of Sciences, Czech Republic
Lower levels of D hordein. D hordein is one of the storage proteins in the grain, with a negative effect on malting quality.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Qinghai Province Key Laboratory of Crop Molecular Breeding
Chinese Academy of Sciences
University of Chinese Academy of Sciences, China
Altered protein composition due to mutations in seed storage proteins. Two major families of storage proteins, account for about 70% of total soy seed protein. Some major biochemical components influencing the quality of soy food products, for example tofu, are both the quantity and quality of storage proteins in soybean seeds.
( Li et al., 2019 )
SDN1
CRISPR/Cas
Agriculture and Agri-Food Canada
Western University
Harrow Research and Development Centre, Canada
Sun Yat-sen University
Guangdong Academy of Agricultural Sciences
Minnan Normal University
China
Increased grain weight and grain size. Carbohydrate and total protein levels also increased.
( Guo et al., 2021 )
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
University of California, USA
Imrpoved rice eating and cooking quality with down-regulated rice grain protein content, which is negatively regulated to ECQ.
( Yang et al., 2022 )
SDN1
CRISPR/Cas
Yangzhou University, China
Improved aleurone layer with enhanced grain protein content. Improved grain nutritional quality by improved accumulation of essential dietary minerals (Fe, Zn, K, P, Ca) in the endosperm of rice grain. Improved root and shoot architecture.
( Achary et al., 2021 )
SDN1
CRISPR/Cas
International Centre for Genetic Engineering and Biotechnology, India
Generation of a new glutinous Photothermosensitive Genic-Male-Sterile (PTGMS) line with a low amylose content. PTMGS line combines high-quality and high-light-efficiency use, disease and stress resistance.
( Teng et al., 2021 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Reduction of amylose content (AC). AC is the predominant factor determining rice eating and cooking quality.
( He et al., 2020 )
SDN1
CRISPR/Cas
Northeast Agricultural University
Chinese Academy of Sciences
Jiangsu Academy of Agricultural Sciences
Northeast Agricultural University, China
Reduction in cadmium accumulation. Cadmium is a heavy metal, harmful for human health. Cadmium accumulation represents a severe threat to people consuming rice as a staple food.
( Yang et al., 2019 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Chinese Academy of Sciences, China
High-quality sugar production by rice (98% sucrose content). Carbohydrates are an essential energy-source. Sugarcane and sugar beet were the only two crop plants used to produce sugar.
( Honma et al., 2020 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University, China
Faculty of Engineering
Kitami Institute of Technology
NagoyaUniversity
Tokyo Metropolitan University, Japan
Carnegie Institution for Science, USA
Reduce malnutrition by decreasing antinutrient phytic acid (PA) and increasing Iron and Zinc accumulation. PA has adverse effects on essential mineral absorption and thus is considered as an anti-nutritive for monogastric animals.
( Ibrahim et al., 2021 )
SDN1
CRISPR/Cas
Quaid-i-Azam University Islamabad
National Agricultural Research Centre, Pakistan
Production of high amylose and resistant starch rice. Starch accounts for 80 to 90% of the total mass of rice seeds and is low in resistant starch (RS), which is beneficial in preventing various diseases. Starch with high amylose content (AC) and RS have a lower GI value. Foods with low GI value have beneficial effects on glycemic control.
( Wang et al., 2021 )
SDN1
CRISPR/Cas
National Chiayi University
Taiwan Agricultural Research Institute Chiayi Agricultural Experiment Branch, Taiwan
Fragrance by accumulation of the natural aroma substance 2-acetyl-1-pyrroline (2AP). Fragrance is one of the most important rice quality traits, with 2AP being the major contributor to aroma.
( Tang et al., 2021 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Hubei Academy of Agriculture Sciences
Guangdong Academy of Agricultural Sciences, China
Agricultural Research Center, Egypt
Improved amylose levels to influence grain eating and cooking quality (ECQ).
( Huang et al., 2020 )
SDN1
CRISPR/Cas
Yangzhou University, China
Generation of seed lipoxygenase-free soybean. Lipoxygenases are responsible for an unpleasant beany flavor by the oxidation of unsaturated fatty acids, restricting human consumption.
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Hebei Academy of Agricultural and Forestry Sciences, China
Increased soya bean isoflavone content and resistance to soya bean mosaic virus. Isoflavonoids play a critical role in plant-environment interactions and are beneficial to human health.
( Zhang et al., 2020 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Anhui Academy of Agricultural Science
Guangzhou University, China
High oleic, low linoleic and alpha-linolenic acid phenotype. High concentration of linoleic and alpha-linolenic acids causes oxidative instability.
( Do et al., 2019 )
SDN1
CRISPR/Cas
University of Missouri, USA
Vietnam Academy of Science and Technology, Vietnam
Reduced raffinose family oligosaccharide (RFO) levels in seeds. Human and other monogastric animals cannot digest major soluble carbohydrates, RFOs.
( Le et al., 2020 )
SDN1
CRISPR/Cas
Vietnam Academy of Science and Technology, Vietnam
University of Missouri, USA
Leibniz Institute of Plant Genetics and Crop Plant Research
Germany
High oleic acid, low linoleic content.
( al Amin et al., 2019 )
SDN1
CRISPR/Cas
Jilin Agricultural University, China
Low polyunsaturated fats content. Soybean oil is high in polyunsaturated fats and is often partially hydrogenated. The trans-fatty acids produced through hydrogenation pose a health threat.
( Haun et al., 2014 )
SDN1
TALENs
Cellectis plant sciences Inc., USA
High oleic and low linolenic oil to improve nutritional characteristics, increase shelf-life and frying stability.
( Demorest et al., 2016 )
SDN1
TALENs
Cellectis plant science Inc.
Calyxt, USA
Increased protein content and increased grain weight. Increase in grain protein content has a positive effect on flour protein content and gluten strength, two quality parameters.
( Zhang et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of Chinese Academy of Sciences
Shandong Normal University, China
Reduced gluten content. Coeliac disease is an autoimmune disorder triggered in genetically predisposed individuals by the ingestion of gluten proteins.
( Sánchez-León,et al., 2017 )
SDN1
CRISPR/Cas
Instituto de Agricultura Sostenible (IASCSIC), Spain
University of Minnesota, USA
Modification of starch composition, structure and properties. Foods with a high amylose content (AC) and resistant starch (RS) offer potential to improve human health and lower the risk of serious non-infectious diseases.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences (CAAS)
Nanjing Agricultural University, China
Increased iron (Fe) and magnesium (Mn) content for biofortification: increasing the intrinsic nutritional value of crops.
(Connorton et al., 2017)
SDN1
CRISPR/Cas
John Innes Centre
University of East Anglia, UK
Increased grain number per spikelet.
( Zhang et al., 2019 )
SDN1
CRISPR/Cas
University of Missouri
South Dakota State University
University of California
Donald Danforth Plant Science Center, USA
University of Bristol, UK
Reduce allergen proteins. Structural and metabolic proteins, like α-amylase/trypsin inhibitors are involved in the onset of wheat allergies (bakers' asthma) and probably Non-Coeliac Wheat Sensitivity (NCWS).
( Camerlengo et al., 2020 )
SDN1
CRISPR/Cas
University of Tuscia, Italy
Rothamsted Research, UK
Impasse Thérèse Bertrand-Fontaine, France
Reduced accumulation of free asparagine, the precursor for acrylamide. Acrylamide is a contaminant which forms during the baking, toasting and high-temperature processing of foods made from wheat.
( Raffan et al., 2021 )
SDN1
CRISPR/Cas
Rothamsted Research
University of Bristol, UK
Reduced amount of saturated fatty acids (FA) in soybean seeds for nutrititional improvement. FA are linked to cardiovascular diseases.
( Ma et al., 2021 )
SDN1
CRISPR/Cas
Zhejiang University, China
La Trobe University, Australia
Improve glutinosity in elite varieties. Decreased amylose content without affecting other desirable agronomic traits.
( Zhang et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Purdue University
University of Queensland, USA
Fragrant rice.
( Shan et al., 2015 )
SDN1
TALENs
Chinese Academy of Sciences, China
Increased amylose content. Cereals high in amylose content (AC) and resistant starch (RS) offer potential health benefits and reduce risks of diseases such as coronary heart disease, diabetes and certain colon and rectum cancers.
( Sun et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
University of California, USA
University of Liege, Belgium
Reduced arsenic content, a highly toxic metalloid harming human health. Inorganic Arsenic is listed as a carcinogen.
( Ye et al., 2017 )
SDN1
CRISPR/Cas
Huazhong Agricultural University, China
Altered fatty acid composition. High oleic/low linoleic acid rice. Oleic acid has potential health benefits and helps decrease lifestyle disease.
( Abe et al., 2018 )
SDN1
CRISPR/Cas
National Agriculture and Food Research Organization, Japan
Reduced cesium content. The production of radiocesium in food in contaminated soils is a serious health concern.
( Nieves-Cordones et al., 2017 )
SDN1
CRISPR/Cas
Université Montpellier, France
Reduced cadmium content. Cadmium poses a health treath, as it is a highly toxic heavy metal for most living organisms.
( Tang et al., 2017 )
SDN1
CRISPR/Cas
Hunan Agricultural University, Hunan Hybrid Rice Research Center, Normal University, China
Carotenoid accumulation to solve the problem of vitamin A deficiency that is prevalent in developing countries.
( Endo et al., 2019 )
SDN1
CRISPR/Cas
National Agriculture and Food Research Organization
Ishikawa Prefectural University, Japan
Fine-tuning the amylose content, one of the major contributors to the eating and cooking quality.
( Xu et al., 2021 )

BE
Jiangsu Academy of Agricultural Sciences/Nanjing Branch of Chinese National Center for Rice Improvement
Yangzhou University
Chinese Academy of Sciences, China
CSIRO Agriculture and Food, Australia
Fragrant rice by introducing aroma into non-aromatic rice varieties. The genome edited fragrant rice was then used as starting material for molecular breeding to introduce both fragrance and high anthocyanin levels in rice.
( Shi et al., 2023 )
SDN1
CRISPR/Cas
Chinese Academy of Agriculture Sciences (CAAS)
Tianjin Academy of Agricultural Sciences
Chengdu National Agricultural Science and Technology Center, China
Lowered amylose content and viscosity, risen gel consistency and gelatinization temperature values, all resulting in improved eating and cooking quality.
( Song et al., 2023 )
SDN1
CRISPR/Cas
Jiangsu University
Institute of Food Crops
Yangzhou University, China
Glossy sheat phenotype.
( Gerasimova et al., 2023 )
SDN1
CRISPR/Cas
Siberian Branch of the Russian Academy of Sciences
Vavilov Institute of Plant Genetic Resources (VIR)
Siberian Branch of the Russian Academy of Sciences, Russia

Leibniz Institute of Plant Genetics and Crop Plant Research (IPK), Germany
High levels of monounsaturated fatty acids (MUFAs) in soybean seed oil. High MUFA content in vegetable oils can lead to significant health benefits and improve the oxidative stability, which are essential for both food usage and biodiesel (and other renewable resource) synthesis.
( Li et al., 2023 )
SDN1
CRISPR/Cas
Northeast Agricultural University, China
Reduced content of trypsin inhibitors, one of the most abundant anti-nutritional factors in soybean seeds. Reduction of trypsin inhibitors leads to improved. digestibility of soybean meal.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Virginia Tech, USA
Reduced grain chalkiness.
( Gann et al., 2023 )
SDN1
CRISPR/Cas
Cell and Molecular Biology Program
Department of Chemistry and Biochemistry
University of Arkansas at Little Rock, USA
Reduced levels of phytic acid (PA). PA has adverse effects on essential mineral absorption and thus is considered as an anti-nutritive for monogastric animals.
( Krishnan et al., 2023 )
SDN1
CRISPR/Cas
ICAR-Indian Agricultural Research Institute (IARI)
Bharathidasan University, India
Reduced levels of polybrominated diphenyl ethers, organic pollutants which have great ecological and health risks, in the edible parts.
( Chen et al., 2023 )
SDN1
CRISPR/Cas
Zhejiang University
Zhejiang Provincial Key Laboratory of Organic Pollution Process and Control, China
Improved fatty acid content: high oleic acid, decreased linoleic acid content to improve nutritional characteristics, increase shelf-life and frying stability.
(Zhang et al., 2023)
SDN1
CRISPR/Cas
Jilin Agricultural University, China
Reduced content of anti-nutritional factors in soybean seeds, leading to improved digestibility.
( Figliano et al., 2023 )
SDN1
CRISPR/Cas
UEL - Universidade Estadual de Londrina, Portugal
Decreased cadmium accumulation in rice grain, while leaving important agronomic traits including yield, unaffected. Cadmium poses a health threat, as it is a highly toxic heavy metal for most living organisms
( Luo et al., 2023 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of the Chinese Academy of Sciences
China National Rice Research Institute
Southern University of Science and Technology, China
Rice grain with a reduced amino acid and total protein content without affecting the agronomic traits of the plant. Additionally, the grain showed improved cooking and eating quality.
( Yang et al., 2023 )
SDN1
CRISPR/Cas
Yangzhou University, China
Highly specific detection of Ochratoxin A (OTA) in cereal samples. OTA is classified as a Class 2B carcinogens. The method can be flexibly customized to detect a wide range of small molecular targets and holds great promise as a versatile sensing kit with applications in various fields requiring sensitive and specific detection of diverse analytes.
( Chen et al., 2023 )
SDN1
CRISPR/Cas
Ningbo University
Hainan University
Ningbo Clinical Pathology Diagnosis Center, China
University of New South Wales, Australia
Decreased storage-proteins, which allows improved forein protein production in seed.
( Ha et al., 2023 )
SDN1
CRISPR/Cas
Dong-A University
South Korea
High amylose content. High-amylose starches are digested slowly which could provide increased satiety and reduced risk of diabetes, cardiovascular disease and colorectal cancer.
( Kim et al., 2023 )
SDN1
CRISPR/Cas
Kyungpook National University
National Institute of Crop Science, South Korea
Reduced arsenic (As) accumulation in rice grain. Inorganic As is a carcinogen and decreasing the accumulation would improve the food safety of rice.
( Xu et al., 2024 )
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Slender grains in bold grain varieties.
( Shanthinie et al., 2024 )
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University, India
Zero amylose grain. Amylose levels significantly influence processing of grain.
( Li et al., 2024 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
Qinghai University
Qinghai Academy of Agricultural and Forestry
Sciences
Shandong Academy of Agricultural Sciences, China
β-conglycinin deficiency, which lowers allergenicity and increases nutritional value.
( Song et al., 2024 )
SDN1
CRISPR/Cas
Northeast Agricultural University/Key Laboratory of Soybean Biology of the Chinese Education Ministry
Harbin Normal University
Keshan Branch of Heilongjiang Academy of Agricultural Sciences
Jilin Agricultural University, China
USDA Agricultural Research Service
University of Missouri, USA
Decrease in percentage of grains with chalkiness and chalkiness degree.
( Fan et al., 2024 )
SDN1
CRISPR/Cas
Yangtze University
Ningbo Academy of Agricultural Science
Yichang Academy of Agricultural Sciences, China

Traits related to increased plant yield and growth

Improvement of yield by reducing the "easy to shatter" trait. Reduced seed shattering ensures better stability during the harvesting processes and improved yields.
( Sheng et al., 2020 )
SDN1
CRISPR/Cas
Hunan Agricultural University
Hunan Hybrid Rice Research Center
Hunan Academy of Agricultural Sciences, China
Increased yield under different environmental conditions: well-watered, drought, normal nitrogen and low nitrogen field conditions and at multiple geographical locations.
(Wang et al., 2020)
SDN1
CRISPR/Cas
Sinobioway Bio-Agriculture Group Co.
Ltd
Corteva Agriscience
Johnston, USA
Improved rice photosynthetic efficiency and yield: increased light saturation points, stomatal conductance, light tolerance and photosynthetic yields.
(Ye et al., 2021)
SDN1
CRISPR/Cas
South China Agricultural University, China
Semi-dwarf phenotype to improve product and lodging resistance.
( Zhang et al., 2020 )
SDN1
CRISPR/Cas
Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, China
Control grain size and seed coat color.
( Tra et al., 2021 )

BE
International Rice Research Institute, Philippines
Dahlem Center of Plant Sciences Freie Universität, Germany
Synthetic Biology, Biofuel and Genome Editing R&
D Reliance Industries Ltd, India
Increased yield potential by nitrogen use efficiency. Nitrogen fertilizer has been applied broadly to increase yield. However, low nitrogen use efficiency causes environmental pollution and ecological deterioration by the nitrogen fertilizers.
( Zhang et al., 2021 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Zhengzhou University, China
Improved grain yield by modulating pyruvate enzymes and cell cycle proteins, leading to increased grain size. The grain size is a major determinant for rice yield and a vital trait for domestication and breeding.
( Usman et al., 2020 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Improved yield and fragrance.
( Usman et al., 2020 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University, China
Early flowering and maturity. Flowering time (heading date) is an important trait for crop yield and cultivation.
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Sinobioway Bio-Agriculture Group, Co., China
Corteva™ Agriscience, USA
Improved high-density yield and drought/osmotic stress tolerance.
( Chen et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Shanxi Academy of Agricultural Sciences, China
Texas Tech University, USA
Regulate shade avoidance. Soybean displays the classic shade avoidance syndrome (SAS), which leads to yield reduction and lodging under density farming conditions.
( Lyu et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Jilin Agricultural University
Shandong Agricultural University
Northeast Agricultural University, China
Increasing the number of seeds per pod (NSPP), an important yield determinant.
( Cai et al., 2021 )
SDN1
CRISPR/Cas
South China Agricultural University, China
Control flowering time, an important determinant for soybean yield and adaptation.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of Chinese Academy of Sciences
Guangzhou University
Agronomy College of Heilongjiang Bayi Agricultural University
Nanjing Agricultural University
Heilongjiang Academy of Agricultural Sciences, China
Late flowering. Photoperiod sensitivity limits geographical range of cultivation.
( Cai et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Plant architecture: high tillering and reduced height.
(Butt et al., 2018)
SDN1
CRISPR/Cas
King Abdullah University of Science and Technology, Saudi Arabia
Improved nitrogen use efficiency.
( Li et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Huazhong Agricultural University, China
University of California, USA
Improvement of grain weight. Longer panicle.
( Xu et al., 2016 )
SDN1
CRISPR/Cas
China National Rice Research Institute, China
China Three Gorges University, China
Altered grain number per panicle and increased seed weight.
( Li et al., 2016 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Altered grain number per panicle.
( Shen et al., 2016 )
SDN1
CRISPR/Cas
National Rice Research Institute, China
Increased seed weight.
( Hu et al., 2018 )
SDN1
CRISPR/Cas
Fudan University, China
Increased seed weight.
( Shen et al., 2017 )
SDN1
CRISPR/Cas
Yangzhou University, China
Increased seed weight.
( Ji et al., 2017 )
SDN1
CRISPR/Cas
Agronomy College of Henan Agricultural University, China
Genetic diversity.
( Shen et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Yangzhou University, China
Promote outgrowth buds and increase tiller number.
( Lu et al., 2017 )
SDN1
CRISPR/Cas
Wuhan Institute of Bioengineering
Huazhong Agricultural University
Chinese Academy of Sciences, China
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. Complete abolition of pollen development.
( Lee et al., 2016 )
SDN1
CRISPR/Cas
Kyung Hee University, South Korea
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.
( Li et al., 2016 )
SDN1
CRISPR/Cas
Shanghai Jiao Tong University, China
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.
( Xie et al., 2017 )
SDN1
CRISPR/Cas
South China Agricultural University, China
Regulation of pollen tube growth. The tube grows in female reproductive tissues to transport two sperm cells into the embryo sac for double fertilization during sexual reproduction.
( Liu et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of Chinese Academy of Sciences, China
Increased grain number per main panicle and an increased seed settling rate.
( Qian et al., 2017 )
SDN1
CRISPR/Cas
China Agricultural University, China
Grain yield, regulation of seed development.
( Yuan et al., 2017 )
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Generation of important yield-related trait characteristics: dense and erect panicles and reduced plant height.
(Wang et al., 2017)
SDN1
CRISPR/Cas
Syngenta Biotechnology, China
Altered spike architecture and grain treshability to increase grain production.
( Liu et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Longer grains and increased glume cell length.
( Sheng et al., 2022 )
SDN1
CRISPR/Cas
China Agricultural University
Chinese Academy of Sciences, China
Bigger grains, increased grain weight.
( Zhang et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Reduced seed dormancy: rapid and uniform germination of seeds is important for rice production. Mutant seeds began to germinate 1 day after sowing, while WT seeds needed 2 days.
(Jung et al., 2019)
SDN1
CRISPR/Cas
Hankyong National University
Chungbuk National University
Hanyang University, China
Central Luzon State University, Philippines
Plants with longer primary roots and more crown roots, as well as increased sensitivity to auxins and cytokinins. The rice root system is important for growth.
( Mao et al., 2019 )
SDN1
CRISPR/Cas
Fudan University
Sichuan Agricultural University
Shanghai Normal University
Chinese Academy of Sciences, China
Enhanced rice grain yield by decoupling panicle number and size
( Song et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
Shandong Agricultural University
Hainan Yazhou Bay Seed Laboratory, China
Enhanced photosynthesis and increases seed yield.
( Hu et al., 2022 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Chinese Academy of Sciences
Henan Institute of Science and Technology, China
Semi-dwarf phenotype. Plant height is an important agronomic trait of rice, it directly affects the yield potential and lodging resistance.
( Han et al., 2019 )
SDN1
CRISPR/Cas
Guangxi University
South China Agricultural University
Guangxi University, China
Semi-dwarf phenotype with desired agronomic traits: tolerance to low phosporus levels and broad-spectrum resistance to diseases and insects.
(Hu et al., 2019)
SDN1
CRISPR/Cas
China National Rice Research Institute, China
Range of beneficial phenotypes: additional tillers and smaller culms and panicles.
(Cui et al., 2020)
SDN1
CRISPR/Cas
China National Rice Research Institute
Huazhong Agricultural University, China
Yangzhou University, Nagoya University, Japan
Positive regulation for grain dormancy. Lack of grain dormancy in cereal crops causes losses in yield and quality because of preharvest sprouting.
( Lawrenson et al., 2015 )
SDN1
CRISPR/Cas
Norwich Research Park, UK
Murdoch University, Australia
Compact architecture with a smaller petiole angle than wild-type plants.
( Zhang et al., 2022 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Beijing Vocational College of Agriculture
Xiamen University, China
Increased grain yield without side effect.
( Gho et al., 2022 )
SDN1
CRISPR/Cas
Kyung Hee University, South Korea
International Rice Research Institute, Philippines
Altered plant architecture to inrease yield: increased node number on the main stem and branch number.
(Bao et al., 2019)
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Huazhong Agricultural University, China
Duy Tan University, Vietnam
RIKEN Center for Sustainable Resource Science, Japan
Increased nodule numbers. Soybean is a globally important crop for oil production and protein for human diet.
( Bai et al., 2019 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Nanchang University, China
Improved rice grain shape and appearance quality. Potential application in breeding of rice varieties with optimized grain morphologies. Slender grain shape.
( Zhao et al., 2018 )
SDN1
CRISPR/Cas
Yangzhou University, China
Increased yield.
( Zhou et al., 2019 )
SDN1
CRISPR/Cas
University of Electronic Science and Technology of China
Xichang University, China
University of Maryland, USA
Promoted rice growth and productivity.
( Miao et al., 2018 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Purdue University, USA
Increased yield.
( Huang et al., 2018 )
SDN1
CRISPR/Cas
Yunnan University
Chinese Academy of Sciences
BGI-Baoshan, China
Improvement for larger kernel and yield.
( Ma et al., 2015 )
SDN1
CRISPR/Cas
Northwest A &
F University
Chinese Academy of Agricultural Sciences, China
Increased grain size and modulated shoot architecture.
( Miao et al., 2020 )
SDN1
CRISPR/Cas
Zhejiang A&
F University
Nanchang University
Chinese Academy of Sciences, China
Purdue University, USA
Dwarf and high tillering phenotypes.
( Yang et al., 2017 )
SDN1
CRISPR/Cas
Shenzhen University
The Chinese University of Hong Kong, China
Increased spikelet number and delayed heading date. Two traits that are crucial and correlated to yield in wheat.
( Chen et al., 2022 )
SDN1
CRISPR/Cas
China Agricultural University, China
Dwarf stature and a lesion-mimic phenotype. Fungal resistance: enhanced resistance to the pathogen Magnaporthe oryzae. Increased content of salicylic acid and induced plant defense responses.
(Ma et al., 2018)
SDN1
CRISPR/Cas
Peking University
Chinese Academy of Agricultural Sciences, China
Improved grain yield by promoting outgrowth buds and increasing tiller number.
( Lu et al., 2018 )
SDN1
CRISPR/Cas
Wuhan Institute of Bioengineering
Huazhong Agricultural University, China
Increased yield potential trough improved nitrogen use efficiency. Enhanced tolerance to N starvation, and showed delayed senescence and increased grain yield in field conditions. Lowered use of N fertilizer.
( Zhang et al., 2021 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Zhengzhou University, China
Increase in plant height, tiller number, grain protein content and yield. 1.5- to 2.8-fold increase in total chlorophyll content in the flag leaf at the grain filling stage. Delayed senescence by 10–14 days. High nitrogen content in shoots under low nitrogen conditions.
( Karunarathne et al., 2022 )
SDN1
CRISPR/Cas
Murdoch University
Department of Primary Industries and Regional Development, Australia
Overexpression causes strongly promoted stem elongation, lower expression resulted in dwarf phenotype.
( Mu et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Improved grain length and weight by promoting cell proliferation in spikelet hull
( Wu et al., 2022 )
SDN1
CRISPR/Cas
Chongqing University, China
Increased grain weight and grain size. Carbohydrate and total protein levels also increased.
( Guo et al., 2021 )
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
University of California, USA
Improved grain quality without severe yield penalty under nitrogen reduction conditions.
( He et al., 2022 )
SDN1
CRISPR/Cas
Rice Research Institute of Shenyang Agricultural University
Tianjin Tianlong Science and Technology Co. LTD.
National Japanica Rice Research and Development Center, China
Enhanced performance of soybean under dense conditions.
( Ji et al., 2022 )
SDN1
CRISPR/Cas
Academy of Agricultural Sciences
Southern University of Science and Technology, China
Improved rice yield and immunity.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Chinese Academy of Agricultural Sciences, China

Higher yield than wild-type (WT) plants due to increased grain number per panicle, elevated grain weight, and enhanced harvest index.
( Wei et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Shanghai Normal University, China
Improved grain length and weight by promoting cell proliferation.
( Wu et al., 2022 )
SDN1
CRISPR/Cas
Chongqing University, China
Promoting nodulation: up-regulation of expression levels of genes involved in nodulation. Nitrogen-fixing symbiotic nodules strongly up regulate yield.
(Wang et al., 2022)
SDN1
CRISPR/Cas
Beijing Institute of Technology
Chinese Academy of Agricultural Sciences, China
Root growth angle regulation, among the most important determinants of root system architecture. Root growth angle controls water uptake capacity, stress resilience, nutrient use efficiency and thus yield of crop plants.
( Kirschner et al., 2021 )
SDN1
CRISPR/Cas
University of Bonn
University of Cologne
Leibniz Institute of Plant Genetics and Crop Plant Research Gatersleben
Justus-Liebig-University Giessen, Germany
University of Bologna, Italy

Increased water use efficiency without growth reductions in well-watered conditions.
( Blankenagel et al., 2022 )
SDN1
CRISPR/Cas
Technical University of Munich
Max Planck Institute of Molecular Plant Physiology
German Research Center for Environmental Health
KWS SAAT SE &
Co.KGaA
Université Technique de Munich
Heinrich Heine University, Germany
LEPSE - Écophysiologie des Plantes sous Stress environnementaux, France
Increased rice grain size and yield.
( Wang et al., 2022 )
SDN1
CRISPR/Cas
China National Seed Group Co. Ltd., China
Increased yield: plants produced more tillers and grains than azygous wild-type controls and the total yield was increased up to 15 per cent.
(Holubova et al., 2018)
SDN1
CRISPR/Cas
Palacký University
Centre of the Region Haná for Biotechnological and Agricultural Research, Czech Republic
Leibniz Institute of Plant Genetics and Crop Plant Research (IPK) Gatersleben, Germany
Improved pod shattering resistance. Pod shattering has been a negatively selected trait in soybean domestication and breeding as it can lead to devastating yield loss of soybean.
( Zhang et al., 2022 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Heilongjiang Bayi Agricultural University
Hebei Academy of Agricultural and Forestry Sciences, China
Altered spike architecture.
( de Souza Moraes et al., 2022 )
SDN1
CRISPR/Cas
Wageningen University and Research, The Netherlands
Universidade de São Paulo, Brazil
Norwich Research Park, UK
Rheinische Friedrich-Wilhelms-Universität, Germany
Reduction of soybean plant height and shortening of the internodes. The height of the soybean plant is a key trait that significantly impacts the yield.
( Cheng et al., 2019 )
SDN1
CRISPR/Cas
Guangzhou University
Chinese Academy of Sciences
University of Chinese Academy of Sciences, China
Increased grain size and chalkiness.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Henan Agricultural University, China
Increased grain size.
( Chen et al., 2020 )
SDN1
CRISPR/Cas
China National Rice Research Institute
Huazhong Agricultural University
Nanchong Academy of Agricultural Sciences, China
Increased grain number due to increased meristem activity and enhanced panicle branching.
( Li et al., 2013 )
SDN1
ZFN
Chinese Academy of Sciences
National Hybrid Rice Research and Development Center
Chinese Academy of Agricultural Sciences
China National Hybrid Rice Research and Development Center
Wuhan University, China
Delayed heading date, increased yield and reduced chalkiness under field high temperature stress.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Hubei Academy of Agricultural Sciences

Hubei Hongshan Laboratory, China
Semi-dwarf phenotype to improve lodging resistance and increased seed dormancy. Increased seed dormancy can be beneficial for use in the malting industry.
( Cheng et al., 2023 )
SDN1
CRISPR/Cas
University of Tasmania
Murdoch University
Department of Primary Industries and Regional Development, Australia
Chinese Academy of Agricultural Sciences, China
OsGEF5 and OsGDI1 single mutants show significantly reduced height and longer and thinner grains.
( Shad et al., 2022 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Hubei Hongshan Laboratory, China
Increased grain yield under phosphorus-deficient conditions.
( Ishizaki et al., 2022 )
SDN1
CRISPR/Cas
Japan International Research Center for Agricultural Sciences (JIRCAS), Japan
Early flowering time. Flowering time (heading date) is an important trait for crop yield and cultivation.
( Yin et al., 2023 )
SDN1
CRISPR/Cas
Shenyang Agricultural University, China
Control flowering time, an important determinant for soybean yield and adaptation.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Guangzhou University
Yunnan Agricultural University
Nanjing Agricultural University
Key Laboratory of Crop Genetics and Breeding of Hebei, China
Increase in 1000-grain weight, grain area, grain width, grain length, plant height, and spikelets per spike.
( Errum et al., 2023 )
SDN1
CRISPR/Cas
National Agricultural Research Centre (NARC)
PARC Institute of Advanced Studies in Agriculture (PIASA)
Pakistan Agricultural Research Council, Pakistan
Altered plant architecture to increase yield: more compact plant architecture.
(Kong et al., 2023)
SDN1
CRISPR/Cas
Nanjing Agricultural University
Chinese Academy of Agricultural Sciences
Hebei Academy of Agricultural and Forestry Sciences, China
Accelerated seedling growth. Because seedling growth and development are the basis of rice tillering and reproduction, rapid seedling growth and fast sprouting from the soil are vital for the emergence rate and yield.
( Teng et al., 2023 )
SDN1
CRISPR/Cas
Hangzhou Normal University
Inner Mongolia University
Zhejiang Academy of Agricultural Sciences
Chinese Academy of Agricultural Sciences, China
Longer root hairs. Root hairs effectively enlarge the soil-root contact area and play essential roles for nutrient and water absorption.
( Yang et al., 2023 )
SDN1
CRISPR/Cas
Zhejiang University
Linyi University
Hunan Agricultural University, China
Improved yield under short day conditions.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
South China Agricultural University, China
Increased nitrogen utilization efficiency under high nitrate concentrations.
( Hang et al., 2023 )
SDN1
CRISPR/Cas
Guizhou University
Guangdong Provincial Key Laboratory of Applied Botany
Guangdong Academy of Agricultural Sciences, China
Increased stomatal density, stomatal conductance, photosynthetic rate and transpiration rate. Fine tuning the stomatal traits can enhance climate resilience in crops.
( Rathnasamy et al., 2023 )
SDN1
CRISPR/Cas
Tamil Nadu Agricultural University
Sugarcane Breeding Institute, India
Enhanced photosynthesis.
( Caddell et al., 2023 )
SDN1
CRISPR/Cas
United States Department of Agriculture - Agricultural Research Service (USDA ARS)
University of California at Berkeley
Utah State University
Texas A&
M University, USA
Altered plant architecture along with a shorter plant height, grain size and increased spikelets and grain density.
( Zhang et al., 2023 )
SDN1
CRISPR/Cas
Shanghai Agrobiological Gene Center, China
Increased tiller number and grain yield.
( Cui et al., 2023 )
SDN1
CRISPR/Cas
The University of Tokyo
Kyoto University
National Institute of Crop Science, Japan
Leaf inclination: the leaf angle is a trait that contributes to crop yield determination.
(Trionfini et al., 2023)
SDN1
CRISPR/Cas
Universidad Nacional del Litoral, Argentina
Increased breaking force, leading to improved lodging resistance.
( Dang et al., 2023 )
SDN1
CRISPR/Cas
Shenyang Agricultural University/Key Laboratory of Northern geng Super Rice Breeding, China
Super-dwarf phenotype. Rice plants with compact growth habits and reduced plant height can be useful in some environments.
( Peng et al., 2023 )
SDN1
CRISPR/Cas
Hunan Agricultural University
Chinese Academy of Agricultural Sciences
Agricultural College of Yangzhou University
Tianjin Academy of Agriculture Sciences, China
Improved lodging resistance in later growth stages due to shorter plant height with enhanced resistance to rice blast.
( Gang et al., 2023 )
SDN1
CRISPR/Cas
Huaiyin Institute of Agricultural Science/Huai'
an Key Laboratory of Agricultural Biotechnology
Huaiyin Normal University
China National Rice Research Institute, China
Reduction of plant height through accumulation of ceramides. Plant height is an important agronomic trait of rice, it directly affects the yield potential and lodging resistance.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Nanchang University
Henan Agricultural University, China
Hokkaido University, Japan
Early heading. Heading date is an important agronomic trait that affects climatic adaptation and yield potential.
( Fan et al., 2023 )
SDN1
CRISPR/Cas
Henan Agricultural University, China
Enhanced grain yield and semi-dwarf phenotype by manipulating brassinosteroid signal pathway.
( Song et al., 2023 )
SDN1
CRISPR/Cas
China Agricultural University, China
Hard Winter Wheat Genetics Research Unit, USA
Decreased spike rachis node number and increased grain size and weight.
( Fan et al., 2023 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Hainan Yazhou Bay Seed Laboratory
Shandong Academy of Agricultural Sciences
China Agricultural University
Hubei Academy of Agricultural Sciences, China
Improved nitrogen use efficiency, growth and yield in low nitrogen environment.
( Liu et al., 2023 )
SDN1
CRISPR/Cas
The University of Tokyo, Japan
Shorter flowering time and increased yield.
( Cheng et al., 2023 )
SDN1
CRISPR/Cas
Jilin Normal University
Jilin Academy of Agricultural Sciences, China
Early heading phenotype that escapes from cold stress and achieves high yield potential.
( Zhou et al., 2023 )
SDN1
CRISPR/Cas
Nanjing Agricultural University
Institute of Lianyungang Agricultural Science of Xuhuai Area/Lianyungang Institute of Agricultural Sciences
Chinese Academy of Agricultural Sciences, China
Delayed heading date with improved yield-related traits e.g. height, tiller number and grain weight.
( Li et al., 2023 )
SDN1
CRISPR/Cas
South China Agricultural University
Guangdong Laboratory for Lingnan
Modern Agriculture, China
Altered root architecture with increased tillers and total grain weight.
( Rahim et al., 2023 )
SDN1
CRISPR/Cas
Quaid-e-Azam University
National Agricultural Research Centre (NARC)
The University of Haripur, Pakistan
King Saud University, Saudi Arabia
Nile University
Ain Shams University, Egypt
Chonnam National University, South Korea
Improved spikelet number per panicle led to increased grain yield per plant.
( Ludwig et al., 2023 )
SDN1
CRISPR/Cas
International Rice Research Institute (IRRI), Philippines
University of Pavia, Italy
Delayed flowering, which can increase grain yield and quality.
( Zhou et al., 2024 )
SDN1
CRISPR/Cas
Northeast Forestry University
Chinese Academy of Sciences
Graduate University of Chinese Academy of Sciences
Beidahuang Group Erdaohe Farm CO., China
Increased grain yield and quality.
( Luo et al., 2024 )
SDN1
CRISPR/Cas
Guizhou University, China
King Saud University, Saudi Arabia
Shortened flowering time and maturity, determining their favourable latitudinal zone for cultivation.
( Gao et al., 2024 )
SDN1
CRISPR/Cas
Syngenta Seed Technology China Co., China
Bigger seeds and increased yield.
( Xie et al., 2024 )
SDN1
CRISPR/Cas
Anhui Agricultural University
Anhui Agricultural University
Bellagen Biotechnology Co. Ltd
Ministry of Agriculture and Rural Affairs
Southern University of Science and Technology
Hainan Yazhou Bay Seed Laboratory, China
Dwarf phenotype, which can aid in obtaining more compact, densely planted soybean varieties to boost productivity.
( Xiang et al., 2024 )
SDN1
CRISPR/Cas
Wuhan Polytechnic University
Chinese Academy of Agricultural Sciences, China
Increased grain yield when grown at low latitudes.
( Song et al., 2024 )
SDN1
CRISPR/Cas
Zhejiang Academy of Agricultural Sciences
Zhejiang A&
F University, China
Improved lodging resistance and biomass saccharification.
( Wang et al., 2024 )
SDN1
CRISPR/Cas
Shenyang Agricultural University, China
Enhanced tillering and yield.
( Jin et al., 2024 )
SDN1
CRISPR/Cas
Guizhou University, China
Increased seed size and yields without alterations in plant architecture or seed nutrition.
( Wang et al., 2024 )
SDN1
CRISPR/Cas
Northeast Forestry University
Northeast Agricultural University, China
Increased plant height with an earlier heading date.
( Fu et al., 2024 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Henan Normal University
Sichuan Agricultural University
Henan Agricultural University
Shanxi University, China
Longer rice grains with reduces plant height.
( Xu et al., 2024 )
SDN1
CRISPR/Cas
Rice Research Institute of Shenyang Agricultural University
Shenyang Agricultural University, China
Earlier maturation time under both short-day and long-day conditions.
( Wu et al., 2024 )
SDN1
CRISPR/Cas
Heilongjiang Bayi Agricultural University
Chinese Academy of Agricultural Sciences
Northeast Agricultural University
Syngenta Biotechnology (China) Co. Ltd, China
Increased rice grain yield under field conditions.
( Li et al., 2024 )
SDN1
CRISPR/Cas
Sichuan Agricultural University
Nanchong Academy of Agricultural Science
Neijiang Academy of Agricultural Science, China
Delayed flowering.
( Kim et al., 2024 )
SDN1
CRISPR/Cas
Myongji University, Korea
Earlier heading date. Heading date is one of the key agronomic traits that determines adaptation of rice cultivars.
( Wei et al., 2024 )
SDN1
CRISPR/Cas
Yangzhou University
Jiangsu Ruihua Agricultural Technology Co. Ltd, China
Increased grain length and yield.
( Zhang et al., 2024 )
SDN1
CRISPR/Cas
Shenyang Agricultural University
Ningbo University, China
Increased grain yield.
( Chen et al., 2024 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Chinese Academy of Agricultural Sciences
Tianjin Academy of Agricultural Sciences
Chinese Academy of Agricultural Sciences
Minzu University of China
Hebei Academy of Agriculture and Forestry Science, China
Increased tiller number.
( Awan et al., 2024 )
SDN1
CRISPR/Cas
National Institute for Biotechnology and Genetic Engineering
Quaid-i-Azam University, Pakistan

Traits related to industrial utilization

Early heading: in regions with short growing seasons, early maturing varieties to escape frost damage are required.
(Sohail et al., 2022)
SDN1
CRISPR/Cas
China National Rice Research Institute
Northern Center of China National Rice Research Institute
Zhejiang A&
F University, China
Mir Chakar Khan Rind University
Agriculture Research System Khyber, Pakistan
Ministry of Agriculture, Bangladesh
Agriculture Research Center, Egypt
Early heading: timing of heading is crucial for the reproduction and the geographical expansion of cultivation of rice.
(Sun et al., 2022)
SDN1
CRISPR/Cas
China National Rice Research Institute
Shanghai Academy of Agricultural Sciences
Northern Center of China National Rice Research Institute
Xuzhou Institute of Agricultural Sciences, China
Enabled clonal reproduction trough seeds. Application of the method may enable self-propagation of a broad range of elite F1 hybrid crops.
( Wang et al., 2019 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Université Paris-Saclay, France
Late flowering time.
( Li et al., 2022 )
SDN1
CRISPR/Cas
Zhejiang University
China Zhejiang Zhengjingyuan Pharmacy Chain Co., Ltd. &
Hangzhou Zhengcaiyuan Pharmaceutical Co., China
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
Enhanced genetic recombination frequency to increase genetic diversity and disrupting genetic interference.
( Liu et al., 2021 )
SDN1
CRISPR/Cas
China National Rice Research Institute
Chinese Academy of Sciences
Chinese Academy of Agricultural Sciences, China
Significantly longer seed dormancy period, may result in reduced pre-harvest sprouting of grains on spikes.
( Abe et al., 2019 )
SDN1
CRISPR/Cas
Institute of Crop Science
Okayama University
Yokohama City University
Institute of Agrobiological Sciences
Obihiro University of Agriculture and Veterinary Medicine, Japan
Thermosensitive genic male sterile lines with high blast resistance and fragrance quality. Resources for hybrid rice breeding.
( Liang et al., 2022 )
SDN1
CRISPR/Cas
China National Rice Research Institute, China
Regulation of flowering time and drought tolerance: flowered 9.6 and 5.8 days earlier.
(Gu et al., 2022)
SDN1
CRISPR/Cas
Yangzhou University, China
New red-grained and pre-harvest sprouting (PHS)-resistant wheat varieties with elite agronomic traits. PHS reduces yield and grain quality, additionally the red pigment of the grain coat contains proanthocyanidins, which have antioxidant activity and thus health-promoting properties.
( Zhu et al., 2022 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Fujian Academy of Agricultural Sciences
Henan University
Shenzhen Research Institute of Henan university
Taiyuan University of Technology
Southern University of Science and Technology, China
University of Edinburgh, UK
Generating male sterility lines (MLS). Using MLS in hybrid seed production reduces costs and ensures high purity of the varieties because it does not produce pollen and has exserted stigmas.
( Zhang et al., 2023 )
SDN1
CRISPR/Cas
Shandong Academy of Agricultural Sciences
Key Laboratory of Wheat Biology and Genetic Improvement on North Yellow and Huai River Valley
National Engineering Laboratory for Wheat and Maize
Chinese Academy of Agricultural Sciences, China
Wine fermentation: minimize ethyl carbamate (EC) accumulation. EC is a potential carcinogen to humans. EC is mainly produced through the reaction between urea and ethanol during the Chinese wine brewing process.
(Wu et al., 2020)
SDN2
CRISPR/Cas
Jiangnan University
Zhejiang Shuren University, China
Generation of male sterility lines. Heterosis, the breeding result in which heterozygous hybrid progeny are superior to both homozygous parents, depends on the selection and application of male-sterile lines (MSL). Using MSL can reduce the production cost of hybrid seeds and improve its quality.
( Chen et al., 2021 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of Chinese Academy of Sciences
Jilin Agricultural University
Jilin Academy of Agricultural Sciences, China
Control photoperiodic flowering to allow adaptation of cultivars. Flowering time is a critical characteristic to determine the geographic distribution and regional adaptability of soybean.
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
Generating male sterility lines (MSL). MS is the absence or non-function of pollen grain in plant or incapability of plants to produce or release functional pollen grains. Using MS lines eliminates the process of mechanical emasculation in hybrid seed production.
( Zou et al., 2017 )
SDN1
CRISPR/Cas
Sichuan Agricultural University, China
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
Rescued male fertility. Hybrids between divergent populations commonly show hybrid sterility; this reproductive barrier hinders hybrid breeding of the japonica and indica rice subspecies.
( Shen et al., 2017 )
SDN1
CRISPR/Cas
State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources
Key Laboratory of Plant Functional Genomics and Biotechnology of Guangdong Provincial Higher Education Institutions
South China Agricultural University, China
Early maturity of rice varieties. Rice is a tropical short-day plant. The northward cultivation in China is accompanied with daylength extension and temperature decrease, which are unfavorable for rice, to complete flowering and seed setting.
( Li et al., 2017 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
Jiangsu Academy of Agricultural Sciences, China
Restoring cytoplasmic sterility.
( Kazama et al., 2019 )
SDN2
TALENs
Tohoku University
Tamagawa University
The University of Tokyo
National Institute of Genetics
Tokyo Institute of Technology
Tamagawa University
Japan Science and Technology Agency, Japan
Conversion of hulled into naked barley.
( Gasparis et al., 2018 )
SDN1
CRISPR/Cas
National Research Institute
Warsaw University of Life Sciences (SGGW), Poland
Generating male sterility lines (MLS). Using MLS in hybrid seed production reduces costs and ensures high purity of the varieties because it does not produce pollen and has exserted stigmas.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Peking University Institute of Advanced Agricultural Sciences
Peking University
Beijing Key Laboratory of Plant Gene Resources and Biotechnology for Carbon Reduction and Environmental Improvement, China
Fertility recovery of male sterility in wheat lines with excelling agronomic and economic traits for breeding purpose, as male-sterile plants cannot be used for selection.
( Tang et al., 2021 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences
China Agricultural University, China
Improve biofuel production by mediating lignin modification. Lignocellulosic biomasses are an abundant renewable source of carbon energy. Heterogenous properties of lignocellulosic biomass and intrinsic recalcitrance caused by cell wall lignification lower the biorefinery efficiency. Reduced lignin content is desired.
( Lee et al., 2021 )
SDN1
CRISPR/Cas
Korea Institute of Science and Technology (KIST)
University of Science and Technology (UST)
Daejeon, South Korea
Confer male sterility for hybrid seed production. Male sterility is an important trait, especially for self-pollinated crops such as rice.
( Ma et al., 2019 )
SDN1
CRISPR/Cas
South China Agricultural University, China
Generation of male-sterile hexaploid wheat lines for use in hybrid seed production. The development and adoption of hybrid seed technology have led to dramatic increases in agricultural productivity.
( Okada et al., 2019 )
SDN1
CRISPR/Cas
The University of Adelaide, Australia
Huaiyin Normal University, China
Complete male sterility. The generation, restoration, and maintenance of male sterile lines are the key issues for large-scale commercial hybrid seed production.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Peking University Institute of Advanced Agricultural Sciences
School of Advanced Agriculture Sciences and School of Life Sciences
Beijing Key Laboratory of Plant Gene Resources and Biotechnology for Carbon Reduction and Environmental Improvement, China
Generation of a new thermo-sensitive genic male sterile rice line for hybrid breeding of indica rice.
( Barman et al., 2019 )
SDN1
CRISPR/Cas
China National Rice Research Institute, China
Bangladesh Rice Research Institute, Bangladesh
Fertility restoration of cytoplasmic male sterility.
( Suketomo et al., 2020 )
SDN1
CRISPR/Cas
Tohoku University, Japan
Male sterility and decreased total fatty acid content in the anther.
( Basnet et al., 2019 )
SDN1
CRISPR/Cas
Zhejiang University
Yangtze University, China
Development of commercial thermosensitive genic male sterile lines to accelerate hybrid rice breeding.
( Zhou et al., 2016 )
SDN1
CRISPR/Cas
State Key Laboratory for Conservation and Utilization of Subtropical Agro-bioresources
Key Laboratory of Plant Functional Genomics and Biotechnology of Guangdong Provincial Higher Education Institutions
South China Agricultural University
China National Hybrid Rice R&
D Center, China
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
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
Genetic variability. The genetically reprogrammed rice plants can act as donor lines to stabilize important agronomic traits or can be a potential resource to create more segregating population.
( K et al., 2021 )
SDN1
CRISPR/Cas
University of Agricultural Sciences
Regional Centre for Biotechnology, India
Creation of photoperiod-/thermo-sensitive genic male-sterile (P/TGMS) lines, important for commercial rice breeding. P/TGMS rice lines are useful germplasm resources for two-line hybrid breeding.
( Lan et al., 2019 )
SDN1
CRISPR/Cas
Chinese Academy of Agricultural Sciences, China
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.
( Li et al., 2020 )
SDN1
CRISPR/Cas
Peking University Institute of Advanced Agricultural Sciences
School of Advanced Agriculture Sciences and School of Life Sciences
Peking University
Beijing Key Laboratory of Plant Gene Resources and Biotechnology for Carbon Reduction and Environmental Improvement,China
Removal of methyl iodide emissions. The release of methyl iodide in the athmospere causes ozone depletion and thus represents an important environmental threat.
( Carlessi et al., 2021 )
SDN1
CRISPR/Cas
PlantLab
Institute of Life Sciences
Scuola Superiore Sant’Anna
University of Pisa
University of Milan, Italy
Enhanced biomass saccharification by altered lignin biosynthesis. The intrinsic recalcitrance of lignocellulose residues requires high energy input for bioethanol production.
( Zhang et al., 2020 )
SDN1
CRISPR/Cas
Huazhong Agricultural University
Hubei University of Arts &
Science
Guangxi University, China
Prolonged basic vegetative growth periods for flexible cropping systems in southern China, as well as in other low-latitude regions. Most of the mid-latitude varities were sensitive to temperature or photoperiod, resulting in low grain yield when cultivated in low-latitude regions.
( Wu et al., 2020 )
SDN1
CRISPR/Cas
Fujian Agricultural and Forestry University
Fujian Academy of Agricultural Sciences
Minjiang University, China
Production of herbicide-sensitive strain to prevent volunteer infestation. Volunteer rice grows when cultivated rice seed fall into fields, overwinter and spontaneously germinate the next spring.
( Komatsu et al., 2020 )

BE
Institute of Agrobiological Sciences
National Agriculture and Food Research Organization (NARO)
Graduate School of Science
Technology and Innovation, Japan
Rescued hybrid female fertility. Hybrids between divergent populations commonly show hybrid sterility; this reproductive barrier hinders hybrid breeding of the japonica and indica rice subspecies.
( Guo et al., 2023 )
SDN1
CRISPR/Cas
Ministry of Agriculture and Rural Affairs
Guangdong Key Laboratory of New Technology in Rice Breeding
Guangdong Academy of Agricultural Sciences
South China Agricultural University, China
Enhanced biomass saccharification by remodelling of cell wall composition.
( Dang et al., 2023 )
SDN1
CRISPR/Cas
Shenyang Agricultural University/Key Laboratory of Northern geng Super Rice Breeding, China
Higher haploid induction rate. Haploid induction allows formation of doubled haploids, which can be used to rapidly fix genetic information.
( Jang et al., 2023 )
SDN1
CRISPR/Cas
Chonnam National University
Pusan National University
Kyung Hee University, South Korea
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. Complete abolition of pollen development.
( An et al., 2023 )
SDN1
CRISPR/Cas
University of Science and Technology Beijing
Yili Normal University
Zhongzhi International Institute of Agricultural Biosciences
Beijing Solidwill Sci-Tech Co. Ltd., China
Confer male and female sterility to prevent the risk of trasgene flow from transgenic plants to their wild relatives.
( Wu et al., 2024 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences
University of Chinese Academy of Sciences
Jilin Agricultural University
Zhejiang Lab, China

Traits related to herbicide tolerance

Herbicide resistance.
( Li et al., 2016 )
SDN2
TALENs
Iowa State University, USA
Resistance to ALS-inhibiting herbicides.
( Okuzaki et al., 2003 )

ODM
Tohoku University, Japan
Herbicide glyphosate tolerance.
( Arndell et al., 2019 )
SDN1
CRISPR/Cas
CSIRO
New South Wales Department of Primary Industries
The University of Adelaide, Australia
Bispyribac sodium, haloxyfop
( Xu et al., 2021 )

BE
Anhui Academy of Agricultural Sciences, China
Haloxyfop
( Liu et al., 2020 )

BE
Anhui Agricultural University
Anhui Academy of Agricultural Sciences, China
Haloxyfop-R-methyl
( Xu et al., 2020 )

PE
Anhui Academy of Agricultural Science, China
Glyphosate
( Li et al., 2016 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Bispyribac sodium
( Kuang et al., 2020 )

BE
Chinese Academy of Agricultural Sciences
China Agricultural University
Zhejiang University, China
Norwegian Institute of Bioeconomy Research, Norway
Bispyribac sodium
( Butt et al., 2020 )

PE
King Abdullah University of Science and Technology (KAUST), Saudi Arabia
Nicosulfuron
( Zong et al., 2018 )

BE
Chinese Academy of Sciences, China
Herbicide (haloxyfop) resistance.
( Li et al., 2020 )

BE
Chinese Academy of Sciences
University of Chinese Academy of Sciences, China
Increased herbicide tolerance.
( Sun et al., 2016 )
SDN2
CRISPR/Cas
Chinese Academy of Agricultural Sciences
Huazhong Agricultural University, China
Herbicide tolerance: Bispyribac-sodium (BS). BS is a pyrimidinyl carboxy herbicide.
(Zafar et al., 2023)
SDN2
CRISPR/Cas
Constituent College of Pakistan Institute of Engineering and Applied Sciences
Engineering and Management Sciences (BUITEMS), Pakistan
Improved paraquat resistance in rice without obvious yield penalty.
( Lyu et al., 2022 )
SDN1
CRISPR/Cas
Zhejiang University, China
Herbicide tolerance (ALS-targeting)
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Jiangsu Academy of Agricultural Sciences/Nanjing Branch of Chinese National Center for Rice Improvement
Yangzhou University
Jiangsu Academy of Agricultural Sciences
Jiangsu University, China
CSIRO Agriculture and Food, Australia
Herbicide tolerance: ALS-inhibiting
(Okuzaki et al., 2004)

ODM
Tohoku University, Japan
Herbicide resistance
( Shimatani et al. 2018 )

BE
Kobe University, Japan
University of Tsukuba, Japan
Imazethapyr, imazapic
( Wang et al., 2020 )
SDN1
CRISPR/Cas
Jiangsu Academy of Agricultural Sciences/Nanjing Branch of Chinese National Center for Rice Improvement
Yangzhou University
Jiangsu University, China
CSIRO Agriculture and Food, Australia
Bispyribac sodium
( Butt et al., 2017 )
SDN2
CRISPR/Cas
King Abdullah University of Science and Technology, Saudi Arabia
Agricultural Research Center, Egypt
Rice University, USA
Chlorsulfuron
( Li et al., 2015 )
SDN2
CRISPR/Cas
DuPont Pioneer Agricultural Biotechnology, USA
Glyphosate
( Li et al., 2016 )
SDN1
CRISPR/Cas
Chinese Academy of Sciences, China
Herboxidiene
( Butt et al., 2019 )
SDN1
CRISPR/Cas
King Abdullah University of Science and Technology (KAUST), Saudi Arabia
Universite Paris-Saclay, France
FCD & bipyrazone
( Lu et al., 2021 )
SDN1
CRISPR/Cas
China Agricultural University
Qingdao Kingagroot Compounds Co. Ltd
Guizhou University
Chinese Academy of Sciences, China
Imazamox
( Shimatani et al. 2017 )

BE
Kobe University
University of Tsukuba
Meijo University, Japan
ALS-inhibiting herbicides broad spectrum: Nicosulfuron, imazapic, pyroxsulam, flucarbazone, bispyriba
(Zhang et al., 2020)

BE
Chinese Academy of Sciences
China Agricultural University, China
Nicosulfuron, mesosulfuron, imazapic, quizalofop
( Zhang et al., 2019 )

BE
Chinese Academy of Sciences
China Agricultural University, China
Haloxyfopo-R-methyl
( Li et al., 2018 )

BE
Chinese Academy of Sciences, China
Dinitroanaline
( Liu et al., 2021 )

BE
Chinese Academy of Agricultural Sciences
China Agricultural University
Zhejiang University
Scientific Observing and Experimental Station of Crop Pests in Guilin, Ministry of Agriculture and Rural Affairs, China
Norwegian Institute of Bioeconomy Research, Norway
Dinitroanaline
( Han et al., 2021 )

BE
Shandong Normal University
Shandong Academy of Agricultural Sciences, China
Imidazolinone, haloxyfop-R-methyl, glufosinate, dinitroaniline
( Yan et al., 2021 )

BE
Chinese Academy of Agricultural Sciences
China Agricultural University
Ministry of Agriculture and Rural Affairs
Jilin Agricultural University
Zhejiang University
Resistance to HPPD-inhibiting herbicides.
( Wu et al., 2023 )
SDN1
CRISPR/Cas
Jiangsu Key Laboratory of Crop Genomics and Molecular Breeding, China
Herbicide tolerance: resistance to AHAS-inhibiting herbicides.
(Wei et al., 2023)

BE
Nankai University
China Agricultural University, China

Traits related to product color/flavour

Albino phenotype.
( Brewer et al., 2022 )
SDN1
CRISPR/Cas
University of Florida, USA
Tangerine color
( Kim et al., 2022 )
SDN2
CRISPR/Cas
Hankyong National University
Korea Polar Research Institute
Chungbuk National University
Seoul National University College of Medicine
Hankyong National University, South Korea
Red rice. The pigments of coloured rice contain high levels of proanthocyanidins and anthocyanins which have been recognized as health-promoting nutrients.
( Zhu et al., 2019 )
SDN1
CRISPR/Cas
Xiamen University
Fujian Academy of Agricultural Sciences
Minjiang University, China
Brown seed-coat color.
( Jia et al., 2020 )
SDN1
CRISPR/Cas
Southern University of Science and Technology
Chinese Academy of Agricultural Sciences
South China Agricultural University, China
Donald Danforth Plant Science Center
University of Missouri, USA
Popcorn-like fragrance.
( Zhang et al., 2024 )
SDN1
CRISPR/Cas
China National Rice Research Institute
China

Traits related to storage performance

High vigor and improved storage tolerance of seeds.
( Chen et al., 2022 )
SDN1
CRISPR/Cas
Nanjing Agricultural University, China
Improved seed storability. Deterioration of rice grain reduces the quality of rice, resulting in serious economic losses for farmers.
( Ma et al., 2015 )
SDN1
TALENs
China Agricultural University, China
Increased seed longevity. Maintaining seed longevity and preventing the decline of quality during long-term storage is a universal problem.
( Wang et al., 2023 )
SDN1
CRISPR/Cas
Fujian Agriculture and Forestry University
Fujian Academy of Agricultural Sciences
Ministry of Agriculture and Affairs, China