SeedQuest - Central information website for the global seed industry

News Page

The news
and
beyond the news

Index of news sources

Topics

Alliances / M & A
Artificial intelligence
Bees & pollinators health
Biodiversity
Bioinformatics
Biologicals & inoculants
Biotechnology
Carbon
Cereal crops
Climate resilience
Coexistence
Conservation seed
Cover crops
Crop protection
Data science
Digital agriculture
Drones / UAV
Drought tolerance
Education & careers
Financial
Food & health
Food safety
Food security
Forage crops
Fungicide resistance
Genetic resources
Genome-editing technology
Genomics
Heat tolerance
Herbicide resistance
Indoor agriculture
Insecticide resistance
Intellectual property protection
Legal & regulatory
Legumes
Lighting technology
Machinery & equipment
Market data
Microbials / Microbiome
New breeding techniques
New products & tools
New services
New technologies
Non-food agriculture
Oilseed crops
Organic
Ornamentals
Pasture grasses
People
Pesticide resistance
Phenotyping / Phenomics
Plant & seed nutrition
Plant breeding
Plant health
Plant protein
Post-harvest technology
Precision agriculture
Published in print
Pulse crops
Reclamation
Regenerative agriculture
Remote sensing
Research
Robots / Robotics
Root health
Seed analysis
Seed colorants & polymers
Seed enhancement
Seed health
Seed processing
Seed science & technology
Seed testing
Seed treatment
Soil health
Sustainable ag
Turfgrass
Urban farming
Vegetable crops
Web & IT solutions
Weed management

Species

Archives

News archive 1997-2008

New genome editing technology for plant breeding

Matsuyama, Japan
July 19, 2019

Adenine in the target sequence is substituted by guanine - Credit: Ehime University

We developed a new genome editing technology in rice. We combined adenine-to-guanine single base editing technology and Cas9 with an extended targeting scope and demonstrated that it is possible to efficiently introduce base substitution mutations in rice genes. We plan to expand our research to citrus fruit breeding using this new technology.

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR)/ CRISPR-associated protein 9 (Cas9) is a powerful genome editing tool.

Cas9 can modify any desired target sequence, but is limited to the sequence just upstream of the protospacer adjacent motif (PAM). SpCas9 derived from Streptococcus pyogenes is the most widely used.

The PAM sequence of SpCas9 is NGG (N is any base and G is guanine) and is the smallest of Cas9s known.

Recently a new type of SpCas9-NG that reduced this restriction of PAM to NG has been reported. On the other hand, Cas9 usually causes deletions and insertion mutations in genome. The frequency of substitution mutation caused by Cas9 is very low and even if it occured, the substitution pattern was random.

Recently, a technology was developed that can replace A (adenine) to G (guanine) at the targeted sequence. We fused these two latest technologies and examined whether it could replace A-to-G at a desired position in the rice genome.

As a result, we successfully induced A-to-G base substitutions in the rice genome. We would like to further verify this technology and apply this technology to citrus, which is the most important crop of Ehime Prefecture, and lead to the development of new varieties.

https://onlinelibrary.wiley.com/doi/full/10.1111/pbi.13120

Full bibliographic information

An adenine base editor with expanded targeting scope using SpCas9‐NGv1 in rice, Katsuya Negishi, Hidetaka Kaya, Kiyomi Abe, Naho Hara, Hiroaki Saika, Seiichi Toki, Plant Biotechnology Journal, 17 1476-1478, DOI:10.1111/pbi.13120, 2019 (August)

More news from: Ehime University

Website: https://www.ehime-u.ac.jp

Published: July 22, 2019

The news item on this page is copyright by the organization where it originated
Fair use notice