A novel type of Brassica napus with higher stearic acid in seeds developed through genome editing of BnaSAD2 family

Key message Modifications of multiple copies of the BnaSAD2 gene family with genomic editing technology result in higher stearic acid content in the seed of polyploidy rapeseed. Solid fats from vegetable oils are widely used in food processing industry. Accumulating data showed that stearic acid is...

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Bibliographic Details
Published in:Theoretical and applied genetics 2023-09, Vol.136 (9), p.187, Article 187
Main Authors: Huang, Huibin, Ahmar, Sunny, Samad, Rana Abdul, Qin, Pin, Yan, Tong, Zhao, Qin, Xie, Kabin, Zhang, Chunyu, Fan, Chuchuan, Zhou, Yongming
Format: Article
Language:English
Subjects:
Agriculture
Alleles
Biochemistry
Biomedical and Life Sciences
Biosynthesis
Biotechnology
Chemical properties
Desaturase
Fatty acids
Food industry
Food processing
Genetic aspects
Genome editing
Genomes
Genomics
Germplasm
Life Sciences
Methods
Mutants
Oilseeds
Original Article
Physiological aspects
Plant Biochemistry
Plant Breeding/Biotechnology
Plant genetic engineering
Plant Genetics and Genomics
Polyploidy
Production processes
Rape (Plant)
Seeds
Stearic acid
Vegetable seed
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Summary:Key message Modifications of multiple copies of the BnaSAD2 gene family with genomic editing technology result in higher stearic acid content in the seed of polyploidy rapeseed. Solid fats from vegetable oils are widely used in food processing industry. Accumulating data showed that stearic acid is more favorite as the major composite among the saturate fatty acids in solid fats in considerations of its effects on human health. Rapeseed is the third largest oil crop worldwide, and has potential to be manipulated to produce higher saturated fatty acids as raw materials of solid fats. Toward that end, we identified four SAD2 gene family members in B. napus genome and established spatiotemporal expression pattern of the BnaSAD2 members. Genomic editing technology was applied to mutate all the copies of BnaSAD2 in this allopolyploid species and mutants at multiple alleles were generated and characterized to understand the effect of each BnaSAD2 member on blocking desaturation of stearic acid. Mutations occurred at BnaSAD2.A3 resulted in more dramatic changes of fatty acid profile than ones on BnaSAD2.C3 , BnaSAD2.A5 and BnaSAD2.C4 . The content of stearic acid in mutant seeds with single locus increased dramatically with a range of 3.1–8.2%. Furthermore, combination of different mutated alleles of BnaSAD2 resulted in more dramatic changes in fatty acid profiles and the double mutant at BnaSAD2.A3 and BnaSAD2.C3 showed the most dramatic phenotypic changes compared with its single mutants and other double mutants, leading to 11.1% of stearic acid in the seeds. Our results demonstrated that the members of BnaSAD2 have differentiated in their efficacy as a Δ9-Stearoyl-ACP-Desaturase and provided valuable rapeseed germplasm for breeding high stearic rapeseed oil.
ISSN:0040-5752
1432-2242
DOI:10.1007/s00122-023-04414-x