利用CRISPR/Cas9技术创制大豆高油酸突变系

doi:10.3724/SP.J.1006.2019.84157

摘要/Abstract

摘要：

大豆是重要的油料作物, 其种子脂肪酸中油酸含量是评价大豆油脂品质的重要指标之一。本研究设计了分别由AtU3d、AtU3b和AtU6-1启动子驱动、长20 bp的guide RNA (gRNA)靶点以靶向编辑GmFAD2-1A基因的外显子区, 首先将这3个靶点一起组装到pYLCRISPR/Cas9-DB载体上, 然后利用农杆菌介导的方法转化大豆材料华夏3号。通过PCR技术及测序分析对T₁代转基因大豆植株靶点编辑情况进行检测, 获得纯合GmFAD2-1A大豆突变体。GmFAD2-1A突变大豆植株在株高、主茎节数、单枝分枝数、叶形、花色、种皮色、种脐色、生育期等方面与对照大豆植株没有显著差异; 而GmFAD2-1A突变体大豆种子油酸含量显著高于对照大豆品种华夏3号, 说明GmFAD2-1A是油酸代谢过程中的关键基因。本研究利用CRISPR/Cas9技术成功对控制大豆油酸基因GmFAD2-1A进行编辑, 获得稳定的纯合GmFAD2-1A大豆突变体材料, 为高油酸育种提供了新的种质资源并创建了方法。

关键词: 大豆, 脂肪酸, 油酸, GmFAD2-1A, CRISPR/Cas9

Abstract:

Oleic acid content is one of the essential indicators to evaluate quality of oil in soybean. Three sites of 20 nt guide RNA (gRNA) targeted to the exon of GmFAD2-1A were designed and transcribed from the AtU3d, AtU3b, and AtU6-1 promoters, respectively. The three target sites of gRNA were ligated to the vector pYLCRISPR/Cas9-DB, and then the recombinant plasmid was transformed into a soybean cultivar Huaxia 3 by Agrobacterium-mediated transformation. The sequences near the editing site were analyzed by the PCR method and sequencing from T₁ transgenic soybean plants, homozygous GmFAD2-1A mutants were obtained using CRISPR/Cas9 technology. The agronomic traits such as plant height, main stem number, branching number per plant, leaf shape, flower color, seed coat color, hilum color and growth period were no significant difference between the transgenic soybeans and non-transformed controls. However, the content of oleic acid in the transgenic soybean seed was significantly higher than that of the control cultivar Huaxia 3, indicating that GmFAD2-1A was a key gene during synthesis of oleic acid. We succeeded in editing the GmFAD2-1A by CRISPR/Cas9 technology in soybean and obtained homozygous mutant materials, which provides new germplasm resources and method for the breeding of high oleic acid.

Key words: soybean, fatty acid, oleic acid, GmFAD2-1A, CRISPR/Cas9

侯智红,吴艳,程群,董利东,芦思佳,南海洋,甘卓然,刘宝辉. 利用CRISPR/Cas9技术创制大豆高油酸突变系[J]. 作物学报, 2019, 45(6): 839-847.

Zhi-Hong HOU,Yan WU,Qun CHENG,Li-Dong DONG,Si-Jia LU,Hai-Yang NAN,Zhuo-Ran GAN,Bao-Hui LIU. Creation of high oleic acid soybean mutation plants by CRISPR/Cas9[J]. Acta Agronomica Sinica, 2019, 45(6): 839-847.

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引物名称 Primer name	寡核苷酸序列 Oligonucleotide sequence (5'-3')
FAD-AtU3d-T1-F1	gtcACAAAGCCACCATTCACTGT
FAD-AtU3d-T1-R1	aaacACAGTGAATGGTGGCTTTG
FAD-AtU3b-T2-F2	gtcAACCAAAATCCAAAGTTGCA
FAD-AtU3b-T2-R2	aaacTGCAACTTTGGATTTTGGT
FAD-AtU6-1-T3-F3	attGTTTGGCTGCTATGTGTTTA
FAD-AtU6-1-T3-R3	aaacTAAACACATAGCAGCCAAA
FAD2-1A-CasF-Test	GAGGGATTGTAGTTCTGTTG
FAD2-1A-CasR-Test	CTATGGCCCATTGGTTGCTC
U-F	CTCCGTTTTACCTGTGGAATCG
gRNA-R	CGGAGGAAAATTCCATCCAC
B1’	TTCAGAggtctcTctcgCACTGGAATCGGCAGCAAAGG
B2	AGCGTGggtctcGtcagGGTCCATCCACTCCAAGCTC
B2’	TTCAGAggtctcTctgaCACTGGAATCGGCAGCAAAGG
B3	AGCGTGggtctcGtcttGGTCCATCCACTCCAAGCTC
B3’	TTCAGAggtctcTaagaCACTGGAATCGGCAGCAAAGG
BL	AGCGTGggtctcGaccgGGTCCATCCACTCCAAGCTC
Bar-F	TGCCAGTTCCCGTGCTTGAA
Bar-R	CTGCACCATCGTCAACCACTA

		萌发培养基 Germination medium		共培养培养基 Co-cultivation medium		诱导培养基 Shoot induction medium		伸长培养基 Shoot elongation medium		生根培养基 Rooting medium
MS合成盐 MS salt mixture		—		—		—		1×		1×
B5合成盐 B5 salt mixture		1×		1/10×		1×		—		—
2-(4-吗啉)乙磺酸 MES (g L^-1)		—		4.2		0.6		0.6		—
6-苄基腺嘌呤 6-BAP (mg L^-1)		—		3.2		1.6		—		—
赤霉素 GA₃ (mg L^-1)		—		—		—		0.5		—
羧苄青霉素Car (mg L^-1)		—		—		50		50		—
二硫苏糖醇 DTT (mg L^-1)		—		150		—		—		—
替卡西林 Tic (mg L^-1)		—		—		100		100		25
头孢霉素 Cef (mg L^-1)		—		—		75		75		25
L-天冬酰胺 L-Asp (mg L^-1)		—		—		—		50		—
谷氨酰胺 Glu (mg L^-1)		—		—		—		50		—
草铵膦 Glufosinate (mg L^-1)		—		—		250		—		—
	萌发培养基 Germination medium		共培养培养基 Co-cultivation medium		诱导培养基 Shoot induction medium		伸长培养基 Shoot elongation medium		生根培养基 Rooting medium
吲哚乙酸 IAA (mg L^-1)	—		—		—		0.1		—
玉米素 ZR (mg L^-1)	—		—		—		1		—
吲哚丁酸 IBA (mg L^-1)	—		—		—		—		1
蔗糖 Sucrose (g L^-1)	20		30		30		30		20
琼脂 Agar (g L^-1)	12		6.5		8.5		9		12
pH	5.8		5.4		5.7		5.6		5.8

农艺性状 Agronomic trait	华夏3号 Huaxia 3	GmFAD2-1A突变体 GmFAD2-1A mutant
株高 Plant height (cm)	58.53±1.47	57.60±0.54
主茎节数 Main stem number	11±0	11±0
单株分枝数 Branching number per plant	4±0	4±0
叶形 Leaf shape	椭圆形 Oval	椭圆形 Oval
花色 Flower color	白色 White	白色 White
种皮色 Seed coat color	黄色 Yellow	黄色 Yellow
种脐色 Hilum color	浅褐色 Pale brown	浅褐色 Pale brown
生育期 Growth period (d)	107±0	107±0
蛋白 Protein (%)	40.47±0.54	40.61±0.12
油脂 Oil (%)	20.06±0.12	20.5±0.16