BnaBZR1和BnaPIF4基因调控甘蓝型油菜弱光光效的机制

doi:10.3724/SP.J.1006.2020.94198

摘要/Abstract

摘要：

甘蓝型油菜品系XY881和XY883是湘油15辐照诱变后连续自交筛选的2个种子含油量、光合效率和弱光敏感性等有明显差别的子代品系。分别从XY881和XY883中克隆了芸薹素唑抗性因子1 (brassinazole-resistant 1, BnaBZR1) 和光敏色素互作因子4 (phytochrome interacting factor 4, BnaPIF4)基因并进行了序列结构、表达和功能分析。结果表明, XY883的BnaBZR1和BnaPIF4基因存在结构变异, 引起表达和调控模式的差异。XY883中BnaBZR1的启动子具有124 bp的富含A/T的插入序列, 且XY883具有比XY881高的BnaBZR1表达, 并且在弱光和2,4-表油菜素内酯(2,4-BL)诱导下具有较少的表达变化。XY883中BnaPIF4的5'-UTR区域存在可变剪接, 形成长度分别为424 bp (U01)、239 bp (U02)和332 bp (U03)的3种5'-UTR, 在弱光和2,4-BL诱导下, XY883中3种可变剪接的BnaPIF4转录产物的变化不一致。将BnaPIF4的3个5'-UTR与CDS分别组合转化拟南芥后其表达在转录水平无明显差异, 但蛋白翻译存在明显差异, 表明BnaPIF4的5'-UTR变异影响其翻译过程。转BnaPIF4基因拟南芥出现株高增加、叶片狭长且光合作用下降的表型, 共转化BnaBZR1能减弱BnaPIF4造成的光合作用下降; 转BnaPIF4和BnaBZR1基因对油菜的影响与拟南芥相似, 但表型不如拟南芥明显, 表明BnaPIF4是油菜光合作用的负调控因子, 而BnaBZR1可对BnaPIF4的光合负调控产生拮抗; 这与XY881和XY883中两基因表达调控模式及其光合表型相吻合。

关键词: 甘蓝型油菜, BnaPIF4, BnaBZR1, 可变剪接, 插入突变

Abstract:

Double-low seed rape B. napus L. varieties XY881 and XY883 screened from the same parent Xiangyou 15 have significant differences in seed oil content, photosynthetic efficiency, and poor light sensitivity. Brassinazole-resistant 1 (BnaBZR1) and phytochrome interacting factor 4 (BnaPIF4) genes were cloned from XY881 and XY883, respectively, and their sequence structure, gene expression and gene function were analyzed. There were structural mutations in the BnaBZR1 and BnaPIF4 of XY883, causing differences in gene expression and regulation. The promoter of BnaBZR1 in XY883 had a 124 bp A/T-rich insertion mutation, and XY883 had a higher expression of BnaBZR1 than XY881, and fewer expression changes under low light and 2,4-epibrassinolide(2,4-BL) treatment. Splicing differences of BnaPIF4 in the 5'-UTR region were found in XY883, and the alternative splicing resulted in three 5'-UTRs of 424 bp (U01), 239 bp (U02), and 332 bp (U03). Under the induction of low light and 2,4-BL treatments the changed of three alternative spliced BnaPIF4 transcripts in XY883 had significant differences. The three 5'-UTRs combined with the CDS of BnaPIF4 were transformed into Arabidopsis thaliana. There was no significant difference in BnaPIF4 gene expression, but a significant difference in protein expression, indicating that the 5'-UTR mutation of BnaPIF4 affects protein synthesis. Transgenic BnaPIF4 Arabidopsis thaliana showed a phenotype with increased plant height, narrow leaves, and decreased photosynthesis. Co-transformation whit BnaBZR1 could attenuate the decrease in photosynthesis caused by BnaPIF4. The effects of BnaPIF4 and BnaBZR1 genes on Brassica napus L. were similar to those on Arabidopsis thaliana, while the phenotype was not as obvious as that of Arabidopsis thaliana, suggesting that BnaPIF4 is a negative regulator of photosynthesis in rapeseed, and BnaBZR1 can antagonize the negative regulation of photosynthesis by BnaPIF4, while is consistent with the regulation pattern and photosynthetic phenotype of the two genes in XY881 and XY883.

Key words: Brassica napus L., BnaPIF4, BnaBZR1, alternative splicing, insertion mutation

冯韬,谭晖,官梅,官春云. BnaBZR1和BnaPIF4基因调控甘蓝型油菜弱光光效的机制[J]. 作物学报, 2020, 46(8): 1146-1156.

FENG Tao,TAN Hui,GUAN Mei,GUAN Chun-Yun. Mechanism of BnaBZR1 and BnaPIF4 regulating photosynthetic efficiency in oilseed rape (Brassica napus L.) under poor light[J]. Acta Agronomica Sinica, 2020, 46(8): 1146-1156.

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引物 Primer	克隆产物 Product of cloning	序列 Sequence (5'-3')
PIF4_mF	mRNA of BnaPIF4	ATAGATCTCATCCCTAAAGA
PIF4_mR		TATGTTCAAAAGATAGCCTTAG
BZR1_mF	mRAN of BnaBZR1	GGAGAAGGAAAGAGAGATTC
BZR1_mR		TTGAGAGAAACAAAATGGGC
PIF4_cF	CDS of BnaPIF4	ATGGAACACCAAGGTTGGAG
PIF4_cR		CTAACGGGGACCGTCGG
BZR1_cF	CDS of BnaBZR1	ATGACGTCAGATGGAGCTACG
BZR1_cR		TCAACCACGAGCTTTGCC
PIF4_pF	Promoter of BnaPIF4	ATTGAAACCGATTGTAAGGA
PIF4_pR		AGAAACAAAGGAGCATAAAG
BZR1_pF	Promoter of BnaBZR1	GGTTATTTTCAAATAATGGATG
BZR1_pR		CTTGAGCTCTTAGCCCTGTG
PIF4_uF	5'-UTR of BnaPIF4	ATAGATCTCATCCCTAAAGA
PIF4_uR		GTCAGATCTCAGATTTGGAAAGC
PIF4_dF	Full-length gene of BnaPIF4	ATAGATCTCATCCCTAAAGAAG
PIF4_dR		TTTTGACAAACTAAACCAGG

引物 Primer	基因 Gene	序列 Sequence (5'-3')
ActF	BnaActin	GGTTGGGATGGACCAGAAGG
ActR		TCAGGAGCAATACGGAGC
PIF4F	BnaPIF4_cds	CTGTGCTGTTGTGCTTAC
PIF4R		AGTCTCTACATAAACCCATAGG
U1_F	BnaPIF4_UTR_U01	CTGTGCTGTTGTGCTTAC
U1_R		AGTCTCTACATAAACCCATAGG
U2_F	BnaPIF4_UTR_U02	CTGTGCTGTTGTGCTTAC
U2_R		TTCCTCTCACTTGCTCTC
U3_F	BnaPIF4_UTR_U03	GAGAGCAAGTGAGAGGAA
U3_R		CAGAAGCTGAAGTAGTAGAAG
BZR1F	BnaBZR1	CTCTCATCTCCAACTTCCAA
BZR1R		GACTCATCACACTCAGGTATA