马铃薯淀粉酶StBAM9互作蛋白的鉴定及其互作机制分析

doi:10.3724/SP.J.1006.2023.34009

作物学报 ›› 2023, Vol. 49 ›› Issue (10): 2643-2653.doi: 10.3724/SP.J.1006.2023.34009

• 作物遗传育种·种质资源·分子遗传学 • 上一篇下一篇

马铃薯淀粉酶StBAM9互作蛋白的鉴定及其互作机制分析

杜鹃¹(), 彭晓君¹^,², 侯娟¹^,³, 刘腾飞¹^,⁴, 刘增¹, 宋波涛¹()

¹果蔬园艺作物种质创新与利用全国重点实验室 / 农业农村部马铃薯生物学与生物技术重点实验室 / 华中农业大学, 湖北武汉 430070
²阿克陶县巴仁乡人民政府, 新疆克孜勒苏柯尔克孜自治州 845555
³河南农业大学园艺学院, 河南郑州 450002
⁴山东农业大学食品科学与工程学院, 山东泰安 271018

收稿日期:2023-01-13 接受日期:2023-04-17 出版日期:2023-10-12 网络出版日期:2023-04-26
通讯作者: 宋波涛, E-mail: songbotao@mail.hzau.edu.cn
作者简介:E-mail: juandu@mail.hzau.edu.cn
基金资助:
贵州省科技支撑计划(农业领域重点项目)生物育种先导性项目(黔科合支撑[2022]重点030-3);国家自然科学基金项目(31671749)

Identification of potato amylase StBAM9 interacting protein and analysis of the interaction mechanism

DU Juan¹(), PENG Xiao-Jun¹^,², HOU Juan¹^,³, LIU Teng-Fei¹^,⁴, LIU Zeng¹, SONG Bo-Tao¹()

¹National Key Laboratory for Germplasm Innovation and Utilization of Horticultural Crops / Key Laboratory of Potato Biology and Biotechnology, Ministry of Agriculture and Rural Affairs / Huazhong Agricultural University, Wuhan 430070, Hubei, China
²People's Government of Baren Township, Aktau County, Kizilsu Kirgiz Autonomous Prefecture 845555, Xinjiang, China
³College of Horticulture, Henan Agricultural University, Zhengzhou 450002, Henan, China
⁴College of Food Science and Engineering, Shandong Agricultural University, Tai'an 271018, Shandong, China

Received:2023-01-13 Accepted:2023-04-17 Published:2023-10-12 Published online:2023-04-26
Contact: E-mail: songbotao@mail.hzau.edu.cn
Supported by:
Guizhou Science and Technology Support Plan (the Key Project in Agricultural Field) Biological Breeding Pilot Project (Qiankehe Support [2022] Key 030-3);National Natural Science Foundation of China(31671749)

摘要/Abstract

摘要：

本实验室前期研究表明β-淀粉酶9 (StBAM9)在马铃薯抗低温糖化中具有重要作用, 但其并无β-淀粉酶活性。为了研究StBAM9在马铃薯抗低温糖化中的功能机制, 我们构建了低温贮藏后块茎cDNA酵母双杂交文库, 并以StBAM9蛋白为诱饵, 对其进行了互作蛋白的筛选和分析, 结果显示分别以全长StBAM9和截去转运肽的StBAM9为诱饵筛选到的候选互作蛋白中有12个是共有的。酵母双杂交结果显示有4个蛋白(StDUF842、StTPR01660、StTPR22129和StTPR45174)与StBAM9互作。进一步通过谷胱甘肽-S-转移酶融合蛋白沉降技术验证表明, 其中的2个蛋白StTPR01660和StTPR4517与StBAM9互作。双分子荧光互补结果显示只有StTPR01660与StBAM9互作于淀粉粒上, 而StTPR01660自身定位于细胞质。因此, 我们推测StBAM9可能通过从细胞质中招募StTPR01660到淀粉粒上发挥淀粉降解的功能。

关键词: 马铃薯, 低温糖化, 淀粉降解, β-淀粉酶, 蛋白互作

Abstract:

Previous research conducted in our laboratory has demonstrated the crucial role of StBAM9 (β-Amylase 9) in the resistance of potatoes to cold-induced sweetening (CIS), although StBAM9 lacks β-Amylase activity. To investigate the mechanism, we generated a yeast two-hybrid library of tuber cDNA following low-temperature storage and screened for potential interacting proteins with StBAM9 as bait. The results revealed that 12 of the identified interacting proteins were common among both full-length and truncated transport peptide StBAM9 bait screens. Among them, four proteins (StDUF842, StTPR01660, StTPR22129, and StTPR45174) had significant interactions with StBAM9 in yeast two-hybrid assay. Subsequently, two of these proteins, StTPR01660 and StTPR4517, were identified as the interactors with StBAM9 through Glutathione-S-transferase (GST) pull-down experiments. Bimolecular fluorescence complementation (BiFC) assays demonstrated that only StTPR01660 was co-localized with StBAM9 on starch granules, while StTPR01660 itself was observed in the cytoplasm. In conclusion, StBAM9 may recruit StTPR01660 from the cytoplasm to starch granules, potentially enabling starch degradation.

Key words: potato, cold-induced sweetening (CIS), starch degradation, β-amylase, protein interaction

杜鹃, 彭晓君, 侯娟, 刘腾飞, 刘增, 宋波涛. 马铃薯淀粉酶StBAM9互作蛋白的鉴定及其互作机制分析[J]. 作物学报, 2023, 49(10): 2643-2653.

DU Juan, PENG Xiao-Jun, HOU Juan, LIU Teng-Fei, LIU Zeng, SONG Bo-Tao. Identification of potato amylase StBAM9 interacting protein and analysis of the interaction mechanism[J]. Acta Agronomica Sinica, 2023, 49(10): 2643-2653.

图/表 10

附表1

本研究所用的引物"

引物名称 Primer name	引物序列 Primer sequence (5°-3°)	用途 Use
5°-T7	TAATACGACTCACTATAGG	酵母文库构建 Yeast library construction
3°-AD	ACTGTGCATCGTGCACCATCTC	酵母文库构建 Yeast library construction
AD-StDUF842-F	CCATGGAGGCCAGTGAATTCATGGACGCAATAGCAGCAGC	酵母双杂交Y2H
AD-StDUF842-R	AGCTCGAGCTCGATGGATCCTCAATTGTTGAAGCCGAGAG	酵母双杂交Y2H
AD-StTPR01660-F	CCATGGAGGCCAGTGAATTCATGTTATTGAGAAGCTCATC	酵母双杂交Y2H
AD-StTPR01660-R	AGCTCGAGCTCGATGGATCCCTAAGAAGCAGCAGCCAAGG	酵母双杂交Y2H
AD-StTPR22129-F	CCATGGAGGCCAGTGAATTCATGTTGCTAAGGAGTTCTTC	酵母双杂交Y2H
AD-StTPR22129-R	AGCTCGAGCTCGATGGATCCTCAAACAGTTATAGAAGCCG	酵母双杂交Y2H
AD-StTPR45174-F	CCATGGAGGCCAGTGAATTCATGAGAACTGTCCTTTTCCG	酵母双杂交Y2H
AD-StTPR45174-R	AGCTCGAGCTCGATGGATCCCTAGTAAGCTGCAACCGTTG	酵母双杂交Y2H
AD-StSTPK69936-F	CCATGGAGGCCAGTGAATTCATGGAGGTAATAGAGAAGGA	酵母双杂交Y2H
AD-StSTPK69936-R	AGCTCGAGCTCGATGGATCCTCAAGTTGGTGATTCAGCTA	酵母双杂交Y2H
AD-StSTPK63153-F	CCATGGAGGCCAGTGAATTCATGAGTTCCAGAGGTGGTGG	酵母双杂交Y2H
AD-StSTPK63153-R	AGCTCGAGCTCGATGGATCCTCATTGTGGTCCCTCTAGCT	酵母双杂交Y2H
AD-StSTPK61170-F	CCATGGAGGCCAGTGAATTCATGGAGAAATACGAGCTTGT	酵母双杂交Y2H
AD-StSTPK61170-R	AGCTCGAGCTCGATGGATCCTTAGGTGAGACGAACTTCCC	酵母双杂交Y2H
AD-StPP2C-F	CCATGGAGGCCAGTGAATTCATGGAAGAAAGTAAAATGAT	酵母双杂交Y2H
AD-StPP2C-R	AGCTCGAGCTCGATGGATCCTTAATCTTTCAAGGTATCCA	酵母双杂交Y2H
AD-StGAPDH-F	CCATGGAGGCCAGTGAATTCATGGCCAATGGCAAGATCAA	酵母双杂交Y2H
AD-StGAPDH-R	AGCTCGAGCTCGATGGATCCTCAAGCCTTGGCCATATGGC	酵母双杂交Y2H
AD-StSHSP12249-F	CCATGGAGGCCAGTGAATTCATGGCAACTTCACTTGCTCT	酵母双杂交Y2H
AD-StSHSP12249-R	AGCTCGAGCTCGATGGATCCTCACTCAATTTTAACATCAA	酵母双杂交Y2H
AD-StSHSP78006-F	CCATGGAGGCCAGTGAATTCATGTCACTGATCCCAAGAAT	酵母双杂交Y2H
AD-StSHSP78006-R	AGCTCGAGCTCGATGGATCCTTAACCAGAGATCTCAATGG	酵母双杂交Y2H
AD-StAFTP4-F	CCATGGAGGCCAGTGAATTCATGAAGCAAAAGGTTGTTAT	酵母双杂交Y2H
AD-StAFTP4-R	AGCTCGAGCTCGATGGATCCTCACATAATGGAGCAATTGG	酵母双杂交Y2H
AD-StSSIV-F	CCATGGAGGCCAGTGAATTCATGGAGATGAAGATCTCCAA	酵母双杂交Y2H
AD-StSSIV-R	AGCTCGAGCTCGATGGATCCTCAACTACGACTTGCAGCTC	酵母双杂交Y2H
AD-StGWD-F	CCATGGAGGCCAGTGAATTCATGAGTAATTCCTTAGGGAA	酵母双杂交Y2H
AD-StGWD-R	AGCTCGAGCTCGATGGATCCTCACATCTGAGGTCTTGTCT	酵母双杂交Y2H
StTPR01660-A1-180-F	CCATGGAGGCCAGTGAATTCATGTTATTGAGAAGCTCATC	酵母双杂交Y2H
StTPR01660-A1-180-R	AGCTCGAGCTCGATGGATCCCTATTTCTGGTAATAGGCAT	酵母双杂交Y2H
StTPR01660-A181-262-F	CCATGGAGGCCAGTGAATTCATGATCGAAGCCCACCCAGG	酵母双杂交Y2H
StTPR01660-A181-262-R	AGCTCGAGCTCGATGGATCCCTACAGTACGTAGCAGTCAT	酵母双杂交Y2H
StTPR01660-A263-317-F	CCATGGAGGCCAGTGAATTCATGGGCTCTTATGCTCGATT	酵母双杂交Y2H
StTPR01660-A263-317-R	AGCTCGAGCTCGATGGATCCCTAAGAAGCAGCAGCCAAGG	酵母双杂交Y2H
StTPR01660-A181-277-F	CCATGGAGGCCAGTGAATTCATGATCGAAGCCCACCCAGG	酵母双杂交Y2H
StTPR01660-A181-277-R	AGCTCGAGCTCGATGGATCCCTACTCATATTCTTCACCAG	酵母双杂交Y2H
StTPR01660-A278-317-F	CCATGGAGGCCAGTGAATTCATGAATGAGGGTGAGGACGA	酵母双杂交Y2H
StTPR01660-A278-317-R	AGCTCGAGCTCGATGGATCCCTAAGAAGCAGCAGCCAAGG	酵母双杂交Y2H
StTPR01660-A181-317-F	CCATGGAGGCCAGTGAATTCATGATCGAAGCCCACCCAGG	酵母双杂交Y2H
StTPR01660-A181-317-R	AGCTCGAGCTCGATGGATCCCTAAGAAGCAGCAGCCAAGG	酵母双杂交Y2H
pET32a-StDUF842-F	CTGATATCGGATCCGAATTCATGGACGCAATAGCAGCAGC	原核表达 Prokaryotic expression
pET32a-StDUF842-R	TGGTGGTGGTGGTGCTCGAGTCAATTGTTGAAGCCGAGAG	原核表达 Prokaryotic expression
pET32a-StTPR01660-F	CTGATATCGGATCCGAATTCATGTTATTGAGAAGCTCATC	原核表达 Prokaryotic expression
pET32a-StTPR01660-R	TGGTGGTGGTGGTGCTCGAGCTAAGAAGCAGCAGCCAAGG	原核表达 Prokaryotic expression
pET32a-StTPR22129-F	CTGATATCGGATCCGAATTCATGTTGCTAAGGAGTTCTTC	原核表达 Prokaryotic expression
pET32a-StTPR22129-R	TGGTGGTGGTGGTGCTCGAGTCAAACAGTTATAGAAGCCG	原核表达 Prokaryotic expression
pET32a-StTPR45174-F	CTGATATCGGATCCGAATTCATGAGAACTGTCCTTTTCCG	原核表达 Prokaryotic expression
pET32a-StTPR45174-R	TGGTGGTGGTGGTGCTCGAGCTAGTAAGCTGCAACCGTTG	原核表达 Prokaryotic expression
pGEX6p-1-StDUF842-F	TCCAGGGGCCCCTGGGATCCATGGACGCAATAGCAGCAGC	原核表达 Prokaryotic expression
pGEX6p-1-StDUF842-R	ATGCGGCCGCTCGAGTCGACTCAATTGTTGAAGCCGAGAG	原核表达 Prokaryotic expression
StDUF842-YFP^N-F	TGTTGATACATATGGGATCCATGGACGCAATAGCAGCAGC	双分子荧光互补BiFC
StDUF842-YFP^N-R	CCGAATTCACTAGTGTCGACATTGTTGAAGCCGAGAGAAG	双分子荧光互补BiFC
StTPR22129-YFP^N-F	TGTTGATACATATGGGATCCATGTTGCTAAGGAGTTCTTC	双分子荧光互补BiFC
StTPR22129-YFP^N-R	CCGAATTCACTAGTGTCGACAACAGTTATAGAAGCCGTGG	双分子荧光互补BiFC
actin-F	CAGAAAGGACCTCTACGGTAACATT	cDNA检测cDNA detection
actin-R	TCTGTGGACGATGGACGGAC	cDNA检测cDNA detection
attB1+StDUF842-F	GGGGACAAGTTTGTACAAAAAAGCAGGCTCAATGGACGCAATAGCAGCAGC	BP反应BP reaction
attB2+StDUF842-R	GGGGACCACTTTGTACAAGAAAGCTGGGTATCAATTGTTGAAGCCGAGAG	BP反应BP reaction
attB1+StTPR01660-F	GGGGACAAGTTTGTACAAAAAAGCAGGCTCAATGTTATTGAGAAGCTCATC	BP反应BP reaction
attB2+StTPR01660-R	GGGGACCACTTTGTACAAGAAAGCTGGGTACTAAGAAGCAGCAGCCAAGG	BP反应BP reaction
attB1+StTPR22129-F	GGGGACAAGTTTGTACAAAAAAGCAGGCTCAATGTTGCTAAGGAGTTCTTC	BP反应BP reaction
attB2+StTPR22129-R	GGGGACCACTTTGTACAAGAAAGCTGGGTATCAAACAGTTATAGAAGCCG	BP反应BP reaction
attB1+StTPR45174-F	GGGGACAAGTTTGTACAAAAAAGCAGGCTCAATGAGAACTGTCCTTTTCCG	BP反应BP reaction
attB2+StTPR45174-R	GGGGACCACTTTGTACAAGAAAGCTGGGTACTAGTAAGCTGCAACCGTTG	BP反应BP reaction

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参考文献 17

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饵蛋白 Bait protein	测序转化子数 Number of sequencing transformers	潜在互作蛋白个数 Number of potential interaction proteins	相同潜在互作蛋白个数 Number of proteins with the same potential interaction
StBAM9	68	29	12
StBAM9-P	118	75

序号 Serial number	基因名称 Gene name	PGSC编号 PGSC number	注释 Annotation	CDS (bp)
1	StDUF842	PGSC0003DMT400042117	含DUF842结构域的蛋白质 DUF842 domain containing protein	450
2	StTPR01660	PGSC0003DMT400001660	含四肽重复结构域的蛋白 Tetratricopeptide repeat domain-containing protein	951
3	StTPR22129	PGSC0003DMT400022129	含四肽重复结构域的蛋白 Tetratricopeptide repeat domain-containing protein	1083
4	StTPR45174	PGSC0003DMT400045174	含四肽重复结构域的蛋白 Tetratricopeptide repeat domain-containing protein	909
5	StSHSP12249	PGSC0003DMT400012249	线粒体小分子热休克蛋白 Mitochondrial small heat shock protein	636
6	StSHSP78006	PGSC0003DMT400078006	17.6 kD I类热休克蛋白 17.6 kD class I heat shock protein	465
7	StGAPDH	PGSC0003DMT400044944	胞质甘油醛-3-磷酸脱氢酶 Glyceraldehyde-3-phosphate dehydrogenase, cytosolic	1017
8	StAFTP4	PGSC0003DMT400044590	金属离子结合蛋白 Metal ion binding protein	396
9	StSTPK61170	PGSC0003DMT400061170	渗透应激激活蛋白激酶 Osmotic stress-activated protein kinase	1083
10	StSTPK63153	PGSC0003DMT400063153	丝氨酸/苏氨酸蛋白激酶 Ser/Thr protein kinase	1515
11	StSTPK69936	PGSC0003DMT400069936	丝氨酸/苏氨酸蛋白激酶 NEK8Serine/threonine-protein kinase Nek8	1425
12	StPP2C	PGSC0003DMT400067098	蛋白磷酸酶 2CProtein phosphatase 2C	1128

马铃薯淀粉酶StBAM9互作蛋白的鉴定及其互作机制分析

Identification of potato amylase StBAM9 interacting protein and analysis of the interaction mechanism

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