葡萄G2-like转录因子家族的鉴定及在穗梗褐变过程中的表达分析

doi:10.3969/j.issn.1674-7968.2022.09.006

摘要
图/表
参考文献
相关文章 (15)

全文: PDF (5897 KB) HTML (1 KB)
输出: BibTeX | EndNote (RIS)

摘要 Golden2-like (G2-like)转录因子在植物叶绿体发育、叶绿素积累、光合作用和衰老过程中发挥着重要作用。为探究G2-like转录因子在葡萄(Vitis vinifra)生长发育过程中的功能,本研究利用生物信息学方法鉴定了葡萄中G2-like转录因子家族,在聚类、保守结构域和共线性分析基础上,对其在葡萄不同组织及穗梗褐变过程中的表达量进行了测定。结果显示,在葡萄基因组中共鉴定到43个G2-like转录因子基因,分为6个亚家族,不均匀地分布在葡萄的17条染色体上。葡萄和拟南芥(Arabidopsis thaliana)中存在34对同线基因,5个片段复制和1个随机复制,且存在Myb DNA-binding保守结构域。qPCR结果显示,在葡萄穗梗褐变过程中,VvG1、VvG28、VvG43、VvG2、VvG14、VvG6和VvG24基因的表达与叶绿素含量的变化呈正相关,而VvG27基因的表达与叶绿素含量的变化呈负相关。研究结果表明,G2-like基因可能参与葡萄的器官发育和穗梗褐变过程。本研究为进一步探讨研究G2-like基因功能提供了参考依据。

	服务

	把本文推荐给朋友
	加入我的书架
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章
	李志谦
	邹东方
	李靖雯
	叶霞
	冯建灿

关键词 ：葡萄, Golden2-like (G2-like), 生物信息学, 器官, 穗梗褐变

Abstract：Golden2-like (G2-like) transcription factors play important roles during chloroplast development, chlorophyll accumulation, photosynthesis and senescence in plants. In order to explore the role of G2-like transcription factor during grape (Vitis vinifra) development, bioinformatics method was used to identifiy G2-like family transcription factor in grape, on the basis of phylogenetic, conserved domain and synteny analysis, expression of G2-like in different organs and during rachis browning was quantified. A total of 43 G2-like (VvG1~VvG43) transcription factors uneven distributed in 17 chromosomes were identified in grape genome, and were classified into 6 groups based on phylogeny analysis with Arabidopsis thaliana. 34 pairs of synteny between A. thaliana and grape, 5 segmental duplication, 1 tandem duplication and conserved Myb DNA-binding domain were found in grape. qPCR results revealed that VvG1, VvG28, VvG43, VvG2, VvG14, VvG6, VvG24 showed positive correlation with chlorophyll content variation during rachis browning of grape, but VvG27 showed negative expression pattern. This results indicated G2-like genes played the important role in tissue development and rachis browning of grape, which provides a reference basis for further function analysis of G2-like genes.

Key words： Grape Golden2-like (G2-like) Bioinformatics Organs Rachis browning

收稿日期: 2022-01-13

ZTFLH:

S663.1

基金资助:国家自然科学基金(32002017)

通讯作者: *jcfeng@henau.edu.cn

引用本文:

李志谦, 邹东方, 李靖雯, 叶霞, 冯建灿. 葡萄G2-like转录因子家族的鉴定及在穗梗褐变过程中的表达分析[J]. 农业生物技术学报, 2022, 30(9): 1713-1723.
LI Zhi-Qian, ZOU Dong-Fang, LI Jing-Wen, YE Xia, FENG Jian-Can. Characterization of the G2-like Transcription Factor Family of Grape (Vitis vinifra) and Its Expression Analysis in Rachis Browning. 农业生物技术学报, 2022, 30(9): 1713-1723.

链接本文:

http://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2022.09.006 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2022/V30/I9/1713

[1] 李具鹏, 傅茂润, 杨晓颖. 2018. 1-MCP处理对采后葡萄果梗褐变及叶绿素降解相关基因的影响[J]. 食品工业科技, 39(20): 268-273; 285.
(Li J P, Fu M R, Yang X Y. 2018. Effect of 1-MCP treatment on postharvest browning and chlorophyll breakdown pathway related genes in grape rachis[J]. Science and Technology of Food Industry, 39(20): 268-273; 285.)
[2] 李志谦, 李靖雯, 邹东方, 等. 2021.葡萄采后贮藏过程中穗梗褐变的研究进展[J]. 河南农业大学学报, 55(5): 815-820.
(Li Z X, Li J W, Zou D F, et al.2021. Research progress of rachis browning in postharvest storage of grape[J]. Journal of Henan Agricultural University, 55(5): 815-820.)
[3] 刘俊芳. 2018. 番茄G2-like转录因子家族生物信息学分析及抗逆相关基因鉴定[D]. 硕士学位论文, 东北农业大学, 导师: 李景富, pp.18-30.
(Liu J F.2018. Bioinformatics analysis of tomato G2-like transcription factor family and identification of resistance-related genes[D]. Thesis for M.S., Northeast Agricultural University, Supervisor: Li J F, pp.18-30.)
[4] Alem A L, Ariel F D, Cho Y, et al.2022. TCP15 interacts with GOLDEN2-LIKE 1 to control cotyledon opening in Arabidopsis[J]. Plant Journal, 110(3): 748-763.
[5] An X H, Tian Y, Chen Y H, et al.2018. Functional identification of apple MdGLK1 which regulates chlorophyll biosynthesis in Arabidopsis[J]. Journal of Plant Growth Regulation, 38(3): 778-787.
[6] Balic I, Moreno A, Sanhueza D, et al., 2012. Molecular and physiological study of postharvest rachis browning of table grape cv Red Globe[J]. Postharvest Biology and Technology, 72: 47-56.
[7] Bravo-Garcia A, Yasumura Y, Langdale J A.2009. Specialization of the Golden2-like regulatory pathway during land plant evolution[J]. New Phytology, 183: 133-141.
[8] Chen M, Ji M, Wen B, et al., 2016. Golden 2-like transcription factors of plants[J]. Front Plant Science, 7: 1509.
[9] Fitter D W, Marti D J, Copley M J, et al.2002. GLK gene pairs regulate chloroplast development in diverse plant species[J]. The Plant Journal, 31(6): 713-727.
[10] Fromme P, Melkozernov A, Jordan P, et al.2003. Structure and function of photosystemⅠ: Interaction with its soluble electron carriers and external antenna systems[J]. FEBS Letters, 555: 40-44.
[11] Hall L N, Rossini L, Cribb L, et al.1998. Golden 2: A novel transcriptional regulator of cellular differentiation in the maize leaf[J]. The Plant Cell, 10: 925-936.
[12] Holub E.2001. The arms race is ancient history in Arabidopsis, the wildflower[J]. Nature Reviews Genetics, 2(7): 516-527.
[13] Kirchhoff H.2019. Chloroplast ultrastructure in plants[J]. New Phytology, 223(2): 565-574.
[14] Li X, Wang P, Li J, et al.2020. Maize GOLDEN2-LIKE genes enhance biomass and grain yields in rice by improving photosynthesis and reducing photoinhibition[J]. Communications Biology, 3(1): 151.
[15] Li Z, Zhang C, Guo Y, et al.2017. Evolution and expression analysis reveal the potential role of the HD-Zip gene family in regulation of embryo abortion in grapes (Vitis vinifera L.)[J]. BMC Genomics, 18(1): 744.
[16] Liu F, Xu Y, Han G, et al.2016. Molecular evolution and genetic variation of G2-like transcription factor genes in maize[J]. PLOS ONE, 11(8): e0161763.
[17] Liu X, Li L, Li M, et al.2018. AhGLK1 affects chlorophyll biosynthesis and photosynthesis in peanut leaves during recovery from drought[J]. Scientific Reports, 8(1): 2250.
[18] Liu X, Li L, Zhang B, et al.2020. AhHDA1-mediated AhGLK1 promoted chlorophyll synthesis and photosynthesis regulates recovery growth of peanut leaves after water stress[J]. Plant Science, 294: 110461.
[19] Lupi A C D, Lira B S, Gramegna G, et al.2019. Solanum lycopersicum GOLDEN 2-LIKE 2 transcription factor affects fruit quality in a light-and auxin-dependent manner[J]. PLOS ONE, 14(2): e0212224.
[20] Nagatoshi Y, Mitsuda N, Hayashi M, et al.2016. GOLDEN 2-LIKE transcription factors for chloroplast development affect ozone tolerance through the regulation of stomatal movement[J]. Proceedings of the National Academy of Sciences of the USA, 113(15): 4218-4223.
[21] Nguyen C V, Vrebalov J T, Gapper N E, et al.2014. Tomato GOLDEN2-LIKE transcription factors reveal molecular gradients that function during fruit development and ripening[J]. Plant Cell, 26(2): 585-601.
[22] Qin M, Zhang B, Gu G, et al.2021. Genome-wide analysis of the G2-like transcription factor genes and their expression in different senescence stages of tobacco (Nicotiana tabacum L.)[J]. Frontiers in Genetics, 12: 626352.
[23] Rauf M, Arif M, Dortay H, et al.2013. ORE1 balances leaf senescence against maintenance by antagonizing G2-like-mediated transcription[J]. EMBO Reports, 14(4): 382-388.
[24] Rossini L, Cribb L, Martin D J, et al.2001. The maize golden2 gene defines a novel class of transcriptional regulators in plants[J]. The Plant Cell, 13: 1231-1244.
[25] Sakuraba Y, Kim E Y, Han S H, et al.2017. Rice phytochrome-interacting factor-like1 (OsPIL1) is involved in the promotion of chlorophyll biosynthesis through feed-forward regulatory loops[J]. Journal of Experimental Botany, 68(15): 4103-4114.
[26] Savitch L V, Subramaniam R, Allard G C, et al.2007. The GLK1 'regulon' encodes disease defense related proteins and confers resistance to Fusarium graminearum in Arabidopsis[J]. Biochemical & Biophysical Research Communications, 359(2): 234-238.
[27] Schreiber K J, Nasmith C G, Allard G, et al.2011. Found in translation: High-throughput chemical screening in Arabidopsis thaliana identifies small molecules that reduce Fusarium head blight disease in wheat[J]. Molecular Plant-Microbe Interactions, 24(6): 640-648.
[28] Wang L, Luo Z, Li J, et al.2019. Morphological and quality characterization of grape berry and rachis in response to postharvest 1-methylcyclopropene and elevated oxygen and carbon dioxide atmospheres[J]. Postharvest Biology and Technology, 153: 107-117.
[29] Xu G, Guo C, Shan H, et al.2012. Divergence of duplicate genes in exon-intron structure[J]. Proceedings of the National Academy of Sciences of the USA, 109(4): 1187-1192.
[30] Zhang C, Zhang J, Tang Y, et al.2021. Deep green panicle1 suppresses GOLDEN2-LIKE activity to reduce chlorophyll synthesis in rice glumes[J]. Plant Physiology, 185(2): 469-477.
[31] Zhang D, Tan W, Yang F, et al.2020. A BIN2-GLK1 signaling module integrates brassinosteroid and light signaling to repress chloroplast development in the dark[J]. Developmental Cell, 56(3): 310-324.