[1]许艺钏,柏杨,亓希武,等.薄荷McHY5基因克隆、表达定位及功能分析[J].江苏农业科学,2026,54(8):102-113.
 Xu Yichuan,et al.Cloning,expression localization and function analysis of McHY5 gene in Mentha canadensis[J].Jiangsu Agricultural Sciences,2026,54(8):102-113.
点击复制

薄荷McHY5基因克隆、表达定位及功能分析()

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

卷:
第54卷
期数:
2026年第8期
页码:
102-113
栏目:
耐干旱基因鉴定
出版日期:
2026-04-20

文章信息/Info

Title:
Cloning,expression localization and function analysis of McHY5 gene in Mentha canadensis
作者:
许艺钏12柏杨2亓希武2于盱2李莉2房海灵2刘冬梅2梁呈元12
1.南京中医药大学,江苏南京 210023; 2.江苏省中国科学院植物研究所,江苏南京 210014
Author(s):
Xu Yichuanet al
关键词:
薄荷转录因子HY5表达分析非生物胁迫下胚轴发育
Keywords:
-
分类号:
S188;S567.23+9.01
DOI:
-
文献标志码:
A
摘要:
为研究薄荷(Mentha canadensis L.)McHY5基因的表达特征和生物学功能,从薄荷中克隆到该基因,对其进行生物信息学、不同组织和不同胁迫条件下的表达模式、蛋白亚细胞定位以及转录自激活活性分析,并在拟南芥中进行了初步的功能研究。结果表明,McHY5基因的编码区包含474个碱基对,编码长度为157个氨基酸的多肽链;McHY5蛋白是具有亲水性的不稳定蛋白,其理论相对分子质量为16.96 ku,预测共有24个磷酸化位点,含有碱性亮氨酸拉链(bZIP)结构域;通过构建系统进化发育树发现,薄荷McHY5与地黄(KAK6119672.1)的亲缘关系最近。McHY5基因在各组织中均有表达,在花中表达量最高;黑暗能够抑制McHY5基因的表达,而恢复光照则促进其表达;盐(NaCl)、甘露醇和激素(ABA、MeJA)处理24 h后,薄荷叶片中McHY5基因的表达被显著诱导;McHY5是细胞核定位的蛋白,且不具备转录自激活活性;在拟南芥hy5-215突变体中异源过表达McHY5能够抑制下胚轴伸长,使其长度与野生型相当。本研究结果为解析McHY5调控下胚轴伸长的分子机制,以及探究其应对非生物胁迫的作用提供了重要的前期基础。
Abstract:
-

参考文献/References:

[1]温亚娟,项丽玲,苗明三. 薄荷的现代应用研究[J]. 中医学报,2016,31(12):1963-1965.
[2]陈泽群,亓希武,房海灵,等. 薄荷McHD-Zip3基因的克隆及其调控腺毛发育的功能分析[J]. 植物资源与环境学报,2020,29(3):1-10.
[3]蒋征,王红,吴啟南,等. 药用植物腺毛研究进展[J]. 中草药,2016,47(22):4118-4126.
[4]Saqib S,Ullah F,Naeem M,et al. Mentha:nutritional and health attributes to treat various ailments including cardiovascular diseases[J]. Molecules,2022,27(19):6728.
[5]Tissier A. Glandular trichomes:what comes after expressed sequence tags?[J]. The Plant Journal,2012,70(1):51-68.
[6]Jiao Y L,Lau O S,Deng X W. Light-regulated transcriptional networks in higher plants[J]. Nature Reviews Genetics,2007,8(3):217-230.
[7]许亚楠,闫家榕,孙鑫,等. 红光和远红光在调控植物生长发育及应答非生物胁迫中的作用[J]. 植物学报,2023,58(4):622-637.
[8]Paik I,Huq E. Plant photoreceptors:Multi-functional sensory proteins and their signaling networks[J]. Seminars in Cell & Developmental Biology,2019,92:114-121.
[9]McNellis T W,Deng X W. Light control of seedling morphogenetic pattern[J]. The Plant Cell,1995,7(11):1749-1761.
[10]Hersch M,Lorrain S,de Wit M,et al. Light intensity modulates the regulatory network of the shade avoidance response in Arabidopsis[J]. PNAS,2014,111(17):6515-6520.
[11]Osterlund M T,Hardtke C S,Wei N,et al. Targeted destabilization of HY5 during light-regulated development of Arabidopsis[J]. Nature,2000,405(6785):462-466.
[12]杨东旭,王昕源,黄迪,等. 高等植物下胚轴生长发育研究进展[J]. 黑龙江农业科学,2023(1):118-123.
[13]Feng X J,Li J R,Qi S L,et al. Light affects salt stress-induced transcriptional memory of P5CS1 in Arabidopsis[J]. PNAS,2016,113(51):E8335-E8343.
[14]Nawkar G M,Kang C H,Maibam P,et al. HY5,a positive regulator of light signaling,negatively controls the unfolded protein response in Arabidopsis[J]. PNAS,2017,114(8):2084-2089.
[15]Yang C,Shen W J,Yang L M,et al. HY5-HDA9 module transcriptionally regulates plant autophagy in response to light-to-dark conversion and nitrogen starvation[J]. Molecular Plant,2020,13(3):515-531.
[16]Xiao Y T,Chu L,Zhang Y M,et al. HY5:a pivotal regulator of light-dependent development in higher plants[J]. Frontiers in Plant Science,2022,12:800989.
[17]Gangappa S N,Botto J F. The multifaceted roles of HY5 in plant growth and development[J]. Molecular Plant,2016,9(10):1353-1365.
[18]Lee J,He K,Stolc V,et al. Analysis of transcription factor HY5 genomic binding sites revealed its hierarchical role in light regulation of development[J]. The Plant Cell,2007,19(3):731-749.
[19]Stawska M,Oracz K. phyB and HY5 are involved in the blue light-mediated alleviation of dormancy of Arabidopsis seeds possibly via the modulation of expression of genes related to light,GA and ABA[J]. International Journal of Molecular Sciences,2019,20(23):5882.
[20]Modak A,Singh S,Singhal C,et al. The E3 ubiquitin ligases RING DOMAIN OF UNKNOWN FUNCTION 1117 1 (RDUF1) and RDUF2 control seedling photomorphogenesis in Arabidopsis[J]. The New Phytologist,2025,247(2):684-705.
[21]Fu J L,Liao L,Jin J J,et al. A transcriptional cascade involving BBX22 and HY5 finely regulates both plant height and fruit pigmentation in Citrus[J]. Journal of Integrative Plant Biology,2024,66(8):1752-1768.
[22]Pham V N,Kathare P K,Huq E. Phytochromes and phytochrome interacting factors[J]. Plant Physiology,2018,176(2):1025-1038.
[23]Kelly G,Brandsma D,Egbaria A,et al. Guard cells control hypocotyl elongation through HXK1,HY5,and PIF4[J]. Communications Biology,2021,4:765.
[24]Xia B,Li Z W,Liu X W,et al. Functional characterization of CiHY5 in salt tolerance of Chrysanthemum indicum and conserved role of HY5 under stress in Chrysanthemum[J]. Plant Physiology and Biochemistry,2025,223:109797.
[25]Lin R,Zhang W J,Tian R,et al. CPK27 enhances cold tolerance by promoting flavonoid biosynthesis through phosphorylating HY5 in tomato[J]. The New Phytologist,2025,246(5):2174-2191.
[26]Liu S Y,Wang Q L,Zhong M,et al. The CRY1-COP1-HY5 axis mediates blue-light regulation of Arabidopsis thermotolerance[J]. Plant Communications,2025,6(4):101264.
[27]Chang Y K,Shi M M,Wang X,et al. A CRY1-HY5-MYB signaling cascade fine-tunes guard cell reactive oxygen species levels and triggers stomatal opening[J]. The Plant Cell,2025,37(4):koaf064.
[28]李莹莹. ASDs对拟南芥ABA及盐和干旱胁迫响应的调控机制[D]. 长春:东北师范大学,2024:45.
[29]Wang Y,Mostafa S,Zeng W,et al. Function and mechanism of jasmonic acid in plant responses to abiotic and biotic stresses[J]. International Journal of Molecular Sciences,2021,22(16):8568.
[30]Mukherjee A,Dwivedi S,Bhagavatula L,et al. Integration of light and ABA signaling pathways to combat drought stress in plants[J]. Plant Cell Reports,2023,42(5):829-841.
[31]Nguyen T H,Goossens A,Lacchini E. Jasmonate:a hormone of primary importance for plant metabolism[J]. Current Opinion in Plant Biology,2022,67:102197.
[32]Wang M L,Fan X L,Ding F. Jasmonate:a hormone of primary importance for temperature stress response in plants[J]. Plants,2023,12(24):4080.
[33]房海灵,李维林,梁呈元. 不同前处理条件对薄荷种子萌发的影响[J]. 植物资源与环境学报,2009,18(4):53-57.
[34]郑晓薇,柏杨,亓希武,等. 薄荷McZFP1基因克隆及表达分析[J]. 植物资源与环境学报,2024,33(1):35-46,58.
[35]Li Z,Wang W W,Li G L,et al. MAPK-mediated regulation of growth and essential oil composition in a salt-tolerant peppermint (Mentha piperita L.) under NaCl stress[J]. Protoplasma,2016,253(6):1541-1556.
[36]Bai Y,Zhang T,Zheng X W,et al. Overexpression of a WRKY transcription factor McWRKY57-like from Mentha canadensis L. enhances drought tolerance in transgenic Arabidopsis[J]. BMC Plant Biology,2023,23(1):216.
[37]Chou K C,Shen H B. Cell-PLoc 2.0:an improved package of web-servers for predicting subcellular localization of proteins in various organisms[J]. Natural Science,2010,2(10):1090-1103.
[38]Li X,Wang Y M,Li J Y,et al. qPCRtools:an R package for qPCR data processing and visualization[J]. Frontiers in Genetics,2022,13:1002704.
[39]Nijhawan A,Jain M,Tyagi A K,et al. Genomic survey and gene expression analysis of the basic leucine zipper transcription factor family in rice[J]. Plant Physiology,2008,146(2):333-350.
[40]Singh R,Ahmed S,Luxmi S,et al. An assessment of the physicochemical characteristics and essential oil composition of Mentha longifolia (L.) Huds.exposed to different salt stress conditions[J]. Frontiers in Plant Science,2023,14:1165687.
[41]Zaid A,Mohammad F,Siddique K H M. Salicylic acid priming regulates stomatal conductance,trichome density and improves cadmium stress tolerance in Mentha arvensis L.[J]. Frontiers in Plant Science,2022,13:895427.
[42]Al-Taisan W A,Alabdallah N M,Almuqadam L. Moringa leaf extract and green algae improve the growth and physiological attributes of Mentha species under salt stress[J]. Scientific Reports,2022,12:14205.
[43]马媛,杨卓雄,董笛,等. 日本结缕草ZjHY5的克隆、亚细胞定位及转录自激活检测[J]. 草地学报,2022,30(3):560-567.
[44]胡漪文,陈丽娟,黄利,等. 药用植物中bZIP转录因子家族的研究进展[J]. 中药与临床,2025,16(2):56-61,16.
[45]吕艳贞,崔凯伦,张昭,等. 转录因子bZIP调控种子发育与活力及植物非生物胁迫响应的研究进展[J]. 植物生理学报,2024,60(10):1502-1513.
[46]徐兴源,李艳肖,朱梦洋,等. 蓖麻RcbZIP44基因克隆及表达特性[J]. 南方农业学报,2024,55(7):2069-2079.
[47]Zhang H J,Mao L L,Xin M,et al. Overexpression of GhABF3 increases cotton (Gossypium hirsutum L.) tolerance to salt and drought[J]. BMC Plant Biology,2022,22(1):313.
[48]Niu S K,Gu X Y,Zhang Q,et al. Grapevine bZIP transcription factor bZIP45 regulates VvANN1 and confers drought tolerance in Arabidopsis[J]. Frontiers in Plant Science,2023,14:1128002.
[49]Wang Q,Guo C,Li Z Y,et al. Identification and analysis of bZIP family genes in potato and their potential roles in stress responses[J]. Frontiers in Plant Science,2021,12:637343.
[50]Liu X Y,Bulley S M,Varkonyi-Gasic E,et al. Kiwifruit bZIP transcription factor AcePosF21 elicits ascorbic acid biosynthesis during cold stress[J]. Plant Physiology,2023,192(2):982-999.
[51]Liu X M,Wei J T,Li S J,et al. MdHY5 positively regulates cold tolerance in apple by integrating the auxin and abscisic acid pathways[J]. New Phytologist,2025,246(5):2155-2173.
[52]Gao S Z,Chen X H,Lin M H,et al. A birch ELONGATED HYPOCOTYL 5 gene enhances UV-B and drought tolerance[J]. Forestry Research,2024,4:e022.
[53]Sah S K,Reddy K R,Li J X. Abscisic acid and abiotic stress tolerance in crop plants[J]. Frontiers in Plant Science,2016,7:571.
[54]Repkina N,Ignatenko A,Holoptseva E,et al. Exogenous methyl jasmonate improves cold tolerance with parallel induction of two cold-regulated (COR) genes expression in Triticum aestivum L.[J]. Plants,2021,10(7):1421.
[55]Fatma M,Iqbal N,Sehar Z,et al. Methyl jasmonate protects the PSⅡ system by maintaining the stability of chloroplast D1 protein and accelerating enzymatic antioxidants in heat-stressed wheat plants[J]. Antioxidants,2021,10(8):1216.
[56]Cui H W,Yang F F,Li Y F. Exogenous methyl jasmonate enhances lipid production in Isochrysis galbana under nitrogen deprivation and high light[J]. Algal Research,2021,58:102406.
[57]杨达,范梓晗,杨静莉. 植物光敏色素作用因子调控植物下胚轴伸长的研究进展[J]. 东北农业大学学报,2025,56(2):179-188.
[58]Li J G,Yang L,Jin D,et al. UV-B-induced photomorphogenesis in Arabidopsis[J]. Protein & Cell,2013,4(7):485-492.
[59]Chattopadhyay S,Ang L H,Puente P,et al. Arabidopsis bZIP protein HY5 directly interacts with light-responsive promoters in mediating light control of gene expression[J]. The Plant Cell,1998,10(5):673-683.
[60]Ang L H,Chattopadhyay S,Wei N,et al. Molecular interaction between COP1 and HY5 defines a regulatory switch for light control of Arabidopsis development[J]. Molecular Cell,1998,1(2):213-222.
[61]Burko Y,Seluzicki A,Zander M,et al. Chimeric activators and repressors define HY5 activity and reveal a light-regulated feedback mechanism[J]. The Plant Cell,2020,32(4):967-983.

相似文献/References:

[1]梁文洁,张丽,郭新勇,等.薄荷组织培养及抗除草剂基因的遗传转化[J].江苏农业科学,2018,46(04):37.
 Liang Wenjie,et al.Tissue culture of mint and genetic transformation of its herbicide resistant genes[J].Jiangsu Agricultural Sciences,2018,46(8):37.
[2]吴雯雯,陆兵,李文清,等.留兰香薄荷离体快繁技术研究[J].江苏农业科学,2018,46(04):47.
 Wu Wenwen,et al.Study on in vitro rapid propagation of Mentha spicata[J].Jiangsu Agricultural Sciences,2018,46(8):47.
[3]徐璐,肖雪峰,汪涛,等.高温胁迫下薄荷叶片的转录组和代谢组分析[J].江苏农业科学,2026,54(2):64.
 Xu Lu,et al.Transcriptome and metabolome analysis of Mentha haplocalyx leaves under high temperature stress[J].Jiangsu Agricultural Sciences,2026,54(8):64.

备注/Memo

备注/Memo:
收稿日期:2025-10-13
基金项目:国家自然科学基金(编号:32100313、32370397);江苏省自然科学基金(编号:BK20210164);江苏省植物资源保护与利用重点实验室开放基金(编号:JSPKLB202029、JSPKLB202412)。
作者简介:许艺钏(1999—),女,福建漳州人,硕士研究生,主要从事天然药物学研究。E-mail:xuyichuan929@163.com。
通信作者:梁呈元,博士,研究员,主要从事药用植物种质资源收集保护和种质创新研究。E-mail:liangcy618@cnbg.net。
更新日期/Last Update: 2026-04-20