|
|
Functional Identification of GmPME2 Gene and Effects on Aluminum Resistance in Tobacco (Nicotiana tabacum) |
XIE Yong-Hong*, WEI Yun-Min*, HAN Rong-Rong, YU Shi-Tian, WANG Yi, LIN Tao, LIU Lu-Sheng, JIANG Cao-De, YU Yong-Xiong** |
College of Animal Science and Technology, Southwest University, Chongqing 400715, China |
|
|
Abstract Pectin methylesterase (PME) is a cell wall-localized protein associated with aluminum tolerance of plant. Tamba Black soybean (Glycine max cv. Tamba) belongs to leguminous plants and has great potential for aluminum tolerance. To study the function of GmPME2 (GenBank No. MN867684) in Tamba Black soybean under aluminum stress, this research cloned one of Tamba Black soybean's gene of GmPME2 by using reverse transcription PCR (RT-PCR). The coding regions of GmPME2 was 900 bp in length and encoded a protein of 299 amino acids with the isoelectric point of 8.85. GmPME2 was a stable protein with instability coefficient of 30.11<40. The expression analyses of GmPME2 in Tamba Black soybean challenged by Al3+ (pH4.5, 0.5 mmol/L CaCl2, 50 μmol/L AlCl3) showed an upregulation of GmPME2 within 12 h and downregulation from 12~24 h with the highest spot on the 12 h. Expression of GmPME2 in roots was significantly higher than that in stems or leaves (P<0.05), especially in root tips. Transient expression of tobacco (Nicotiana benthamiana) revealed that GmPME2 protein was located in cell wall. The expression vector, pBI121-GmPME2-eGFP, was constructed and transformed into tobacco by Agrobacterium mediated transformation and subsequently obtained transgenic tobaccos. Three transgenic tobaccos (GmPME2-1, GmPME2-3 and GmPME2-4) were selected to investigate the aluminum tolerance, The results showed that the relative expression of GmPME2 increased significantly (P<0.05), GmPME2 activity and malondialdehyde (MDA) content in root tips had remarkable decrease in root relative elongation compared to wild type (WT). Hematoxylin and Evans blue staining revealed a deeper stain in transgenic tobacco than that in WT. Compared with WT, the secretion of citrate in transgenic tobacco root tips significantly increased due to more aluminum absorption (P<0.05). This research indicated that plant could enhance its aluminum tolerance by decreasing aluminum absorption in root tips via regulating the expression of PME2 gene which provides the genetic resources for researches in aluminum toxicity.
|
Received: 17 November 2019
|
|
Corresponding Authors:
**yuyongxiong8@126.com *The authors who contribute equally
|
|
|
|
[1] 胡俊, 刘卢生, 韩蓉蓉, 等. 2019. 丹波黑大豆GmMATE2基因的克隆及功能鉴定[J]. 农业生物技术学报, 27(7): 1161-1170. (Hu J, Liu L S, Han R R, et al.2019. Cloning and functional identification of GmMATE2 gene from Tamba Black soybean (Glycine max 'Tamba')[J]. Journal of Agricultural Biotechnology, 27(7): 1161-1170. ) [2] 宋倩, 钱绍方, 陈宣钦, 等. 2014. 丹波黑大豆GmbHLH30转录因子耐铝功能初步研究[J]. 生命科学研究, 18(04): 332-337. (Song Q, Qian S F, Cheng X Q, et al.2014. Study on the function of transcription factor GmbHLH30 on aluminum tolerance preliminary in Tamba Black soybean[J]. Life Science Research, 18(04): 332-337.) [3] 唐剑锋, 罗湖旭, 林咸永, 等. 2006. 铝胁迫下小麦根细胞壁果胶甲酯酶活性的变化及其与耐铝性的关系[J]. 浙江大学学报(农业与生命科学版), 32(2): 145-151. (Tang J F, Luo H X, Lin X Y, et al.2006. Aluminum induced changes in cell wall pectin methylesterase activity of wheat seedlings in relation to their aluminum tolerance[J]. Journal of Zhejiang University (Agriculture and Life Sciences), 32(2): 145-151. ) [4] 杨晓颖. 2011. 柠檬酸转运子和果胶甲酯酶在植物耐铝中的作用[D]. 博士学位论文, 浙江大学, 导师: 郑绍建. pp. 1-2. (Yang X Y.2011. Role of citrate transporter and pectin methylesterase in plant aluminum resistance[D]. Thesis for Ph.D., Zhejiang University, Supervisor: Zheng S J, pp. 1-2.) [5] Abd El-Moneim D, Contreras R, Silva-Navas J, et al.2014. Pectin methylesterase gene and aluminum tolerance in Secale cereale[J]. Environmental and Experimental Botany, 107(1): 125-133. [6] Bao Y, Guo A, Ma J, et al.2019. Citric acid and glycine reduce the uptake and accumulation of Fe2O3 nanoparticles and oxytetracycline in rice seedlings upon individual and combined exposure[J]. Science of The Total Environment, 695(1): 133859-133870. [7] Chen S, Liu Y, Deng Y, et al.2019. Cloning and functional analysis of the VcCXIP4 and VcYSL6 genes as Cd-regulating genes in blueberry[J]. Gene, 686(1): 104-117. [8] Choudhury S, Sharma P.2014. Aluminum stress inhibits root growth and alters physiological and metabolic responses in chickpea (Cicer arietinum L.)[J]. Plant Physiology and Biochemistry, 85(1): 63-70. [9] Farokhzadeh S, Fakheri B A, Nezhad N M, et al.2019. Mapping QTLs of flag leaf morphological and physiological traits related to aluminum tolerance in wheat (Triticum aestivum L.)[J]. Physiology and Molecular Biology of Plants, 25(4): 975-990. [10] Guo P, Qi Y P, Huang W L, et al.2018. Aluminum-responsive genes revealed by RNA-Seq and related physiological responses in leaves of two Citrus species with contrasting aluminum-tolerance[J]. Ecotoxicology and Environmental Safety, 158(1): 213-222. [11] Jaskowiak J, Kwasniewska J, Milewska-Hendel A, et al.2019. Aluminum alters the histology and pectin cell wall composition of barley roots[J]. International Journal of Molecular Sciences, 20(12): 3039-3056. [12] Jiang C, Liu L, Li X, et al.2018. Insights into aluminum-tolerance pathways in Stylosanthes as revealed by RNA-Seq analysis[J]. Scientific Reports, 8(1): 6072-6080. [13] Kochian L V, Pineros M A, Liu J, et al.2015. Plant adaptation to acid soils: The molecular basis for crop aluminum resistance[J]. Annual Review of Plant Biology, 66(1): 571-598. [14] Li D, Shu Z, Ye X, et al.2017. Cell wall pectin methyl-esterification and organic acids of root tips involve in aluminum tolerance in Camellia sinensis[J]. Plant Physiology and Biochemistry, 119(1): 265-274. [15] Liu W, Xu F, Lv T, et al.2018. Spatial responses of antioxidative system to aluminum stress in roots of wheat (Triticum aestivum L.) plants[J]. Science of the Total Environment, 627(1): 462-469. [16] Melo J O, Lana U G P, Piñeros M A, et al.2013. Incomplete transfer of accessory loci influencing SbMATE expression underlies genetic background effects for aluminum tolerance in Sorghum[J]. The Plant Journal, 73(2): 276-288. [17] Ma Q B, Yi R, Li L, et al.2018. GsMATE encoding a multidrug and toxic compound extrusion transporter enhances aluminum tolerance in Arabidopsis thaliana[J]. BMC Plant Biology, 18(1): 212-221. [18] Muhammad N, Zvobgo G, Zhang G P.2019. A review: The beneficial effects and possible mechanisms of aluminum on plant growth in acidic soil[J]. Journal of Integrative Agriculture, 18(7): 1518-1528. [19] Min Y, Guo C L, Zhao X L, et al.2018. Adenosine 5'-monophosphate decreases citrate exudation and aluminium resistance in Tamba black soybean by inhibiting the interaction between 14-3-3 proteins and plasma membrane H+-ATPase[J]. Plant Growth Regulation, 84(2): 285-292. [20] Nogueirol R C, Monteiro F A, Gratao P L, et al.2015. Tropical soils with high aluminum concentrations cause oxidative stress in two tomato genotypes[J]. Environmental Monitoring and Assessment, 187(3): 73-88. [21] Pan C L, Yao S C, Xiong W J, et al.2017. Nitric Oxide inhibits Al-induced programmed cell death in root tips of Peanut (Arachis hypogaea L.) by affecting physiological properties of antioxidants systems and cell wall[J]. Frontiers in Physiology, 8(1): 1037-1051. [22] Paz Carcamo M, Reyes-Diaz M, Rengel Z, et al.2019. Aluminum stress differentially affects physiological performance and metabolic compounds in cultivars of highbush blueberry[J]. Scientific Reports, 9(1): 11275-11287. [23] Reyna-Llorens I, Corrales I, Poschenrieder C, et al.2015. Both aluminum and ABA induce the expression of an ABC-like transporter gene (FeALS3) in the Al-tolerant species Fagopyrum esculentum[J]. Environmental and Experimental Botany, 111(1): 74-82. [24] Ribeiro A P, de Souza W R, Martins P K, et al.2017. Overexpression of BdMATE gene improves aluminum tolerance in setaria viridis[J]. Frontiers in Plant Science, 8(1): 865-876. [25] Richard L, Qin L X, Gadal P, et al.1994. Molecular cloning and characterization of a putative pectin methylesterase cDNA in Arabidopsis thaliana (L.) Heynh.[J]. FEBS Letters, 355(2): 135-139. [26] Silambarasan S, Logeswari P, Valentine A, et al.2019. Role of curtobacterium herbarum strain CAH5 on aluminum bioaccumulation and enhancement of Lactuca sativa growth under aluminum and drought stresses[J]. Ecotoxicology and Environmental Safety, 183(1): 109573-109582. [27] Sun C, Lu L, Yu Y, et al.2016. Decreasing methylation of pectin caused by nitric oxide leads to higher aluminium binding in cell walls and greater aluminium sensitivity of wheat roots[J]. Journal of Experimental Botany, 67(3): 979-989. [28] Wang M, Qiao J, Yu C, et al.2019. The auxin influx carrier, OsAUX3, regulates rice root development and responses to aluminium stress[J]. Plant Cell and Environment, 42(4): 1125-1138. [29] Wang P, Yu W, Zhang J, et al.2016. Auxin enhances aluminium-induced citrate exudation through upregulation of GmMATE and activation of the plasma membrane H+-ATPase in soybean roots[J]. Annals of Botany, 118(5): 933-940. [30] Wu Y, Yang Z, How J, et al.2017. Overexpression of a peroxidase gene (AtPrx64) of Arabidopsis thaliana in tobacco improves plant's tolerance to aluminum stress[J]. Plant Molecular Biology, 95(1-2): 157-168. [31] Yang X Y, Zeng Z H, Yan J Y, et al.2013. Association of specific pectin methylesterases with Al-induced root elongation inhibition in rice[J]. Physiologia Plantarum, 148(4): 502-511. [32] Yang Z, Wang C, Xue Y, et al.2019. Calcium-activated 14-3-3 proteins as a molecular switch in salt stress tolerance[J]. Nature communications, 10(1): 1199-1210. [33] Yu Y, Jin C, Sun C, et al.2015. Elevation of arginine decarboxylase-dependent putrescine production enhances aluminum tolerance by decreasing aluminum retention in root cell walls of wheat[J]. Journal of Hazardous Materials, 299(1): 280-288. [34] Zhang F, Yan X, Han X, et al.2019. A defective vacuolar proton pump enhances aluminum tolerance by reducing vacuole sequestration of organic acids[J]. Plant Physiology, 181(2): 743-761. [35] Zhang M, Deng X, Yin L, et al.2016. Regulation of galactolipid biosynthesis by overexpression of the rice MGD gene contributes to enhanced aluminum tolerance in tobacco[J]. Frontiers in Plant Science, 7(1): 337-346. [36] Zhang M, Lu X, Li C, et al.2018. Auxin efflux carrier ZmPGP1 mediates root growth inhibition under aluminum stress[J]. Plant Physiology, 177(2): 819-832. [37] Zhao Z, Gao X, Ke Y, et al.2019. A unique aluminum resistance mechanism conferred by aluminum and salicylic-acid-activated root efflux of benzoxazinoids in maize[J]. Plant and Soil, 437(1-2): 273-289. [38] Zhu C Q, Cao X C, Zhu L F, et al.2019. Boron reduces cell wall aluminum content in rice (Oryza sativa) roots by decreasing H2O2 accumulation[J]. Plant Physiology and Biochemistry, 138(1): 80-90. |
|
|
|