Welcome to Acta Agronomica Sinica,

Acta Agronomica Sinica ›› 2018, Vol. 44 ›› Issue (04): 483-492.doi: 10.3724/SP.J.1006.2018.00483

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Enhanced Accumulation of BnA7HSP70 Molecular Chaperone Binding Protein Improves Tolerance to Drought Stress in Transgenic Brassica napus

Li-Li WAN1,*(), Zhuan-Rong WANG2, Qiang XIN2, Fa-Ming DONG2, Deng-Feng HONG2, Guang-Sheng YANG2   

  1. 1 Institute of Crop, Wuhan Academy of Agricultural Sciences, Wuhan 430065, Hebei, China
    2 National Key Laboratory of Crop Genetic Improvement, Huazhong Agricultural University, Wuhan 430065, Hebei, China
  • Received:2017-09-04 Accepted:2018-01-08 Online:2018-01-31 Published:2018-01-31
  • Contact: Li-Li WAN E-mail:wanlili13226@163.com
  • Supported by:
    This study was supported by Germplasm Innovation Foundation of Wuhan Academy of Agricultural Sciences (CX201710), the National Natural Science Foundation of China (31401413), and the High Technology Innovation Foundation of Hubei Province (2016ABA084).

Abstract:

The molecular chaperone binding protein gene participates in the constitutive function of plant growth and protects plant cells against stresses. In this study, we found that BnA7HSP70 overexpressed transgenic lines did not wilt and showed only a small decrease in water potential. However, the wild type lines showed a large decrease in leaf water potential. The transgenic plants had higher relative water content, better osmotic adjustment and less lipid membrane peroxidation. In addition, the leaves from the elevated levels of BnA7HSP70 in transgenic lines conferred tolerance to the glycosylation inhibitor tunicamycin during germination. BnA7HSP70 overexpression-mediated attenuation of stress-induced cell death was confirmed by the decreased percentage of dead cell and the reduced induction of the senescence-associated marker gene BnCNX1. These phenotypes were accompanied by a delay in the induction of the cell death marker genes BnNRP, which are involved in transducing a cell death signal generated by ER stress and osmotic stress through the NRP (N-rich protein)-mediated signaling pathway. Enhanced expression of BnA7HSP70 delayed unfold protein response and NRP pathway mediated chlorosis and the appearance of senescence-associated markers BnLSC222 and BnLSC54 in Brassica napus. These results suggest that overexpression of BnA7HSP70 in Brassica napus alleviate ER stress and osmotic stress-integrating cell death response confronted with water stress.

Key words: BnA7HSP70, drought tolerance, Brassica napus, leaf senescence, antioxidant enzymes

Fig. 1

Subcellular localization of BnA7HSP70 and GFP fusion protein in Arabidopsis protoplasts. (A) Subcellular localization of full-length GFP fused with green fluorescent protein (GFP), the cytoplasm showed a green fluorescent signal at 488 nm. (B) The mesophyll cells showed a red fluorescent signal at 580 nm. (C) A bright-field image of protoplast cell; (D) A bright-field image and the merged image are shown at the bottom. Scale bars, 10 µm."

Fig. 2

BnA7HSP70 overexpressed (OE) plants confer tolerance under a restricted water regime and 20% PEG treatment(A) For the fast soil drying treatment, wild type (WT) and BnA7HSP70 overexpressed (OE) lines were allowed to reach four to five weeks leaves stage of development when drought was rapidly induced by withholding irrigation for 10 days. The stress condition was prolonged until the leaves of wild type plants completely wilted. (B) For the fast soil drying treatment, wild type (WT) and BnA7HSP70 overexpressed (OE) lines were allowed to reach four to five weeks leaves stage of development when drought was rapidly induced by withholding irrigation for 15 days. The stress condition was prolonged until the leaves of wild type plants completely wilted. (C) After rewatering for 3 days, most wild type plants were unable to recover, while OE plants survived continued to grow. (D) 40-day-old WT and OE transgenic plants grown in nutrient solution. (E) For drought stress, 40-day-old WT and OE transgenic plants were transferred into nutrient solution containing 20% (w/v) PEG-6000 for 48 h. The concentration of PEG was maintained daily by changing the nutrient solution. (F) Leaf relative water content from WT and OE plants after 10 days, 15 days drought stress and 3 days rewater treatment. (G) Leaf relative water content from WT and OE plants after 20% PEG-6000 treatment for 48 h."

Fig. 3

Changes of H2O2 content and MDA levels in wild plant and transgenic plant line under 20% PEG treatment. (A) H2O2 content of seedlings at these days of the 20% PEG treatment; (B) MDA levels of seedlings at these days of the 20% PEG treatment. Data are shown as mean±SD of three independent measurements."

Fig. 4

Antioxidant enzyme activities in wild plant and transgenic plants after treatment with 20% PEG(A) SOD activity; (B) POD activity. Data are shown as means ±SD of three independent measurements."

Fig. 5

Overexpression of BnA7HSP70 makes Brassica napus hold more water in soil pot without irrigation for 10 days(A) Relative water content (RWC) of wild type and BnA7HSP70 overexpressing seedling (OE2, OE3, OE7, and OE8) leaves under drought condition. (B) Chlorophyll a and b concentrations were calculated as described in the materials and methods 1.5.3 and combined to give the total chlorophyll concentration, each of which is a mean of the samples taken from 6-8 leaf disks in each pool. Control: the wild and OE plants grew in the irrigated condition; Stress: four-week old wild and OE plants were subjected to progressive drought for seven days."

Fig. 6

BnA7HSP70 overexpression delays drought-induced leaf senescence in OE lines confronted with stress Drought was induced in wild type (WT) and OE transgenic plants (OE2, OE3, OE7, and OE8) at four-week old stage by withholding irrigation for 10 days. Control: normally irrigated plants. Stress: drought-stressed plants. Values are given as mean SD from three replicates. The experiment of senescence-associated genes BnLSC45 and BnLSC222 was induced by drought treatment. Total RNA was isolated from irrigated and drought-stressed mature leaves of wild plants and OE lines, and gene induction was monitored by quantitative RT-PCR using gene-specific primers."

Fig. 7

BnA7HSP70 overexpression increases resistance against tunicamycin (TUN)-induced cell death(A) Seeds and seedlings from overexpressed plants (OE) and untransformed wild-type (WT) plants were exposed to 2.5 µg mL-1 or 5.0 µg mL-1 tunicamycin. (B)-(C) Seedlings were monitored for the development of chlorosis and necrotic lesions, and cell viability were measured by the Evans blue dye method. Abs (600 nm) reflects the dead cell content. The values represent the average of three replicates (±SD)."

Fig. 8

Gene expression analysis of senescence and cell death-associated genes in wild type and OE plants under tunicamycin treatment Total RNA were isolated from wild type and transgenic plant leaves at 0, 24, 48, and 72 h of treatment, and the endogenous BnA7HSP70, BnCNX1, BnBiP3, and BnNRP in wild type and OE transgenic plants treatment with tunicamycin and the control DMSO were monitored by qRT-PCR. The bars indicate the confidence interval (P < 0.05, n = 3). BnCNX1, BnBiP3, and BnNRP are ER stress markers."

Fig. 9

Model for BnA7HSP70 expression on the mobilization of bZIP28 and upregulation of UPR genes(A) In response to the stress, BnA7HSP70 is competed away by the accumulation of misfolded proteins and bZIP28 is proteolytically activated by Golgi-localized S1P or S2P to release bZIP28n, which relocates to the nucleus where it upregulates stress genes including BnBiP3 and BnCNX1; (B) When BnA7HSP70 is overexpressed, accumulated BnA7HSP70 is enough for association with bZIP28 and misfolded proteins. As a result, bZIP28 is detained in the ER even under stress conditions."

[1] Hartl F U, Bracher A, Hayer-Hartl M.Molecular chaperones in protein folding and proteostasis.Nature, 2011, 475: 324-332
[2] Wang W, Vinocur B, Shoseyov O, Altman A.Role of plant heat-shock proteins and molecular chaperones in the abiotic stress response.Trends Plant Sci, 2004, 9: 244-252
[3] Carvalho H H, Brustolini O J, Pimenta M R.The molecular chaperone binding protein BiP prevents leaf dehydration-induced cellular homeostasis disruption.PLoS One, 2014, 9: e86661
[4] Liu J X, Howell S H.Managing the protein folding demands in the endoplasmic reticulum of plants. New Phytol, 2016, 211: 418-428
[5] Valente M A, Faria J A, Soares-Ramos J R. The ER luminal binding protein (BiP) mediates an increase in drought tolerance in soybean and delays drought-induced leaf senescence in soybean and tobacco.J Exp Bot, 2009, 60: 533-546
[6] Liu J X, Howell S H.Endoplasmic reticulum protein quality control and its relationship to environmental stress responses in plants.Plant Cell, 2010, 22: 2930-2942
[7] Carvalho H H, Silva P A, Mendes G C.The endoplasmic reticulum binding protein BiP displays dual function in modulating cell death events.Plant Physiol, 2014, 164: 654-670
[8] Srivastava R, Deng Y, Howell S H.Stress sensing in plants by an ER stress sensor/transducer, bZIP28.Front Plant Sci, 2014, 5: 59
[9] Shen J, Chen X, Hendershot L, Prywes R.ER stress regulation of ATF6 localization by dissociation of BiP/GRP78 binding and unmasking of Golgi localization signals.Dev Cell, 2002, 3: 99-111
[10] Ma Y, Hendershot L M.ER chaperone functions during normal and stress conditions.J Chem Neuroanat, 2004, 28: 51-65
[11] Srivastava R, Chen Y, Deng Y, Brandizzi F, Howell S H.Elements proximal to and within the transmembrane domain mediate the organelle-to-organelle movement of bZIP28 under ER stress conditions.Plant J, 2012, 70: 1033-1042
[12] Urano F, Wang X, Bertolotti A, Zhang Y, Chung P, Harding H P, Ron D.Coupling of stress in the ER to activation of JNK protein kinases by transmembrane protein kinase IRE1.Science, 2000, 287: 664-666
[13] Martinez I M, Chrispeels M J.Genomic analysis of the unfolded protein response in Arabidopsis shows its connection to important cellular processes.Plant Cell, 2003, 15: 561-576
[14] Costa M D, Reis P A, Valente M A.A new branch of endoplasmic reticulum stress signaling and the osmotic signal converge on plant-specific asparagine-rich proteins to promote cell death.J Biol Chem, 2008, 283: 20209-20219
[15] Liu J X, Howell S H. bZIP28 and NF-Y transcription factors are activated by ER stress and assemble into a transcriptional complex to regulate stress response genes in Arabidopsis. Plant Cell, 2010, 22: 782-796
[16] Gomer C J, Ferrario A, Rucker N, Wong S, Lee A S.Glucose regulated protein induction and cellular resistance to oxidative stress mediated by porphyrin photosensitization.Cancer Res, 1991, 51: 6574-6579
[17] Alvim F C, Carolino S M, Cascardo J C.Enhanced accumulation of BiP in transgenic plants confers tolerance to water stress.Plant Physiol, 2001, 126: 1042-1054
[18] Cascardo J C, Almeida R S, Buzeli R A.The phosphorylation state and expression of soybean BiP isoforms are differentially regulated following abiotic stresses.J Biol Chem, 2000, 275: 14494-14500
[19] Cascardo J C, Buzeli R A, Almeida R S, Otoni W C, Fontes E P.Differential expression of the soybean BiP gene family.Plant Sci, 2001, 160: 273-281
[20] Anderson J V, Li Q B, Haskell D W, Guy C L.Structural organization of the spinach endoplasmic reticulum-luminal 70-kilodalton heat-shock cognate gene and expression of 70-kilodalton heat-shock genes during cold acclimation.Plant Physiol, 1994, 104: 1359-1370
[21] Park C J, Bart R, Chern M.Overexpression of the endoplasmic reticulum chaperone BiP3 regulates XA21-mediated innate immunity in rice.PLoS One, 2010, 5: e9262
[22] 宋仲戬, 张登峰, 李永祥. 石云素, 宋燕春, 王天宇, 黎裕. 玉米分子伴侣基因ZmBiP2在逆境下的功能分析. 作物学报, 2015, 41: 708-716
Song Z J, Zhang D F, Li Y X, Shi Y S, Song Y C, Wang T Y, Li Y.Cloning of maize molecular chaperone gene ZmBiP2 and its functional analysis under abiotic stress.Acta Agron Sin, 2015, 41: 708-716
[23] 赵真真, 韩莹琰, 范双喜, 刘超杰, 郝敬虹, 李婷, 李雅博. 叶用莴苣热激蛋白LsHsp70-3701基因的克隆及高温胁迫下的表达分析. 核农学报, 2016, 30: 1083-1090
Zhao Z Z, Han Y Y, Fan S X, Liu C J, Hao J H, Li T, Li Y B.The cloning and expression analysis of Heat-shock protein LsHsp70-3701 of Leaf lettuce.J Nucl Agric Sci, 2016, 30: 1083-1090 (in Chinese with English abstract)
[24] Livak K J, Schmittgen T D.Analysis of relative gene expression data using real-time quantitative PCR and the 2(-delta delta C(T)) method.Methods, 2001, 25: 402-408
[25] Hanfrey C, Fife M, Buchanan-Wollaston V.Leaf senescence inBrassica napus: expression of genes encoding pathogenesis- related proteins. Plant Mol Biol, 1996, 30: 597-609
[26] Buchanan-Wollaston V.Isolation of cDNA clones for genes that are expressed during leaf senescence in Brassica napus: identification of a gene encoding a senescence-specific metallothionein- like protein. Plant Physiol, 1994, 105: 839-846
[27] Srivastava R, Deng Y, Shah S, Rao A G, Howell S H.BINDING PROTEIN is a master regulator of the endoplasmic reticulum stress sensor/transducer bZIP28 in Arabidopsis.Plant Cell, 2013, 25: 1416-1429
[28] Iwata Y, Fedoroff N V, Koizumi N.Arabidopsis bZIP60 is a proteolysis-activated transcription factor involved in the endoplasmic reticulum stress response.Plant Cell, 2008, 20: 3107-3121
[1] CHEN Song-Yu, DING Yi-Juan, SUN Jun-Ming, HUANG Deng-Wen, YANG Nan, DAI Yu-Han, WAN Hua-Fang, QIAN Wei. Genome-wide identification of BnCNGC and the gene expression analysis in Brassica napus challenged with Sclerotinia sclerotiorum and PEG-simulated drought [J]. Acta Agronomica Sinica, 2022, 48(6): 1357-1371.
[2] ZHOU Wen-Qi, QIANG Xiao-Xia, WANG Sen, JIANG Jing-Wen, WEI Wan-Rong. Mechanism of drought and salt tolerance of OsLPL2/PIR gene in rice [J]. Acta Agronomica Sinica, 2022, 48(6): 1401-1415.
[3] YUAN Da-Shuang, DENG Wan-Yu, WANG Zhen, PENG Qian, ZHANG Xiao-Li, YAO Meng-Nan, MIAO Wen-Jie, ZHU Dong-Ming, LI Jia-Na, LIANG Ying. Cloning and functional analysis of BnMAPK2 gene in Brassica napus [J]. Acta Agronomica Sinica, 2022, 48(4): 840-850.
[4] HUANG Cheng, LIANG Xiao-Mei, DAI Cheng, WEN Jing, YI Bin, TU Jin-Xing, SHEN Jin-Xiong, FU Ting-Dong, MA Chao-Zhi. Genome wide analysis of BnAPs gene family in Brassica napus [J]. Acta Agronomica Sinica, 2022, 48(3): 597-607.
[5] WANG Rui, CHEN Xue, GUO Qing-Qing, ZHOU Rong, CHEN Lei, LI Jia-Na. Development of linkage InDel markers of the white petal gene based on whole-genome re-sequencing data in Brassica napus L. [J]. Acta Agronomica Sinica, 2022, 48(3): 759-769.
[6] WANG Yan-Hua, LIU Jing-Sen, LI Jia-Na. Integrating GWAS and WGCNA to screen and identify candidate genes for biological yield in Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(8): 1491-1510.
[7] LI Jie-Hua, DUAN Qun, SHI Ming-Tao, WU Lu-Mei, LIU Han, LIN Yong-Jun, WU Gao-Bing, FAN Chu-Chuan, ZHOU Yong-Ming. Development and identification of transgenic rapeseed with a novel gene for glyphosate resistance [J]. Acta Agronomica Sinica, 2021, 47(5): 789-798.
[8] TANG Xin, LI Yuan-Yuan, LU Jun-Xing, ZHANG Tao. Morphological characteristics and cytological study of anther abortion of temperature-sensitive nuclear male sterile line 160S in Brassica napus [J]. Acta Agronomica Sinica, 2021, 47(5): 983-990.
[9] ZHOU Xin-Tong, GUO Qing-Qing, CHEN Xue, LI Jia-Na, WANG Rui. Construction of a high-density genetic map using genotyping by sequencing (GBS) for quantitative trait loci (QTL) analysis of pink petal trait in Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(4): 587-598.
[10] LI Shu-Yu, HUANG Yang, XIONG Jie, DING Ge, CHEN Lun-Lin, SONG Lai-Qiang. QTL mapping and candidate genes screening of earliness traits in Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(4): 626-637.
[11] TANG Jing-Quan, WANG Nan, GAO Jie, LIU Ting-Ting, WEN Jing, YI Bin, TU Jin-Xing, FU Ting-Dong, SHEN Jin-Xiong. Bioinformatics analysis of SnRK gene family and its relation with seed oil content of Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(3): 416-426.
[12] MENG Jiang-Yu, LIANG Guang-Wei, HE Ya-Jun, QIAN Wei. QTL mapping of salt and drought tolerance related traits in Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(3): 462-471.
[13] LI Qian, Nadil Shah, ZHOU Yuan-Wei, HOU Zhao-Ke, GONG Jian-Fang, LIU Jue, SHANG Zheng-Wei, ZHANG Lei, ZHAN Zong-Xiang, CHANG Hai-Bin, FU Ting-Dong, PIAO Zhong-Yun, ZHANG Chun-Yu. Breeding of a novel clubroot disease-resistant Brassica napus variety Huayouza 62R [J]. Acta Agronomica Sinica, 2021, 47(2): 210-223.
[14] WEI Li-Juan, SHEN Shu-Lin, HUANG Xiao-Hu, MA Guo-Qiang, WANG Xi-Tong, YANG Yi-Ling, LI Huan-Dong, WANG Shu-Xian, ZHU Mei-Chen, TANG Zhang-Lin, LU Kun, LI Jia-Na, QU Cun-Min. Genome-wide association analysis reveals zinc-tolerant loci of rapeseed at germination stage [J]. Acta Agronomica Sinica, 2021, 47(2): 262-274.
[15] WANG Rui-Li, WANG Liu-Yan, LEI Wei, WU Jia-Yi, SHI Hong-Song, LI Chen-Yang, TANG Zhang-Lin, LI Jia-Na, ZHOU Qing-Yuan, CUI Cui. Screening candidate genes related to aluminum toxicity stress at germination stage via RNA-seq and QTL mapping in Brassica napus L. [J]. Acta Agronomica Sinica, 2021, 47(12): 2407-2422.
Viewed
Full text


Abstract

Cited

  Shared   
  Discussed   
No Suggested Reading articles found!