盐胁迫下中国沙棘生理指标变化及水通道蛋白基因的表达模式

施会; 严雯雯; 尹代浩; 张宇; 王蔚; 鲍玉英; 马玉花

doi:10.19303/j.issn.1008-0384.2023.12.004

盐胁迫下中国沙棘生理指标变化及水通道蛋白基因的表达模式

doi: 10.19303/j.issn.1008-0384.2023.12.004

1.
青海大学农牧学院，青海　西宁　810016

基金项目: 青海省高端创新人才千人计划项目（2022）；国家自然科学基金项目（31660071）；青海省科技厅项目（2017-ZJ-734）

详细信息

作者简介:
施会（1997 —），女，硕士研究生，主要从事林木遗传育种相关研究，E-mail：3211227527@qq.com

通讯作者:
马玉花（1978 —），女，博士，教授，主要从事森林培育理论与技术研究，E-mail：qhxnmyh@163.com

中图分类号: S793.6
计量
- 文章访问数: 200
- HTML全文浏览量: 112
- PDF下载量: 43
- 被引次数: 0
出版历程
- 收稿日期: 2023-03-01
- 修回日期: 2023-07-22
- 网络出版日期: 2023-12-21
- 刊出日期: 2023-12-28

Physiology and Expression of PIP of Hippophae rhamnoides under Salt Stress

1.
College of Agriculture and Husbandry, Qinghai University, Xining, Qinghai　810016, China

摘要

摘要: 目的探讨水通道蛋白（Plasma membrane intrinsic proteins，PIPs）在中国沙棘盐胁迫响应中的作用，为中国沙棘应对盐胁迫机理研究提供参考。方法以中国沙棘（Hippophae rhamnoides subsp. sinensis）为试验材料，对中国沙棘质膜内在蛋白基因（HrPIP）序列进行生物信息学分析，并研究不同程度盐胁迫（200、400、600、800、1000 mmol·L⁻¹）对中国沙棘生理指标及HrPIP基因表达模式的影响。结果中国沙棘HrPIP基因编码110个氨基酸，其编码蛋白质位于细胞膜上，无信号肽，无跨膜螺旋区，为疏水性蛋白。中国沙棘相对含水量随着盐胁迫的加深逐渐下降；叶绿素含量总体呈先下降后升高的趋势；质膜透性和丙二醛含量在低浓度盐胁迫下变化不大，在高盐浓度下急剧上升，在1000 mmol·L⁻¹时丙二醛含量有所降低而膜透性继续升高。HrPIP基因的表达随着盐胁迫程度的加剧而变化，其在根中的表达量呈先上升后下降再上升的趋势，在叶中呈先下调后急剧上升而后又下降的趋势，在茎中则呈“M”型表达模式。结论中国沙棘在盐胁迫下具有一定的抗盐性，胁迫下HrPIP基因的表达量变化促进根的吸水、茎的运输、叶的保水等，从而提高水分吸收，调节自身的耐盐性，说明该基因在中国沙棘应对盐胁迫的过程中起着重要作用。
- 中国沙棘 /
- HrPIP基因 /
- 盐胁迫 /
- 表达模式
Abstract: Objective Mechanism of aquaporins relating to the plasma membrane intrinsic proteins (PIPs) of Hippophae rhamnoides subsp. sinensis in response to salt stress was studied. Methods Bioinformatics of HrPIP was analyzed. Physiological indexes and expressions of the gene in tissues of H. rhamnoides under normal and imposed salt stresses of 200, 400, 600, 800, or 1,000 mmol ·L⁻¹ NaCl were determined. Results Located in the cell membrane, HrPIP encoded 110 amino acids. The hydrophobic protein had no signal peptide or transmembrane helix region. As salt stress intensified, the RWC decreased gradually, and the chlorophyll content declined initially followed by an incline. The permeability of the plasma membrane and the content of MDA changed slightly when the salt concentration was low but increased significantly when the concentration was high. The 1000 mmol·L⁻¹ salt stress induced declined MDA but continuously rising membrane permeability. The expressions of HrPIP in different organs varied by the increasing salt stress. In roots, it rose at lower salt concentrations then declined but rose again at high salt levels. In the leaves, the opposite trend was observed, whereas it was in an “M” pattern in the stems. Conclusion H.rhamnoides subsp. sinensis was salt resistant to a certain degree. Under the stress, by altering the HrPIP expression to increase water absorption in roots, transport in stems, and retention in leaves the plant manipulated the cellular salt concentration to achieve an improved stress tolerance.
- Hippophae rhamnoides subsp. sinensis /
- HrPIP /
- salt stress /
- expression pattern

HTML全文

图 1 HrPIP蛋白亲疏水性分析

Figure 1. Hydrophobicity of HrPIP

下载: 全尺寸图片幻灯片

图 2 HrPIP蛋白跨膜结构域预测

Figure 2. Predicted transmembrane region of HrPIP

下载: 全尺寸图片幻灯片

图 3 HrPIP蛋白二级结构预测

蓝色区域：α-螺旋；红色区域：延伸链；紫色区域：无规则卷曲。

Figure 3. Predicted secondary structure of HrPIP protein

Blue regions: α-helix; red regions: extended strand; purple regions: random coil.

下载: 全尺寸图片幻灯片

图 4 HrPIP蛋白磷酸化位点预测

红色为丝氨酸磷酸化位点；绿色为苏氨酸磷酸化位点；紫色为酪氨酸磷酸化位点；粉色线为阈值。

Figure 4. Predicted phosphorylation site in HrPIP protein

Red indicates serine phosphorylation site; green, tyrosine phosphorylation site; purple, threonine phosphorylation site; pink line, threshold value.

下载: 全尺寸图片幻灯片

图 5 盐胁迫下中国沙棘生理指标的变化

不同大写字母表示不同处理在0.01水平差异极显著。

Figure 5. Changes on physiological indexes of H. rhamnoides under salt stress

Different uppercase letters indicate significant difference at 0.01 level.

下载: 全尺寸图片幻灯片

图 6 HrPIP基因在中国沙棘根茎叶中的表达模式

不同大写字母表示不同胁迫处理下差异极显著（P＜0.01），不同小写字母表示不同组织之间差异显著（P＜0.05）。

Figure 6. Expressions of HrPIP in roots and leaves of H. rhamnoides

Data with different capital letters indicate extremely significant difference under treatments (P＜0.01); those with different lowercase letters, significant difference between tissues (P＜0.05).

下载: 全尺寸图片幻灯片

参考文献(24)

[1]	曲悦, 王姝瑶, 郝鑫, 等. 盐胁迫诱导植物交叉适应及其信号转导 [J]. 植物生理学报, 2022, 58(6):1045−1054. doi: 10.13592/j.cnki.ppj.300027 QU Y, WANG S Y, HAO X, et al. Plant cross-adaptation and signal transduction induced by salt stress [J]. Plant Physiology Journal, 2022, 58(6): 1045−1054.(in Chinese) doi: 10.13592/j.cnki.ppj.300027
[2]	刘云芬, 彭华, 王薇薇, 等. 植物耐盐性生理与分子机制研究进展 [J]. 江苏农业科学, 2019, 47(12):30−36. LIU Y F, PENG H, WANG W W, et al. Research progress on physiological and molecular mechanisms of salt tolerance for plants [J]. Jiangsu Agricultural Sciences, 2019, 47(12): 30−36.(in Chinese)
[3]	赵亚楠, 王建鑫, 陈蜜蜜, 等. 盐胁迫下对植物生长影响的研究进展[C]//华北五省市(区)环境科学学会第二十二届学术年会论文集. 2021: 18–24.
[4]	包珠拉太, 高丽, 王锁民. 植物水通道蛋白及其生理功能 [J]. 植物生理学报, 2017, 53(7):1171−1178. BAO Z, GAO L, WANG S M. Physiological functions of plant aquaporin [J]. Plant Physiology Journal, 2017, 53(7): 1171−1178.(in Chinese)
[5]	MAUREL C, VERDOUCQ L, RODRIGUES O. Aquaporins and plant transpiration [J]. Plant, Cell & Environment, 2016, 39(11): 2580−2587.
[6]	PAWŁOWICZ I, MASAJADA K. Aquaporins as a link between water relations and photosynthetic pathway in abiotic stress tolerance in plants [J]. Gene, 2019, 687: 166−172. doi: 10.1016/j.gene.2018.11.031
[7]	ZWIAZEK J J, XU H, TAN X F, et al. Significance of oxygen transport through aquaporins [J]. Scientific Reports, 2017, 7: 40411. doi: 10.1038/srep40411
[8]	阮成江, 谢庆良. 盐胁迫下沙棘的渗透调节效应 [J]. 植物资源与环境学报, 2002, 11(2):45−47. RUAN C J, XIE Q L. Osmotic adjustment effect of Hippophae rhamnoides L. under salt stress [J]. Journal of Plant Resources and Environment, 2002, 11(2): 45−47.(in Chinese)
[9]	李合生. 植物生理生化实验原理和技术[M]. 北京: 高等教育出版社, 2000.
[10]	PFAFFL M W. A new mathematical model for relative quantification in real-time RT-PCR [J]. Nucleic Acids Research, 2001, 29(9): e45. doi: 10.1093/nar/29.9.e45
[11]	谭照国, 苑少华, 李艳梅, 等. 小麦TaPIP₁基因克隆及其在花药开裂中潜在功能分析 [J]. 作物学报, 2022, 48(9):2242−2254. TAN Z G, YUAN S H, LI Y M, et al. Cloning of TaPIP₁ gene and its potential function in anther dehiscence in wheat [J]. Acta Agronomica Sinica, 2022, 48(9): 2242−2254.(in Chinese)
[12]	LI R, WANG J F, LI S T, et al. Plasma membrane intrinsic proteins SlPIP2;1, SlPIP2;7 and SlPIP2;5 conferring enhanced drought stress tolerance in tomato [J]. Scientific Reports, 2016, 6: 31814. doi: 10.1038/srep31814
[13]	张冰冰, 孙天旭, 赵月明, 等. 羊草LcPIP基因遗传转化露地菊及其抗盐性鉴定 [J]. 植物生理学报, 2018, 54(3):491−499. ZHANG B B, SUN T X, ZHAO Y M, et al. Genetic transformation of LcPIP gene in Chrysanthemum morifolium and identification of its salt resistance [J]. Plant Physiology Journal, 2018, 54(3): 491−499.(in Chinese)
[14]	余桂红, 孙晓波, 张旭, 等. 转SbPIP1基因小麦植株的获得及发芽期耐盐性鉴定 [J]. 分子植物育种, 2012, 10(4):398−403. YU G H, SUN X B, ZHANG X, et al. Obtaining of transgenic wheat plants with SbPIP₁ gene and preliminary assay of salt tolerance [J]. Molecular Plant Breeding, 2012, 10(4): 398−403.(in Chinese)
[15]	HUANG L Y, LI Z Z, PAN S B, et al. Ameliorating effects of exogenous calcium on the photosynthetic physiology of honeysuckle (Lonicera japonica) under salt stress [J]. Functional Plant Biology, 2019, 46(12): 1103−1113. doi: 10.1071/FP19116
[16]	刘晶, 才华, 刘莹, 等. 两种紫花苜蓿苗期耐盐生理特性的初步研究及其耐盐性比较 [J]. 草业学报, 2013, 22(2):250−256. LIU J, CAI H, LIU Y, et al. A study on physiological characteristics and comparison of salt tolerance of two Medicago sativa at the seedling stage [J]. Acta Prataculturae Sinica, 2013, 22(2): 250−256.(in Chinese)
[17]	冉昆, 孙晓莉, 张勇, 等. 杜梨质膜水孔蛋白基因PbPIP1的克隆与表达分析 [J]. 植物生理学报, 2016, 52(6):868−876. RAN K, SUN X L, ZHANG Y, et al. Cloning and expression analysis of a plasma membrane aquaporion gene PbPIP₁ in Pyrus betulifoli a [J]. Plant Physiology Journal, 2016, 52(6): 868−876.(in Chinese)
[18]	周洪华, 李卫红. 胡杨木质部水分传导对盐胁迫的响应与适应 [J]. 植物生态学报, 2015, 39(1):81−91. doi: 10.17521/cjpe.2015.0009 ZHOU H H, LI W H. Responses and adaptation of xylem hydraulic conductivity to salt stress in Populus euphratic a [J]. Chinese Journal of Plant Ecology, 2015, 39(1): 81−91.(in Chinese) doi: 10.17521/cjpe.2015.0009
[19]	岳川, 曹红利, 王赞, 等. 茶树水通道蛋白基因的克隆与表达分析 [J]. 西北植物学报, 2018, 38(8):1419−1427. doi: 10.7606/j.issn.1000-4025.2018.08.1419 YUE C, CAO H L, WANG Z, et al. Cloning and expression analysis of aquaporin protein genes in tea plant(Camellia sinensis) [J]. Acta Botanica Boreali-Occidentalia Sinica, 2018, 38(8): 1419−1427.(in Chinese) doi: 10.7606/j.issn.1000-4025.2018.08.1419
[20]	颜培玲, 潘学军, 张文娥. 野生毛葡萄水通道蛋白基因VhPIP1的克隆及其在干旱胁迫下的表达分析 [J]. 园艺学报, 2015, 42(2):221−232. doi: 10.16420/j.issn.0513-353x.2014-0875 YAN P L, PAN X J, ZHANG W E. Cloning of aquaporion gene VhPIP₁ in Vitis heyneana and its expression under drought stress [J]. Acta Horticulturae Sinica, 2015, 42(2): 221−232.(in Chinese) doi: 10.16420/j.issn.0513-353x.2014-0875
[21]	LI W, FU L F, GENG Z W, et al. Physiological characteristic changes and full-length transcriptome of rose (Rosa chinensis) roots and leaves in response to drought stress [J]. Plant and Cell Physiology, 2021, 61(12): 2153−2166. doi: 10.1093/pcp/pcaa137
[22]	KIM Y, CHUNG Y S, LEE E, et al. Root response to drought stress in rice (Oryza sativa L. ) [J]. International Journal of Molecular Sciences, 2020, 21(4): 1513. doi: 10.3390/ijms21041513
[23]	GUPTA A, RICO-MEDINA A, CAÑO-DELGADO A I. The physiology of plant responses to drought [J]. Science, 2020, 368(6488): 266−269. doi: 10.1126/science.aaz7614
[24]	李淑钰, 李传友. 植物根系可塑性发育的研究进展与展望 [J]. 中国基础科学, 2016, 18(2):14−21. doi: 10.3969/j.issn.1009-2412.2016.02.002 LI S Y, LI C Y. Developmental plasticity of plant roots [J]. China Basic Science, 2016, 18(2): 14−21.(in Chinese) doi: 10.3969/j.issn.1009-2412.2016.02.002