«上一篇/Previous Article|本期目录/Table of Contents|下一篇/Next Article»

[1]章加应,安海山,李水根,等.低温胁迫下枇杷抗寒生理指标变化规律及关键候选基因的筛选[J].江苏农业科学,2025,53(22):148-156.
　Zhang Jiaying,et al.Change of physiological indicator related to cold tolerance in loquat under cold stress and screening of key candidate genes[J].Jiangsu Agricultural Sciences,2025,53(22):148-156.
点击复制

低温胁迫下枇杷抗寒生理指标变化规律及关键候选基因的筛选()

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

卷:: 第53卷
期数:: 2025年第22期

页码:: 148-156

栏目:: 园艺与林学

出版日期:: 2025-11-20

文章信息/Info

Title:: Change of physiological indicator related to cold tolerance in loquat under cold stress and screening of key candidate genes

作者:: 章加应; 安海山; 李水根; 张学英; 上海市农业科学院林木果树研究所/上海市设施园艺技术重点实验室，上海 201403

Author(s):: Zhang Jiaying; et al

关键词:: 枇杷; 花序; 低温胁迫; 生理指标; 差异表达基因; 关键候选基因

Keywords:: -

分类号:: S667.301

DOI:: -

文献标志码:: A

摘要:: 为探究枇杷不同品种对低温胁迫的生理响应和分子调控机制，以枇杷耐寒型品种火炬和低温敏感型品种宁海白为试材，选取长势一致的花序在人工模拟的-4 ℃低温胁迫条件下测定不同处理时间的相关抗寒生理生化指标。同时，结合前期转录组数据筛选到的差异表达基因，分析其在低温胁迫处理不同时间的耐寒型和低温敏感型枇杷品种中的表达模式，筛选与枇杷抗寒性相关的关键候选基因。低温胁迫处理下，低温敏感型枇杷品种宁海白花序先与耐寒型品种火炬表现出褐化，相对电导率、半致死温度(LT₅₀)和冻害率明显高于火炬。火炬花序中相关抗寒生理指标(可溶性糖和脯氨酸)值高于宁海白花序并具有更强的抗氧化酶活性和活性氧清除能力。结合转录组数据筛选的差异表达基因(EjUGT88、EjSTP13、EjGT10、EjPERK9、EjPOD11、EjPOD47)表达模式与相关抗寒生理指标表现出一致的变化趋势，并在火炬花序中的表达水平整体上高于宁海白，表明差异表达基因可能在枇杷响应低温胁迫过程中发挥重要作用，可以作为与枇杷抗寒性相关的关键候选基因。研究结果为枇杷低温胁迫响应中特定基因的鉴定提供了宝贵的资源，并有助于阐明枇杷响应低温胁迫的分子调控机制。

Abstract:: -

参考文献/References:

［1］潘翠萍，谢红江，王永清，等. 6个枇杷品种对低温胁迫的生理响应及抗寒性评价［J］. 热带作物学报，2019，40(12)：2369-2374.
［2］章加应，张学英，安海山，等. 5份枇杷品种(系)的抗寒性生理评价［J］. 上海农业学报，2021，37(5)：39-46.
［3］Wu L L，Li J A，Li Z，et al. Transcriptomic analyses of Camellia oleifera ‘Huaxin’ leaf reveal candidate genes related to long-term cold stress［J］. International Journal of Molecular Sciences，2020，21(3)：846.
［4］Zhao Q，Xiang X H，Liu D，et al. Tobacco transcription factor NtbHLH123 confers tolerance to cold stress by regulating the NtCBF pathway and reactive oxygen species homeostasis［J］. Frontiers in Plant Science，2018，9：381.
［5］Valitova J，Renkova A，Mukhitova F，et al. Membrane sterols and genes of sterol biosynthesis are involved in the response of Triticum aestivum seedlings to cold stress［J］. Plant Physiology and Biochemistry，2019，142：452-459.
［6］Wang J W，Dong S Z，Jiang Y G，et al. Influence of long-term cold storage on phenylpropanoid and soluble sugar metabolisms accompanied with peel browning of ‘Nanguo’ pears during subsequent shelf life［J］. Scientia Horticulturae，2020，260：108888.
［7］Duan L N，Dietrich D，Ng C H，et al. Endodermal ABA signaling promotes lateral root quiescence during salt stress in Arabidopsis seedlings［J］. The Plant Cell，2013，25(1)：324-341.
［8］Virlouvet L，Fromm M. Physiological and transcriptional memory in guard cells during repetitive dehydration stress［J］. New Phytologist，2015，205(2)：596-607.
［9］Berg J，Rodrigues C M，Scheid C，et al. The vacuolar inositol transporter BvINT1；1 contributes to raffinose biosynthesis and reactive oxygen species scavenging during cold stress in sugar beet［J］. Plant，Cell & Environment，2025，48(5)：3471-3486.
［10］Deng R J，Fan J X，Wang Y Q，et al. Physiological responses of pitaya (Hylocereus spp.) seedlings to chilling stress and comprehensive evaluation of their cold resistance ［J］. Plant Physiology Journal，2014，50(10)：1529-1534.
［11］Zhang F，Jiang Y，Bai L P，et al. The ICE-CBF-COR pathway in cold acclimation and AFPs in plants ［J］. Middle East Journal of Scientific Research，2011，8(2)：493-498.
［12］Zhang G Y，Chen M，Li L C，et al. Overexpression of the soybean GmERF3 gene，an AP2/ERF type transcription factor for increased tolerances to salt，drought，and diseases in transgenic tobacco［J］. Journal of Experimental Botany，2009，60(13)：3781-3796.
［13］Huang X S，Wang W，Zhang Q，et al. A basic helix-loop-helix transcription factor，PtrbHLH，of Poncirus trifoliata confers cold tolerance and modulates peroxidase-mediated scavenging of hydrogen peroxide［J］. Plant Physiology，2013，162(2)：1178-1194.
［14］Xie Y P，Chen P X，Yan Y，et al. An atypical R2R3 MYB transcription factor increases cold hardiness by CBF-dependent and CBF-independent pathways in apple［J］. New Phytologist，2018，218(1)：201-218.
［15］Hu H H，You J，Fang Y J，et al. Characterization of transcription factor gene SNAC2 conferring cold and salt tolerance in rice［J］. Plant Molecular Biology，2008，67(1/2)：169-181.
［16］Zou C S，Jiang W B，Yu D Q. Male gametophyte-specific WRKY34 transcription factor mediates cold sensitivity of mature pollen in Arabidopsis［J］. Journal of Experimental Botany，2010，61(14)：3901-3914.
［17］Xing C H，Liu Y，Zhao L Y，et al. A novel MYB transcription factor regulates ascorbic acid synthesis and affects cold tolerance［J］. Plant，Cell & Environment，2019，42(3)：832-845.
［18］Xu M，Li S J，Liu X F，et al. Ternary complex EjbHLH1-EjMYB2-EjAP2-1 retards low temperature-induced flesh lignification in loquat fruit［J］. Plant Physiology and Biochemistry，2019，139：731-737.
［19］Zhang J Y，An H S，Zhang X Y，et al. Transcriptomic analysis reveals potential gene regulatory networks under cold stress of loquat (Eriobotrya japonica Lindl.)［J］. Frontiers in Plant Science，2022，13：944269.
［20］Dong H Z，Chen Q M，Dai Y Q，et al. Genome-wide identification of PbrbHLH family genes，and expression analysis in response to drought and cold stresses in pear (Pyrus bretschneideri)［J］. BMC Plant Biology，2021，21(1)：86.
［21］Xu J D，Zhou S S，Gong X Q，et al. Single-base methylome analysis reveals dynamic epigenomic differences associated with water deficit in apple［J］. Plant Biotechnology Journal，2018，16(2)：672-687.
［22］Sun X M，Zhang L L，Wong D C J，et al. The ethylene response factor VaERF092 from Amur grape regulates the transcription factor VaWRKY33，improving cold tolerance［J］. The Plant Journal，2019，99(5)：988-1002.
［23］Ashiq Rabbani M，Maruyama K，Abe H，et al. Monitoring expression profiles of rice genes under cold，drought，and high-salinity stresses and abscisic acid application using cDNA microarray and RNA gel-blot analyses［J］. Plant Physiology，2003，133(4)：1755-1767.
［24］Hayano-Kanashiro C，Calderón-Vázquez C，Ibarra-Laclette E，et al. Analysis of gene expression and physiological responses in three Mexican maize landraces under drought stress and recovery irrigation［J］. PLoS One，2009，4(10)：e7531.
［25］张波，荣立苹，陈柳，等. 盐胁迫下木本植物光合作用响应机制研究进展［J］. 上海农业科技，2017(5)：27-29.
［26］施春晖，王晓庆，张学英，等. 水肥一体化配套营养液配方对葡萄生理生化的影响［J］. 上海农业科技，2017(4)：114-117.
［27］Song H W，Wang X F，Hu W C，et al. A cold-induced phytosulfokine peptide is related to the improvement of loquat fruit chilling tolerance［J］. Food Chemistry，2017，232：434-442.
［28］Mickelbart M V，Hasegawa P M，Bailey-Serres J. Genetic mechanisms of abiotic stress tolerance that translate to crop yield stability［J］. Nature Reviews Genetics，2015，16(4)：237-251.
［29］Sun S X，Li J，Tu M Y，et al. Freezing damage factors and physiological indexes of frost resistance in loquat［J］. Acta Horticulturae，2011(887)：171-176.
［30］Ge H，Zhang J，Zhang Y J，et al. EjNAC3 transcriptionally regulates chilling-induced lignification of loquat fruit via physical interaction with an atypical CAD-like gene［J］. Journal of Experimental Botany，2017，68(18)：5129-5136.
［31］张淑文，梁森苗，朱婷婷，等. 不同杨梅品种的耐低温能力比较［J］. 浙江农业学报，2020，32(10)：1773-1780.
［32］Kumar V，Yadav S K. Proline and betaine provide protection to antioxidant and methylglyoxal detoxification systems during cold stress in Camellia sinensis (L.) O.Kuntze［J］. Acta Physiologiae Plantarum，2009，31(2)：261-269.
［33］邓仁菊，范建新，王永清，等. 火龙果幼苗离体辐射诱变及其对低温胁迫的生理响应［J］. 热带作物学报，2018，39(2)：260-266.
［34］阎依超，万春雁，古咸彬，等. 低温胁迫下转RdreB1BI草莓逆境相关基因表达及抗性评价［J］. 核农学报，2018，32(11)：2135-2146.
［35］徐卫平，蒋景龙，任绪明，等. 低温胁迫对3种柑橘幼苗细胞膜及渗透调节的影响［J］. 分子植物育种，2017，15(3)：1104-1108.
［36］惠竹梅，王智真，胡勇，等. 24-表油菜素内酯对低温胁迫下葡萄幼苗抗氧化系统及渗透调节物质的影响［J］. 中国农业科学，2013，46(5)：1005-1013.
［37］Talanova V V，Titov A F，Repkina N S，et al. Effect of methyl jasmonate on the expression of WCS genes and the activity of antioxidant enzymes at wheat cold adaptation［J］. Doklady Biochemistry and Biophysics，2018，482(1)：238-241.
［38］王阿宁，齐安国，王梦瑶，等. 杂交杏李种质的抗寒性鉴定及生理机制解析［J］. 果树学报，2025，42(7)：1397-1406.
［39］Wang L，Yao L N，Hao X Y，et al. Tea plant SWEET transporters：expression profiling，sugar transport，and the involvement of CsSWEET16 in modifying cold tolerance in Arabidopsis［J］. Plant Molecular Biology，2018，96(6)：577-592.
［40］Zhao M Y，Cai B B，Jin J Y，et al. Cold stress-induced glucosyltransferase CsUGT78A15 is involved in the formation of eugenol glucoside in Camellia sinensis［J］. Horticultural Plant Journal，2020，6(6)：439-449.
［41］Priyanka B，Sekhar K，Reddy V D，et al. Expression of pigeonpea hybrid-proline-rich protein encoding gene (CcHyPRP) in yeast and Arabidopsis affords multiple abiotic stress tolerance［J］. Plant Biotechnology Journal，2010，8(1)：76-87.
［42］Peng T，Jia M M，Liu J H.RNAi-based functional elucidation of PtrPRP，a gene encoding a hybrid proline rich protein，in cold tolerance of Poncirus trifoliata［J］. Frontiers in Plant Science，2015，6：808.
［43］宋佳敏，何佳伟，蒋伟勤，等. 喷施水杨酸和褪黑素对药隔期低温胁迫下小麦产量及生理特性的影响［J］. 江苏农业学报，2025，41(3)：477-484.
［44］Llorente F，López-Cobollo R M，Catalá R，et al. A novel cold-inducible gene from Arabidopsis，RCI3，encodes a peroxidase that constitutes a component for stress tolerance［J］. The Plant Journal，2002，32(1)：13-24.
［45］Zhou M Q，Li W W，Zheng Y，et al. CbRCI35，a cold responsive peroxidase from Capsella bursa-pastoris regulates reactive oxygen species homeostasis and enhances cold tolerance in tobacco［J］. Frontiers in Plant Science，2016，7：1599.

相似文献/References:

[1]杨若鹏,张祖芸,谢开美,等.云南蒙自枇杷叶霉病病原菌的初步鉴定[J].江苏农业科学,2013,41(04):111.
[2]王庆莲,赵密珍,袁华招,等.花前GA3处理对无核葡萄花序拉长和果实品质的影响[J].江苏农业科学,2014,42(11):171.
　Wang Qinglian,et al(7).Effects of GA3 treatment before flowering on elongating inflorescence and fruit quality of seedless grapes[J].Jiangsu Agricultural Sciences,2014,42(22):171.
[3]宋虎卫,张瑞越,李文卉,等.过氧乙酸结合钙处理对青种枇杷的保鲜效应[J].江苏农业科学,2013,41(06):208.
　Song Huwei,et al.Preservation effect of peracetic acid combined with calcium treatments on Eriobotrya japonica Lindl. cv. Qingzhong fruit[J].Jiangsu Agricultural Sciences,2013,41(22):208.
[4]袁卫明,宋虎卫,杨益花,等.枇杷SRAP标记体系优化及对枇杷矮化杂交种的鉴定[J].江苏农业科学,2015,43(12):36.
　Yuan Weiming,et al.Optimization of SRAP marker system of loquat (Eriobotrya japonica) and identification of its dwarfing hybrid line[J].Jiangsu Agricultural Sciences,2015,43(22):36.
[5]鲁海菊,董梅,崔同敏,等.从枇杷内生真菌中筛选抗枇杷根腐病菌的活性菌株[J].江苏农业科学,2014,42(01):95.
　Lu Haiju,et al.Screening of active strains against loquat root rot pathogen from loquat endophytic fungus[J].Jiangsu Agricultural Sciences,2014,42(22):95.
[6]王洋,姜卫兵,魏家星,等.枇杷的文化意蕴及其在园林绿化中的应用[J].江苏农业科学,2014,42(02):127.
　Wang Yang,et al.Cultural connotations of Eriobotrya japonica and its application in landscape architecture[J].Jiangsu Agricultural Sciences,2014,42(22):127.
[7]沈云玫,张建春,李河,等.枇杷根际土壤真菌对生防木霉菌株P3.9的影响[J].江苏农业科学,2014,42(04):106.
　Shen Yunmei,et al.Effect of loquat rhizosphere soil fungi on Trichoderma sp. strain P3.9[J].Jiangsu Agricultural Sciences,2014,42(22):106.
[8]陶宏征,张建春,鲁海菊,等.抗枇杷根腐病病菌的6株枇杷主干内生真菌生物学特性研究[J].江苏农业科学,2015,43(09):166.
　Tao Hongzheng,et al.Biological characteristics of 6 endophytic fungi strains from loquat stem with root rot pathogen resistance[J].Jiangsu Agricultural Sciences,2015,43(22):166.
[9]王利芬,赵雪阳,朱军贞.枇杷幼苗的水培技术[J].江苏农业科学,2015,43(08):155.
　Wang Lifen,et al.Hydroponics techniques of loquat seedling[J].Jiangsu Agricultural Sciences,2015,43(22):155.
[10]张旭晖,杨建全,王俊,等.江苏枇杷冻害发生规律及风险区划[J].江苏农业科学,2015,43(08):157.
　Zhang Xuhui,et al.Occurrence and risk zoning of freezing injury of loquat in Jiangsu Province[J].Jiangsu Agricultural Sciences,2015,43(22):157.

备注/Memo

备注/Memo:: 收稿日期：2025-05-12
基金项目：上海市“科技创新行动计划”启明星项目(扬帆专项)(编号：23YF1439600)。
作者简介：章加应(1993—)，男，安徽望江人，硕士，助理研究员，主要从事枇杷生理栽培及抗寒机理研究。E-mail：jiayingzsaas@163.com。
通信作者：张学英，博士，研究员，主要从事特色水果栽培技术和遗传育种研究。E-mail：zhangxueying@saas.sh.cn。

常用功能

工具/Tools

统计/Statistics

摘要浏览/Viewed265
全文下载/Downloads391
评论/Comments

更新日期/Last Update: 2025-11-20