{"title":"表油菜素内酯通过稳定电子传递链和光系统II的功能来改善冷藏番茄的光合性能","authors":"Wenlang Hu, X. Hu, C. Liu, B.-Q. Wang, X. Yan","doi":"10.32615/bp.2022.008","DOIUrl":null,"url":null,"abstract":"Abbreviations : ABS/CS - absorption flux per CS; ABS/RC - absorption flux (exciting PS II antenna of Chl a molecules) per RC; AQY - apparent quantum yield; BRs - brassinosteroids; CEF - cyclic electron transport around PS I; c i - intercellular CO 2 concentration; CS - cros section; E - transpiration rate; EBR - 24-epibrassinolide; ET o /CS – electron transport flux per CS; ET o /RC - electron transport flux (further than Q A- ) per RC; ETR - electron transport rate; F m - maximal fluorescence yield; F o - minimal fluorescence yield; F v /F m - maximal quantum yield of PS II photochemistry; g s - stomatal conductance; M o - approximated initial slop (in ms -1 ) of the fluorescence transient normalized on the maximal variable fluorescence F v ; NPQ - nonphotochemical quenching coefficient; OEC - oxygen-evolving complex; OJIP curve - Chl a fluorescence transient; PI ABS - performance index for energy conservation from photons absorbed by PS II until the reduction of intersystem electron acceptors; P m - maximum P700 oxidation; P N - net photosynthetic rate; P N,max - maximum net photosynthetic rate; PPFD - photosynthetic photon flux density; PS I - photosystem I; PS II - photosystem II; qP - photochemical quenching coefficient; RC/CS - density of Q A -reducing PS II RCs per CS; RCs - PS II reaction centers; ROS - reactive oxygen species; TR o /CS - trapped energy flux per CS; TR o /RC - trapped energy flux (leading to Q A reduction) per RC; V J - relative variable fluorescence at the J-step; W K - normalized relative variable fluorescence at the K step; Y(I) - effective photochemical quantum yield of PS I; Y(II) - effective PS II quantum yield; Y(NA) - quantum yield of non-photochemical energy dissipation of reaction centers due to PS I acceptor side limitation; Y(ND) - quantum yield of non-photochemical energy dissipation in reaction centers due to PS I donor side limitation; Y(NPQ) - quantum yield of regulated energy dissipation; Y(NO) - quantum yield of nonregulated energy dissipation; φ Eo - quantum yield for electron transport (ET); φ Po - maximum quantum yield for primary photochemistry; Ψ o - probability that a trapped exciton moves an electron into the electron transport chain beyond Q A- . Abstract To explore the protective mechanisms of brassinosteroids in the chill-induced photoinhibition in tomato ( Solanum lycopersicum ), we studied the effect of foliar sprayed 24-epibrassinolide (EBR, 0.1µM) on the gas exchange, chlorophyll fluorescence characteristics, and chlorophyll a fluorescence transient in tomato seedlings under chilling stress (a temperature of 8 ℃ and an irradiance of 200 µmol m -2 s -1 ) for 4 d. Results showed that chilling significantly inhibited CO 2 assimilation and induced photoinhibition of photosystem II (PS II). However, photosystem I (PS I) was relatively tolerant to chilling stress, which was due to the downregulation of PS II activity and increase of cyclic electron transport around PS I (CEF). Chilling led to the inactivation of PS II reaction centers (RCs) and blocked the electron transport at the PS II acceptor side, but did not affect the oxygen-evolving complex (OEC) on the donor side of PS II. Exogenous EBR could alleviate chill-induced PS II photoinhibition mainly by the increase of CO 2 assimilation and thermal dissipation of excitation energy in the PS II antennae, while the protective effect of CEF was relatively smaller. This study demonstrated that EBR maintained the stability of the electron transport chain and the function of PS II in chilled tomatoes. EBR promoted the absorption (ABS/CS), trapping (TR o /CS), and electron transport (ET o /CS) per leaf area in tomatoes under chilling stress, which was due to increasing the density of active reaction centers (RC/CS), rather than the activity of active RCs.","PeriodicalId":8912,"journal":{"name":"Biologia Plantarum","volume":" ","pages":""},"PeriodicalIF":0.8000,"publicationDate":"2022-07-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"24-epibrassinolide improved chilled tomato photosyntheticperformance by stabilizing electron transport chain and function of photosystem II\",\"authors\":\"Wenlang Hu, X. Hu, C. Liu, B.-Q. Wang, X. Yan\",\"doi\":\"10.32615/bp.2022.008\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abbreviations : ABS/CS - absorption flux per CS; ABS/RC - absorption flux (exciting PS II antenna of Chl a molecules) per RC; AQY - apparent quantum yield; BRs - brassinosteroids; CEF - cyclic electron transport around PS I; c i - intercellular CO 2 concentration; CS - cros section; E - transpiration rate; EBR - 24-epibrassinolide; ET o /CS – electron transport flux per CS; ET o /RC - electron transport flux (further than Q A- ) per RC; ETR - electron transport rate; F m - maximal fluorescence yield; F o - minimal fluorescence yield; F v /F m - maximal quantum yield of PS II photochemistry; g s - stomatal conductance; M o - approximated initial slop (in ms -1 ) of the fluorescence transient normalized on the maximal variable fluorescence F v ; NPQ - nonphotochemical quenching coefficient; OEC - oxygen-evolving complex; OJIP curve - Chl a fluorescence transient; PI ABS - performance index for energy conservation from photons absorbed by PS II until the reduction of intersystem electron acceptors; P m - maximum P700 oxidation; P N - net photosynthetic rate; P N,max - maximum net photosynthetic rate; PPFD - photosynthetic photon flux density; PS I - photosystem I; PS II - photosystem II; qP - photochemical quenching coefficient; RC/CS - density of Q A -reducing PS II RCs per CS; RCs - PS II reaction centers; ROS - reactive oxygen species; TR o /CS - trapped energy flux per CS; TR o /RC - trapped energy flux (leading to Q A reduction) per RC; V J - relative variable fluorescence at the J-step; W K - normalized relative variable fluorescence at the K step; Y(I) - effective photochemical quantum yield of PS I; Y(II) - effective PS II quantum yield; Y(NA) - quantum yield of non-photochemical energy dissipation of reaction centers due to PS I acceptor side limitation; Y(ND) - quantum yield of non-photochemical energy dissipation in reaction centers due to PS I donor side limitation; Y(NPQ) - quantum yield of regulated energy dissipation; Y(NO) - quantum yield of nonregulated energy dissipation; φ Eo - quantum yield for electron transport (ET); φ Po - maximum quantum yield for primary photochemistry; Ψ o - probability that a trapped exciton moves an electron into the electron transport chain beyond Q A- . Abstract To explore the protective mechanisms of brassinosteroids in the chill-induced photoinhibition in tomato ( Solanum lycopersicum ), we studied the effect of foliar sprayed 24-epibrassinolide (EBR, 0.1µM) on the gas exchange, chlorophyll fluorescence characteristics, and chlorophyll a fluorescence transient in tomato seedlings under chilling stress (a temperature of 8 ℃ and an irradiance of 200 µmol m -2 s -1 ) for 4 d. Results showed that chilling significantly inhibited CO 2 assimilation and induced photoinhibition of photosystem II (PS II). However, photosystem I (PS I) was relatively tolerant to chilling stress, which was due to the downregulation of PS II activity and increase of cyclic electron transport around PS I (CEF). Chilling led to the inactivation of PS II reaction centers (RCs) and blocked the electron transport at the PS II acceptor side, but did not affect the oxygen-evolving complex (OEC) on the donor side of PS II. Exogenous EBR could alleviate chill-induced PS II photoinhibition mainly by the increase of CO 2 assimilation and thermal dissipation of excitation energy in the PS II antennae, while the protective effect of CEF was relatively smaller. This study demonstrated that EBR maintained the stability of the electron transport chain and the function of PS II in chilled tomatoes. EBR promoted the absorption (ABS/CS), trapping (TR o /CS), and electron transport (ET o /CS) per leaf area in tomatoes under chilling stress, which was due to increasing the density of active reaction centers (RC/CS), rather than the activity of active RCs.\",\"PeriodicalId\":8912,\"journal\":{\"name\":\"Biologia Plantarum\",\"volume\":\" \",\"pages\":\"\"},\"PeriodicalIF\":0.8000,\"publicationDate\":\"2022-07-29\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Biologia Plantarum\",\"FirstCategoryId\":\"99\",\"ListUrlMain\":\"https://doi.org/10.32615/bp.2022.008\",\"RegionNum\":4,\"RegionCategory\":\"生物学\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q4\",\"JCRName\":\"PLANT SCIENCES\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Biologia Plantarum","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.32615/bp.2022.008","RegionNum":4,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"PLANT SCIENCES","Score":null,"Total":0}
引用次数: 0
摘要
缩写:ABS/CS -每CS的吸收通量;ABS/RC -每个RC的吸收通量(激发Chl a分子的PS II天线);AQY—表观量子产率;BRs—油菜素内酯;围绕psi的循环电子输运;c i -细胞间co2浓度;CS—截面;E——蒸腾速率;EBR - 24-表油菜素内酯;ET o /CS—每CS的电子输运通量;ET 0 /RC -每个RC的电子传递通量(大于Q A-);ETR—电子传递速率;F -最大荧光量;F -最小荧光量;fv / fm - PSⅱ光化学的最大量子产率G -气孔导度;对最大可变荧光F v进行瞬态归一化的初始近似斜率(单位ms -1);NPQ—非光化学猝灭系数;OEC -出氧配合物;OJIP曲线- Chl a荧光瞬态;PI ABS -从PS II吸收光子到系统间电子受体还原的能量守恒性能指标;pm -最大P700氧化;磷氮净光合速率;pn,最大净光合速率;PPFD—光合光子通量密度;PS I—光系统I;PS II—光系统II;qP—光化学猝灭系数;RC/CS -降Q型PSⅱRCs的密度/CS;RCs - PSⅱ反应中心;ROS—活性氧;TR /CS—每CS捕获的能量通量;TR /RC -每个RC捕获的能量通量(导致Q A减少);V J-相对可变荧光在J步;W K - K步归一化相对可变荧光;Y(I)—PS I的有效光化学量子产率;Y(II) -有效PS II量子产率;Y(NA) - PS I受体侧限制下反应中心非光化学能量耗散的量子产率;Y(ND) - PS I给体侧限制下反应中心非光化学能量耗散的量子产率Y(NPQ)—调节能量耗散量子产率;Y(NO) -非调节能量耗散的量子产率;φ Eo -电子输运量子产率(ET);φ Po -初级光化学的最大量子产率Ψ o -被捕获的激子将电子移动到电子传递链中超过Q a -的概率。摘要为探讨油菜素内酯对番茄低温光抑制的保护机制,研究了叶面喷施24-表油菜素内酯(EBR, 0.1µM)对番茄叶片气体交换、叶绿素荧光特性和光合作用的影响。和茄幼苗叶绿素荧光瞬态压力冷却(8℃的温度和辐照度200µ摩尔m 2 s 1) 4 d。结果表明,冷却显著抑制CO 2同化和诱导的光抑制光系统II (PS II)。然而,光系统I (PS I)相对宽容的压力,PSⅱ的差别是由于对这些活动和增加循环电子传递PS我(CEF)。冷却导致PS II反应中心(rc)失活,并阻断PS II受体侧的电子传递,但不影响PS II供体侧的出氧复合物(OEC)。外源EBR主要通过增加CO 2同化和激发能在PS II天线中的热耗散来缓解低温诱导的PS II光抑制,而CEF的保护作用相对较小。本研究表明,EBR维持了冷藏番茄电子传递链的稳定性和PS II的功能。EBR促进了低温胁迫下番茄叶面积吸收(ABS/CS)、捕获(TR /CS)和电子传递(ET /CS),这主要是由于增加了活性反应中心(RC/CS)的密度,而不是活性反应中心的活性。
24-epibrassinolide improved chilled tomato photosyntheticperformance by stabilizing electron transport chain and function of photosystem II
Abbreviations : ABS/CS - absorption flux per CS; ABS/RC - absorption flux (exciting PS II antenna of Chl a molecules) per RC; AQY - apparent quantum yield; BRs - brassinosteroids; CEF - cyclic electron transport around PS I; c i - intercellular CO 2 concentration; CS - cros section; E - transpiration rate; EBR - 24-epibrassinolide; ET o /CS – electron transport flux per CS; ET o /RC - electron transport flux (further than Q A- ) per RC; ETR - electron transport rate; F m - maximal fluorescence yield; F o - minimal fluorescence yield; F v /F m - maximal quantum yield of PS II photochemistry; g s - stomatal conductance; M o - approximated initial slop (in ms -1 ) of the fluorescence transient normalized on the maximal variable fluorescence F v ; NPQ - nonphotochemical quenching coefficient; OEC - oxygen-evolving complex; OJIP curve - Chl a fluorescence transient; PI ABS - performance index for energy conservation from photons absorbed by PS II until the reduction of intersystem electron acceptors; P m - maximum P700 oxidation; P N - net photosynthetic rate; P N,max - maximum net photosynthetic rate; PPFD - photosynthetic photon flux density; PS I - photosystem I; PS II - photosystem II; qP - photochemical quenching coefficient; RC/CS - density of Q A -reducing PS II RCs per CS; RCs - PS II reaction centers; ROS - reactive oxygen species; TR o /CS - trapped energy flux per CS; TR o /RC - trapped energy flux (leading to Q A reduction) per RC; V J - relative variable fluorescence at the J-step; W K - normalized relative variable fluorescence at the K step; Y(I) - effective photochemical quantum yield of PS I; Y(II) - effective PS II quantum yield; Y(NA) - quantum yield of non-photochemical energy dissipation of reaction centers due to PS I acceptor side limitation; Y(ND) - quantum yield of non-photochemical energy dissipation in reaction centers due to PS I donor side limitation; Y(NPQ) - quantum yield of regulated energy dissipation; Y(NO) - quantum yield of nonregulated energy dissipation; φ Eo - quantum yield for electron transport (ET); φ Po - maximum quantum yield for primary photochemistry; Ψ o - probability that a trapped exciton moves an electron into the electron transport chain beyond Q A- . Abstract To explore the protective mechanisms of brassinosteroids in the chill-induced photoinhibition in tomato ( Solanum lycopersicum ), we studied the effect of foliar sprayed 24-epibrassinolide (EBR, 0.1µM) on the gas exchange, chlorophyll fluorescence characteristics, and chlorophyll a fluorescence transient in tomato seedlings under chilling stress (a temperature of 8 ℃ and an irradiance of 200 µmol m -2 s -1 ) for 4 d. Results showed that chilling significantly inhibited CO 2 assimilation and induced photoinhibition of photosystem II (PS II). However, photosystem I (PS I) was relatively tolerant to chilling stress, which was due to the downregulation of PS II activity and increase of cyclic electron transport around PS I (CEF). Chilling led to the inactivation of PS II reaction centers (RCs) and blocked the electron transport at the PS II acceptor side, but did not affect the oxygen-evolving complex (OEC) on the donor side of PS II. Exogenous EBR could alleviate chill-induced PS II photoinhibition mainly by the increase of CO 2 assimilation and thermal dissipation of excitation energy in the PS II antennae, while the protective effect of CEF was relatively smaller. This study demonstrated that EBR maintained the stability of the electron transport chain and the function of PS II in chilled tomatoes. EBR promoted the absorption (ABS/CS), trapping (TR o /CS), and electron transport (ET o /CS) per leaf area in tomatoes under chilling stress, which was due to increasing the density of active reaction centers (RC/CS), rather than the activity of active RCs.
期刊介绍:
BIOLOGIA PLANTARUM is an international journal for experimental botany. It publishes original scientific papers and brief communications, reviews on specialized topics, and book reviews in plant physiology, plant biochemistry and biophysics, physiological anatomy, ecophysiology, genetics, molecular biology, cell biology, evolution, and pathophysiology. All papers should contribute substantially to the current level of plant science and combine originality with a potential general interest. The journal focuses on model and crop plants, as well as on under-investigated species.