«Previous Article|Table of Contents|Next Article»

《北方园艺》[ISSN:1001-0009/CN:23-1247/S]

Issue:

2023年17

Page:

15-24

Research Field:

Publishing date:

Info

Title:

Effects of Soil Saline-alkali Stress Degree on Photosynthetic Characteristics of Tomato

Author(s):

CUI Hongxin; GUAN Sihui; CHAI Yaqian; XU Jing; LIU Huiying; DIAO Ming

(College of Agriculture，Shihezi University/Key Laboratory of Physiology and Germplasm Resource Utilization of Characteristic Fruit and Vegetable Cultivation，Shihezi，Xinjiang 832003)

Keywords:

salin-alkali stress; chlorophyll fluorescence induction kinetics; pot experiments; PSⅡ; electron transport

PACS:

S 641.2

DOI:

10.11937/bfyy.20225299

Abstract:

Taking C2 and C5 tomato germplasm with different resistance as experimental materials，pot experiments were carried out and three saline-alkali soil treatments with different stress degrees were set up.Compared with non-saline-alkali stressed soil，the effects of different saline-alkali stress degrees on photosynthetic gas exchange parameters of two tomato varieties，as well as the rapid chlorophyll fluorescence kinetic curve and parameters of leaves were studied，in order to provide reference for further comprehensive analysis of tomato salt-alkali tolerance mechanism and salt-alkali resistance breeding.The results showed that saline-alkali stress reduced the net photosynthetic rate and affected the parameters of light and gas exchange by inhibiting the synthesis of chlorophyll in tomato.Saline-alkali stress reduced the maximum photochemical efficiency，actual photochemical efficiency，photosynthetic electron transfer rate and photochemical quenching coefficient of the two tomato varieties.At the same time，saline-alkali stress also changed the shape of OJIP curve of two tomato varieties.To sum up，saline-alkali stress would reduce the activity，electron transfer efficiency and photochemical efficiency of PSⅡ reaction center of C2 and C5 varieties，harm OEC and PSⅡ receptor side，reduce chlorophyll content，and thus reduce the net photosynthetic rate.In case of saline-alkalitress，C2 variety had higher PSⅡ reaction center activity and electron transfer rate than C5 variety，improved the net photosynthetic rate，and reduced the damage caused by saline-alkali stress by dissipating excess light energy，so the growth inhibition degree was significantly lower than C5 variety.

References:

［1］ 朱金方，刘京涛，陆兆华,等.盐胁迫对中国柽柳幼苗生理特性的影响［J］.生态学报，2015，35(15)：5140-5146.�ぃ�2］ ZELM E V，ZHANG Y，TESTERINK C.Salt tolerance mechanisms of plants［J］.Annual Review of Plant Biology，2020，71(1)：507-513.�ぃ�3］ 郭家鑫，鲁晓宇，陶一凡，等.盐碱胁迫对棉花生长和养分吸收的影响［J］.干旱地区农业研究,2022，40(4)：23-32,59.�ぃ�4］ SHI�� D，SHENG Y.Effect of various salt-alkaline mixed stress conditions on sunflower seedlings and analysis of their stress factors［J］.Environmental and Experimental Botany，2004，54(1)：54-75.�ぃ�5］ 李学孚，倪智敏，吴月燕，等.盐胁迫对‘鄞红’葡萄光合特性及叶片细胞结构的影响［J］.生态学报,2015，35(13)：4436-4444.�ぃ�6］ YANG J Y，ZHENG W，TIAN Y，et al.Effects of various mixed salt-alkaline stresses on growth，photosynthesis，and photosynthetic pigment concentrations of medicago ruthenica seedlings［J］.Photosynthetica，2011，49(2)：275-284.�ぃ�7］ KALAJI H M，JAJOO A，OUKARROUM A，et al.Chlorophyll a fluorescence as a tool to monitor physiological status of plants under abiotic stress conditions［J］.Acta Physiologiae Plantarum，2016，38(4)：38-42.�ぃ�8］ 刘卫国，丁俊祥，邹杰，等.NaCl对齿肋赤藓叶肉细胞超微结构的影响［J］.生态学报,2016，36(12)：3556-3563.�ぃ�9］ GRIEVE C M，LESCH S M，MAAS E V，et al.Leaf and spikelet primordia initiation in salt-stressed wheat［J］.Crop Science，1993，33(6)：1286-1294.�ぃ�10］�A张继峯，王振华，张金珠，等.盐碱胁迫对滴灌加工番茄生理生长和干物质积累的影响［J］.水土保持学报,2019，33(1)：270-276. �ぃ�11］�A严衍禄，刘心生.叶绿素测定方法的研究［J］.北京农业大学学报,1982(2)：53-67.�ぃ�12］�A温泽林.外源GSH介导NO调控番茄幼苗盐适应性研究［D］.石河子:石河子大学，2018.�ぃ�13］�A杨建军，张国斌，郁继华,等.盐胁迫下内源NO对黄瓜幼苗活性氧代谢和光合特性的影响［J］.中国农业科学，2017，50(19)：3778-3788.�ぃ�14］�ASCHANSKER G，SRIVASTAVA A，GOVINDJE E，et al.Characterization of the 820-nm transmission signal paralleling the chlorophyll a fluorescence rise (OJIP) in pea leaves［J］.Functional Plant Biology，2003，30(7)：785-796.�ぃ�15］�A朱延凯，王振华，李文昊.不同盐胁迫对滴灌棉花生理生长及产量的影响［J］.水土保持学报，2018，32(2)：298-305.�ぃ�16］�ASHARKEY T D，IMAI K，FARQUHAR G D，et al.A direct confirmation of the standard method of estimating intercellular partial pressure of CO��2［J］.Plant Physiology，1982，69(3)：657-659.�ぃ�17］�A张春梅，邹志荣，黄志，等.外源亚精胺对干旱胁迫下不同品种番茄幼苗光合作用的影响［J］.干旱地区农业研究,2010，28(3)：182-187.�ぃ�18］�A王素平，郭世荣，胡晓辉，等.盐胁迫对黄瓜幼苗叶片光合色素含量的影响［J］.江西农业大学学报,2006(1)：32-38.�ぃ�19］�A周静.藜麦对NaHCO��3胁迫适应性机制研究［D］.长春:东北师范大学，2017.�ぃ�20］�ABAKER N R，ROSENQVIST E.Applications of chlorophyll fluorescence can improve crop production strategies：An examination of future possibilities［J］.Journal of Experimental Botany，2004，55(403)：1607-1621.�ぃ�21］�A吴鹏，吕剑，郁继华，等.褪黑素对盐碱复合胁迫下黄瓜幼苗光合特性和渗透调节物质含量的影响［J］.应用生态学报，2022，33(7)：1901-1910.�ぃ�22］�A邵瑞鑫，李蕾蕾，郑会芳，等.外源一氧化氮对干旱胁迫下玉米幼苗光合作用的影响［J］.中国农业科学,2016，49(2)：251-159. �ぃ�23］�AWANG L Z，WANG L M，XIANG H T，et al.Relationship of photosynthetic efficiency and seed-setting rate in two contrasting rice cultivars under chilling stress［J］.Photosynthetica，2016，54(4)：581-588.�ぃ�25］�ALAZAR D.The polyphasic chlorophyll a fluorescence rise measured under high intensity of exciting light［J］.Functional Plant Biology，2006，33(1)：9-30.�ぃ�26］�A陆思宇，杨再强，张源达,等.高温条件下光周期对鲜切菊花叶片光合系统荧光特性的影响［J］.中国农业气象,2020，41(10)：632-643.�ぃ�27］�A李鹏民.快速叶绿素荧光诱导动力学在植物逆境生理研究中的应用［D］.泰安:山东农业大学，2007.

Memo

Memo:

-

Common functions

Last Update: 2023-10-24