开放时PSⅡ的最大光化学量子产量,即PSⅡ反应中心内的原初转化效率,是衡量PSⅡ的光抑制程度重要指标[5]。Fv/F0常用于表示植物叶片PSⅡ的潜在活性[6]。结果表明:干旱胁迫时,随着相对含水量的减少,Fv/Fm逐渐减少;在极度干旱的条件下,鸭茅的潜在光合效率增加。在盐胁迫下,随着盐浓度的增加,鸭茅的最大光合效率先上升后下降。潜在活性与最大光合效率有相同的趋势。
Y(Ⅱ)表示电子传递的量子效率,是PSⅡ反应中心在部分关闭的情况下的实际原初光能的捕获效率[7]。对干旱胁迫而言,随着含水量的减少实际原初光能的捕获效率降低,达到稳态后20%的实际捕获效率高于35%的效率。在未受盐胁迫时,鸭茅对原初光能的捕获速率最淡,但在被胁迫时,随着盐浓度的增加,原初光能的捕获效率先增加后降低。
ETR反映了实际光强条件下的表观电子传递效率;在胁迫下,植物叶片的ETR会下降[8]。试验分析表明,随着相对含水量的减少,ETR的幅度表现为CK(75%)>55%>35%>20%。随着盐浓度的增加,相对电子传递速率CK(75 mmol/L)>70 mmol/L>100 mmol/L>35 mmol/L。
光系统中叶绿素吸收的光能主要通过光合电子传递、叶绿素荧光发射和热耗散3种途径来消耗[9,10]。光合速率上升引起的qP反映了PSⅡ天线色素捕获的光能用于光化学电子传递的份额;而由热耗散引起的NPQ反映的则是PSⅡ天线色素吸收的光能不能用于光化学电子传递而以热的形式消耗掉的部分[11,12]。结果表明:随着土壤相对含水量的减少,鸭茅的热耗散加剧,光合作用减少;但在极度干旱胁迫时,热耗散能力降低,光合作用上升。盐胁迫时,低浓度促进热耗散幅度抑制光合作用,相反高浓度抑制剩余光能的转化和促进光合效率。
采用模糊数学隶属函数的方法,对鸭茅的盐胁迫和干旱胁迫进行了综合性评价:其总体评价结果鸭茅盐胁迫大于干旱胁迫。
随着相对含水量的减少,鸭茅的热耗散加剧,光合作用减少;Fv/Fm、Fv/F0逐渐减少,ETR逐渐降低;实际原初光能的捕获效率Y(Ⅱ)降低。但在极度干旱胁迫时,热耗散能力降低,光合作用上升,潜在光合效率增加,Y(Ⅱ)增加。
盐胁迫时,低浓度促进热耗散幅度抑制光合作用,相反高浓度抑制剩余光能的转化和促进光合效率;鸭茅的最大光合效率先上升后下降,潜在活性与最大光合效率有相同的趋势;ETR先上升后减少,原初光能的捕获效率先增加后降低。
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Responses of the chlorophyll fluorescence parameters
of cocksfoot (Dactylis glomerata) to water
and salt stress
LI Shuo1,NIE Zhongnan1,2,CHEN Wei3,JIANG Zhehao1,
CHEN Jiangang1,ZHANG Degang1
(1.College of Pratacultural Science,Gansu Agricultural University,Lanzhou 730070,China; 2.Department
of Environment and Primary Industries,Private Bag 105,Hamilton,VIC 3300,Australia;
3.Lanzhou City University,Lanzhou 730070,China)
Abstract:In order to understand the response of cocksfoot (Dactylis glomerata) to drought and salt stresses,a pot experiment was conducted in a randomized completely block design.There were 7 treatments including 4 water stress treatments (75%,55%,35% and 20% of gravimetric water content) and 3 salinity stress treatments (35 mmol/L NaCl,70 mmol/L NaCl and 100 mmol/L NaCl).The water content of 75% was used as control.After 20 days of the drought and salt stress treatment,the chlorophyll fluorescence parameters were measured using the chlorophyll fluometer.The results showed that Fv/Fm,Fv/F0,ETR,Y(Ⅱ) and NPQ gradually decreased,and qP increased with water content decreasing.However,under extreme water stress,heat dissipation was decreased,and photosynthesis and its efficacy were increased in cocksfoot,indicating that cocksfoot responded to water stress to avoid potential damage to the plants.With the increasing of salt stress level,Fv/Fm of cocksfoot initially increased and then declined.ETR,Fv/F0 and Y(Ⅱ) showed a similar trend as Fv/Fm.The heat dissipation increased at lower salinity levels but decreased at higher salinity levels.The photosynthesis responded in an opposite way to heat dissipation.The tolerance of cocksfoot to water stress was better than salt stress under the experimental conditions.
Key words:chlorophyll fluorescence parameters;drought stress;salt stress;Dactylis glomerata