两个不同基因型小麦光抑制特性的比较

比较了两个不同基因型小麦（Ｔｒｉｔｉｃｕｍ ａｅｓｔｉｖｕｍ Ｌ．）“京４１１”和“小偃５４”的原初光能转化效率、荧光猝灭参数和光合色素对强光胁迫的响应。在正常生长条件下“京４１１”的光合色素含量高于“小偃５４”;但在高光强下“京４１１”出现明显的光抑制,而“小偃５４”对高光强的适应上优于“京４１１”。“小偃５４”适应高光强的原因是它在高光强下能大幅度地提高叶黄素循环的调控因子抗坏血酸的浓度及紫黄     

两种基因型小麦光合作用对NaHSO3响应的差别

两种不同基因型小麦京411(J411,北京地区高产小麦品种)和小偃54(X54,一种远源杂交品种)的光合作用对低浓度NaHS03处理的响应不同。NaHS031mmol／L处理能够提高京411在CO2浓度为350和900μL／L的空气中的净光合速率;而对小偃54,在这两种情况下的净光合速率均无明显影响。以往的研究表明NaHS03促进光合作用的原因类似于PMS(Phenazine methosulfate),都是增加了ATP的合成。此文再次证明并发现经过NaHS031mmol／L处理后,京411叶片作用光关闭后叶绿素荧光瞬时上升的幅度提高,远红光后P700^ (reaction center cholorophyll of PSI)再还原的半时间缩短,表明NaHS03可以促进小麦京411中围绕PSI循环电子传递及其耦联的磷酸化。然而,NaHS03对小偃54的作用光关闭后叶绿素荧光瞬时上升的幅度及远红光后P700^ 再还原的半时间均无明显影响。与小麦京411相比较,小偃54的作用光停止后叶绿素荧光瞬时上升的幅度增大,而且其在远红光后P700^ 再还原的半时间更短,表明小偃54的循环电子传递的能力远高于京411的。两种不同基因型小麦对NaHS03的响应不同很可能是由于二者在循环电子传递能力上有很大的差别。     

强光诱导小麦叶片花青素积累的研究

以'小偃54'、'京411'等67份小麦品种(系)为试材,对强光诱导小麦叶片花青素积累的现象及品种间变异进行分析,以探讨花青素在小麦响应强光过程中的生理与分子机制.结果显示,'小偃54'和'京411'分别经25℃强光处理24 h和48 h叶片花青素含量大幅增加,而15℃和30℃强光处理增幅较小;强光处理48 h后,'京411'的花青素含量高达7.2 μg·g-1FW,约为'小偃54'的10倍.对'京411'而言,花青素含量随叶位自下而上递减,并且按叶鞘、叶基部、叶中部和叶尖的部位依次递减.强光处理24 h和48 h后能诱导'小偃54'和'京411'的PAL活性增强.强光处理48 h后,紫色胚芽鞘类品种的花青素含量高于绿色胚芽鞘类品种,不同品种强光下的花青素吸收峰均在520 nm处.研究表明,强光下叶片花青素含量升高可能是紫色胚芽鞘类小麦品种抗强光的一种机制.     

不同品种小麦PSⅠ颗粒光抑制过程的光谱学比较研究

用不同品种小麦（Ttiticum aestivum L.）“京411”和“小偃54”中分离纯化的PSⅠ光破坏过程的光谱特性,并比较了两的异。结果表明,强光导致PSⅠ中色素的破坏,特别是683nm状态的Chl a分子对强光敏感。光照过程中,荧光光谱的变化表明,光破坏还导致了PSⅠ中能量传递过程的破坏。“小偃54”PSⅠ颗粒在光照初期,长波长状态的Chl a分子的吸收度值略有下降后,可保持较长时间的稳定水平,在40min后才开始明显下降,同时,在强光照射的初期荧光发射增强;而“京411”PSⅠ颗粒在光抑制过程中没有这些变化。推测“小偃54”PSⅠ可能通过将能量较多地分配给长波长状态的叶绿素分子和保持相对较少的天线色素分子,以避免过多的能量向P700反应中心传递,而起到保护作用。因而具有较强的抗光氧化能力。     

光和水分胁迫对臭柏实生幼苗光化学效率及色素组成的影响

为探明毛乌素沙地3年生臭柏(Sabina vulgaris)实生苗在不同光照和水分条件下的光抑制响应机制,研究了各处理臭柏实生苗的最大光化学效率(F_v/F_m)及叶绿素(Chla+Chlb)和叶黄素(A+V+Z)含量,分析了其叶绿素循环和叶黄素循环的变化规律。结果表明,77%透光区通过减少Chlb含量,升高Chla/Chlb,避免光能过剩;同时,增加A+V+Z及热散逸色素(A+Z)含量、提高(A+V+Z)/(Chla+Chlb)和(A+V)/(A+V+Z)值,耗散过剩光能,避免光破坏。25%透光区的叶绿素和叶黄素循环机制随着水分条件的变化迅速发生改变。10%透光区通过增加Chlb含量,降低Chla/Chlb,捕捉更多的光能,几乎不存在光抑制。毛乌素臭柏实生幼苗能够适应不同的光照和水分条件,在恶劣的沙漠中完成天然更新,形成独特的群落景观,与叶绿素循环和叶黄素循环有着密切的关系。     

低磷条件下不同基因型小麦幼苗对磷的吸收和利用效率及水分的影响

 选用在土壤磷水平为5～7mgP·kg-1土的条件下筛选出来的不同磷效率的4个冬小麦品种,采用盆栽试验研究了有效磷为3．2mgP·kg-1土时的磷效率、磷吸收效率、磷利用效率及土壤水分对这些指标的影响。结果表明：在有效磷很低的土壤上,“磷高效”品种小偃54和81(85)5—3—3—3在幼苗期并未表现出较高的磷效率。尽管这两个品种的磷吸收效率显著地高于NC37和京411,但由于它们的磷利用效率相对低于京411,从而使磷效率并未显著地提高。土壤水分对4个品种的磷吸收效率和利用效率均有显著影响。     

高产小麦品种茎秆的解剖和化学特性

小麦(Triticum aestivum L.)新品种"小偃81",是由抗病虫害小麦品种"小偃54"和高产小麦品种"8602"杂交筛选出的具有优良特性的后代.作者运用多种实验手段,研究了新品种茎秆组织结构以及木质素含量和分布的变化规律.结果表明:与母本"小偃54"和父本"8602"相比,"小偃81"的茎秆直径变小、横切面上维管束数目减少,而茎秆直径与壁厚比、横切面上机械组织比例却显著增大,单位面积上维管束数目增多.Klason法测定木质素结果显示:"小偃81"茎秆中木质素含量高于"小偃54"和"8602".经Maule和Wiesner的木质素显色反应,"小偃81"茎秆横切面染色明显加深.用H2O2/Hac弃除酚酸以后,新品种小麦的木质素自发荧光明显强于亲本.FTIR分析结果表明:"小偃8l"中所含的紫丁香基、愈创木酚基等木质素特征基团的吸收峰值也显著高于亲本.由此推断,新品种"小偃8l"的茎秆具有优良的组织结构和化学组成.     

植株叶片的光合色素构成对遮阴的响应

叶绿素在植株体内负责光能的吸收、传递和转化, 类胡萝卜素则行使光能捕获和光破坏防御两大功能, 它们在光合作用中起着非常重要的作用。该文综述了几大主要光合色素的分布和功能, 以及不同物种的色素含量和构成差异。阳生植物的叶黄素库较大, 但脱环氧化水平不及阴生植物。黄体素与叶黄素库的比值与植物的耐阴性呈正相关关系。由不同的遮阴源造成的遮阴环境, 光强和光质有很大的差异, 总体来说对植物生长的影响, 建筑物遮阴<阔叶林遮阴<针叶林遮阴。光强的改变可诱导类胡萝卜素的两大循环——叶黄素循环和黄体素循环。由光强诱导的叶绿素含量和叶绿素a/b比值的改变与该物种的耐阴性无关。短时间的遮阴不会对植物的生长造成危害, 叶黄素库的大小不仅与每天接受的光量子有关, 更与光量子在一天的分布有关, 因为光照和温度是协同作用的。光合作用或色素构成是蓝光、红光和远红光共同作用的结果, 不是某一种单色光所能替代的。我们总结了影响植物色素构成的内因和外因, 指出植物主要通过调整光反应中心和捕光天线色素蛋白复合体的比例, 以及两个光系统的比值来调整色素含量和构成以适应不同的光照条件, 提出了现存研究中存在的一些问题, 旨在为今后的相关研究提供建议。     

叶黄素循环及其在光保护中的分子机理研究

植物的生命活动离不开充足的光照,但是当光照过强时,叶片吸收的光能超过了光合电子传递所需,过剩的光能便会对光合器官产生潜在的危害,引起光合作用的光抑制或光破坏.依赖于叶黄素循环的热耗散被认为是光保护的主要途径.本文着重介绍近年来有关植物叶黄素循环在酶学方面的分子调控、它的主要功能以及依赖于叶黄素循环的热耗散在光保护中的分子机理等,并对需进一步研究的问题作了探讨.     

温州蜜柑叶片光系统反应中心光能分配的变化

为深入了解果树光化学反应中心光能分配的状况,以柑橘为试材,采用调制荧光法对叶片光系统在高光强和低光强下的状态转换进行了研究.结果表明, 光系统在100 μmol·m^-2·s^-1的低光强下,由于QA的还原使PQ库处于还原状态,导致光能由PSⅡ转向PSⅠ分配,光系统处于状态2;在1 000 μmol·m^-2·s^-1 的高光强下, PQ库无法得到电子而处于氧化状态,导致光能分配由PSⅠ转向PSⅡ,光系统处于状态1.叶片经磷酸酯酶抑制剂NaF处理后,光系统从高光强下状态2到状态1的转换受到抑制.高光强下过多的光能由PSⅠ向PSⅡ分配是导致PSⅡ光破坏的重要原因.     

Photoinhibition and Photooxidation in Leaves of indica and  japonica Rice Under Different Temperatures and Light Intensities

Physiological indices related to the efficiency （ Fv/Fm ） of light energy conversion in PSⅡ and the peroxidation of membrane lipid were measured in leaves of Oryza sativa L. sp. indica rice cv. “Shanyou 63” and sp. japonica rice cv. “9516” under different temperatures and light intensities for 4 days. No changes in Fv/Fm and membrane lipid peroxidation product (MDA) were observed, so neither photoinhibition nor photooxidation happened in both rice cultivars under moderate temperature and medium light intensity. However, Fv/Fm dropped obviously with no change in MDA contents, and photoinhibition appeared in indica rice cv. “Shanyou 63” under medium temperature and strong light intensity. Furthermore, both photoinhibition and photooxidation were observed in two rice cultivars under chilling temperature and strong light intensity. Experiments with inhibitors under chilling temperature and strong light intensity showed that indica rice had a decrease in D1 protein content and SOD activity, and the extent of inhibition of xanthophyll cycle and nonphotochemical quenching ( qN ) was larger, and a higher level of MDA was observed. The photoinhibition and photooxidation in indica rice were more distinct as compared with japonica rice. The authors suggested that PSⅡ light energy conversion efficiency ( Fv/Fm ) and membrane lipid peroxidation were the key indices for the detection of photooxidation.     

Comparative Spectroscopic Studies on the Photoinhibition Process in Photosystem ￠?Complex from Two Wheat Cultivars

The photodamage processes of PSⅠ particles isolated from two wheat cultivars “Jing 411” and “Xiaoyan 54” were studied by comparing the difference in spectroscopic properties. It was found that high light intensity caused the damage of pigments in PSⅠ, especially Chl a molecules with maximum absorption at 683 nm is very sensitive to high light. The change in fluorescence spectra revealed that photodamage also led to the damage of the process of energy transfer in PSⅠ. In the PSⅠ particles “Xiaoyan 54”, the absorption of Chl a molecules at 683 nm slightly decreased at the beginning of illumination and meanwhile the fluorescence become stronger, but the absorption become stable rather long, and declining after 40 min. On the other hand, PSⅠ particles of “Jing 411” showed no such changes during the process of photodamage. Presumably in PSⅠ of “Xiaoyan 54”, excessive energy was distributed to long wave chlorophyll molecules and the number of antenna pigment molecules was less, so that less energy was transferred to the reaction center P700 and thus it was protected. This is the possible reason why “Xiaoyan 54” was more resistant to photooxidation.     

Effect of Heat Stress on Photosynthetic Characteristics of Different Green Organs of Winter Wheat During Grain-filling Stage

Four winter wheat ( Triticum aestivum L.) varieties (“JD 8”, “Jing 411”,“Centurk” and “Tam 202”) were used to study the effect of heat stress on photosynthetic characteristics of flag leaf blade, flag leaf sheath, peduncle, glume, lemma and awn during grain-filling stage. The results showed that heat acclimation during grain-filling stage increased thermotolerance of wheat with significant differences among different green organs. During heat stress, the decreases of the efficiency of primary light energy conversion ( Fv/Fm ) of PS and pigment (chlorophyll and carotenoid) content were much slower in peduncle, flag leaf sheath and glume than in flag leaf blade, lemma and awn; and the percentage of decrease in net photosynthetic rate ( Pn ) of ear was lower than that of the flag leaf blade. The measured photosynthetic parameters ( Fv/Fm , Pn and pigment content) of “JD 8”, a relatively heat tolerant variety, declined more slowly than those of the other three varieties during the whole heat stress period.      

Comparative proteomic analysis of salt response proteins in seedling roots of two wheat varieties

A comparative proteomic analysis was made of salt response in seedling roots of wheat cultivars Jing-411 (salt tolerant) and Chinese Spring (salt sensitive) subjected to a range of salt stress concentrations (0.5%, 1.5% and 2.5%) for 2 days. One hundred and ninety eight differentially expressed protein spots (DEPs) were located with at least two-fold differences in abundance on 2-DE maps, of which 144 were identified by MALDI-TOF-TOF MS. These proteins were involved primarily in carbon metabolism (31.9%), detoxification and defense (12.5%), chaperones (5.6%) and signal transduction (4.9%). Comparative analysis showed that 41 DEPs were salt responsive with significant expression changes in both varieties under salt stress, and 99 (52 in Jing-411 and 47 in Chinese Spring) were variety specific. Only 15 and 9 DEPs in Jing-411 and Chinese Spring, respectively, were up-regulated in abundance under all three salt concentrations. All dynamics of the DEPs were analyzed across all treatments. Some salt responsive DEPs, such as guanine nucleotide-binding protein subunit beta-like protein, RuBisCO large subunit-binding protein subunit alpha and pathogenesis related protein 10, were up-regulated significantly in Jing-411 under all salt concentrations, whereas they were down-regulated in salinity-stressed Chinese Spring.     

Relationship between flavonoids and photoprotection in shade-developed Erigeron breviscapus transferred to sunlight

Flavonoids are thought to participate in protection of the photosynthetic apparatus against photoinhibition under excessive light. Flavone glycoside, scutellarin, is a main active ingredient extracted from Erigeron breviscapus, the plant used in Chinese medicine. Shade-developed leaves of E. breviscapus were transferred from shade to full sunlight to quantify a relationship between the concentration of leaf scutellarin and tolerance to high radiation stress or the recovery from photoinhibition. The maximal quantum yield of PSII photochemistry showed a diurnal fluctuation in both shaded and sunlit leaves throughout the day. It indicated dynamic photoinhibition in the leaves of Erigeron, i.e., higher photoinhibition at solar noon and lower one in the morning and late afternoon. The sun-developed leaves reached the higher scutellarin content and values of nonphotochemical quenching coefficient with a lower degree of photoinhibition than the shade-developed leaves. When the shade-developed leaves were transferred to full sunlight, the content of scutellarin was declining continuously for 10 d and then was increasing for 15 d. After 50 d, all leaves became the sun-developed leaves with their scutellarin contents of about 138.5 ± 5.2 mg g^?1(dry mass, DM) which was significantly higher than that of the shade-developed leaves [107.8 ± 9.8 mg g^?1(DM)]. During acclimatization, the degree of photoinhibition was negatively correlated with the scutellarin content. Our results demonstrated a synchronous fluctuation between the flavonoid content and degree of protection against photoinhibition.     

Relationship between xanthophyll cycle and non-photochemical quenching in rice (Oryza sativa L.) plants in response to light stress

Thirty days old rice plants grown under low and moderate light conditions were transferred to full sunlight to observe the extent of photoinhibitory damage and protective mechanism, and the relationship between xanthophyll cycle and nonphotochemical quenching (qN) under changing light environment. Control plants (low, moderate and sun grown) exhibited similar Fv/Fm ratio, indicating similar photosynthetic efficiency prior to light stress. On exposure to the high light treatment, low light grown plants exhibited faster and higher degree of photoinhibition compared to moderate and high light grown plants. Moderate and high light grown plants showed relatively less photoinhibition and also showed higher qN, indicating better capacity of energy dissipation. Increase in qN in moderate light and sun grown plants was accompanied by conversion of violaxanthin (V) to antheraxanthin (A) and zeaxanthin (Z) indicating operation of Z-dependent thermal dissipation. Rice plants fed with ascorbate (AsA), a stimulator of the de-epoxidation state of V to Z, showed higher Fv/Fm ratio and qN than the plants fed with dithiothreitol (DTT) an inhibitor of xanthophyll cycle. This indicated that an increased amount of energy reached PS II reaction centre, due to absence of A and Z formation, thereby causing greater damage to photosynthesis in DTT fed rice plants. The present data confirmed the relationship between qN and Z in dissipating the excess light energy, thereby protecting plants against photodamage.     

PHOTOINHIBITION AND RECOVERY AFTER HIGH LIGHT STRESS IN DIFFERENT DEVELOPMENTAL AND LIFE-HISTORY STAGES OF LAMINARIA SACCHARINA (PHAEOPHYTA)1,2

The capacity to cope with high light stress was investigated in different life-history and developmental stages of Laminaria saccharina Lamour. sporophytes and gametophytes. Changes in photosynthetic efficiency and in the level of photoinhibition were measured by in vivo fluorescence changes of photosystem II. Pigment content was studied using high performance liquid chromatography. Additionally, the morphology of the various developmental stages during the life cycle was studied by light microscopy in relation to the photosynthetic parameters. High light stress (2 h, 500 μmol.m-².s^?1) induced photoinhibition of photosynthesis with fast kinetics in older sporophytes and gametophytes. In contrast, the absolute degree of photoinhibition after light stress was higher in younger than in older sporophytes. Photosynthesis recovered faster in older sporophytes and gametophytes compared to young sporophytes. In very young sporophytes, photosynthesis did not recover fully even after 12 h exposure to low light, indicating severe photodamage. Kinetics of recovery in old sporophytes and in gametophytes showed a fast and a slow phase, whereas younger sporophytes recovered only with a slow phase, The fast phase is indicative of a decline of the photoprotective process, whereas the slow phase indicates a recovery from photodamage. The capacity to cope with high light stress in Laminaria sporophytes increased with increasing age of the thalli. The gametophytes are less sensitive to high light stress and may be selected to endure unfavorable white light conditions. Investigation of the xanthophylls showed that the higher resistance to high light is not caused solely by a higher content of xanthophyll cycle pigments. Additionally, changes in the thallus structure during the development of the sporophytes seemed to cause a higher resistance to high light. The observed changes in the ability to cope with high light in the different life-history and developmental stages of Laminaria saccharina may influence the distribution of the species on the shore.     

Study of Diurnal Changes in Photosynthetic Rate and Quantum Efficiency of Grapevine Leaves and Their Utilization in Canopy Management

Photosynthetic rate and quatum efficiency of grapevine (Vitis vinifera L. cv. Sauvignon blanc) leaves were measured under the field with ample soil water supply, and in phytotron with ample supply of water and mineral nutrients, constant air humidity and CO2 concentration, and optimum air temperature, respectively. Under field conditions CO2 assimilation quantum efficiency of leaves reached its maximum in the morning, which was followed by continuous decrease and midday depression. The leaves intercepting more light energy in the morning showed a higher quantum efficiency. Those leaves subjected continuously to strong irradiance exhibited a more obvious and longer midday depression. Reduction of leaf light interception around midday could reduce midday depression. Shaded leaves had a higher quantum efficiency than leaves under direct sunlight. The diurnal changes in photosynthetic rate and quantum efficiency of leaves were shown to be closely related to the variations in mesophyll resistance to CO2. In phytotron experiments the photosynthetic quantum efficiency of leaves was reduced after a certain period of illumination not only at 1200 μmol · m-2 · s-1 PFD, higher than the saturating light of vine leaves (≈1000 μmol · m-2 · s-1), which was caused by "photoinhibition”, but also at 800 and 200μmol · m-2 · s-1, which was similar to "photoinhibition”. But photosynthetic quantum efficiency of leaves exposed continuously to a very weak PFD (100 μmol · m -2 · s-1) remained contant. The diurnal changes in mesophyll resistance to CO2 of vine leaves could be partly related to photoinhibition. It is considered that, under field conditions without soil water limitation, midday depression of vine leaf photosynthesis could be a result of an increase of the mesophyll resistance induced by multiple effects of strong light, high temperature and low humidity. A higher light interception by canopy plane in the morning may be advantageous to exploit higher photosynthetic potentiality of leaves, but a lower light interception in the middle of day may reduce midday depression. The north-south orientation plane can provide optimum light regime and improve photosynthetic environment in vineyards.     

水稻耐光氧化和耐荫特性的生理基础

用简易、有效的人工光氧化和遮荫技术对30个水稻(Oryza sativa L.)种质进行筛选,鉴定出既耐光氧化又耐荫、耐光氧化不耐荫、耐荫不耐光氧化、既不耐荫又不耐光氧化等4种品种类型,并用既耐光氧化又耐荫的品种"武育粳3号"和对光氧化和遮荫均敏感的品种"香籼"进行光合特性研究.结果表明:在遮荫条件下,与对光氧化和遮荫敏感的品种"香籼"比较,"武育粳3号"的PSⅡ活性差异不大,RuBisCO活性降低较少,光合能力、光合生产力较高.在光抑制条件下,"武育粳3号"的PSⅡ活性,PSⅡ光化学效率(Fv/Fm),PSⅡ-D1蛋白含量降低较少,光合作用光抑制较轻.在光氧化条件下,内源活性氧清除剂SOD诱导活性高,清除O-能力强,因而叶绿素衰减较慢.上述研究为水稻育种提供了配套的优良生理特性的鉴定技术和生理依据.