不同品质类型小麦非叶光合器官光合荧光特性研究

以强筋(郑麦9023)、中筋(新麦13)和弱筋(豫麦50)型小麦品种为试材,测定了它们非叶光合器官的叶绿素含量、荧光动力学参数、净光合速率及对籽粒的贡献率.结果显示,不同品质类型小麦非叶光合器官叶绿素含量表现为旗叶鞘>穗下节间>芒>穗部颖片,各非叶光合器官开花18d后叶绿素含量均表现为弱筋小麦>中筋小麦>强筋小麦;弱筋小麦的非叶光合器官在灌浆前期具有较高的Fv/Fm、ΦPSⅡ值,在灌浆后期其Fv/Fm和ΦPSⅡ值下降幅度显著小于强筋小麦并有较高的净光合速率;非叶光合器官对籽粒的相对贡献率依次为穗部>旗叶>节鞘,且对弱筋小麦籽粒的贡献率高于中筋和强筋小麦,其中节鞘和穗对弱筋小麦粒重的相对贡献率分别为15.7%和35.4%.研究表明,弱筋小麦豫麦50的非叶光合器官能维持较较强的光合能力,生产更多的光合产物,花后形成的光合产物对其粒重的增加起重要作用.     

指甲油涂抹撕取法制取植物叶气孔装片

叶既是植物光合、蒸腾作用的场所,又是呼吸的器官,叶的表皮具较多的气孔,是与外界进行气体交换的门户,也是水气蒸腾的通道.不同植物的气孔数目、形态结构和分布有差异,现介绍一种简便制取植物叶气孔装片的方法--指甲油涂抹撕取法.     

高山植物光合机构耐受胁迫的适应机制

植物的光合作用是易受环境影响的重要生理过程之一.高山植物作为生长在特定极端环境(低温/强辐射)下的植物群体,其光合器官在形态结构和生理功能上形成了抵御强辐射和低温胁迫的特殊适应机制.但由于较高的生境异质性,高山植物的光保护适应机制存在较大的差异.光保护适应机制与光合作用密切关联,影响植物的碳同化能力和生物量的形成能力.本文对近年来国内外有关高山植物光合器官叶绿体的形态、超微解剖结构及光合机构光保护适应机理的研究进展进行了综述,并提出了今后高山植物光合作用生理适应性研究的方向.     

薇甘菊(Mikania micrantha)非同化器官光合特征及其生态学意义

薇甘菊因为其在新生境的强入侵能力而臭名昭著,有关其入侵的光合生理原因主要集中在叶片光合速率研究,而对非同化器官光合特性少见报道.以叶片为对照,对非同化器官花、果、茎、根的光合电子传递速率、PSII光化效率以及不同器官光合碳固定对群落碳平衡的影响进行了研究,发现尽管非同化器官光合电子传导速率均低于叶片,但是其色素利用效率(叶绿素和类胡萝卜素)显著高于叶片.在生殖生长季节,叶片光合能力明显下降的时期内,非同化器官的光合碳固定对薇甘菊生长起到积极作用.把不同器官的光合碳固定量尺度放大到群体水平发现,基于使用红外线CO2分析法和叶绿素荧光方法计算结果表明,单位土地面积上分布的薇甘菊非同化器官(生殖器官、茎和根等)分别占群体总光合能力的19%和49%,说明非同化器官光合在薇甘菊生长和入侵中可能具有的重要作用.尽管薇甘菊叶片为典型C3植物特征,结果发现了茎以及主叶脉内存在类似C4途径的、具有丰富叶绿体的维管束鞘结构.C4途径的光合效率远比C3植物高可能是薇甘菊非同化器官光合叶绿素效率高于叶片的一个原因,尚需要更多的直接生化证据支持.     

植物叶片花青素的光破坏防御机制研究进展

植物花青素广泛分布在植物的根、茎、叶、花和果实等器官中,是植物形态建成过程中或响应逆境而产生的一种次生代谢物质.植物叶片中的花青素具有特殊的化学结构和光谱特性,在光破坏防御机制方面发挥了重要的作用,已经成为植物光合生理生态的研究热点.本文综述了近年来植物叶片花青素与光合作用的研究进展,从叶片花青素的分布、光谱特性及其与光合色素的关系等方面说明花青素对植物光合作用的影响,重点介绍了叶片花青素通过光吸收、抗氧化剂和渗透调节等在植物光破坏防御机制方面的作用,展望了今后的主要研究方向     

不同供水条件下冬小麦叶与非叶绿色 器官光合日变化特征

为揭示小麦叶片与非叶绿色器官的光合活性在一日中的变化特性及其在器官间的差异性,探讨群体及不同器官光合日变化对不同供水条件的响应特征,在田间设置生育期不灌水(I0)、灌2水(I2,拔节水＋开花水)和灌4水(I4,起身水+孕穗水+开花水+灌浆水)3个处理,于灌浆期测定了群体光合与呼吸速率的日变化, 旗叶片、叶鞘、穗、穗下节间各器官光合速率、蒸腾速率、气孔导度及叶绿素荧光参数的日变化。结果表明,灌浆期小麦穗和穗下节间光合速率日变化呈单峰曲线,而旗叶叶片与旗叶鞘光合速率均呈双峰型,表现出不同程度的午休。随着灌水次数减少,各器官光合速率降低,叶片对严重水分亏缺的反应大于各非叶器官。器官光合速率的日变化与F_v/F_m变化相一致,而与气孔导度日变化有较大差异。各器官上午的累积光合量均高于下午,上午光合量占日总光合量的比例为51％-62％,随着灌水次数减少而增大。不同灌水处理群体光合速率、呼吸速率日变化均未出现午休现象。春季浇2水处理与春浇4水处理相比,灌浆期群体光合速率及日光合积累量没有显著差异。综合研究认为,小麦叶与非叶器官光合性能及其日变化特征有较大不同,非叶光合对水分亏缺的敏感性低于叶片,生育期浇2水可以获得与浇4水相似的群体日光合积累量。     

两种盐生植物解剖结构的生态适应性

结合对研究区域土壤水分和盐分的分析,对3种不同生境下梭梭和多枝柽柳两种荒漠盐生植物光合器官解剖结构的研究表明:梭梭(Haloxylon ammodendron)依靠当年生绿色同化枝进行光合作用,且同化枝具有发达的贮水组织,是典型的超旱生稀盐盐生植物;同化枝的栅栏组织富含叶绿体,是C_4高光效植物,提高了植物的光合作用效率,进一步增强了梭梭对荒漠干旱、盐渍化环境的适应能力.多枝柽柳(Tamarix ramosissima)同化枝及叶的表皮上均具下陷的气孔和泌盐腺,是旱生泌盐盐生植物;叶为全栅型,且同化枝具有发达的维管柱,占同化枝直径的60%以上,此外,其同化枝及叶的表皮细胞外凸形成乳状突,是一种环境胁迫指示结构.这些特征均能说明梭梭和多枝柽柳具有很好的抗旱、耐盐碱能力,且作为荒漠环境的优势树种,它们对荒漠生态系统的恢复和重建有积极意义.     

叶片花色素苷对植物光合作用影响的研究进展

近年来,花色素苷在彩叶植物呈色机制的研究中备受关注,但目前有关其对彩叶植物光合特性影响的机制仍缺乏系统的评述。本文简单介绍了花色素苷的基本特性,并基于国内外相关研究进展,综述了叶片花色素苷对植物光合特性的影响机制及其对叶片光合机构的保护意义,对彩叶植物光合作用的研究方向提出了建磷。     

植物光合系统对高温胁迫的响应机制

温度变化是影响植物生长和发育的一个非常重要的因素,而光合作用是植物对温度变化最为敏感的生理过程.高温胁迫给植物光合器官造成了严重的危害,但在高温胁迫下,植物并不是消极被动的,并且能够在生理生化及分子水平上发生各种变化来渡过逆境.本文结合当今国内外研究进展,从光合系统热量耗散与光合修复的相关因素,如类囊体膜上相关蛋白,热激蛋白,水杨酸,抗过氧化物酶及抗坏血酸等几个方面展开分析,阐述了植物光合系统对高温胁迫的防御机制,并对今后的研究方向进行了探讨和展望.     

二氧化碳通过根部对植物营养的问题

近年来,苏联研究家们的工作证明:植物也能通过根部获得二氧化碳。及其同事藉放射性碳素之助指出,根自土壤中吸收的二氧化碳能以很大的速度转运到植物的绿色部分,并在叶中被同化为碳水化合物(光合作用);而且,自根部吸入的二氧化碳佔很大的数量。其他研究家们的材料同样也说明了这一事实。曾以各种植物进行试验,证明通过根以二氧化碳营养植物可以提高植物的收获量。用二氧化碳改善植物的营养能提高叶的光合作用强度。指出,增加叶的光合作用强度首先会影响到植物有经济價值器官     

CONTRASTING PHOTOSYNTHETIC BEHAVIOR IN LEAVES AND TWIGS OF HYMENOCLEA SALSOLA,A GREEN-TWIGGED WARM DESERT SHRUB

The photosynthetic behavior of leaves and twigs was compared in Hymenoclea salsola T. and G., a subshrub of the Mohave and Sonoran deserts, in which both leaves and green twigs make substantial contributions to whole-plant carbon gain. Light saturated photosynthesis in twigs was 0.62 times that of leaves (36.9 μmol m^-2 s^-1) when plants were well watered. Similar ratios were consistently observed in contrasting the photosynthetic responses of the two organ types to light, temperature, and intercellular CO₂, regardless of whether rates were compared under saturating or highly limiting conditions of light or intercellular CO₂. These scalar differences in photosynthetic rate between leaves and green twigs under a wide range of conditions were correlated with contrasting anatomical features such as chlorenchyma volume per projected area. Under normal ambient CO₂ concentrations (350 μl 1^-1), twigs on well watered plants operated at lower intercellular CO₂ concentrations than the leaves. Possible causes of this difference are discussed with respect to performance under well-watered conditions, organ lifespans, and contrasting anatomical constraints. Twigs require larger investments than do leaves of both carbon and nitrogen per projected area of the respective organs, yet they realize lower photosynthetic rates per intercepted light. Twigs, however, fulfill additional roles besides photosynthesis such as structural support and vascular transport which does not allow them to be as anatomically specialized as leaves for photosynthesis. Twigs also have a longer expected lifespan than leaves with a larger fraction of them surviving the summer drought period. This was correlated with a greater tolerance of twig than leaf photosynthesis to low plant water potentials.     

Evolution of notions about relationships between photosynthesis and plant productivity

The concepts of photosynthesis role in the production process underwent evolution from the initial assumption of complete identity of these terms to the notion that photosynthesis is only a supplier of assimilates for sink organs. The following issues are discussed as individual stages of problem resolution: whether or not photosynthesis restricts productivity; what is the contribution of chlorophyll-containing non-leaf organs to the production process; what are the roles of photooxidation processes and source-sink relations between photosynthesizing organs and assimilate consumers; how the apoplast is involved in regulation of photosynthetic function of the whole plant; and what is the role of nitrate in control of photosynthesis and assimilate export from the leaf. Finally, the distribution of assimilates among the sink organs and the role of competition among the organs in regulation of photosynthesis and yield formation are considered.     

4种作物部分非叶器官气孔频度及其在光合作用中的意义（英文

 通过对小麦（Triticum aestivum L.）、大豆 (Glycine max (L.) Merrill)、 油菜（Brassica napus L.）和玉米（Zea mays L.）等4种作物部分非叶器官(油菜和大豆的豆荚;小麦的外稃和玉米的苞叶)的气孔频度、气孔大小和气孔指数进行了比较研究。结果发现,上述作物非叶器官的气孔频度均较对应叶低;而气孔大小和气孔指数则变化较大。其中油菜和大豆非叶器官气孔的直径通常比对应叶大,小麦和玉米非叶器官的气孔直径则较小;大豆和油菜的非叶器官气孔指数比对应叶小,     

Important photosynthetic contribution of silique wall to seed yield-related traits in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

In plants, green non-foliar organs are able to perform photosynthesis just as leaves do, and the seed-enclosing pod acts as an essential photosynthetic organ in legume and Brassica species. To date, the contribution of pod photosynthesis to seed yield and related components still remains largely unexplored, and in Arabidopsis thaliana, the photosynthetic activity of the silique (pod) is unknown. In this study, an Arabidopsis glk1/glk2 mutant defective in both leaf and silique photosynthesis was used to create tissue-specific functional complementation lines. These lines were used to analyze the contribution of silique wall photosynthesis to seed yield and related traits, and to permit the comparison of this contribution with that of leaf photosynthesis. Our results showed that, together with leaves, the photosynthetic assimilation of the silique wall greatly contributed to total seed yield per plant. As for individual components of yield traits, leaf photosynthesis alone contributed to the seed number per silique and silique length, while silique wall photosynthesis alone contributed to thousand-seed weight. In addition, enhancing the photosynthetic capacity of the silique wall by overexpressing the photosynthesis-related RCA gene in this tissue resulted in significantly increased seed weight and oil content in the wild-type (WT) background. These results reveal that silique wall photosynthesis plays an important role in seed-related traits, and that enhancing silique photosynthesis in WT plants can further improve seed yield-related traits and oil production. This finding may have significant implications for improving the seed yield and oil production of oilseed crops and other species with pod-like organs.     

Effect of Heat Stress During Grain Filling on Phosphoenolpyruvate Carboxylase and Ribulose-1,5-bisphosphate Carboxylase/Oxygenase Activities of Various Green Organs in Winter Wheat

In two winter wheat (Triticum aestivum L.) cultivars differing in their response to high temperature, JD8 (tolerant) and J411 (sensitive) we studied the effect of heat stress on the activities of phosphoenolpyruvate carboxylase (PEPC) and ribulose-1,5-bisphosphate carboxylase (RuBPC) in green organs during grain-filling. There were significantly higher PEPC activities and lower RuBPC activities in each of the non-leaf organs (awn, glume, lemma, peduncle, and sheath) than in the flag leaf blade. Under heat stress for 12 d, the activity of RuBPC quickly declined and the activity of PEPC first increased and later declined in all organs, resulting in a great increase of the PEPC/RuBPC ratios in the organs, particularly in non-leaf organs which had a higher PEPC/RuBPC than the flag leaf blade in all times. The PEPC activity and PEPC/RuBPC ratio in every organ of JD8 were higher than those in the same organ of J411. Thus the differences in PEPC activities and PEPC/RuBPC may be associated with the differences in photosynthetic heat tolerance among the organs of the same plant or between the two cultivars.     

光质对植物光合作用的调控及其机理

光合作用是植物生长发育的基础.光质对植物光合作用的调控主要包括可见光对植物气孔器运动、叶片生长、叶绿体结构、光合色素、D1蛋白及其编码基因和光合碳同化等的调节,以及紫外光对植物光系统Ⅱ的影响.蓝光和红光能促进气孔的开张,而绿光能够逆转这种作用.蓝光有利于叶绿体的发育,红、蓝、绿复合光有利于叶面积的扩展,而红光更有利于光合产物的积累;不同光质对不同植物、不同组织器官叶绿素积累的影响不同.蓝光和远红光可以促进psbA基因转录物质的积累.大多数高等植物和绿藻在橙、红光下光合速率最高,蓝紫光其次,绿光最低.紫外光可以导致光系统Ⅱ的电子传递活性下降.此外,针对光质与光合作用研究领域中存在的问题,对今后的研究方向进行了讨论.     

冬小麦节水栽培群体“穗叶比”及其与产量和水分利用的关系

建立高光效低耗水的群体结构是小麦节水高产栽培的核心内容。为此,需要明确节水高产群体的适宜调控指标。以穗叶比(单位面积穗数与上三叶总面积之比,穗/m2)为指标,在不同品种、不同灌水和种植密度条件下研究了小麦群体穗叶比的变化,并分析了穗叶比与群体光合性能、水分利用的关系。结果表明,在相同密度下,随着灌水减少,孕穗、开花和灌浆期的穗叶比均相应增大;在限水灌溉下,随密度增加穗叶比也相应增加。不同品种的穗叶比也存在明显差异。在适宜叶面积基础上,随穗叶比增加,群体中非叶面积指数(NAI)增加,冠层内光照状况明显改善,群体光合效率提高;非叶器官贮藏物质转移率增加,收获指数提高。在一定范围内,随穗叶比增加产量明显增加,而耗水量显著减少,从而使水分利用效率得到提高。研究认为,群体穗/叶比是衡量小麦节水栽培库源关系是否协调的适宜指标。试验中小麦节水省肥高产栽培适宜的穗叶比值为230—270穗/m2。     

不规则植物材料单位鲜重光合速率的测定

本文介绍了一种单位鲜重叶片光合速率的测定和换算方法,并分析了其优点和用途。该方法特别适合测定不规则叶片及非叶器官的光合速率。