超高产水稻剑叶衰老过程中PSⅡ激发压与Rubisco大、小亚基含量的相关性

研究了大田生长条件下两系超高产杂交水稻(Oryza sativa L.)“两优培九”和我国大面积推广的三系杂交水稻“汕优63”从灌浆期到收获期剑叶PSⅡ光化学特性和Rubisco大、小亚基含量的变化。结果表明：可溶性蛋白质和叶绿素含量随剑叶生长时间的延长先缓慢下降,后期有一个快速降解的过程,“汕优63”降解的速率高于“两优培九”;Fv/Fm和qP都呈下降的趋势,qN则是先降然后上升。激发压(1-qP)在前期的变化较为平稳,后期则急剧增加,“汕优63”较“两优培九”增加快。Rubisco大、小亚基的含量与叶绿素、可溶性蛋白含量一样在前期下降比较慢,后期也有一个快速降解的过程,“汕优63”比“两优培九”降解快。激发压的增加与Rubisco大、小亚基的降解呈显著的线性相关性。我们推测PSⅡ激发压的急剧增加可能诱发了水稻剑叶的快速衰老过程。“两优培九”高产的重要生理原因之一,可能是它比“汕优63”有更强的光合能力并能维持更持久和较高的光合功能期。     

小麦Rubisco活化酶基因的克隆和表达特性

Rubisco活化酶是广泛存在于光合生物中调节Rubisco活性的酶,我们利用PCR技术,从小麦(Triticum aestivum)叶片cDNA文库中克隆得到Rubisco活化酶基因cDNA片段,该片段长度为850 bp,编码201个氨基酸.Northern blot表明,小麦叶片在暗诱导衰老的条件下,叶片中活化酶基因表达水平逐渐下降;同时,小麦叶片的光合特性、叶绿素含量和Rubisco活性呈现下降趋势.这些结果表明,衰老时小麦叶片Rubisco活化酶基因表达水平下降与光合速率下降密切相关.     

小麦Rubisco 活化酶基因的克隆和表达特性

Rubisco活化酶是广泛存在于光合生物中调节Rubisco活性的酶, 我们利用PCR技术, 从小麦(Triticum aestivum)叶片cDNA文库中克隆得到Rubisco活化酶基因cDNA片段, 该片段长度为850 bp, 编码201个氨基酸。Northern blot表明, 小麦叶片在暗诱导衰老的条件下, 叶片中活化酶基因表达水平逐渐下降; 同时, 小麦叶片的光合特性、叶绿素含量和Rubisco活性呈现下降趋势。这些结果表明, 衰老时小麦叶片Rubisco活化酶基因表达水平下降与光合速率下降密切相关。     

水稻转绿型白化突变系W25转绿过程中Rubisco、Rubisco活化酶活性与光合速率的变化

水稻 (OryzasativaL .)转绿型白化突变系W2 5在转绿过程中叶绿素、可溶性蛋白质和Rubisco含量的动态变化过程表明 ,白化突变体内叶绿素、可溶性蛋白质和Rubisco含量极低 ,随着转绿过程各组分含量迅速提高 ,转绿至第 30天时超过野生种 2 177s;Rubisco初始活力与Rubisco活化酶含量呈极显著正相关。Rubisco活化酶基因表达的研究结果表明 ,突变体的Rubisco活化酶表达高于野生种 2 177s。在转绿过程中 ,Rubisco活化酶含量的提高要先于Rubisco和光合速率     

超高产水稻剑叶的高效光合特性

以多年来大面积推广的杂交水稻汕优63为对照。研究了超高产杂交水稻两优培九的光合生理特性。结果表明：在生殖生长期两优培九剑叶具有较高的叶绿素含量,Fv/Fo,Fv/Fm,qP,φi和Rubisco含量,表明它有相对较高的光能吸收,转化和利用的能力;且两优培九的qN较汕优63大,1-qP/qN比它小,说明它比对照品种更耐光抑制;两个品种在剑叶衰老过程中都发生了光碳失衡,但两优培九光碳失衡状态较轻;这些可能是超高产水稻两优培九高产的重要原因。     

超高产水稻剑叶衰老过程中PSⅡ激发压与 Rubisco大、小亚基含量的相关性

研究了大田生长条件下两系超高产杂交水稻(Oryza sati va L.)"两优培九"和我国大面积推广的三系杂交水稻"汕优63"从灌浆期到收获期剑叶PSⅡ光化学特性和Rubjsco大、小亚基含量的变化.结果表明:可溶性蛋白质和叶绿素含量随剑叶生长时间的延长先缓慢下降,后期有一个快速降解的过程,"汕优63"降解的速率高于"两优培九";Fv/Fm和qP都呈下降的趋势,qN则是先降然后上升.激发压(1 qP)在前期的变化较为平稳,后期则急剧增加,"汕优63"较"两优培九"增加快.Rubi Sco大、小亚基的含量与叶绿素、可溶性蛋白含量一样在前期下降比较慢,后期也有一个快速降解的过程,"汕优63"比"两优培九"降解快.激发压的增加与Rubisco大、小亚基的降解呈显著的线性相关性.我们推测PSⅡ激发压的急剧增加可能诱发了水稻剑叶的快速衰老过程."两优培九"高产的重要生理原因之,可能是它比"汕优63"有更强的光合能力并能维持更持久和较高的光合功能期.     

Rubisco活化酶的分子生物学

Rubisco活化酶是广泛存在于光合生物中、调节Rubisco活性的酶,Rubisco活化酶同时具有活化Rubisco和催化ATP水解的作用.它依赖ATP水解,促使RuBP或其它磷酸糖类从Rubisco上解离下来,以恢复Rubisco的活性.该文介绍Rubisco活化酶的分子特性、作用机制、光合作用调节及基因工程的最新研究进展.     

光和糖对水稻Rubisco活化酶基因表达的影响

水稻黄化苗在光照2h内其Rubisco。活化酶的mRNA和蛋白量明显增加,然后维持在相对稳定的水平。光对水稻Rubisco活化酶的基因表达的诱导作用主要在转录水平上。Rubisco活化酶主要在绿叶中表达,这与Rubisco基因表达的器官特异性完全一致。用等渗葡萄糖喂养成熟的水稻叶片1h,促使水稻Rubisco大、小亚基和Rubisco活化酶可翻译mRNA含量下降。同样蔗糖对Rubisco小亚基和Rubisco活化酶的表达也有抑制,其作用弱于葡萄糖。     

水稻Rubisco和RCA的日变化及其细胞定位

采用免疫胶体金标记电镜技术对水稻(Oryza satova subsp.indica cv.浙农952)叶片中的Rubisco及其活化酶(RCA)进行细胞器定位和定量,同时用免疫扩散法进行叶片含量分析,研究了这两种酶含量及活力的日变化。结果表明Rubisco主要分布于叶绿体,RCA分布于叶绿体和线粒体中;光合速率(Pn)、Rubisco初始活力和RCA活力与光合日变化密切相关;在光照最强的13时,出现光合“午休”,叶绿体中Rubisco的密度有一定程度降低,而全叶的总Rubisco保持稳定,Rubisco初始活力也有明显的“午休”,这意味着体内Rubisco的活力除受RCA调节外,可能还与叶绿体中Rubisco的分布有关。RCA活力变化与叶绿体中RCA含量变化较为一致,表明RCA在叶绿体中的分布对调节其本身活力和Rubisco活性有重要作用。     

植物Rubisco活化酶的研究进展

植物Rubisco活化酶广泛存在于光合生物中,是AAA＋家族成员,具有ATP酶活性,并具有对温度反应的活化Rubisco和分子伴侣的双重功能。该文重点介绍了近年来对Rubisco活化酶的分子特性、作用机制、温度等因子的影响及基因工程研究的最新进展。     

Relationship between leaf photosynthetic function at grain filling stage and yield in super high-yielding hybrid rice (<Emphasis Type="Italic">Oryza sativa</Emphasis>. L)

The characteristics of dry matter production before and after heading and the relationships between photosynthesis of flag leaves and dry matter accumulation in panicles were investigated on super high-yielding rice cv. Xieyou 9308 (the yield of up to 12 t/ha) with rice cv. Xieyou 63 as a control. The results showed that (i) the capacity of dry matter production before and after heading in Xieyou 9308, i.e. biomass and daily dry matter production, was remarkably higher than that in Xieyou 63, especially after heading; (ii) CO₂ assimilation capacity in flag leaves in Xieyou 9308, namely Leaf Source Capacity (LSC), was also significantly higher than that in Xieyou 63, and the supply of photosynthate in leaves and the demand of grain filling were completely synchronous in Xieyou 9308, but photosynthetic function in flag leaves in Xieyou 63 declined sharply 20 days after heading and it was not enough to meet the demand of grain filling. These results confirmed that high efficient photosynthetic function in leaves after heading and its complete synchronization with grain filling are the key approaches to super high yield of rice.     

Relationship between leaf photosynthetic function at grain filling stage and yield in super high-yielding hybrid rice (Oryza sativa. L)

The characteristics of dry matter production before and after heading and the relationships between photosynthesis of flag leaves and dry matter accumulation in panicles were investigated on super high-yielding rice cv. Xieyou 9308 (the yield of up to 12 t/ha) with rice cv. Xieyou 63 as a control. The results showed that (i) the capacity of dry matter production before and after heading in Xieyou 9308, i.e. biomass and daily dry matter production, was remarkably higher than that in Xieyou 63, especially after heading; (ii) CO2 assimilation capacity in flag leaves in Xieyou 9308, namely Leaf Source Capacity (LSC), was also significantly higher than that in Xieyou 63, and the supply of photosynthate in leaves and the demand of grain filling were completely synchronous in Xieyou 9308, but photosynthetic function in flag leaves in Xieyou 63 declined sharply 20 days after heading and it was not enough to meet the demand of grain filling. These results confirmed that high efficient photosynthetic function in     

Relationship between leaf photosynthetic function at grain filling stage and yield in super high-yielding hybrid rice ( Oryza sativa . L)

The characteristics of dry matter production before and after heading and the relationships between photosynthesis of flag leaves and dry matter accumulation in panicles were investigated on super high-yielding rice cv. Xieyou 9308 (the yield of up to 12 t/ha) with rice cv. Xieyou 63 as a control. The results showed that (i) the capacity of dry matter production before and after heading in Xieyou 9308, i.e. biomass and daily dry matter production, was remarkably higher than that in Xieyou 63, especially after heading; (ii) CO₂ assimilation capacity in flag leaves in Xieyou 9308, namely Leaf Source Capacity (LSC), was also significantly higher than that in Xieyou 63, and the supply of photosynthate in leaves and the demand of grain filling were completely synchronous in Xieyou 9308, but photosynthetic function in flag leaves in Xieyou 63 declined sharply 20 days after heading and it was not enough to meet the demand of grain filling. These results confirmed that high efficient photosynthetic function in leaves after heading and its complete synchronization with grain filling are the key approaches to super high yield of rice.     

超高产水稻组合‘培矮64S/E32’的耐光氧化特性及其机理

甲基紫精（MV）介导的光氧化导致两个水稻品种‘汕优63’(目前我国大面积推广的杂交水稻)和‘培矮64S/E32’（新培育的超高产杂交水稻）细胞电解质渗漏率都增加,前者增加的量大于后者,显示‘培矮64S/E32’的细胞膜系统受光氧化的伤害小。光氧化条件下,‘培矮64S/E32’仍能维持较高的光合放氧能力（Amax、Φi）、PSⅡ活性（Fv/Fm、ΦPSⅡ）和叶绿素荧光猝灭系数（qP、NPQ）,而且光氧化引起‘培矮64S/E32’这些参数的下降幅度也小。另外,光氧化导致了两个水稻品种抗氧化酶SOD和APX活性增加,‘培矮64S/E32’增加的幅度约为‘汕优63’的3倍。结果表明超高产水稻具有更强的耐光氧化能力。     

在光氧化条件下不同类型高产稻的叶绿素荧光特性和膜脂过氧化特点

用不同类型高产稻(Oryza sativa L.)粳稻9516、具有粳型成分的两系法亚种间杂交稻培矮64/E32、两优培九(培矮64/9311)和籼型杂交稻X07S/紫恢100、冈优881、汕优63为材料,研究了孕穗期叶片在光氧化条件下的叶绿素荧光特性和膜脂过氧化表现.光氧化处理后,与籼型杂交稻比较,粳稻和具有粳型组分的亚种间杂交稻的PSⅡ原初光化学效率(Fv/Fm)、PSⅡ的线性电子传递的量子效率(ΦPSⅡ)和光化学猝灭系数(qP)下降的较少;超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)诱导的活性较高,活性氧 (O(-)/()2、H2O2)和丙二醛(MDA)的产生积累较少,叶绿素和蛋白质含量下降较少,表现出耐光氧化特性,这与在自然条件下生育后期叶绿素含量变化相一致.相关分析表明它们的耐光氧化特性与结实率密切相关,说明耐光氧化品种抗早衰,有利籽粒充实.这些结果启示我们:从超高产育种出发,兼顾杂种优势利用和抗早衰两方面考虑,在母本不育系中引入粳型成分是一个值得重视的育种策略.     

自然条件下不同高产稻生育后期剑叶叶绿素荧光和膜脂过氧化的表现

以籼型(Oryza sativa L.)杂交组合汕优63为对照,以中粳9516、两系亚种间杂交组合培矮64S/E32、培矮64S/9311、亚种间三系杂交稻冈优881和两系杂交组合X07S/紫恢100为材料,研究其在生育后期(抽穗-成熟)自然条件下剑叶的叶绿素衰减、CO2交换、叶绿素荧光参数和膜脂过氧化表现.结果表明: 水稻在生育后期伴随叶绿素衰减,其叶内的原初光化学效率Fv/Fm、PSⅡ非环式电子传递效率ΦPSⅡ、电子流传递速率ETR都有相应地下降,这种光能转化的障碍使多余的光能传递给PSⅡ的还原侧,产生O(-)/(*)2累积,发生膜脂过氧化和MDA的积累,引起光合色素及光合膜的破坏,发生光氧化早衰.这种现象在品种间有明显差异,耐光氧化的粳稻9516,其叶内的 Fv/Fm、ΦPSⅡ、ETR、qP下降较少,具有较稳定的光能转化能力,不易早衰,具有较高的结实率;而对光氧化敏感的籼稻汕优63其叶内的Fv/Fm、ΦPSⅡ、ETR,光化学猝灭参数qP下降较多,易发生膜脂过氧化,导致叶片早衰,影响水稻灌浆结实和产量;而二系的和三系的杂交稻的耐光氧化特性和早衰表现居于中间.从水稻超高产育种的角度出发,在目前株型良好的基础上,兼顾杂种优势和防止早衰两方面考虑,在母本中利用粳型或带有粳型基因的不育系是育种上一个值得重视的策略.     

Relationship Between PSⅡExcitation Pressure and Content of Super High-Yielding Hybrid Rice

The changes in photochemical features of PhotosystemⅡ(PSⅡ) and contents of Rubisco large subunit (RLS) and small subunit (RSS) in flag leaf from 75DAS to 113DAS (from filling to harvesting stages) were investigated in two hybrid rices (Oryza sativa L.) cv. Liangyoupeijiu and cv. Shanyou 63 grown in the field. Liangyoupeijiu is a super high-yielding rice and Shanyou 63 has widely been planted in China in these years. The results indicate that soluble protein and chlorophyll in both cultivars degraded slowly at first and dramatically thereafter. The degradation speed of soluble protein in Shanyou 63 was faster than that in Liangyoupeijiu. Both Fv/Fm and qP decreased in parallel with leaf senescence, whereas qN fell at first and then rose. No significant change in excitation pressure (1-qP ) was found before 89DAS but a sharply increase in both cultivars after it occurred. Excitation pressure rose more rapidly in Shanyou 63 than that in Liangyoupeijiu. The changes of RLS and RSS content exhibited the same trend as that of soluble protein content. A better linear correlation between RLS, RSS degradation and elevation of (1-qP ) were shown in both cultivars. We suggest that the increase in PSⅡ excitation pressure possibly induced the quick senescence process in rice flag leaf. The high-yielding of Liangyoupeijiu may be due to its maintenance of stronger photosynthetic capacity, longer and more stable photosynthetic functional du-ration than that of Shanyou 63.