低浓度CO2对水车前和黑藻光合特性的影响

本实验通过对沉水植物水车前(Ottelia alismoides)和黑藻(Hydrilla verticillata)进行低浓度CO2诱导,研究其光合特性的变化.研究显示,诱导后,水车前的PEPC/Rubisco活性比值由0.45上升到4.17,黑藻由0.47上升到4.17,两种植物的C4途径光合酶PEPC和NAD-M...     

转玉米PEPC基因水稻中有限的C4光合微循环及其生理作用

用转PEPC基因水稻(OryzasativaL.subsp.japonicaKitaake)和原种水稻Kitaake为材料,研究了不同基因型水稻叶片中的C4光合微循环及其功能。通过测定与光合C4途径有关的关键酶,如磷酸烯醇式丙酮酸羧化酶(PEPC)、NADP -苹果酸酶(NADP -ME)、NADP -苹果酸脱氢酶(NADP -MDH)和丙酮酸磷酸双激酶(PPDK),说明原种水稻叶片中具有完整的C4光合酶体系;用外源OAA或MA饲喂叶切片或叶绿体后明显增加光合速率,证明原种水稻中具有一个有限的光合C4微循环。将玉米的PEPC基因导入原种水稻后,可大幅度提高光合C4微循环的速率。测定不同基因型的CO2交换速率,看出水稻中C4光合微循环的增强有提高净光合速率(Pn)和降低光呼吸速率/净光合速率(Pr/Pn)比值的作用。叶绿素荧光特性分析表明,C4光合微循环的增强伴随着PSⅡ电子传递效率(Fv/Fm)和光化学猝灭(qP)的增加以及非光化学猝灭(qN)的降低;这些结果为通过基因工程手段提高作物光合效率的遗传育种提供了科学根据。     

转玉米PEPC基因水稻中有限的C4光合微循环及其生理作用

用转PEPC基因水稻(Oryza sativa L. subsp.japonica Kitaake)和原种水稻Kitaake为材料,研究了不同基因型水稻叶片中的C4光合微循环及其功能.通过测定与光合C4途径有关的关键酶,如磷酸烯醇式丙酮酸羧化酶(PEPC)、NADP -苹果酸酶(NADP -ME)、NADP -苹果酸脱氢酶(NADP -MDH)和丙酮酸磷酸双激酶(PPDK),说明原种水稻叶片中具有完整的C4光合酶体系;用外源OAA或MA饲喂叶切片或叶绿体后明显增加光合速率,证明原种水稻中具有一个有限的光合C4微循环.将玉米的PEPC基因导入原种水稻后,可大幅度提高光合C4微循环的速率.测定不同基因型的CO2交换速率,看出水稻中C4光合微循环的增强有提高净光合速率(Pn)和降低光呼吸速率/净光合速率(Pr/Pn)比值的作用.叶绿素荧光特性分析表明,C4光合微循环的增强伴随着PSⅡ电子传递效率(Fv/Fm)和光化学猝灭(qP)的增加以及非光化学猝灭(qN)的降低;这些结果为通过基因工程手段提高作物光合效率的遗传育种提供了科学根据.     

转PEPC基因水稻的光合生理特性

用转PEPC、PPDK、NADP－ME、PEPC＋PPKD双基因水稻（Oryza sativa L.）及原种为材料,以光合酶活性、饱和光合速率及PSⅡ光化学效率（Fv/Fm）为指标,研究了转PEPC基因水稻的光合生理特征。结果如下：转PEPC基因水稻EPC活性比原种提高20倍;饱和光合速率比原种高55％;用高光强或人工光氧化剂甲基紫精（MV）处理后,与原种相比,转PEPC基因水稻光化学效率下降较少,证明其耐光抑制、耐光氧化能力增强,测定其兴合日变化看出：在1d中不同时间,转PEPC基因水稻的光合速率均高于原种,且与PEPC活性的日变化有相似的趋势,上述结果为转PEPC基因水稻的生理机制和种研究提供了依据和途径。     

转C4光合酶基因水稻株系的抗光氧化特性

用经转入磷酸烯醇式丙酮酸羧化酶（PEPC）,丙酮酸磷酸二激酶（PPDK）,NADP－苹果酸酶（NADPME）,PEPC＋PPDK等酶的基因的水稻株系及原种为材料,研究了光氧化条件下的叶绿素荧光特性和膜脂过氧化,光氧化处理后,与原种相比,转C4光合酶基因特别是转PEPC和转PEPC＋PPKD基因水稻株系的PSⅡ原初光化学效率（Fv/Fm),PSⅡ在照光下的实际光化学效率（φPSⅡ)和光化学猝灭（qp)下孤的比原种少,而非光化学猝灭（qN)增加的比原种多,说明在光氧化条件下,转C4光合酶基因水稻株系吸收的光能中有较多的光能转化为化学能,过剩的光能通过热耗散而减轻光破坏,同时转C4光合酶基因水稻株系吸收的光能中有较多的光能转化为化学能,过剩的光能通过热耗散而减轻光破坏;同时转C4兴合酶基因水稻株系诱导产生的内源活性氧清除酶系超氧化物歧化酶（SOD）,过氧化氢酶（CAT）,过氧化物酶（POD）的活性比原种高,从而有效清除水稻叶片内的活性氧（O2^-,H2O2),使活性氧积累比原种少,因而膜脂过氧化产物丙二醛（MDA）产生较少,表明转C4光合酶基因特别是转PEPC和转PEPC＋PPDK基因水稻株系耐光氧化能力较强,在光氧化条件下,它们的叶绿素和蛋白质含量下降较少,表现出在耐光氧化特性,这些结果为应用生物技术创造耐光氧化种质提供了实验依据。     

毛竹快速生长期茎秆不同节间光合色素和光合酶活性的差异

为揭示毛竹(Phyllostachysedulis)快速生长期茎秆中的光合碳同化特征及其在不同节间的变化规律,以毛竹笋竹茎秆为材料,测定不同节间光合色素含量、核酮糖-1,5-二磷酸羧化酶/加氧酶(Rubisco)、磷酸烯醇式丙酮酸羧化酶(PEPC)、苹果酸脱氢酶(NADP-MDH)、NADP-苹果酸酶(NADP-ME)、磷酸烯醇式丙酮酸羧激酶(PEPCK)以及丙酮酸磷酸双激酶(PPDK)活性。结果显示,茎秆中叶绿素a、叶绿素b以及类胡萝卜素含量随节间升高均呈下降趋势,叶绿素a/b比值呈逐渐上升趋势;随着节间的升高,茎秆中Rubisco、PEPC和PPDK活性在第1–10节间显著下降,之后酶活性降幅逐渐减缓;NADP-ME活性在第1–13节间呈显著下降趋势,之后酶活性趋于平稳;NADP-MDH活性在第1–25节间显著下降。PEPC/Rubisco活性比值随节间升高而不断增加,其范围介于18.37–65.09之间,明显大于典型C3植物中的活性比值。上述结果表明,茎秆不同节间的光合碳同化能力存在明显差异,中、下部节间生长相对较快;茎秆中存在多种C4酶且活性较高,这为此时期茎秆中存在C4光合途径提供了有力证据。     

转C4光合酶基因水稻的CO2交换和荧光特性

用转PEPC、PPDK、NADP-ME、PEPC+PPDK酶基因水稻(Oryza sativa L.)及原种为材料 ,研究了光合作用对光照、温度、CO2的响应和光抑制条件下的叶绿素荧光特性,结果如下: 1.转C4光合酶基因水稻的饱和光合速率比原种高,其中转PEPC、PEPC+PPDK双基因水稻的光饱和点比原种高200 μmol*m-2*s-1,饱和光合速率比原种分别高51.6%和 58.5%;转PEPC基因水稻的羧化效率比原种高49.3%,CO2补偿点降低26.2%;在高温(35 ℃)下,转PEPC基因水稻的光合速率比原种高17.5%.2.经光抑制处理8 d后,转PEPC、PEPC +PPDK酶基因水稻的PSⅡ光化学效率(Fv/Fm)和光化学猝灭(qP)下降20%- 30%,非光化学猝灭(qN)增加了约30%;但原种的Fv/Fm和qP下降了5 0%多,qN变化不明显,表明转C4光合基因水稻耐光抑制能力增强.这些结果为用生物技术提高水稻光合效率研究提供了新的依据和途径.     

转C4光合酶基因水稻的CO2交换和荧光特性

用转PEPC、PPDK、NADP_ME、PEPC PPDK酶基因水稻 (OryzasativaL .)及原种为材料 ,研究了光合作用对光照、温度、CO2 的响应和光抑制条件下的叶绿素荧光特性 ,结果如下 :1.转C4 光合酶基因水稻的饱和光合速率比原种高 ,其中转PEPC、PEPC PPDK双基因水稻的光饱和点比原种高 2 0 0 μmol·m-2 ·s-1,饱和光合速率比原种分别高5 1.6 %和 5 8.5 % ;转PEPC基因水稻的羧化效率比原种高 49.3% ,CO2 补偿点降低 2 6 .2 % ;在高温 (35℃ )下 ,转PEPC基因水稻的光合速率比原种高 17.5 %。 2 .经光抑制处理 8d后 ,转PEPC、PEPC PPDK酶基因水稻的PSⅡ光化学效率 (Fv/Fm)和光化学猝灭 (qP)下降 2 0 % - 30 % ,非光化学猝灭 (qN)增加了约 30 % ;但原种的Fv/Fm 和qP下降了 5 0 %多 ,qN变化不明显 ,表明转C4 光合基因水稻耐光抑制能力增强。这些结果为用生物技术提高水稻光合效率研究提供了新的依据和途径     

遮荫条件下草莓的光合持性变化

对宝交早生和硕丰两个草莓品种遮荫处理后测定其光合特性变化结果表明,遮荫处理使两个草莓品种叶片光合速率显著降低,分别下降了20％和47％,而表观量子效率分别提高了13％和8％,叶片中叶绿素含量升高而可溶性蛋白含量显著降低,光系统II电子传递活笥（PSII活性）分别下降了22．5％和53．7％,1,5二磷酸核酮糖羧化酶（Rubisco)活性分别低了19．6％和35．3％,进一步讨论了草莓光饱和速率下降的生理基础。     

转C4光合酶基因水稻株系的抗光氧化特性

用经转入磷酸烯醇式丙酮酸羧化酶(PEPC)、丙酮酸磷酸二激酶(PPDK)、NADP-苹果酸酶(NADP-ME)、PEPC+PPDK等酶的基因的水稻株系及原种为材料,研究了光氧化条件下的叶绿素荧光特性和膜脂过氧化.光氧化处理后,与原种相比,转C4光合酶基因特别是转PEPC和转PEPC+PPDK基因水稻株系的PSⅡ原初光化学效率(Fv/Fm)、PSⅡ在照光下的实际光化学效率(ФPSⅡ)和光化学猝灭(qp)下降的比原种少,而非光化学猝灭(qN)增加的比原种多,说明在光氧化条件下,转C4光合酶基因水稻株系吸收的光能中有较多的光能转化为化学能,过剩的光能通过热耗散而减轻光破坏;同时转C4光合酶基因水稻株系诱导产生的的内源活性氧清除酶系超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、过氧化物酶(POD)的活性比原种高,从而有效清除水稻叶片内的活性氧(O-2、H2O2),使活性氧积累比原种少,因而膜脂过氧化产物丙二醛(MDA)产生较少.表明转C4光合酶基因特别是转PEPC和转PEPC+PPDK基因水稻株系耐光氧化能力较强.在光氧化条件下,它们的叶绿素和蛋白质含量下降较少,表现出耐光氧化特性.这些结果为应用生物技术创造耐光氧化种质提供了实验依据.     

Regulation and Localization of Key Enzymes during the Induction of Kranz-Less,C4-Type Photosynthesis in Hydrilla verticillata

Kranz-less, C4-type photosynthesis was induced in the submersed monocot Hydrilla verticillata (L.f.) Royle. During a 12-d induction period the CO2 compensation point and O2 inhibition of photosynthesis declined linearly. Phosphoenolpyruvate carboxylase (PEPC) activity increased 16-fold, with the major increase occurring within 3 d. Asparagine and alanine aminotransferases were also induced rapidly. Pyruvate orthophosphate dikinase (PPDK) and NADP-malic enzyme (ME) activities increased 10-fold but slowly over 15 d. Total ribulose-1,5-bisphosphate carboxylase/oxygenase activity did not increase, and its activation declined from 82 to 50%. Western blots for PEPC, PPDK, and NADP-ME indicated that increased protein levels were involved in their induction. The H. verticillata NADP-ME polypeptide was larger (90 kD) than the maize C4 enzyme (62 kD). PEPC and PPDK exhibited up-regulation in the light. Subcellular fractionation of C4-type leaves showed that PEPC was cytosolic, whereas PPDK and NADP-ME were located in the chloroplasts. The O2 inhibition of photosynthesis was doubled when C4-type but not C3-type leaves were exposed to diethyl oxalacetate, a PEPC inhibitor. The data are consistent with a C4-cycle concentrating CO2 in H. verticillata chloroplasts and indicate that Kranz anatomy is not obligatory for C4-type photosynthesis. H. verticillata predates modern terrestrial C4 monocots; therefore, this inducible CO2-concentrating mechanism may represent an ancient form of C4 photosynthesis.     

华南地区淡水水鳖科植物的生态特征和群落学观察

本文讨论了华南地区淡水水鳖科植物的生活条件、水生生态的适应特点,研究了该科植物水白菜、水菜花、水筛、黑藻、苦草、大苦草、软骨草等植物所组成群落的群落学特征。     

Overexpression of phosphoenolpyruvate carboxylase from Corynebacterium glutamicum lowers the CO2 compensation point (*) and enhances dark and light respiration in transgenic potato

The effect of decreased or increased phosphoenolpyruvate carboxylase (PEPC) activity on the CO2 compensation point, respiration in the light or dark as well as the partitioning of carbon into starch, soluble sugars, organic acids, and amino acids was investigated using transgenic potato plants. Engineered PEPC activity ranged form 0.5-fold wild-type level in antisense plants to 5-fold wild-type levels in lines overexpressing the ccpc gene of Corynebacterium glutamicum encoding for a PEPC not modulated by protein phosphorylation. The CO2 compensation point determined according to Brooks and Farquhar (1985) was lower in PEPC overexpressors (32 l l^-1 CO2) compared to control potato lines (38 l l^-1 CO2), but was increased in antisense PEPC plants (42 l^-1 CO2). 3-fold overexpression of PEPC gave a minimum CO2 compensation point of 32 l l^-1 CO2. Increased PEPC activity resulted in enhanced respiration in the light and dark. Altered PEPC activity had no effect on the pattern of ¹⁴CO2 incorporation into leaf discs in the light. ¹⁴C pulse-chase experiments in the dark, demonstrated that substantially more total label was lost in the leaf discs from PEPC overexpressors. Metabolite levels were determined in 21 PEPC overexpressing lines after 8 h in the light. A 5-fold increase in PEPC over the wild-type increased malate (61%), starch (75%) and significantly increased sucrose contents 9150%). Total amino acid contents were only marginally increased. From gas exchange characteristics and labeling experiments it was concluded that PEP carboxylation, followed by an increased rate of respiratory CO2 release, might work as a HCO3^-/CO2 pump. This might result in elevated CO2/O2 ratios in the mesophyll, concomitant with a more favoured carboxylation/oxygenation ratio of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco).     

Induction of a C(4)-like mechanism of CO(2) fixation in Egeria densa, a submersed aquatic species

The expression of phosphoenolpyruvate carboxylase (PEPC) and NADP-malic enzyme (NADP-ME) in Egeria densa leaves was studied under low temperature and light (LTL) following incubation under high temperature and light (HTL), conditions previously shown to induce high and low CO(2) compensation points, respectively. Transfer from LTL to HTL conditions induced increases in the activities and amounts of both enzymes. One NADP-ME isoform was observed in induced and uninduced samples. Two isoforms of PEPC were expressed, with the lower M(r) isoform being induced by HTL. NADP-ME showed properties similar to those of the isoform in C(3) species. The inducible PEPC isoform has a low K(m) for both substrates. PEPC kinetic and regulatory properties (V(max) and K(m) for phosphoenolpyruvate, and I(50) for L-malate) are different in samples taken in the dark from those in the light, indicating that some modification of PEPC may be occurring during the day. Finally, abscisic acid induced the expression of PEPC and NADP-ME in a manner similar to temperature induction, except that the activities of both PEPC isoforms were increased. A different signaling system may exist in this species in response to high temperature or abscisic acid, both of which induce changes in photosynthetic metabolism.     

Physiological characteristics of the primitive CO2 concentrating mechanism in PEPC transgenic rice

C4 plants such as maize have CO2 concentrating mechanism and higher photosynthetic efficiency than C3 plants, especially under high light intensity, high temperature and drought conditions. In recent years, due to the rapid development of transgenic technique, different transgenic rice plants with high-level expression of C4 genes have been created by the successful introduction of genes encoding the key C4 photosynthetic path enzymes PEPC, PPDK and NADP-ME through agrobacteria-mediated…     

Physiological characteristics of the primitive CO<Subscript>2</Subscript> concentrating mechanism in PEPC transgenic rice

The relationship between carbon assimilation and high-level expression of the maize PEPC in PEPC transgenic rice was studied by comparison to that in the untransformed rice, japonica kitaake. Stomatal conductance and photosynthetic rates in PEPC transgenic rice were higher than those of untransformed rice, but the increase of stomatal conductance had no statistical correlation with that of photosynthetic rate. Under high levels of light intensity, the protein contents of PEPC and CA were increased significantly. Therefore the photosynthetic capacity was increased greatly (50%) with atmospheric CO2 supply. While CO2 release in leaf was reduced and the compensation point was lowered correspondingly under CO2 free conditions. Treatment of the rice with the PEPC-specific inhibitor DCDP showed that overexpression of PEPC and enhancement of carbon assimilation were related to the stability of Fv/Fm. Labeling with 14CO2 for 20 s showed more 14C was distributed to C4 primary photosynthate asperate in PEPC transgenic rice, suggesting that there exists a limiting C4 photosynthetic mechanism in leaves. These results suggest that the primitive CO2 concentrating mechanism found in rice could be reproduced through metabolic engineering, and shed light on the physiological basis for transgenic breeding with high photosynthetic efficiency.