Photosynthetic Characteristics and Heterosis in Transgenic Hybrid Rice with Maize Phosphoenolpyruvate Carboxylase (pepc) Gene

Three F3 hybrids derived from the sterile rice lines Gang 46A, 776A and 2480A and the improved restorer line Shuhui 881 containing maize phosphoenolpyruvate carboxylase （pepc） gene were used to analyze the effect of pepc gene on the heterosis and photosynthetic characteristics, while the F3 obtained by crossing Shuhui 881 with the above three sterile lines served as controls. The dynamics of photosynthetic characteristics in leaves of three F1 with pepc gene and their controls were determined at the initial-tillering, maxium-tillering, elongation, initial-heading, heading, maturity stages, and other different times after flag leaf fully expanded. The PEPCase activities of the three F1 with pepc gene increased significantly as compared with control plants during the whole developmental stages. Moreover, the net photosynthesis rate （Pn） also increased to certain extent. The data showed that PEPCase activity was significantly correlated to Pn with a correlation coefficient of 0.6081. The photosynthetic indexes of the three F1 with pepc gene were obviously superior to respective controls in apparent quantum efficiency, light compensation point and carboxylation efficiency, while the CO2 compensation point was lower than that of corresponding control. The Pn of the three F1 with pepc gene at light saturation point and CO2 saturation point was also higher than that of control plants. in addition, the three F1 with pepc gene had an average increase of 37.10% in grain yields per plant in comparison with control plants. The results indicated that the photosynthetic characteristics of hybrid rice containing pepc gene had been improved to some extent due to the introduction of pepc gene.

Identification and Expression Analysis of the Phosphoenolpyruvate Carboxylase Gene Family in Peanut (Arachis hypogaea L.)

Phosphoenolpyruvate carboxylase （PEPC） is widely distributed in plants and bacteria, and catalyzes the carboxylation of phosphoenolpyruvate to form oxaloacetate and inorganic phosphate. To investigate the molecular mechanisms of the regulation and control of peanut oil, with the degenerated primers and RACE-PCR approach, five PEPC genes were cloned from peanut, and designated as AhPEPC1, AhPEPC2, AhPEPC3, AhPEPC4, and AhPEPC5, respectively. The structure and phylogenetic analysis of PEPC protein indicated that AhPEPC1-4 genes encoded a typical plant-type PEPC-enzyme, and AhPEPC5 a bacterial-type. By real-time quantitative RT-PCR approach the expression pattern of each gene was detected in various tissues of normal and high oil-content peanut varieties. It was found that there was a lower expression level of AhPEPCs genes except for the AhPEPC2 in high-oil peanut than normal-oil peanut line. The results provide some fundamental information for the further investigation of plant PEPC proteins and their role in regulation of oil-content in peanut seeds.

Functional Analysis of the Phosphoenolpyruvate Carboxylase on the Lipid Accumulation of Peanut(Arachis hypogaea L.) Seeds

Phosphoenolpyruvate carboxylase（PEPC;EC 4.1.1.31） catalyses phosphoenolpyruvate（PEP） to yield oxaloacetate,which is involved in protein biosynthesis.Pyruvate kinase（PK;EC 2.7.1.40） catalyzes PEP to yield pyruvate,which is involved in fatty acid synthesis.In this study,five PEPC genes（AhPEPC1,AhPEPC2,AhPEPC3,AhPEPC4,and AhPEPC5） from peanut have been cloned.Using a quantitative real-time RT-PCR approach,the expression pattern of each gene was monitored during the seed development of four peanut varieties（E11,Hebeigaoyou,Naihan 1,and Huayu 26）.It was found that these five genes shared similar expression behaviors over the developmental stages of E11 with high expression levels at 30 and 40 d after pegging（DAP）;whereas these five genes showed irregular expression patterns during the seed development of Hebeigaoyou.In Naihan 1 and Huayu 26,the expression levels of the five genes remained relatively high in the first stage.The PEPC activity was monitored during the seed development of four peanut varieties and seed oil content was also characterized during whole period of seed development.The PEPC activity followed the oil accumulation pattern during the early stages of development but they showed a significantly negative correlation thereafter.These results suggested that PEPC may play an important role in lipid accumulation during the seed development of four peanut varieties tested.

Concomitant Increases of the Developing Seed Phosph<i>oenol</i>pyruvate Carboxylase Ac-tivity and the Seed Protein Content of Field-Grown Wheat with Nitrogen Supply

Wheat seed storage protein is of great importance for human food. To increase the contents of storage proteins effectively, nitrogen fertilizer at flowering stages is commonly applied. In our previous study, rice phosphoenolpyruvate carboxylase (PEPCase) activity in developing seeds was observed in response to nitrogen application at a flowering stage and was positively correlated to the response of the protein content in seeds of six cultivars. This observation might indicate that the seeds have a biological system for accepting nitrogen in seeds by using PEPCase. To test whether this physiological event occurs in wheat, we examined the PEPCase activity and protein content in field-grown wheat seeds under different nitrogen supply conditions. With only basal dressing, seeds showed lower PEPCase activity and protein content (both 0.90-fold) compared to seeds without basal fertilizer. With ammonium sulfate application at 8.3 and 25 g/m2 at a flowering stage, seeds showed higher PEPCase activity (1.08- and 1.17-fold, respectively) and protein content (1.15- and 1.42-fold, respectively), depending on the nitrogen level. We investigated the relationship between PEPCase activity and protein content in the seeds among four conditions. The effect of the nitrogen supply on PEPCase activity during grain-filling stages was validated by the results of a hydroponic culture experiment. Together the results demonstrate that our hypothesis seems to apply to field-grown wheat.

稗草磷酸烯醇式丙酮酸羧化酶(PEPCase)基因的克隆与分析

为揭示C4野生植物稗草(Echinochloa crusgalli)PEPCase的结构和功能特点,探索改善作物高光效新途径,克隆了稗草(E.crusgalli)磷酸烯醇式丙酮酸羧化酶基因(ppc)的cDNA全长,测序及同源性比较分析结果证实,稗草ppc的cDNA全长为2 886 bp,编码961个氨基酸(GenBank登录号:AY251482);核苷酸序列与谷子(Setaria italica)C3型、高粱(Sorghumbicolor)C3-2型、玉米(Zea mays)C3-2型、水稻(Oryza sativa)C3型磷酸烯醇式丙酮酸羧化酶基因的同源率分别达94.8%、93.2%9、3.0%和89.7%。推导的氨基酸序列中C末端第771位氨基酸是丙氨酸(A),表明是一个C3型基因。与其他植物几种不同形式PEPCase进行的多重序列比对与系统进化分析结果也证实,此基因的核苷酸序列及其编码的氨基酸序列与所有参与对比的C3型序列的同源性均远远高于与C4型的同源性。与玉米、高粱C3-2型PEPCase的同源性分别高达96.5%9、6.4%,与高粱、玉米的C3-1型PEPCase的同源性分别为84.3%、83.8%,而与谷子、玉米、甘蔗和高粱的C4型PEPCase的一致性相对较低,分别为82.2%、79.1%、77.1%和76.6%。因此进一步推论新克隆的稗草ppc基因属于C3-2型。对其编码的蛋白序列进行了结构域、活性位点和功能位点预测。

田间条件下转玉米C4型PEPC基因小麦的光合生理特性

为了检验转PEPC基因小麦是否具有C4光合生理特性,以转PEPC基因小麦和对照周麦19为试验材料,分别于抽穗期、开花期、花后第7天和花后第15天测定其单株旗叶的气体交换参数日变化,对净光合速率日变化进行单位日光合总量分析,并且对净光合速率日变化与单株气孔导度、胞间CO2浓度、蒸腾速率日变化的相关性进行了分析;在花后第15天测定其单株叶绿素荧光参数,并在成熟期调查了单株产量性状。与对照相比,转基因株系在4个测定时期的旗叶净光合速率明显提高,尤其在花后第15天,单位日光合总量较对照提高29.1%和23.3%,气孔导度和蒸腾速率均明显增加,胞间CO2浓度降低;花后第15天12:00与8:00相比,转PEPC基因小麦的Fv/Fm、qP、NPQ、ΦPSII的变幅均小于对照;单茎重、千粒重、单穗重和收获指数较对照显著增加。以上结果表明,转PEPC基因小麦材料在田间条件下光合特性明显优于对照,且具有提高小麦产量水平的潜力。

C3植物绿色器官PEP羧化酶活性的比较研究

本文研究了小麦（Triticum aestivum L.）和大豆（Glycine max L.）的不同光合器官中的PEP羧化酶及其相关的酶类。在这些器官中均含有PEP羧化酶,其中以大豆的荚壳和种皮及小麦的内稃中PEP羧化酶活性最高。不同绿色器官在光下或暗中均能固定CO2,但是在黑暗条件下,小麦的内稃和大豆的荚壳及种皮所固定的CO2远高于叶片。此外,参与暗固定的NAD-苹果酸酶和NAD-苹果酸脱氢酶的活性,在这些器官中也最高,说明这些器官中PEP羧化酶的CO2 β-羧化作用主要在于固定呼吸作用所释放的CO2,只有少量的CO2是通过C4光合途径被固定。

PEPC过表达可以减轻干旱胁迫对水稻光合的抑制作用

为了明确磷酸烯醇式丙酮酸羧化酶(PEPC)过量表达能否提高水稻的光合速率,测定了42个表达不同PEPC水平的转玉米PEPC基因水稻株系及对照(受体亲本中花8号)开花期和灌浆期的光合速率。结果表明,在水田条件下,转基因株系光合速率与未转基因对照相比没有明显差异;而在旱地条件下,转基因水稻的光合速率显著高于对照(27%和24%)。随机选取2个PEPC相对活性分别为10倍和25倍的转基因株系进行网室精确控水盆栽实验得到相似的结果。说明单纯导入PEPC并不能提高水稻的光合速率,而干旱胁迫下转基因水稻的光合优势可能是由于PEPC参与水稻的抗旱反应而减轻了干旱胁迫对光合作用的抑制作用。

蓝藻正反义pepcA基因导入对大肠杆菌中脂类合成的调控

为了探索原核生物中磷酸烯醇式丙酮酸羧化酶(PEPC)在调控脂类代谢中的作用。PCR法扩增了鱼腥藻Anabaena sp.PCC 7120 PEPC基因中含保守结构域Fa的一段基因片段pepcA,并将其克隆到pMD 18-T载体上。将pepcA正反向连接到穿梭表达载体pRL-489上BamHI位点之间,构建得带有pepcA正反义基因的载体pRL-Sen pepcA和pRL-Anti pepcA,转化入大肠杆菌(Escherichia coli)DH5α宿主细胞中。分析结果表明:pepcA片段的转入对宿主菌的生长影响不大;与野生型细胞相比较,转反义pepcA片段E.coli中PEPC酶活性降低到野生菌的30.2%,蛋白合成减少23.6%,脂类的合成增加了46.9%,;而转正义pepcA片段E.coliPEPC酶活性是野生菌的2.38倍,蛋白合成增加了14.5%,脂类合成减少了49.6%;转基因菌中十八碳酸的含量明显增加。上述结果可能为利用原核生物做生物柴油原料提供线索。

谷子PEPC基因的鉴定及其对非生物逆境的响应特性

磷酸烯醇式丙酮酸羧化酶(phosphoenolpyruvate carboxylase,PEPC)是C4植物光合作用关键酶,并在植物多种代谢途径及逆境信号应答过程中起重要作用。本研究通过序列比对,从谷子基因组中筛选出6个SiPEPC候选基因。SiPEPC蛋白特征参数相似度很高,序列非常保守,都含有PEPC基因特征功能域PEPcase Motif。SiPEPC成员主要被定位在细胞质、细胞核和线粒体。在SiPEPC成员启动子序列中含大量有光、激素、逆境以及其他生长调控相关的顺式应答元件。苗期逆境qRT-PCR表达谱分析表明,5个SiPEPC基因(SiPEPC1、SiPEPC2、SiPEPC3、SiPEPC5、SiPEPC6)不同程度受ABA、PEG、高盐和低温诱导表达,表明其参与了苗期对非生物逆境的响应。5个SiPEPC基因表达量在正常生长条件下随着谷子的生长呈增强趋势,且在不同生育时期干旱胁迫下明显增加,表明其参与了拔节、抽穗、灌浆期的干旱胁迫应答。拔节期弱光可诱导5个SiPEPC基因的表达,而在拔节期中等强度光照以及抽穗期和灌浆期的中等光照和弱光照下表达量均急剧降低,揭示光照强度严重影响SiPEPC基因的表达。

外源葡萄糖增强高表达转玉米C_4型pepc水稻耐旱性的生理机制

为揭示葡萄糖参与植物耐旱性的内在机制,以高表达转玉米C4型磷酸烯醇式丙酮酸羧化酶(phosphoenolpyruvate carboxylase,PEPC)基因(C4-pepc)水稻(PC)和受体"Kitaake"(WT)为材料,通过盆栽和水培试验,研究外施葡萄糖联合干旱处理下,功能叶片的光合参数、总可溶性糖及其组分、Ca2+、NO含量、己糖激酶活性、B类钙调磷酸酶(calcineurin B-like,CBL)与蔗糖非发酵1(sucrose nonfermenting-1,SNF1)相关蛋白激酶(SNF1-related protein kinase 3s,Sn RK3s)基因表达的变化。结果表明,在盆栽试验中,分蘖期外施3%葡萄糖联合干旱处理对水稻的产量及其构成因子影响不显著,而在孕穗期处理,PC的株高、穗数、每穗实粒重和单株产量均显著高于WT。在水培试验中,外施1%葡萄糖和12%(m/v)聚乙二醇6000(polyethylene glycol-6000,PEG-6000)模拟干旱处理,均显著提高了PC功能叶片的净光合速率(Pn)、气孔导度(Gs)和羧化效率(CE),叶片内蔗糖和果糖的含量也均显著高于WT。值得关注的是,PC叶片己糖激酶(hexokinase,HXK)活性、CBL1/Sn RK3.1/Sn RK3.4/Sn RK3.21基因的相对表达量在外施1%葡萄糖联合12%PEG模拟干旱处理下均显著低于12%PEG处理,而NO含量则显著上升。相关性分析也表明,PC中Pn、胞间CO2浓度(Ci)和Gs分别与葡萄糖含量、HXK活性和Sn RK3.16基因表达显著相关。外施葡萄糖处理可上调PC糖水平,下调其CBL和Sn RK3s基因表达,诱导NO参与叶片气孔调节,从而增强保水能力,保持光合能力稳定,最终表现为耐旱。

四种油料作物中的细菌型PEPC基因的鉴定及在发育种子中的表达

鉴定和获取了四种油料作物(油菜、大豆、花生和芝麻)中的细菌型PEPC基因,分析了所编码蛋白的保守结构域(BOX I-IV)和蛋白作用功能位点。基因包括甘蓝型油菜的Bna10093361、Bna1009749和Bna10093360,大豆的Glyma10g34970.1,Glyma01g22840.1和Glyma02g14500.1,芝麻的SIN1018296和花生的AhPPC5。这8个基因通常含有19～21个内含子,内部插入一个约350～600bp的高度变异区,编码的蛋白在C端形成R/KNTG结构域,在N端缺乏磷酸化作用位点。在种子发育的不同时期,油菜中仅Bna10093360表达,但其表达量不到油菜Bn-Actin表达量的0.1%;大豆中Glyma10g34970.1表达量最高(接近大豆GlymaActin的2%),Glyma02g14500.1次之;花生AhPPC5表达量为花生AhActin的32%～175%,在种子不同发育时期表达量为早期>中期>晚期;芝麻SIN1018296表达量为芝麻SINActin的3%～18%,在种子发育时期的表达趋势和花生AhPPC5相似。8个基因种子中的表达模式差异明显,说明细菌型PEPC基因可能存在着广泛的功能分化。

谷子磷酸烯醇式丙酮酸羧化酶基因(PEPC)对逆境胁迫的响应

为解析谷子磷酸烯醇式丙酮酸羧化酶(PEPC,Phosphoenolpyruvate carboxylase)在非生物逆境胁迫下的响应特征。从谷子基因组中鉴定出一个SiPEPC(Seita.1G020700)基因,利用相关软件对其氨基酸序列、蛋白特征、功能、信号途径、顺势应答元件等参数特征进行分析和预测,随后分析了该基因在幼苗期逆境胁迫下的动态表达模式及在拔节期、抽穗期、灌浆期不同光照处理和干旱胁迫下的表达。结果表明,该基因位于谷子1号染色体,基因组序列长6 652 bp,编码965个氨基酸,基因无可变剪切、不含内含子;功能域分析显示,该基因含PEPC基因的特征结构域;多序列比对发现,该PEPC蛋白与其他植物PEPC蛋白非常相似,具有非常保守的序列结构。实时荧光定量PCR分析表明,SiPEPC(Seita.1G020700)在ABA、低温、PEG、高盐胁迫下表达量均有所上调,其中,在ABA处理时,表达量呈现波动,在12 h被诱导达到峰值。在低温处理时,表达量持续上升,在24 h达到峰值;在PEG和NaCl处理时表达量整体呈上升趋势,均在12 h达到峰值,在24 h其表达量均急剧下降。进一步研究表明,SiPEPC基因在拔节期和抽穗期正常光照强度下参与了对干旱胁迫的响应,推测SiPEPC(Seita.1G020700)基因参与了谷子对非生物逆境的应答,可能在干旱和其他逆境胁迫信号途径中起关键作用。

干旱对玉米幼苗PEP羧化酶活性的影响

本文研究了土壤干旱过程中及复水后玉米幼苗ＰＥＰ羧化酶活性的变化。结果表明，当土壤含水量由２１．０％降至６．１％时，ＰＥＰ羧化酶活性由０．３５２μｍｏｌＣＯ２／ｍｇ·ｐｒｏ．ｍｉｎ降至０．０６３μｍｏｌＣＯ２／ｍｇ·ｐｒｏ·ｍｉｎ，复水后其活性恢复很慢，即使叶水势恢复到干旱前水平（－０．３ＭＰａ），此酶活性才恢复到０．１７μｍｏｌＣＯ２／ｍｇ·ｐｒｏ·ｍｉｎ，仅为干旱前的４７．４％。光合速率先升后降，叶绿素含量和叶片水势的变化与ＰＥＰ羧化酶相似，气孔阻力则随土壤干旱程度的加剧而逐渐升高。说明土壤干旱过程中玉米幼苗ＰＥＰ羧化酶活性的降低可能是光合作用下降的非气孔因素之一。

微藻油脂生物合成与ACCase、PEPC相关性的研究进展

乙酰辅酶A羧化酶(ACCase)和磷酸烯醇式丙酮酸羧化酶(PEPC)是脂肪酸合成中的两个主要的酶。介绍了ACCase、PEPC的类型、分布、反应机理及在微藻代谢中的作用;对酶代谢调控、基因工程的应用等因素进行了概括;就多酶基因调控微藻油脂合成的发展趋势进行了探讨。

玉米PEPC基因在籼型水稻保持系不同遗传背景下的效应及转PEPC基因后代的耐光氧化特性

分别以转PEPCKitaake和Kitaake作父本,以4份不同来源的保持系珍汕97B、K17B、Ⅱ-32B和G2480B为母本构建F1,考查PEPC的表达及其对光合性状和农艺性状的影响。导入PEPC后,水稻净光合速率、气孔导度、胞间CO2浓度和PEPC酶活性均表现为增加,最突出的是其PEPC酶活性均成倍增加。蒸腾速率方面,只有K17B/PEPC表现为下降。珍汕97B的净光合速率、气孔导度和PEPC酶活性一般配合力相对效应值均最大。在农艺性状上,G2480B/PEPC的有效穗数、结实率和单株产量均大幅度提高,分别增加了31.46%、1.39倍和1.83倍,千粒重也增加了7.84%。珍汕97B/PEPC由于穗变短,即使结实率和千粒重大幅度增加,减产仍达9.84%。G2480B的穗长、每穗粒数、结实率和单株产量一般配合力相对效应值均最大,而珍汕97B最小。在耐光氧化方面,转PEPC基因Kitaake明显优于Kitaake。说明PEPC单个基因对改善籼型三系保持系的光合性能和增加产量有较重要的作用。在供试的4份保持系中选用保持系宜考虑G2480B,PEPC在此遗传背景下的表达丰度较高,提高结实率和单株产量等农艺性状的正效应最好。

菠萝PEPC基因家族生物信息学分析

磷酸烯醇式丙酮酸羧化酶(phosphoenolpyruvate carboxylase,PEPC)在C4和景天酸代谢(CAM)光合途径吸收CO2过程中发挥重要作用,并参与各种非光合作用过程,包括果实成熟、气孔开放、碳氮相互作用、种子形成和萌发以及调节植物对逆境胁迫的耐受性。菠萝为典型的景天酸代谢途径(CAM)植物,为了解磷酸烯醇式丙酮酸羧化酶(PEPC)在菠萝景天酸代谢途径(CAM)中的作用,本研究鉴定到3个菠萝PEPC基因,按照基因描述命名为AcPEPC1、AcPEPC3和AcPEPC4,进化树分析结果AcPEPC1和AcPEPC3为植物型PEPC(PTPCs)蛋白,序列同源性较高且基因结构、保守结构域及保守基序均一致。AcPEPC4为细菌型PEPC(BTPCs)蛋白,与AcPEPC1/AcPEPC3间的序列同源性低。组织表达分析表明AcPEPC1菠萝叶片表达量较高,而AcPEPC3和AcPEPC4在菠萝花和果实表达量较高。

蜀恢881含玉米C_4型pepc基因改良系的遗传背景及其光合特性

从通过分子标记辅助选择育成的含玉米C4型pepc基因蜀恢881中筛选10株，利用530对SSR引物进行遗传背景分析，发现与蜀恢881表现差异的位点仅有1～4个，相似度在95．15％以上，最高的达99．03％。进一步对相似度为99．03％的转育玉米C4型pepc基因蜀恢881的6个生长时期测定有关光合指标，表明6个时期的PEPC酶活性均比蜀恢881增强，PEPC酶活性值最大时期是拔节期，为1264．2μmol／（mg·h），分蘖初期增加的幅度最大达到23．3倍；其净光合速率与蜀恢881相比，在分蘖初期、分蘖盛期、拔节期和始穗期都得到不同程度的提高，其中拔节期最高，达到22．3％。研究表明通过杂交利用C4型pepc基因特征引物对C4型pepc基因进行分子标记辅助选择，能够获得携有c4型pepc基因且与受体亲本遗传背景十分接近的籼型水稻材料，而且C4型pepc基因在新的遗传背景下能够高水平表达和稳定地遗传。据此，建立了分子标记辅助选择、光合生理生化指标鉴定和田间综合农艺性状考查相结合的筛选玉米C4型pepc基因水稻的技术体系；同时认为在拔节期进行转育c4型pepc基因水稻光合生理指标的测定和筛选的效果可能较理想。

3种石斛PEPC羧化酶活力比较

石斛属植物具有兼性景天酸代谢植物特征,磷酸烯醇式丙酮酸羧化酶是该类植物碳代谢的关键酶。本研究选用3种石斛为材料,测定了其磷酸烯醇式丙酮酸羧化酶活性。结果表明,报春石斛晚间黑暗条件下酶活性较强,凌晨高达25μmolCO2/(m2.s),而在中午光照最充足时,酶的活性相对较弱;金钗石斛酶活性日变化特点与报春石斛相似,但是活性比较弱;鼓槌石斛的酶活性很弱,通常在8μmolCO2/(m2.s)以下,昼夜变化幅度很小,表现为黑暗状态下比光下更强。

海水小球藻磷酸烯醇式丙酮酸羧化酶基因(Chpepc2)克隆和生物信息学分析

为了进一步了解藻类PEPC酶的特征,对海水小球藻pepc2基因进行了克隆并通过生物信息学方法分析了海水小球藻PE PCase2的结构和功能特征。结果表明,海水小球藻pepc2基因与莱茵衣藻pepc2基因相似度为90%,且其对应的氨基酸序列的特征与莱茵衣藻PE PCase2特征相同,可见该基因编码的是海水小球藻细菌型PEPC酶。海水小球藻PEPCase2二级结构主要包括α螺旋、β转角、无规则卷曲和伸展链,其三级结构外部为α螺旋结构,中心为平行β桶结构。海水小球藻PEPCase2具有多种重要的生理功能,主要与多种重要的物质合成有关。