机械伤害处理橡胶树萌条树皮的DNA甲基化分析

该研究采用甲基化敏感扩增多态性技术,分析了机械伤害处理橡胶树萌条树皮的DNA甲基化的变化。结果显示：（1）与对照相比,伤害后0.5和2 h,DNA甲基化水平略有上升;伤害后48 h的DNA甲基化水平出现了较大幅度的下降。（2）甲基化变化类型分析表明,在伤害2 h主要发生了DNA的甲基化;伤害后48 h,主要发生了DNA的去甲基化。（3）差异甲基化位点的回收、测序及注释表明,ATP合酶F1亚基1、磷酸核糖胺 甘氨酸类连接酶、冷激结构域蛋白3、光系统II 47 kD 蛋白、E3泛素蛋白连接酶RING1、NADH泛醌氧化还原酶和一些假定蛋白参与了伤害的响应。（4）经重亚硫酸盐测序验证,ATP合酶F1亚基1和NADH泛醌氧化还原酶的CCGG位点发生了去甲基化。研究推断DNA的甲基化可能参与了橡胶树萌条对机械伤害的响应。     

褐飞虱NADH泛醌氧化还原酶51kD亚基全长cDNA序列的克隆及分析

利用反转录聚合酶链式反应(RT-PCR)和快速扩增cDNA末端(RACE)技术克隆了褐飞虱NADH泛醌氧化还原酶51kD亚基(NQO)基因的全长cDNA片段,并进行了核苷酸序列测定.结果表明,该cDNA片段长度为1930 bp,所编码的蛋白与家牛、小家鼠、食蟹猴、人和蟾蜍的NADH泛醌氧化还原酶51kD亚基的氨基酸序列的同源性分别达到77%、76%、76%、75%和75%.Southern杂交分析表明,NQO基因在褐飞虱基因纽中以单拷贝形式存在.     

莲子贮存蛋白的主要亚基及积累模式

红莲（NelumbonuciferaGaertn）成熟于叶总蛋白含量达24．35g／100g干样品,其贮存蛋白（SP）的积累模式与豆科种子相似,即随成熟度的提高,SP猛增至占总蛋白含量的86％以上。对莲子不同发育阶段子叶蛋白SDS-PAGE图谱的光密度测定表明：莲子叶蛋白有12个主要SP亚基（SP1－12）。按分子量（MW）大小和积累顺序可分3组：A组是98kD和93kD的2个亚基,MW最大,积累最晚,但量最多;B组是3个亚基,MW为55－50kD,大小居中,积累最早,量最少;C组的7个亚基MW最小,在27－14kD之间,积累较早,量较多。对莲的不同品种、不同器官进行分析后发现,它们都有1个主峰为68kD的多连峰的代谢蛋白亚基,可能是莲共有的蛋白亚基。     

建兰花哇病毒运动蛋白基因克隆及序列分析

从建兰花叶病毒（CyMV）石斛兰分离物中提取病毒RNA,用反转录－－聚合酶链式反就（RT－PCR）方法获得约500bp的运动蛋白基因片段,插入pGEM-T载体克隆并测序,序列分析表明,该基因片数由474个核苷酸组成,和CyMV美国夏威夷分离物、新加坡分离物相应基因核甘酸序列分别具有97.8%同源性;根据核酸序列推导该片断含有3个部分重叠的开放阅读框架（ORF）,分别编码14kD、12kD和10kD的多肽。     

氧化磷酸化中质子的转运机制介绍和讨论

氧化磷酸化过程中电子传递和磷酸化所伴随的质子（H＋）跨线粒体内膜转运,是生物化学教学中的一个重点和难点。该文介绍参与H＋跨膜（线粒体内膜或细菌质膜）转运的复合体Ⅰ（又称为NADH-Q还原酶或NADH脱氢酶）、复合体Ⅲ（又称为细胞色素还原酶或细胞色素bc1复合体）、复合体Ⅳ（又称为细胞色素氧化酶或细胞色素c氧化酶）和复合体Ⅴ（又称为F1F0-ATP合酶）跨膜转运H＋的机制。     

细菌荧光素酶体外发光体系的建立及应用于NADH定量检测

摘要：【目的】本研究旨在建立鳆发光杆菌（Photobacterium leiognathi）YL 荧光素酶：FMN-NADH氧化还原酶体外发光双酶体系,并对荧光素酶：FMN-NADH氧化还原酶体外发光双酶体系应用于NADH的定量检测进行初步探索。【方法】利用从鳆发光杆菌提取并经部分纯化的荧光素酶和FMN-NADH氧化还原酶,通过优化体系中各底物的添加量,实现荧光素酶的体外发光。【结果】荧光素酶：FMN-NADH氧化还原酶体外发光双酶体系为：1 mL酶液中添加100 μL十二烷醛（27 mmol/L）、0.5 μL FMN-Na（10 mmol/L）、300 μL NADH（0.14 mmol/L）。NADH与荧光素酶：FMN-NADH氧化还原酶体系的发光强度呈良好的线性关系,其线性范围为1.0×10-10 ～1.0×10-8 mol/L。【结论】荧光素酶：FMN-NADH氧化还原酶体外发光双酶体系可以简便、灵敏、快速的定量检测NADH,为其进一步应用于环境检测、食品卫生与安全等领域活细菌数量的检测奠定了基础。     

棉花LIM结构域基因(GhLIM1)的克隆和表达分析

LIM结构域蛋白是一个重要的发育调控因子,参与基因转录,细胞骨架建成和信号传导等许多发育调控过程,胞质骨架是形成和稳定细胞形态以及传递物质,能量和信息的重要成分。为研究棉花纤维细胞发育过程中胞质骨架的形成和作用机理,通过棉花纤维EST序列整合,从陆地棉徐州142胚珠（含纤维）中扩增并克隆出棉花LIM结构域基因的编码区段。该棉花LIM结构域基因（GhL1M1)长848bp,包含一个570bp的开放阅读框,推导的氨基酸序列（189个氨基酸）与拟南芥,烟草和向日葵的LIM结构域蛋白有极高的同源性,而且两个LIM结构域完整,RT-PCR和Northerm杂交分析表明,该基因（GhL1M1）在陆地棉的根,茎尖,上胚轴,叶片,花蕾,花药,胚珠和不同发育时期的陆地棉纤维（4DPA、12DPA、18DPA）以及海岛棉纤维（18DPA）和中棉纤维（12DPA）中均有表达,但GhL1M1基因在茎尖,纤维和有纤维的胚珠中表达量更高,因此GhL1M1基因应与棉花纤维发育有密切关系。     

水分胁迫对小麦幼苗及悬浮培养细胞中诱导蛋白表达的影响

丰抗8号小麦幼苗及成熟胚诱导的悬浮培养细胞在水分胁迫（－1．0MPa PEG6000）下,可溶性蛋白含量与蛋白组分变化有差异,幼苗可溶性蛋白含量高于对照,并随生长的延长呈降低趋势;悬浮培养细胞可溶性蛋白含量低于对照,且略有上升;复水后均可恢复对照水平,SDS－PAGE电泳及薄层扫描分析结果表明,幼苗受水分胁迫诱导,出现44．2kD蛋白亚基,该蛋白亚基含量可随胁迫时间延长上升,复水后消失,在正常条件下悬浮培养细胞中含有44．2kD蛋白亚基表达,轻度胁迫处理时,该蛋白亚基含量上升,对悬浮培养细胞进行水分胁迫,该蛋白则表现下降趋势,复水后又可上升。     

东北虎促卵泡激素和促黄体激素基因的克隆及其序列分析

本研究首次从东北虎（Panthea tigris altaica)脑垂体提取总RNA,利用RT－PCR技术扩增出东北虎垂体促性腺激素α亚基,促卵泡激素（FSH）β亚基和促黄体激素（LH）β亚基的编码区序列,并进行克隆,测序和比较分析。结果表明,其α亚基,FSHβ亚基,LHβ亚基基因的开放阅读框分别为363bp,390bp和420bp,分别编码120,129和142氨基酸的前体蛋白。与已发表的人,牛,绵羊,猪,大鼠,小鼠等物种相应序列比较,无论在核苷酸水平,还是在氨基酸水平都显示出较高的同源性（64．7％－96．6％）,其中与猪的同源性最高（86％－96．6％）。东北虎的基因序列还具有其明显的特异性,首次发现LHβ亚基cDNA编码的前体蛋白在信号肽部分比其它物种相应序列多一个亮氨酸残基（Leu)。     

NADH-细胞色素 b5 还原酶在甲状腺过氧化氢生物合成中的作用

应用高香草酸荧光分析技术及NADH－高铁氰化钾还原酶法,对正常和Graves病甲状腺过氧化氢（H2O2）和NADH－细胞色素b5还原酶（b5R)进行测定,发现Graves病甲状腺b5R活性和H2O2水平均明显高于正常,而H2O2酶活性在Graves病和正常甲状腺间无显著差异。加b5R抑制剂对氯汞苯甲酸抑制b5R活性,Graves病和正常甲状腺b5R活性降低近85％,同时H2O2降低近50％,蛋白结合碘形成减少近52％。b5R活性和H2O2水平两者呈显著正相关关系。以上结果表明,b5R参与甲状腺内H2O2的生物合成,是甲状腺内产生H2O2的重要酶系。     

Coupling factor F1 ATPase with defective beta subunit from a mutant of Escherichia coli

The defective coupling factor F1 ATPase from a mutant strain (KF11) of Escherichia coli was purified to a practically homogeneous form. The final specific activity of Mg2+-ATPase was 6-9 units/mg protein, which is about 10-15 times lower than that of F1 ATPase from the wild-type strain. The mutant F1 had a ratio of Ca2+-ATPase to Mg2+-ATPase of about 3.5, whereas the wild-type F1 had ratio of about 0.8. The mutant F1 was more unstable than wild-type F1: on storage at -80 degrees C for 2 weeks, about 80% of its activity (dependent on Ca2+ or Mg2+) was lost, whereas none of the activity of the wild-type F1 was lost. The following results indicate that the mutation is in the beta subunit. (i) High Mg2+-ATPase activity (about 20 units/mg protein) was reconstituted when the beta subunit from wild type F1 was added to dissociated mutant F1 and the mixture was dialyzed against buffer containing ATP and Mg2+. (ii) Low ATPase activity having the same ratio of Ca2+-ATPase to Mg2+-ATPase as the mutant F1 was reconstituted when a mixture of the beta subunit from the mutant F1 and the alpha and gamma subunits from wild-type F1 was dialyzed against the same buffer. (iii) Tryptic peptide analysis of the beta subunit of the mutant showed a difference in a single peptide compared with the wild-type strain.     

Temperature-sensitive Escherichia coli mutant with an altered initiation codon of the uncG gene for the H+-ATPase gamma subunit.

A mutant of Escherichia coli showing temperature-sensitive growth on succinate was isolated, and its mutation in the initiation codon (ATG to ATA) of the uncG gene (coding for the gamma subunit of H+-ATPase F0F1) was identified. This strain could grow on succinate as the sole carbon source at 25 and 30 degrees C, but not at 37 or 42 degrees C. When this strain was grown at 25 degrees C on succinate or glycerol, its membranes had about 15% of the ATPase activity of wild-type membranes, whereas when it was grown at 42 degrees C, its membranes had about 2% of the wild-type ATPase activity. Membranes of the mutant grown at 25 or 42 degrees C could bind F1 functionally, resulting in about 40% of the specific activity of wild-type membranes. The gamma subunit was identified in an EDTA extract of membranes of the mutant grown at 25 degrees C, but was barely detectable in the same amount of extract from the mutant grown at 42 degrees C. These results indicate that initiation of protein synthesis from the AUA codon is temperature sensitive and that the gamma subunit is essential for assembly of F1 in vivo as shown by in vitro reconstitution experiments (S. D. Dunn and M. Futai, J. Biol. Chem. 255:113-118, 1980).     

A PP2A active site mutant impedes growth and causes misregulation of native catalytic subunit expression

Activity of protein phosphatase 2A (PP2A) is tightly regulated and performs a diverse repertoire of cellular functions. Previously we isolated a dominant-negative active site mutant of the PP2A catalytic (C) subunit using a yeast complementation assay. We have established stable fibroblastic cell lines expressing epitope-tagged versions of the wild-type and H118N mutant C subunits and have used these cells to investigate mechanisms that regulate PP2A activity. Cells expressing the mutant C subunit exhibit a decreased growth rate and a prolonged G1 cell cycle phase. The mutant protein is enzymatically inactive, but extracts made from cells expressing the H118N C subunit show normal levels of total PP2A activity in vitro. The H118N mutant shows reduced binding to the regulatory A subunit, but binds normally to the alpha4 protein, a non-canonical regulator of PP2A. Expression of the H118N mutant interferes with the normal control of C subunit abundance, causing accumulation of the endogenous wild-type protein as well as the mutant transgene product. Our results indicate that the H118N mutant isoform retards C subunit turnover and suggest that PP2A C subunit turnover may be important for normal cell cycle progression.     

Characterization of cyclic AMP-requiring yeast mutants altered in the catalytic subunit of protein kinase

The cyr2 mutant of yeast, Saccharomyces cerevisiae, required cAMP for growth at 35 degrees C. The cyr2 mutation was suppressed by the bcy1 mutation which resulted in deficiency of the regulatory subunit of cAMP-dependent protein kinase. The DEAE-Sephacel elution profile of cyr2 cAMP-dependent protein kinase was markedly different from that observed for the wild-type enzyme. With histone as substrate, the cAMP-dependent protein kinase activity of cyr2 cells showed 100-fold greater Ka value for activation by cAMP at 35 degrees C than that of the wild-type cells, while the Kd value for cAMP of the mutant enzyme was not altered. The electrophoretic character, molecular weight, and pI value of the regulatory subunit of the mutant enzyme were the same as those of the wild-type enzyme. When histone, trehalase, and glutamate dehydrogenase were used as substrate, the free catalytic subunit of the mutant enzyme showed a markedly decreased affinity for ATP and was more thermolabile compared to that of the wild-type enzyme. The results indicated that the cyr2 phenotype was produced by a structural mutation in the cyr2 gene coding for the catalytic subunit of cAMP-dependent protein kinase in yeast.     

Cytochrome b is necessary for the assembly of subunit VII in the cytochrome b-c1 complex of yeast mitochondria

The synthesis and assembly of subunit VII, the Q-binding protein of the cytochrome b-c1 complex, into the inner mitochondrial membrane has been compared in wild-type yeast cells and in a mutant cell line lacking cytochrome b. Both immunoblotting and immunoprecipitation analysis with specific antiserum against subunit VII indicated that this subunit is not detectable in the mutant as compared to the wild-type mitochondria. However, labeling in vivo of the cytochrome b deficient yeast cells in the presence of the uncoupler carbonyl cyanide m-chlorophenylhydrazone clearly demonstrated that subunit VII was synthesized in the mutant cells to the same extent as in the wild-type cells. Incubation of subunit VII, synthesized in vitro in a reticulocyte lysate programmed with yeast RNA, with mitochondria isolated from both wild-type and cytochrome b deficient yeast cells revealed that the subunit VII was transported into the wild-type mitochondria into a compartment where it was resistant to digestion by exogenous proteinase K. By contrast, subunit VII was bound in lowered amounts to the cytochrome b deficient mitochondria where it remained sensitive to digestion by exogenous proteinase K, suggesting that the import of subunit VII may be impaired due to the lack of cytochrome b. Furthermore, subunit VII was synthesized both in vivo and in vitro with the same molecular mass as the mature form of this protein.     

Decreased catalytic subunit mRNA levels and altered catalytic subunit mRNA structure in a cAMP-resistant Chinese hamster ovary cell line.

The mechanisms responsible for decreased levels of cAMP-dependent protein kinase activity in a mutant Chinese hamster ovary cell line have been examined. The cAMP-resistant Chinese hamster ovary 10260 cell line was found to possess only 20% of the cAMP-dependent protein kinase activity found in wild-type cells. The presence of decreased concentrations of the catalytic subunit in these cells was confirmed through binding studies using a radiolabeled, heat-stable inhibitor of the kinase. Cloned Chinese hamster ovary catalytic subunit cDNAs were isolated, characterized, and used as hybridization probes to examine the relative concentrations of catalytic subunit mRNAs in the wild-type and 10260 cell lines. A 40-50% decrease in the concentration of the mRNA for the C alpha isozyme of the catalytic subunit was observed in 10260 cells, as compared with wild-type. This decrease in catalytic subunit mRNA concentration probably accounts for a portion of the decreased kinase activity in the mutant cells. Further analysis of C alpha mRNA by polymerase chain reaction confirmed the decreased expression of C alpha mRNA in 10260 cells and further demonstrated the presence of two different species of C alpha mRNA in the 10260 cells. One species of C alpha cDNAs was indistinguishable from the wild-type cDNA, but the other species was shorter. Nucleotide sequence analysis of the amplified cDNAs led to the identification of a 191-base pair deletion in the shorter cDNA. Gene transfer studies using wild-type and 10260 C alpha cDNAs demonstrated that the longer cDNA from the 10260 cells produced wild-type activity, but the shorter cDNA was inactive. These studies suggest that at least two alterations in gene expression are responsible for decreased cAMP-dependent protein kinase activity in the 10260 cell line. One alteration results in an approximately 2-fold decrease in the concentrations of C alpha mRNA in the cells. The other change produces two species of C alpha mRNA; one of the C alpha mRNAs does not encode an active kinase.     

Recent developments on structural and functional aspects of the F1 sector of H+-linked ATPases

This review concerns the catalytic sector of F1 factor of the H+-dependent ATPases in mitochondria (MF1), bacteria (BF1) and chloroplasts (CF1). The three types of F1 have many similarities with respect to the structural parameters, subunit composition and catalytic mechanism. An alpha 3 beta 3 gamma delta epsilon stoichiometry is now accepted for MF1 and BF1; the alpha 2 beta 2 gamma 2 delta 2 epsilon 2 stoichiometry for CF1 remains as matter of debate. The major subunits alpha, beta and gamma are equivalent in MF1, BF1 and CF1; this is not the case for the minor subunits delta and epsilon. The delta subunit of MF1 corresponds to the epsilon subunit of BF1 and CF1, whereas the mitochondrial subunit equivalent to the delta subunit of BF1 and CF1 is probably the oligomycin sensitivity conferring protein (OSCP). The alpha beta gamma assembly is endowed with ATPase activity, beta being considered as the catalytic subunit and gamma as a proton gate. On the other hand, the delta and epsilon subunits of BF1 and CF1 most probably act as links between the F1 and F0 sectors of the ATPase complex. The natural mitochondrial ATPase inhibitor, which is a separate protein loosely attached to MF1, could have its counterpart in the epsilon subunit of BF1 and CF1. The generally accepted view that the catalytic subunit in the different F1 species is beta comes from a number of approaches, including chemical modification, specific photolabeling and, in the case of BF1, use of mutants. The alpha subunit also plays a central role in catalysis, since structural alteration of alpha by chemical modification or mutation results in loss of activity of the whole molecule of F1. The notion that the proton motive force generated by respiration is required for conformational changes of the F1 sector of the H+-ATPase complex has gained acceptance. During the course of ATP synthesis, conversion of bound ADP and Pi into bound ATP probably requires little energy input; only the release of the F1-bound ATP would consume energy. ADP and Pi most likely bind at one catalytic site of F1, while ATP is released at another site. This mechanism, which underlines the alternating cooperativity of subunits in F1, is supported by kinetic data and also by the demonstration of partial site reactivity in inactivation experiments performed with selective chemical modifiers. One obvious advantage of the alternating site mechanism is that the released ATP cannot bind to its original site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional dissection of two Arabidopsis PsbO proteins: PsbO1 and PsbO2

PsbO protein is an extrinsic subunit of photosystem II (PSII) and has been proposed to play a central role in stabilization of the catalytic manganese cluster. Arabidopsis thaliana has two psbO genes that express two PsbO proteins; PsbO1 and PsbO2. We reported previously that a mutant plant that lacked PsbO1 (psbo1) showed considerable growth retardation despite the presence of PsbO2 [Murakami, R., Ifuku, K., Takabayashi, A., Shikanai, T., Endo, T., and Sato, F. (2002) FEBS Lett523, 138-142]. In the present study, we characterized the functional differences between PsbO1 and PsbO2. We found that PsbO1 is the major isoform in the wild-type, and the amount of PsbO2 in psbo1 was significantly less than the total amount of PsbO in the wild-type. The amount of PsbO as well as the efficiency of PSII in psbo1 increased as the plants grew; howeVER, it neVER reached the total PsbO level observed in the wild-type, suggesting that the poor activity of PSII in psbo1 was caused by a shortage of PsbO. In addition, an in vitro reconstitution experiment using recombinant PsbOs and urea-washed PSII particles showed that oxygen evolution was better recoVERed by PsbO1 than by PsbO2. Further analysis using chimeric and mutated PsbOs suggested that the amino acid changes Val186-->Ser, Leu246-->Ile, and Val204-->Ile could explain the functional difference between the two PsbOs. Therefore we concluded that both the lower expression level and the inferior functionality of PsbO2 are responsible for the phenotype observed in psbo1.     

Biochemical events essential to the recombination activity of Escherichia coli RecA protein. II. Co-dominant effects of RecA142 protein on wild-type RecA protein function

In the accompanying paper, RecA142 protein was found to be completely defective in DNA heteroduplex formation. Here, we show that RecA142 protein not only is defective in this activity but also is inhibitory for certain activities of wild-type RecA protein. Under appropriate conditions, RecA142 protein substantially inhibits the DNA strand exchange reaction catalyzed by wild-type RecA protein; at equimolar concentrations of each protein, formation of full-length gapped duplex DNA product molecules is less than 7% of the amount produced by wild-type protein alone. Inhibition by RecA142 protein is also evident in S1 nuclease assays of DNA heteroduplex formation, although the extent of inhibition is less than is observed for the complete DNA strand exchange process; at equimolar concentrations of wild-type and mutant proteins, the extent of DNA heteroduplex formation is 36% of the wild-type protein level. This difference implies that RecA142 protein prevents, at minimum, the branch migration normally observed during DNA strand exchange. RecA142 protein does not inhibit either the single-strand (ss) DNA-dependent ATPase activity or the coaggregation activities of wild-type RecA protein. This suggests that these reactions are not responsible for the inhibition of wild-type protein DNA strand exchange activity by RecA142 protein. However, under conditions where RecA142 protein inhibits DNA strand exchange activity, RecA142 protein renders the M13 ssDNA-dependent ATPase activity of wild-type protein sensitive to inhibition by single-strand DNA-binding protein, and it inhibits the double-strand DNA-dependent ATPase activity of wild-type RecA protein. These results imply that these two activities are important components of the overall DNA strand exchange process. These experiments also demonstrate the applicability of using defective mutant RecA proteins as specific codominant inhibitors of wild-type protein activities in vitro and should be of general utility for mechanistic analysis of RecA protein function both in vitro and in vivo.     

Mutations in three of the putative transmembrane helices of subunit a of the Escherichia coli F1F0-ATPase disrupt ATP-driven proton translocation

Three missense mutants in subunit a of the Escherichia coli F1F0-ATPase were isolated and characterized after hydroxylamine mutagenesis of a plasmid carrying the uncB (subunit a) gene. The mutations resulted in Asp119----His, Ser152----Phe, or Gly197----Arg substitutions in subunit a. Function was not completely abolished by any of the mutations. The F0 membrane sector was assembled in all three cases as judged by restoration of dicyclohexylcarbodiimide sensitivity to the F1F0-ATPase. The H+ translocation capacity of F0 was reduced in all three mutants. ATP-driven H+-translocation was also reduced, with the response in the Gly197----Arg mutant being almost nil and that in the Asp119----His and Ser152----Phe mutants less severely affected. The substituted residues are predicted to lie in the second, third, and fourth transmembrane helices suggested in most models for subunit a. The Gly197----Arg mutation lies in a very conserved region of the protein and the substitution may disrupt a structure that is critical to function. The Asp119----His and Ser152----Phe mutations also lie in areas with sequence conservation. A further analysis of randomly generated mutants may provide more information on regions of the protein that are crucial to function. Heterodiploid transformants, carrying plasmids with either the wild-type uncB gene or mutant uncB genes in an uncB (Trp231----stop) background, were characterized biochemically. The truncated subunit a was not detected in membranes of the background strain by Western blotting, and the uncB+ plasmid complemented strain showed normal biochemistry. The uncB mutant genes were shown to cause equivalent defects in either the heterodiploid background configuration, or after incorporation into an otherwise wild-type unc operon. The subunit a (Trp231----stop) background strain was shown to bind F1-ATPase nearly normally despite lacking subunit a in its membrane.