水稻EPSP合酶cDNA克隆、序列分析及其拷贝数测定

根据本室分离的水稻EPSP合酶基因的基因组序列设计一对引物,利用RT-PCR方法首次从水稻(Oryza sativa L. subsp. indica)叶片的RNA中扩增获得了水稻编码EPSP合酶的全长为1 585 bp的cDNA片段,它含有一个完整的开放读码框,编码511个氨基酸,包括444个氨基酸组成的成熟肽序列以及N端的67个氨基酸组成的叶绿体转运肽序列.成熟肽氨基酸序列对比表明,除真菌来源的EPSP合酶变异较大外,其他来源的EPSP合酶同源性较高,均在51%以上.而叶绿体转运肽氨基酸序列同源性较低.Southern杂交表明水稻EPSP合酶基因在水稻基因组中以单拷贝形式存在.RT-PCR分析表明,水稻EPSP合酶基因在根、未成熟种子和叶片中均有转录表达,在叶片中表达量最高.     

水稻EPSP合酶cDNA克隆、序列分析及其拷贝数测定

根据本室分离的水稻EPSP合酶基因的基因组序列设计一对引物 ,利用RT_PCR方法首次从水稻 (Oryzasati vaL .subsp .indica)叶片的RNA中扩增获得了水稻编码EPSP合酶的全长为 15 85bp的cDNA片段 ,它含有一个完整的开放读码框 ,编码 5 11个氨基酸 ,包括 44 4个氨基酸组成的成熟肽序列以及N端的 6 7个氨基酸组成的叶绿体转运肽序列。成熟肽氨基酸序列对比表明 ,除真菌来源的EPSP合酶变异较大外 ,其他来源的EPSP合酶同源性较高 ,均在 5 1%以上。而叶绿体转运肽氨基酸序列同源性较低。Southern杂交表明水稻EPSP合酶基因在水稻基因组中以单拷贝形式存在。RT_PCR分析表明 ,水稻EPSP合酶基因在根、未成熟种子和叶片中均有转录表达 ,在叶片中表达量最高     

大肠杆菌AroG蛋白F209S突变体对苯丙氨酸反馈抑制作用的影响(英文)

在大肠杆菌中 ,80 %的 3 脱氧 D 阿拉伯 庚酮 7 磷酸 (3 deoxy D arabino heptulosonate 7 phosphate,DAHP)合酶由aroG基因编码。分别以大肠杆菌K1 2及其抗苯丙氨酸类似物的突变体总DNA为模板 ,以PCR方法扩增得到aroG基因及其突变体。基因测序结果表明抗苯丙氨酸类似物的突变体 ,其aroG基因核苷酸 62 5位发生了T→C的点突变 ,从而使AroG蛋白的 2 0 9位氨基酸由Ser取代了Phe。aroG基因及其突变体克隆到表达质粒 pTrc99A上 ,在大肠杆菌JM 1 0 5中进行表达 ,表达产物的SDS PAGE上可以看到分子量相当明显的条带 ;菌体粗提物中DAHP合酶的活性提高了 1 .8倍 ;酶活抗性检测表明AroG蛋白突变体在一定程度上解除了苯丙氨酸的反馈抑制作用 ;与含K1 2aroG基因的JM1 0 5细胞相比 ,含aroG基因突变体的JM1 0 5细胞可以在含高浓度苯丙氨酸类似物的培养基上生长。     

中国红豆杉紫杉烯合酶cDNA的分离、表达和鉴定

紫杉烯合酶是一种二萜环化酶,催化牛儿基牛儿基焦磷酸形成紫杉醇生物合成过程中的中间体紫杉烯.利用PCR扩增同源探针筛选cDNA文库,克隆了一个编码中国红豆杉(Taxus chinensis (Pilg.) Rehd.)紫杉烯合酶3′端的2 151 bp的cDNA片段,也通过PCR扩增得到了该基因5′端的611 bp的cDNA片段,将这两个cDNA片段拼接在一起,得到长2 712 bp的cDNA片段,具有一个2 586个碱基的开放阅读框架(ORF),编码包括质体转移肽在内的共862个氨基酸残基;该酶与太平洋红豆杉紫杉烯合酶有97%的同源性(identity),与其他植物萜类环化酶也有较高的同源性.利用融合表达载体pET-32a在大肠杆菌BL21trxB中表达,所表达的融合蛋白以包含体形式存在.包含体经过变性、复性和再折叠,利用His残基亲和凝胶柱层析得到融合的紫杉烯合酶.用毛细管气相色谱-质谱联用对酶促反应产物进行分析,结果表明,融合的紫杉烯合酶能催化产生4(5),11(12)-紫杉烯.     

马尾松毛虫质型多角体病毒多角体蛋白基因的cDNA克隆及序列分析

通过对马尾松毛虫质型多角体病毒的增殖、纯化,获得一株单一类型的质型多角体病毒.提纯的病毒粒子经SDS-酚抽提,琼脂糖凝胶电泳分离基因组dsRNDA,回收纯化第十片段S10.S10经DMSO变性,逆转录合成cDNA第一链,PCR扩增后,克隆在pGEM-T载体上.对重组子进行限制性内切酶分析及序列测定,结果表明,克隆片段全长763bp,起始密码AUG位于3～5残基,终止密码UGA位于747～749残基.推测DpGPV多角体蛋白基因编码248个氨基酸的多肽,分子量28kD.和家蚕质型多角体病毒(BmCPV)多角体蛋白基因相比较,核苷酸和编码氨基酸序列同源性分别为89.3%和97.6%.     

甘薯贮藏蛋白(sporam in)A基因编码区克隆及序列同源性分析

采用 PCR技术 ,从我国广泛栽培甘薯品种南薯 88基因组中扩增和克隆到甘薯贮藏蛋白 A基因编码区段 ,并测定了其全部核苷酸序列 .该编码区长 65 7bp,编码一个长 2 1 9个氨基酸残基的蛋白质 ,其中信号肽长 37个氨基酸残基 ,成熟蛋白质长 1 82个氨基酸残基 ,其分子量为 2 0 k D.将该片段的核苷酸序列与已登录在 Gen Bank中的另外 6个甘薯贮藏蛋白 A基因编码区序列进行比较 ,发现其同源性高达 90 % ,说明甘薯贮藏蛋白 A基因编码区序列具有高度保守性 .虽然 7个基因编码区的核苷酸总变异为 1 0 % ,但在每两个基因之间的比较则表明其核苷酸的变异范围小于 7% .     

水稻EPSP合酶基因的克隆、结构分析和定位

5-烯醇丙酮莽草酸-3-磷酸(EPSP)合酶是芳香族氨基酸合成途径中的一个关键酶, 该基因在植物抗除草剂基因工程中具有重要的应用价值. 根据水稻EPSP合酶基因的EST序列设计探针, 在水稻TAC基因组文库中筛选到16个阳性克隆. 对阳性克隆E11进行亚克隆, 由此获得了由3661核苷酸组成的水稻EPSP合酶基因全序列. 序列分析和同源性比较揭示, 该基因由8个外显子和7个内含子组成. 以窄叶青8号/京系17组合构建的DH群体和分子图谱将水稻EPSP合酶基因定位于水稻第6条染色体的上端.     

大肠杆菌tyrR基因剔除及其对苯丙氨酸生物合成的影响

TyrR是大肠杆菌芳香族氨基酸生物合成和运输途径中的一种全局性调控蛋白质。采用双交换同源重组的方法定位突变大肠杆菌染色体tyrR基因 ,在该基因中插入带有卡那霉素抗性基因的DNA片段 ,使之失活 ,实现基因剔除。经PCR、DNA测序、lacZ报告基因等多种方法证实了基因剔除的可靠性。tyrR基因剔除后 ,大肠杆菌芳香族氨基酸生物合成中受TyrR蛋白调控的关键酶的酶活力有所提高 :3 脱氧 2 阿拉伯庚酮糖 7 磷酸合成酶(DAHPS ,由aroG编码 )酶活力提高了 1.0 8倍 ,转氨酶 (AT ,由tyrB编码 )酶活力提高了 2 .70倍 ;突变菌株发酵生产苯丙氨酸的能力提高了 1.5 9倍 ;同时 ,与芳香族氨基酸运输相关的通透酶基因aroP(P)的阻遏被解除 ,细胞运输芳香族氨基酸的能力提高了 70 .2 %。     

D-泛解酸内酯水解酶的定向进化

易错PCR结合DNA改组方法向D-泛解酸内酯水解酶基因中引入突变,并构建突变体库。利用酶的催化特点和产物特性建立了基于平板初筛和高效液相复筛的两步法D-泛解酸内酯水解酶活性筛选系统。用该筛选系统以酶活力和pH稳定性为指标对突变体库进行筛选,最终获得一株酶活力高且在低pH条件下稳定性好的突变体Mut E-861。该突变体的酶活力是野生型酶的5.5倍。对突变体和野生型酶在pH 6.0和pH 5.0条件下的残余酶活进行对比,在这两种pH条件下,突变体酶的酶活残留分别为75%和50%,而野生型酶只能保持原来的40%和20%。通过软件对突变体Mut E-861酶基因和野生型酶基因进行分析对比,发现突变体Mut E-861酶基因发生了三处点突变,其中突变使两处氨基酸取代,另一处为沉默突变,未引起氨基酸的变化。     

环酰亚胺水解酶C末端区为该酶活性所必需

 为了研究一个新环酰亚胺水解酶（CIH）C端区残基对酶分子构象及酶活性的影响,设计了C末端缺失1～4个氨基酸残基以及C 末端2个Lys替代为2个Glu或2个Leu的突变酶,以野生型酶基因重组质粒pE-cih₂₉₃为模板,在相应引物存在下,通过PCR扩增获得突变的CIH基因片段.经克隆、表达与纯化,得到不同的突变酶蛋白.酶活性测定、荧光光谱与CD谱分析表明,随着C 末端缺失残基的增多,酶活性丧失也越来越多,但酶分子的聚合状态未发生变化;当CIH的C末端2个Lys替代为2个Glu时,酶活性及分子结构变化均不明显,但当替代为2个Leu时,酶活性丧失殆尽,分子结构变得松散而不再保持寡聚态.pH及热稳定性实验也表明,酶的稳定性与其分子的完整性密切相关.结果证实,CIH的C末端电荷残基对该酶活性与分子状态具有重要作用.     

Improvement of glyphosate resistance through concurrent mutations in three amino acids of the Ochrobactrum 5-enopyruvylshikimate-3-phosphate synthase

A mutant of 5-enopyruvylshikimate-3-phosphate synthase from Ochrobactrum anthropi was identified after four rounds of DNA shuffling and screening. Its ability to restore the growth of the mutant ER2799 cell on an M9 minimal medium containing 300 mM glyphosate led to its identification. The mutant had mutations in seven amino acids: E145G, N163H, N267S, P318R, M377V, M425T, and P438L. Among these mutations, N267S, P318R, and M425T have never been previously reported as important residues for glyphosate resistance. However, in the present study they were found by site-directed mutagenesis to collectively contribute to the improvement of glyphosate tolerance. Kinetic analyses of these three mutants demonstrated that the effectiveness of these three individual amino acid alterations on glyphosate tolerance was in the order P318R > M425T > N267S. The results of the kinetic analyses combined with a three-dimensional structure modeling of the location of P318R and M425T demonstrate that the lower hemisphere's upper surface is possibly another important region for glyphosate resistance. Furthermore, the transgenic Arabidopsis was obtained to confirm the potential of the mutant in developing glyphosate-resistant crops.     

TANGLE: two-level support vector regression approach for protein backbone torsion angle prediction from primary sequences

Protein backbone torsion angles (Phi) and (Psi) involve two rotation angles rotating around the C(α)-N bond (Phi) and the C(α)-C bond (Psi). Due to the planarity of the linked rigid peptide bonds, these two angles can essentially determine the backbone geometry of proteins. Accordingly, the accurate prediction of protein backbone torsion angle from sequence information can assist the prediction of protein structures. In this study, we develop a new approach called TANGLE (Torsion ANGLE predictor) to predict the protein backbone torsion angles from amino acid sequences. TANGLE uses a two-level support vector regression approach to perform real-value torsion angle prediction using a variety of features derived from amino acid sequences, including the evolutionary profiles in the form of position-specific scoring matrices, predicted secondary structure, solvent accessibility and natively disordered region as well as other global sequence features. When evaluated based on a large benchmark dataset of 1,526 non-homologous proteins, the mean absolute errors (MAEs) of the Phi and Psi angle prediction are 27.8° and 44.6°, respectively, which are 1% and 3% respectively lower than that using one of the state-of-the-art prediction tools ANGLOR. Moreover, the prediction of TANGLE is significantly better than a random predictor that was built on the amino acid-specific basis, with the p-value<1.46e-147 and 7.97e-150, respectively by the Wilcoxon signed rank test. As a complementary approach to the current torsion angle prediction algorithms, TANGLE should prove useful in predicting protein structural properties and assisting protein fold recognition by applying the predicted torsion angles as useful restraints. TANGLE is freely accessible at http://sunflower.kuicr.kyoto-u.ac.jp/~sjn/TANGLE/.     

Amino acid similarity coefficients for protein modeling and sequence alignment derived from main-chain folding angles

A set of "similarity-parameters" was calculated that reflects the influence of the proteinogenic amino acids on the structure of the protein backbone. The parameters were derived from a detailed analysis of the amino acid specific main-chain torsion angle distributions as they are found in proteins (highly resolved protein structures from the Brookhaven Protein Data Bank). The purpose of these parameters is threefold: (1) they should help in estimating the structural effect of an amino acid substitution during the design of new mutants in protein-engineering; (2) in modeling by homology they should mark places in the protein where changes in the folding are expected; and (3) they should form a scoring matrix in protein sequence alignment superior to identity scoring. The usability of the "structure derived correlation matrix (SCM)" for these purposes is assessed and demonstrated for some examples in the paper.     

Influence of non-bonded parameters on the quality of NMR structures: A new force field for NMR structure calculation

The effects of different non-bonded parameters of force fields for NMR structure calculation on the quality of the resulting NMR solution structures were investigated using Interleukin 4 as a model system. NMR structure ensembles were calculated with an ab initio protocol using torsion angle dynamics. The calculations were repeated with five different non-bonded energy functions and parameters. The resulting ensembles were compared with the available X-ray structures, and their quality was assessed with common structure validation programs. In addition, the impact of torsion angle restraints and dihedral energy terms for the sidechains and the backbone was studied. The further improvement of the quality by refinement in explicit solvent was demonstrated. The optimal parameters, including those necessary for water refinement, are available in the new version of the PARALLHDG force field.     

The influence of stereospecific assignments on the determination of three-dimensional structures of proteins by nuclear magnetic resonance spectroscopy. Application to the sea anemone protein BDS-I

The influence of the stereospecific assignments of beta-methylene protons and the classification of chi 1 torsion angles on the definition of the three-dimensional structures of proteins determined from NMR data is investigated using the sea anemone protein BDS-I (43 residues) as a model system. Two sets of structures are computed. The first set comprises 42 converged structures (denoted STEREO structures) calculated on the basis of the complete list of restraints derived from the NMR data, consisting of 489 interproton and 24 hydrogen bonding distance restraints, supplemented by 23 phi backbone and 21 chi 1 side chain torsion angle restraints. The second set comprises 31 converged structures (denoted NOSTEREO structures) calculated from a reduced data set in which those restraints arising from stereospecific assignments, and the corresponding chi 1 torsion angle restraints, are explicitly omitted. The results show that the inclusion of the stereospecific restraints leads to a significant improvement in the definition of the structure of BDS-I, both with respect to the backbone and the detailed arrangement of the side chains. Average atomic rms differences between the individual structures and the mean structures for the backbone atoms are 0.67 +/- 0.12 A and 0.93 +/- 0.16 A for the STEREO and NOSTEREO structures, respectively; the corresponding values for all atoms are 0.90 +/- 0.17 A and 1.17 +/- 0.17 A, respectively. In addition, while the overall fold remains unchanged, there is a small but significant atomic displacement between the two sets of structures.     

Biochemical bases for a widespread tolerance of cyanobacteria to the phosphonate herbicide glyphosate

Possible non-target effects of the widely used, non-selective herbicide glyphosate were examined in six cyanobacterial strains, and the basis of their resistance was investigated. All cyanobacteria showed a remarkable tolerance to the herbicide up to millimolar levels. Two of them were found to possess an insensitive form of glyphosate target, the shikimate pathway enzyme 5-enol-pyruvyl-shikimate-3-phosphate synthase. Four strains were able to use the phosphonate as the only phosphorus source. Low uptake rates were measured only under phosphorus deprivation. Experimental evidence for glyphosate metabolism was also obtained in strains apparently unable to use the phosphonate. Results suggest that various mechanisms may concur in providing cyanobacterial strains with herbicide tolerance. The data also account for their widespread ability to metabolize the phosphonate. However, such a capability seems limited by low cell permeability to glyphosate, and is rapidly repressed when inorganic phosphate is available.     

The structure and dynamics in solution of Cu(I) pseudoazurin from Paracoccus pantotrophus

The solution structure and backbone dynamics of Cu(I) pseudoazurin, a 123 amino acid electron transfer protein from Paracoccus pantotrophus, have been determined using NMR methods. The structure was calculated to high precision, with a backbone RMS deviation for secondary structure elements of 0.35+/-0.06 A, using 1,498 distance and 55 torsion angle constraints. The protein has a double-wound Greek-key fold with two alpha-helices toward its C-terminus, similar to that of its oxidized counterpart determined by X-ray crystallography. Comparison of the Cu(I) solution structure with the X-ray structure of the Cu(II) protein shows only small differences in the positions of some of the secondary structure elements. Order parameters S2, measured for amide nitrogens, indicate that the backbone of the protein is rigid on the picosecond to nanosecond timescale.     

抗除草剂草甘膦EPSPs基因在小麦中的转化

通过基因枪法,用抗除草剂草甘膦的ＥＰＳＰｓ基因转化小麦京花１号的幼穗约１０００个,及幼胚约８００个,经草甘膦选择后分别获得３８株和４株再生植株。这些再生植株经ＰＣＲ和（或）Ｓｏｕｔｈｅｒｎ杂交证明,其中有部分再生植株的基因组中稳定整合了外源ＥＰＳＰｓ基因,并且转化体中部分是可育的。首次用实验证明,抗除草剂草甘膦的ＥＰＳＰｓ基因作为单子叶禾谷类作物小麦基因转化的选择标记是行之有效的。