neo Trichosanthin及其突变体Y70A neo Trichosanthin的晶体结构研究

天花粉蛋白（Ｔｒｉｃｈｏｓａｎｔｈｉｎ,ＴＣＳ）的一个亚型,ｎｅｏＴｒｉｃｈｏｓａｎｔｈｉｎ（ｎ－ＴＣＳ）,及其突变体Ｙ７０Ａｎ－ＴＣＳ被克隆和表达为重组蛋白。用悬滴汽相扩散法得到ｎ－ＴＣＳ和Ｙ７０Ａｎ－ＴＣＳ的晶体。在ＭａｒＲｅｓｅａｒｃｈ面探测器系统上分别收集了０．２０ｎｍ和０．２０５ｎｍ分辨率的Ｘ射线衍射数据。用同晶差值傅立叶法解析了结构。最后晶体学Ｒ因子分别为０．１８３和０．１８４。键长的     

天花粉蛋白Glu189在N-糖苷酶活性中的作用

培养了(E160A,E189A)TCS(天花粉蛋白)的单晶。用浸泡法得到了(E160A,E189A)TCS与Ade复合物的晶体。在MarResearch面探测器系统上分别收集了均为0.20nm分辨率的X射线衍射数据,数据处理用MarScale程序系统完成。用同晶差值Fourier法解析了(E160A,E189A)TCS和(E160A,E189A)TCS-Ade的晶体结构,结构修正利用X-PLOR程序.修正结果,晶体学R因子分别为0.180、0.184,键长和键角的RMS偏差分别为0.0012nm和2.566°、0.0012nm和2.622°。在(E160A,E189A)TCS-Ade中,Ade仍结合在N-糖苷酶活性口袋之中,它夹在Tyr70和Tyr111两个侧链环之间,与Tyr70环近乎平行。这一结果表明:TCS中的Glu160和Glu189同时突变成Ala,仍能与AMP发生N-糖苷酶反应.前文已经证明在(E160A)TCS中Glu189没有援救作用。目前,没有发现Glu189对TCS与AMP的直接作用,但Glu189与其它残基的协同作用及其在TCS与rRNA作用中扮演什么角色,尚待进一步研究。     

天花粉蛋白Glu160在N-糖苷酶活性中的作用

用浸泡法得到了（Ｅ１６０Ａ）天花粉蛋白（ｔｒｉｃｈｏｓａｎｔｈｉｎ, ＴＣＳ）,（Ｅ１６０Ｄ）ＴＣＳ与Ａｄｅ 和（Ｅ１６０Ａ）ＴＣＳ与ＦＭＰ复合物的晶体．在Ｍａｒ Ｒｅｓｅａｒｃｈ 面探测器系统上分别收集了０．２０ ｎｍ ,０．１９ｎｍ 和０．２０５ ｎｍ 分辨率的Ｘ 射线衍射数据,数据处理用Ｍａｒ Ｓｃａｌｅ 程序系统完成．用同晶差值Ｆｏｕｒｉｅｒ法解析了（Ｅ１６０Ａ）ＴＣＳ－Ａｄｅ,（Ｅ１６０Ｄ）ＴＣＳ－Ａｄｅ 和（Ｅ１６０Ａ）ＴＣＳ－ＦＭＰ的晶体结构,结构修正利用Ｘ－ＰＬＯＲ程序,修正结果,晶体学Ｒ因子分别为０．１６６,０．１７６,０．１７９．键长和键角的ＲＭＳ偏差分别为０．００１０ ｎｍ 和２．５０３°,０．００１３ ｎｍ 和２．６６５°,０．００１２ ｎｍ 和２．６７６°．在这三个结构中均未见到Ｇｌｕ１８９侧链方向的改变．Ａｄｅ 或ＦＭＰ仍结合在Ｎ－糖苷酶活性口袋之中,它夹在Ｔｙｒ７０和Ｔｙｒ１１１两个侧链环之间,与Ｔｙｒ７０环近乎平行．这一结果表明：ＴＣＳ中的Ｇｌｕ１６０分别突变成Ａｌａ 和Ａｓｐ,仍能与ＡＭＰ发生Ｎ－糖苷酶反应,但是活性降低了一些．可见Ｇｌｕ１６０对ＴＣＳ与ＡＭＰ的作用是重要的,但不是必要的．     

天花粉蛋白Y14F/R22L定点突变及其活性研究

利用多聚酶链式反应（ＰＣＲ）技术,对天然天花粉蛋白（ｎＴＣＳ）基因在Ｔｙｒ１４和Ａｒｇ２２两个保守残基处同时进行定点突变,即Ｔｙｒ１４变成Ｐｈｅ,Ａｒｇ２２变成Ｌｅｕ,然后克隆到ｐＥＴ－８ｃ高效表达载体上,构建成重组质粒ｐＥＴＹ１４Ｆ／Ｒ２２Ｌ．经序列分析,定点突变的结果与预先设计的完全一致,突变后的天花粉蛋白命名为Ｙ１４Ｆ／Ｒ２２ＬＴＣＳ．将ｐＥＴＹ１４Ｆ／Ｒ２２Ｌ转化到Ｅ．ｃｏｌｉＢＬ２１（ＤＥ３,ｐＬｙｓＳ）中,进行表达．经ＣＭ－ＳｅｐｈａｒｏｓｅＣＬ－６Ｂ柱纯化,ＳＤＳ－ＰＡＧＥ鉴定,纯度可达９０％．ＲＩＰ活性测定显示,Ｙ１４Ｆ／Ｒ２２ＬＴＣＳ的活性比ｎＴＣＳ降低了７．５倍,活性变化不显著,因此,ＴＣＳ的Ｔｒｙ１４和Ａｒｇ２２对维持其活性部位构象并不是必需的．但由于Ｙ１４Ｆ／Ｒ２２ＬＴＣＳ在Ｅ．ｃｏｌｉ中的表达量与ｎＴＣＳ相比明显下降,因此,Ｔｙｒ１４和Ａｒｇ２２可能与ＴＣＳ翻译后的折叠有关．     

(E160A)和(E160D)天花粉蛋白两种突变体晶体结构研究

培养了（Ｅ１６０Ａ）ＴＣＳ和（Ｅ１６０Ｄ）ＴＣＳ的单晶。在ＭＡＲＲｅｓｅａｒｃｈ面探测器系统上分别收集了０．１９３ｎｍ和０．２０ｎｍ分辨率的Ｘ射线衍射数据。数据处理用ＭＡＲＳＣＡＬＥ程序系统完成。用同晶差值Ｆｏｕｒｉｅｒ法解析了突变体的晶体结构,结构修正利用Ｘ－ＰＬＯＲ程序。修正结果,晶体学Ｒ因子分别为０．１７５,０．１７９,键长和键角的ＲＭＳ偏差分别为０．００１１ｎｍ和２．４５７°,０．００１３ｎｍ和２．６７５°。在这两个突变体的结构中均未见到Ｇｌｕ１８９侧链方向的改变。通过对（Ｅ１６０Ａ）ＴＣＳ和（Ｅ１６０Ｄ）ＴＣＳ的结构比较,说明（Ｅ１６０Ｄ）ＴＣＳ活性低于（Ｅ１６０Ａ）ＴＣＳ的原因：这可能是由于在（Ｅ１６０Ｄ）ＴＣＳ中Ｔｙｒ１１１和Ｔｙｒ７０的侧链都具有较大的运动性,使它们与腺嘌呤碱基的芳香堆垛作用减弱,从而导致活性的降低     

Structure of trichosanthin at 1.88 Å resolution

Trichosanthin (TCS) is one of the single chain ribosome-inactivating proteins (RIPs). The crystals of the orthorhombic form of trichosanthin have been obtained from a citrate buffer (pH 5.4) with KC1 as the precipitant. The crystal belongs to the space group P2₁2₁2₁ with a = 38.31, b = 76.22, c = 79.21 Å. The structure was solved by molecular replacement method and refined using the programs XPLOR and PROLSQ to an R-factor of 0.191 for the reflections within the 6–1.88 Å resolution range. The bond length and bond angle in the protein molecule have root-mean-square deviations from ideal value of 0.013 Å and 3.3°, respectively. The refined model includes 247 residues and 197 water molecules. The TCS molecule consists of two structural domains. The large domain contains six α-helices, a six stranded sheet, and an antiparallel β-sheet. The small domain has a largest α-helix, which shows a distinct bend. The possible active site of the molecule located on the cleft between two domains was proposed. In the active site Arg-163 and Glu-160, Glu-189 and Arg-122 form two ion pairs, Glu-189 and Gln-156 are hydrogen bonded to each other. Three water molecules are bonded to the residues in the active site region. The structures of TCS molecule and ricin A-chain (RTA) superimpose quite well, showing that the structures of the two protein molecules are homologous. Comparison of the structures of the TCS molecule in this orthorhombic crystal with that in the monoclinic crystal indicates that there are no essential differences of the structures between the two protein crystals. © 1994 Wiley-Liss, Inc.     

易错PCR提高华根霉脂肪酶的热稳定性

为了提高华根霉Rhizopus chinensis CCTCC M201021脂肪酶的热稳定性,运用定向进化-易错PCR的方法,经两轮易错PCR引入突变,利用fast-blue RR顶层琼脂法对突变文库进行筛选,第一轮易错PCR后筛选到2株突变菌株,第二轮筛选到4株突变株。第二轮最佳突变株Ep2-4,其中3个氨基酸发生了突变：A129S、P168L和V329A。该突变酶ep2-4在60 ℃下半衰期相对原始酶r27RCL提高5.4倍,T50值提高7.8 ℃。酶学性质研究表明,突变酶ep2-4在热稳定性提高的基础上,仍保有良好的催化活性。蛋白质三维结构模拟显示,突变A129S可以和Gln133形成氢键,增加了酶表面的亲水性和极性;P168L可以与邻近的Leu164形成疏水键,导致突变酶的热稳定性提高。     

Crystal and Molecular Structure of a Cytosine Analog; 5-Bromo-6-Benzylamino Isocytosine

Abstract

Isocytosines are formal analogue of isoguanines for pairing with hydrogen bonds and are substrates for target enzymes for chemotherapy of infections diseases. The compound 5-bromo-6-benzylamino isocytosine crysta-Nized in space group P2₁/c with a =11.393(1)Å. b = 7.341(2)Å, c = 14.425(1) Å, β = 92.06(2)°. The structure was determined by heavy atom methods and refined by full matrix least squares to R = 6.8% based on 1935 X-ray structure amplitudes. The isocytosine ring in the molecule is protonated at N(3) with internal bond angle of 122° compared to 117° at N(1). The structure is stabilized by intermolecular hydrogen bonding pattern based on N-H.N and N-H…O hydrogen bonds.     

Possible formation of the left-handed alpha-helix of poly-L-serine

A conformational study of poly-L -serine has shown that it can exist in the left-handed α-helical form. A study of a pair of peptide units with the serine sidegroup attached to the α carbon atom linking the two units showed that O? H ?O hydrogen bonds between the OH group of the side chain and a carbonyl oxygen of the first peptide group in the backbone can occur in two regions of ?, namely, ? = 15°–30° for χ₁ = 300° and for ? = 225°-230° for ? = 60°. The latter is close to a possible left-handed helix of poly-L -serine, stabilized by N? H ?O hydrogen bonds. From a study of contact criteria, the best conformation for this helix is found to be ? = 227°, Ψ = 238°, χ₁ = 65° which has n = 3.65, h = 1.51 A. The N? H ?O hydrogen bond has a length of 2.90 A. (6°) and the O? H ?O hydrogen bond is of length 2.60 A. (0°). There are no other bad short contacts in the structure. The cylindrical coordinates of the atoms, as well as a perspective view of the structure arc given in this paper.     

人双专一性磷酸酶活性位点Cys^124附近精氨酸突变及功能

为研究人双专一性磷酸酶活性位点Cys12 4 附近 3个带正电的精氨酸对酶催化功能的影响 ,用QuikChange定点突变方法获得 6个突变体 :R12 5L、R130 L、R130 K、R130 L/S131A、R158K和R158L。将含突变基因的重组质粒转化大肠杆菌菌株BL2 1(DE3) ,经IPTG诱导表达获得的目的蛋白质均以可溶形式存在。通过镍离子亲和层析纯化得到纯度大于 90 %的蛋白质。对人痘苗病毒H1相关磷酸酶 (VHR)及其突变体进行稳态动力学参数和竞争性抑制常数Ki 的测定 ,结果显示上述Arg130 和Arg158突变体的kcat/Km 值都较野生型有大幅度下降 ,而Ki 值有明显上升 ,表明 130和 15 8位的精氨酸是VHR活性所必需 ,而且可能与底物上带负电的磷酸基团结合有关。另外 ,单突变体R130 L和双突变体R130 L/S131A之间的kcat值相差很小 ,提示Arg130 单点突变后可能破坏了Ser131与Cys12 4 间的氢键。再者 ,R12 5L、R130 L和R158L突变体都降低了砷酸盐结合亲和性 ,暗示这 3个精氨酸残基侧链上的正电荷可能有助于底物与酶的结合。     

亚天花粉蛋白突变体(R163H n-TCS和R163Q n-TCS)的晶体结构研究

用悬滴汽相扩散法得到了Ｒ１６３Ｈｎ－ＴＣＳ和Ｒ６１３Ｑｎ－ＴＣＳ的晶体,Ｍａｒ－Ｒｅｓｅａｒｃｈ面探测器系统上分别收集了０．２００和０．２０５ｎｍ分辨率的Ｘ－射线衍射数据,采用同晶差值傅立叶法解析结构,用Ｘ－ＰＬＯＲ软件包进行修正,最后的晶体学Ｒ因子分别为０．１８４和０．１８５,键长偏差分别为０．００１３ｎｍ和０．００１４ｎｍ,键角偏差分别为２．５９０和２．８１５,结构测定显示Ｒ１６３Ｈｎ－ＴＣＳ     

A revisit to the three-dimensional structure of B-type starch

A new three-dimensional structure of B-starch is proposed in which the unit cell contains 12 glucose residues located in two left-handed, parallel-stranded double helices packed in a parallel register; 36 water molecules are located between these helices. Chains are crystallized in the hexagonal space group P6₁, with lattice parameters a = b = 1.85 nm, c = 1.04 nm. The space group symmetry was derived from an exhaustive analysis of the large body of structural studies published so far. Diffraction data used in this work were taken from the previously reported x-ray fiber diffractogram [H.C. Wu and A. Sarko (1978), Carbohydrate Research, 61 , 7–25] after adequate reindexing. The final R factor is 0.145 for the three-dimensional data. The repeating unit consists of a maltose molecule where the glucose residues have the ⁴C₁ pyranose conformation and are α(1 → 4) linked. The conformation of the glycosidic linkage is characterized by torsion angles (Φ, Ψ) that take the values (83.8°, ?144.6°) and (84.3°, ?144.1°), whereas the valence angles at the glycosidic bridge have a magnitude of 115.8° and 116.5°, respectively. The primary hydroxyl groups exist in a gauche–gauche conformation. There is no intramolecular hydrogen bond. Within the double helix, interstrand stabilization is achieved without any steric conflict and through the occurrence of O(2)…O(6) type of hydrogen bonds. The model presented here, with an hydration around 27% w/w, corresponds to a well-ordered crystalline sample, since all the water molecules could be located with no apparent sign of a disorder. Half of the water molecules are tightly bound to the double helices; the remainder forms a complex network centered around the sixfold screw axis of the unit cell. The consistency of the present structural model, with both physicochemical and biochemical aspects of the crystalline component of tuber starch granules, is analyzed.     

Refined structure of human carbonic anhydrase II at 2.0 Å resolution

The structure of human erythrocytic carbonic anhydrase II has been refined by constrained and restrained structure–factor least-squares refinement at 2.0 Å resolution. The conventional crystallographic R value is 17.3%. Of 167 solvent molecules associated with the protein, four are buried and stabilize secondary structure elements. The zinc ion is ligated to three histidyl residues and one water molecule in a nearly tetrahedral geometry. In addition to the zinc-bound water, seven more water molecules are identified in the active site. Assuming that Glu-106 is deprotonated at pH 8.5, some of the hydrogen bond donor–acceptor relations in the active site can be assigned and are described here in detail. The Oγ1 atom of Thr-199 donates its proton to the Oε1 atom of Glu-106 and can function as a hydrogen bond acceptor only in additional hydrogen bonds.     

Effect of triclosan exposure on mortality and behavioral changes of Poecilia reticulata and Danio rerio

Triclosan (TCS), a chemical used for its antibacterial properties, is an ingredient in many detergents, soaps, deodorants, cosmetics, antimicrobial creams, toothpastes, and an additive in various plastics and textiles. The behavioral changes at different TCS concentrations (0.001–0.002–0.005–0.01–0.02–0.05–0.1–0.2–0.5 mg/L) were determined for the each test organisms in the study. The synthetic freshwater has temperature 20 ± 2°C, dissolved oxygen 7.0 ± 2 mg/L, pH 7.0–8.0. All experiments were replicated three times, in 14 h light, 10 h dark incubations, 10 fishes were put to each aquarium. In hourly and daily observations, times of dead and number for Poecilia reticulata, Danio rerio were recorded. Behavioral changes of Poecilia reticulata and Danio rerio were observed, such as fast-moving, uncontrolled swimming, trying to escape out of the water, vertical action to the water surface, loss of balance, respiratory difficulties, chills, and inversion.     

Ultrahigh-resolution study on <Emphasis Type="Italic">Pyrococcus abyssi</Emphasis> rubredoxin: II. Introduction of an O–H···Sγ–Fe hydrogen bond increased the reduction potential by 65 mV

The effect of D–H···Sγ–Fe hydrogen bonding on the reduction potential of rubredoxin was investigated by the introduction of an O–H···Sγ–Fe hydrogen bond on the surface of Pyrococcus abyssi rubredoxin. The formation of a weak hydrogen bond between Ser44-Oγ and Cys42-Sγ in mutant W4L/R5S/A44S increased the reduction potential by 56 mV. When side effects of the mutation were taken into account, the contribution of the additional cluster hydrogen bond to the reduction potential was estimated to be +65 mV. The structural analysis was based on ultrahigh-resolution structures of oxidized P. abyssi rubredoxin W4L/R5S and W4L/R5S/A44S refined to 0.69 and 0.86 Å, respectively.     

Tuning of the optical and electrochemical properties of the primary donor bacteriochlorophylls in the reaction centre from Rhodobacter sphaeroides: spectroscopy and structure

A series of mutations have been introduced at residue 168 of the L-subunit of the reaction centre from Rhodobacter sphaeroides. In the wild-type reaction centre, residue His L168 donates a strong hydrogen bond to the acetyl carbonyl group of one of the pair of bacteriochlorophylls (BChl) that constitutes the primary donor of electrons. Mutation of His L168 to Phe or Leu causes a large decrease in the mid-point redox potential of the primary electron donor, consistent with removal of this strong hydrogen bond. Mutations to Lys, Asp and Arg cause smaller decreases in redox potential, indicative of the presence of weak hydrogen bond and/or an electrostatic effect of the polar residue. A spectroscopic analysis of the mutant complexes suggests that replacement of the wild-type His residue causes a decrease in the strength of the coupling between the two primary donor bacteriochlorophylls. The X-ray crystal structure of the mutant in which His L168 has been replaced by Phe (HL168F) was determined to a resolution of 2.5 A, and the structural model of the HL168F mutant was compared with that of the wild-type complex. The mutation causes a shift in the position of the primary donor bacteriochlorophyll that is adjacent to residue L168, and also affects the conformation of the acetyl carbonyl group of this bacteriochlorophyll. This conformational change constitutes an approximately 27 degrees through-plane rotation, rather than the large into-plane rotation that has been widely discussed in the context of the HL168F mutation. The possible structural basis of the altered spectroscopic properties of the HL168F mutant reaction centre is discussed, as is the relevance of the X-ray crystal structure of the HL168F mutant to the possible structures of the remaining mutant complexes.     

亚天花粉蛋白突变体R163Kn-TCS及其复合物R163Kn-TCS/Ade的晶体结构

用悬滴汽相扩散法得到Ｒ１６３Ｋ ｎ－ＴＣＳ的晶体,并用ＡＭＰ浸泡４８小时后利到复合物晶体。在Ｍａｒ－Ｒｅｓｅａｒｃｈ面探测器系统上分别收集了０．２０５和０．１８７分辨率的Ｘ－射线衍射数据。采用同晶差值傅立叶法解析结构,用Ｘ－ＰＬＯＲ软件包进行修正,最后两模型的偏差因子（Ｒ和Ｒｆｒｅｅ）分别为（０．１８７和０．２６３）和（０．１８０和０．２３３）,键长偏差都为０．００１３ｎｍ,键角偏差分别为２．７９     

How Does (E)-2-(Acetamidomethylene)succinate Bind to Its Hydrolase? From the Binding Process to the Final Result

The binding of (E)-2-(acetamidomethylene)succinate (E-2AMS) to E-2AMS hydrolase is crucial for biological function of the enzyme and the last step reaction of vitamin B₆ biological degradation. In the present study, several molecular simulation methods, including molecular docking, conventional molecular dynamics (MD), steered MD (SMD), and free energy calculation methods, were properly integrated to investigate the detailed binding process of E-2AMS to its hydrolase and to assign the optimal enzyme-substrate complex conformation. It was demonstrated that the substrate binding conformation with trans-form amide bond is energetically preferred conformation, in which E-2AMS''s pose not only ensures hydrogen bond formation of its amide oxygen atom with the vicinal oxyanion hole but also provides probability of the hydrophobic interaction between its methyl moiety and the related enzyme''s hydrophobic cavity. Several key residues, Arg146, Arg167, Tyr168, Arg179, and Tyr259, orientate the E-2AMS''s pose and stabilize its conformation in the active site via the hydrogen bond interaction with E-2AMS. Sequentially, the binding process of E-2AMS to E-2AMS hydrolase was studied by SMD simulation, which shows the surprising conformational reversal of E-2AMS. Several important intermediate structures and some significant residues were identified in the simulation. It is stressed that Arg146 and Arg167 are two pivotal residues responsible for the conformational reversal of E-2AMS in the binding or unbinding. Our research has shed light onto the full binding process of the substrate to E-2AMS hydrolase, which could provide more penetrating insight into the interaction of E-2AMS with the enzyme and would help in the further exploration on the catalysis mechanism.     

Structures of p53 cancer mutants and mechanism of rescue by second-site suppressor mutations

We have solved the crystal structures of three oncogenic mutants of the core domain of the human tumor suppressor p53. The mutations were introduced into a stabilized variant. The cancer hot spot mutation R273H simply removes an arginine involved in DNA binding without causing structural distortions in neighboring residues. In contrast, the "structural" oncogenic mutations H168R and R249S induce substantial structural perturbation around the mutation site in the L2 and L3 loops, respectively. H168R is a specific intragenic suppressor mutation for R249S. When both cancer mutations are combined in the same molecule, Arg(168) mimics the role of Arg(249) in wild type, and the wild type conformation is largely restored in both loops. Our structural and biophysical data provide compelling evidence for the mechanism of rescue of mutant p53 by intragenic suppressor mutations and reveal features by which proteins can adapt to deleterious mutations.     

QM/MM studies on the calcium‐assisted β‐elimination mechanism of pectate lyase from bacillus subtilis

Pectate lyase utilizes the anti‐β‐elimination chemistry to catalyze the cleavage of α‐1,4 glycosidic bond between _D‐galacturonate regions during the degradation of plant polysaccharide pectin. We report here detailed mechanistic studies of the Bacillus subtilis pectate lyase (BsPel) using QM/MM calculations. It was found that the residue Arg279 serves as the catalytic base to abstract the α‐proton from C₅₂ atom of substrate Ada2 subsite, forming an unstable carbanion intermediate. The glycosidic bond of this intermediate is scissile to generate the 4,5‐unsaturated digalacturonate product and a negatively charged β‐leaving group. Two active site residues (Lys247 and Arg279) and two Ca²⁺ ions (Ca2 and Ca3) form hydrogen‐bonding and coordination interactions with C₅₂? COO^? of Ada2, respectively, which facilitate the proton abstraction and stabilize the generated carbanion intermediates. Arg284 is not the potential proton donor to saturate the leaving group. Actually, the proton source of leaving group is the solvent water molecule rather than any active site acidic residues. In addition, the calculation results suggest that careful selections of QM‐ and Active‐regions are essential to accurately explore the enzymatic reactions. Proteins 2016; 84:1606–1615. © 2016 Wiley Periodicals, Inc.