2．5分辨率单斜Al－（L－丙氨酸）胰岛素晶体结构研究

空间群为Ｐ２１的Ａ１－（Ｌ－丙氨酸）胰岛素晶胞内,一个不对称单位含有一个六聚体,应用差值Ｆｏｕｒｉｅｒ技术,立体化学制最小二来技术和Ｘ—ＰＬＯＲ程序并辅以电子密度图的人工拟合,解析了分辨率ＡＩ—（Ｌ－丙氨酸）胰岛素（Ａｌ－Ｌ－ＡｌａⅠ）的晶体结构。最终Ｒ因子为２０．６％,与标准键长与键角的均方根偏差分别为和４．１９°,从电子密度图与模型的拟合来看,六聚体中每条Ａ链的Ａｌ位置替换的Ｌ—Ａｌａ清晰可见,每条Ｂ链Ｎ端Ｂ１—Ｂ８伏段都为α螺旋构象,形成了Ｂ１—Ｂ１９的连续α螺旋段。     

2．5分辨率单斜Al－（L－丙氨酸）胰岛素晶体结构研究

空间群为Ｐ２１的Ａ１－（Ｌ－丙氨酸）胰岛素晶胞内,一个不对称单位含有一个六聚体,应用差值Ｆｏｕｒｉｅｒ技术,立体化学制最小二来技术和Ｘ—ＰＬＯＲ程序并辅以电子密度图的人工拟合,解析了分辨率ＡＩ—（Ｌ－丙氨酸）胰岛素（Ａｌ－Ｌ－ＡｌａⅠ）的晶体结构。最终Ｒ因子为２０．６％,与标准键长与键角的均方根偏差分别为和４．１９°,从电子密度图与模型的拟合来看,六聚体中每条Ａ链的Ａｌ位置替换的Ｌ—Ａｌａ清晰可见,每条Ｂ链Ｎ端Ｂ１—Ｂ８伏段都为α螺旋构象,形成了Ｂ１—Ｂ１９的连续α螺旋段。     

单斜Al－（L－丙氨酸）胰岛素初步晶体学研究

用微量气相扩散方法在含酚的柠檬酸缓冲体系中,得到了可供Ｘ射线晶体学分析用的Ａｌ－（Ｌ－丙氨酸）胰岛素晶体,晶体衍射能力为２．５Ａ。经Ｘ射线衍射分析确定,该晶体属于单斜晶系,空间群为Ｐ２_１,晶胞参数：ａ＝６１．５Ａ,ｂ＝６２．２Ａ,ｃ＝４８．３Ａ,α＝γ＝９０．０°,β＝１１０．９°。晶胞中每个结晶学不对称单位含有一个Ａｌ－（Ｌ－丙氨酸）胰岛素六聚体。     

Al-(L-丙氨酸)胰岛素晶体学研究

应用微量过饱和静置法在含柠檬酸钠和氯化钠的晶体生长体系中得到适合Ｘ射线衍射分析用的Ａｌ－（Ｌ－丙氯酸）胰岛素单晶体。晶体属于三方晶系,空间群为Ｒ３晶体衍射分辨率可达１．８Ａ以上。晶胞参数：ａＨ＝８０．８９Ａ,ｂＨ＝８０．８９Ａ,ｃＨ＝３７＼６４Ａ,α＝β＝９０°,γ＝１２０°。每个结晶学不对称单位含有两个Ａｌ－（Ｌ－丙氨酸）胰岛素分子。     

L－丙氨酸生产菌种培养条件的研究

本文从培养基组成、通气量、培养温度及培养时间四个方面研究并提出了Ｌ－丙氨酸生产菌种ＰｓｅｕｄｏｍｏｎａｓＩＡＭ１１５２－Ａ的最佳培养条件。     

L－丙氨酸生产菌种培养条件的研究

本文从培养基组成、通气量、培养温度及培养时间四个方面研究并提出了Ｌ－丙氨酸生产菌种ＰｓｅｕｄｏｍｏｎａｓＩＡＭ１１５２－Ａ的最佳培养条件。     

微生物发酵合成L－缬氨酸－~（15）N

采用含有稳定同位素￣（１５）Ｎ－硫铵为主要氮源的专用发酵培养液配方和相应的工艺条件,在国内首次用微生物直接发酵研制成Ｌ－缬氨酸－￣（１５）Ｎ高丰度精制产品。产品￣（１５）Ｎ丰度９７．６８％,反比原料￣（１５）Ｎ－硫铵丰度下降０．５３％,Ｌ－缬氨酸－￣（１５）Ｎ产酸率最高达４％以上（未校正）。每克￣（１５）Ｎ－硫铵可得到１克以上的Ｌ－缬氨酸－￣（１５）Ｎ（分析值）。提取精制收率平均为８０－９０％（单程）,最高达到９５％以上（二次提取）。实际每克￣（１５）Ｎ－硫铵可得０．６克左右的Ｌ－缬氨酸－￣（１５）Ｎ精制产品。     

猪B_0L-丙氨酰胰岛素和猪B_1L-亮氨酰胰岛素的制备及性质研究

 猪胰岛素经与MSC·ONsu选择性反应,得到[MSC]A_(21)B_(29)胰岛素,再与BOC-L-Ala·TTT缩合,去保护后得到[L-Ala]B_0胰岛素,将得到的[MSC]A_(21)B_(29)胰岛素经Edman降解,再与BOC-L-Leu·TTT缩合、去保护后得到[L-Leu]B_1胰岛素。样品经N-末端分析,醋酸纤维素薄膜电泳、氨基酸组成分析和紫外吸收光谱鉴定,确定它们分别为均一的[L-Ala]B_0胰岛素和[L-Leu]B_1胰岛素。放射免疫法分析[L-Al_a]B_0肽岛素和[L-Leu]B_1胰岛素的免疫活性分别相当于天然胰岛素的30％和47％,小鼠惊厥法分析表明[L-Ala]B_6胰岛素与[L-Leu]B_1胰岛素的生物活力为19.7国际单位/mg和19.1国际单位/mg,相当于天然胰岛素的76％和73％。     

Crystal structure of (L-Arg)-BO bovine insulin at 0.21 nm resolution

The crystal structure of (L-Arg)-B0 bovine insulin has been determined, using data to 0.21 nm and atomic parameters of 2Zn porcine insulin as a starting model, by the difference Fourier method, the restrained least square method and X-PLOR package, interspersed with careful review of the electron density, to a final R-factor of 0.182 and r.m.s. deviation of 0.002 2nm for the bond lengths and 4.3° for the bond angles. The electron densities of additional (L-Arg)-B0 residues to B-chain N-terminus of two monomers in each asymmetric unit are very dear. The crystallographic micro-environment of the N-terminus of the B-chain is different from that of rhombohedral 2-zinc insulin.     

Crystal structure of human coactosin-like protein at 1.9 A resolution

Human coactosin-like protein (CLP) shares high homology with coactosin, a filamentous (F)-actin binding protein, and interacts with 5LO and F-actin. As a tumor antigen, CLP is overexpressed in tumor tissue cells or cell lines, and the encoded epitopes can be recognized by cellular and humoral immune systems. To gain a better understanding of its various functions and interactions with related proteins, the crystal structure of CLP expressed in Escherichia coli has been determined to 1.9 A resolution. The structure features a central beta-sheet surrounded by helices, with two very tight hydrophobic cores on each side of the sheet. CLP belongs to the actin depolymerizing protein superfamily, and is similar to yeast cofilin and actophilin. Based on our structural analysis, we observed that CLP forms a polymer along the crystallographic b axis with the exact same repeat distance as F-actin. A model for the CLP polymer and F-actin binding has therefore been proposed.     

Crystal structure of a proteolytically generated functional monoferric C-lobe of bovine lactoferrin at 1.9A resolution

This is the first crystal structure of a proteolytically generated functional C-lobe of lactoferrin. The purified samples of iron-saturated C-lobe were crystallized in 0.1 M Mes buffer (pH 6.5) containing 25% (v/v) polyethyleneglycol monomethyl ether 550 M and 0.1 M zinc sulphate heptahydrate. The X-ray intensity data were collected with 300 mm imaging plate scanner mounted on a rotating anode generator. The structure was determined by the molecular replacement method using the coordinates of the C-terminal half of bovine lactoferrin as a search model and refined to an R-factor of 0.193 for all data to 1.9A resolution. The final model comprises 2593 protein atoms (residues 342-676 and 681-685), 124 carbohydrate atoms (from ten monosaccharide units, in three glycan chains), one Fe(3+), one CO(3)(2-), two Zn(2+) and 230 water molecules. The overall folding of the C-lobe is essentially the same as that of C-terminal half of bovine lactoferrin but differs slightly in conformations of some of the loops and reveals a number of new interactions. There are 20 Cys residues in the C-lobe forming ten disulphide links. Out of these, one involving Cys481-Cys675 provides an inter-domain link at 2.01A while another Cys405-Cys684 is formed between the main C-lobe 342-676 and the hydrolyzed pentapeptide 681-685 fragment. Six inter-domain hydrogen bonds have been observed in the structure whereas only four were reported in the structure of intact lactoferrin, although domain orientations have been found similar in the two structures. The good quality of electron density has also revealed all the ten oligosaccharide units in the structure. The observation of two metal ions at sites other than the iron-binding cleft is another novel feature of the present structure. These zinc ions stabilize the crystal packing. This structure is also notable for extensive inter-molecular hydrogen bonding in the crystals. Therefore, the present structure appears to be one of the best packed crystal structures among the proteins of the transferrin superfamily.     

Crystal structure of the vertebrate NADP(H)-dependent alcohol dehydrogenase (ADH8)

The amphibian enzyme ADH8, previously named class IV-like, is the only known vertebrate alcohol dehydrogenase (ADH) with specificity towards NADP(H). The three-dimensional structures of ADH8 and of the binary complex ADH8-NADP(+) have been now determined and refined to resolutions of 2.2A and 1.8A, respectively. The coenzyme and substrate specificity of ADH8, that has 50-65% sequence identity with vertebrate NAD(H)-dependent ADHs, suggest a role in aldehyde reduction probably as a retinal reductase. The large volume of the substrate-binding pocket can explain both the high catalytic efficiency of ADH8 with retinoids and the high K(m) value for ethanol. Preference of NADP(H) appears to be achieved by the presence in ADH8 of the triad Gly223-Thr224-His225 and the recruitment of conserved Lys228, which define a binding pocket for the terminal phosphate group of the cofactor. NADP(H) binds to ADH8 in an extended conformation that superimposes well with the NAD(H) molecules found in NAD(H)-dependent ADH complexes. No additional reshaping of the dinucleotide-binding site is observed which explains why NAD(H) can also be used as a cofactor by ADH8. The structural features support the classification of ADH8 as an independent ADH class.     

Insulin at pH 2: structural analysis of the conditions promoting insulin fibre formation

When insulin solutions are subjected to acid, heat and agitation, the normal pattern of insulin assembly (dimers-->tetramers-->hexamers) is disrupted; the molecule undergoes conformational changes allowing it to follow an alternative aggregation pathway (via a monomeric species) leading to the formation of insoluble amyloid fibres. To investigate the effect of acid pH on the conformation and aggregation state of the protein, the crystal structure of human insulin at pH 2.1 has been determined to 1.6 A resolution. The structure reveals that the native fold is maintained at low pH, and that the molecule is still capable of forming dimers similar to those found in hexameric insulin structures at higher pH. Sulphate ions are incorporated into the molecule and the crystal lattice where they neutralise positive charges on the protein, stabilising its structure and facilitating crystallisation. The sulphate interactions are associated with local deformations in the protein, which may indicate that the structure is more plastic at low pH. Transmission electron microscopy analysis of insulin fibres reveals that the appearance of the fibres is greatly influenced by the type of acid employed. Sulphuric acid produces distinctive highly bunched, truncated fibres, suggesting that the sulphate ions have a sophisticated role to play in fibre formation, rather as they do in the crystal structure. Analytical ultracentrifugation studies show that in the absence of heating, insulin is predominantly dimeric in mineral acids, whereas in acetic acid the equilibrium is shifted towards the monomer. Hence, the effect of acid on the aggregation state of insulin is also complex. These results suggest that acid conditions increase the susceptibility of the molecule to conformational change and dissociation, and enhance the rate of fibrillation by providing a charged environment in which the attractive forces between the protein molecules is increased.