牛胰岛素去折叠过程的高效液相色谱法分析

建立了反相高效液相色谱法动态监测牛胰岛素在二硫苏糖醇存在下去折叠的过程。牛胰岛素在二硫苏糖醇作用下,首先发生构象变化,形成稳定的中间体后进一步断裂分子间的二硫键,形成Ａ链和Ｂ链。去折叠过程通过基质辅助激光解吸附质谱得到了鉴定。     

A Synthetic Route to Human Insulin Using Isoacyl Peptides

The chemical synthesis of insulin has been a longstanding challenge, mainly because of the notorious hydrophobicity of the A chain and the complicated topology of this 51‐mer peptide hormone consisting of two chains and three disulfide bonds. Reported herein is a new synthetic route utilizing the isoacyl peptide approach to address the hydrophobicity problems. The incorporation of isoacyl dipeptide segments into both A and B chains greatly improved their preparation and purification, and the RP‐HPLC recovery of the chain ligation intermediates. The new route affords human insulin with a yield of 68 % based on the starting purified A chain and an overall yield of 24 % based on the substitution of the resin used for the preparation of A chain. To the best of our knowledge, this represents the most efficient route of human insulin chemical synthesis reported to date.     

Importance of individual side chains for the stability of a protein fold: computational alanine scanning of the insulin monomer

A new computational approach is proposed to probe the importance of residue side chains for the stability of a protein fold. Computational mutations to estimate protein stability (CMEPS) is based on the notion that the binding free energy corresponding to the complexation of a given side chain, considered as a "pseudo-ligand" of the wild type protein, reflects the importance of this side chain to the thermodynamic stability of the protein. The contribution of a particular side chain to the folding energy is estimated according to the molecular mechanics-generalized born surface area MM-GBSA approach, using a single molecular dynamics simulation trajectory of the wild type protein. CMEPS is a first principles method which does not contain any adjustable parameter that could be fitted to experimental data. The approach is first validated for Barnase and the B1 domain of protein L, for which a correlation coefficient R = 0.73, between experimental and CMEPS calculated DeltaDeltaG values, is found and then applied to the insulin monomer. In the present application, CMEPS replaces each amino acid by an alanine residue. Therefore, most mutations lead to cavities in the protein. From this the change in stability can be correlated with increased cavity volume. For insulin, this correlation is very similar compared with data previously analyzed for T4 lysozyme from an experiment for buried apolar side chains. There, the increased cavity volume has been related to the hydrophobic effect. However, since CMEPS uses the energetics in terms of electrostatic and van der Waals interactions (and not the hydrophobic effect which is difficult to relate to physical interactions), it is possible to study the effect of mutations of polar and solvent accessible side chains. According to CMEPS, residues Leu A16, Tyr A19, Leu B11, Leu B15, and Arg B22 are most important for the stability of the monomeric insulin fold. This is in agreement with experimental data. As a consequence, mutation of these residues may lead to misfolded and inactive insulin analogues.     

高效液相色谱-电喷雾质谱法分离和鉴别枯草芽孢杆菌产生的脂肽类化合物

枯草芽孢杆菌JA因产生多种脂肽类化合物而具有广阔的开发前景。JA发酵液经过离心、酸沉淀、甲醇抽提等步骤得到脂肽类化 合物的粗提物。将粗提物溶于流动相,采用反相高效液相色谱分离,对收集的洗脱峰组分进行电喷雾质谱(ESI-MS)分析。根据质荷比推 断JA菌株产生的脂肽类化合物属于3个家族,分别为surfactin, iturin和fengycin,是枯草芽孢杆菌合成的重要生物表面活性素。对一 级质谱中的主成分进行串联质谱分析,进一步确定了3种脂肽类化合物的分子结构。实验证明ESI-MS是一种鉴定脂肽类化合物及其同系 物的可靠方法。     

Time-of-flight secondary ion mass spectrometry of matrix-diluted oligo- and polypeptides bombarded with slow and fast projectiles: Positive and negative matrix and analyte ion yields, background signals, and sample aging

Human angiotensin II, chain B of bovine insulin, and porcine insulin were determined by time-of-flight secondary ion mass spectrometry under impact of approximately 25 keV Xe+ and SF5+ ion beams and approximately 100 MeV 252Cf fission fragments. Matrix-embedded samples, dissolved in a large surplus of alpha-cyano-4-hydroxycinnamic acid, were prepared by nebulizer spray deposition, neat samples by the droplet technique. It is shown that the status of the sample can be assessed by evaluating the matrix-specific features of the mass spectra. The beneficial effect of matrix isolation was small for angiotensin but large for the insulin samples, which did not show parent peaks from neat material. Negative ion yields under SF5+ impact were up to a factor of 50 higher than with Xe+. For positive secondary ions, the enhancement was much smaller. The mass spectra produced by slow ion beams or fast fission fragments were qualitatively similar. Quantitative differences include the following: with fast projectiles the yields were about 10-30 times higher than with slow ions, but similar for negative ion emission under SF5+ bombardment; the analyte-to-matrix yield ratios were higher with slow ions and up to 250 times higher than the molar analyte concentration; for analyte ions the peak-to-background ratios were higher using slow projectiles; the fraction of carbon-rich collisionally formed molecular ions was much higher with fast projectiles. Sample aging in vacuum for up to five weeks strongly reduced the yield of protonated analyte molecules ejected by slow ion impact, but not of deprotonated species. Hence protonation seems to correlate with sample "wetness" or the presence of volatile proton-donating additives.     

High Performance Liquid Cbromatographic Separation of Globin Chains on a Large-Pore C4 Column

Abstract

Excellent resolution of human and baboon globin chains may be obtained by HPLC on a Vydac large-pore C₄ column. The procedure is rapid and uses a gradient between aqueous trifluoroacetic acid and trifluoroacetic acid in acetonitrile. The common human γ chains are easily separable from each other as are some α- and β-chain variants from the normal chains and from each other.     

Accurate evaluation method of the polymer content in Monomethoxy(polyethylene glycol) modified proteins based on Amino acid analysis

To overcome the uncertainty of the colorimetric or fluorimetric method so far employed for the evaluation of monomethoxy(polyethylene glycol) (MPEG) covalently bound to protein, a direct method based on amino acid analysis is proposed. The method exploits the use of MPEG, which was bounded with the unnatural amino acid norleucine (MPEG-Nle). MPEG-Nle was activated at its carboxylic group to succinimidyl ester for the binding to the amino groups of protein. After acid hydrolysis, the amino acid content is evaluated by conventional amino acid analyzer or by reverse-phase HPLC as phenylthiocarbamyl derivative. The number of bound MPEG chains is calculated from the amino acid composition, since one norleucine residue is released from each bound polymer chain. The method was verified with several proteins in comparison with colorimetric ones, also in the case of proteins that contain chromophores in the visible range, such cytocrome C. It was observed that in most of the cases, the colorimetric methods give an overestimation of the degree of protein modification.     

Separation and quantitation of insulins and related substances in bulk insulin crystals and in injectables by reversed-phase high performance liquid chromatography and the effect of temperature on the separation

The Food and Drug Administration performs potency assays of insulin products as part of the insulin certification program required by the Code of Federal Regulations. The official method specified in the United States Pharmacopeia (USP) is a bioassay measuring the depression of blood sugar concentrations in rabbits treated with the insulin under test and the official standard. The insulin products resulting from today's technology include highly purified isolates from bovine or porcine pancreas and insulin that is identical in structure to human insulin. A study of the effects of temperature on the separation of the components in insulin injectables led to the development of a reversed-phase high performance liquid chromatographic (HPLC) method that uses a sulfate buffer/acetonitrile mobile phase at 40 degrees C for the separation and quantitation of bovine, porcine, and human insulins and related substances. This HPLC method reduces analysis time to 1/60 of that required for the bioassay and yields more information about purity than the percent nitrogen determination that is one of the USP official procedures. The results of HPLC analyses were compared with those for the bioassay by means of a potency/area conversion factor computed on a species by species basis. Results for the bioassays and the HPLC determinations for 40 lots of bulk crystalline insulin were compared in this study; in general, the HPLC estimates fell within the 95% confidence interval for combined independent bioassays.     

Rapid isolation method for lipopolysaccharide and lipid A from gram-negative bacteria

A fast, convenient extraction method for lipopolysaccharide (LPS), using a commercial RNA isolating reagent, allows the isolation of LPS or lipid A from low milligram (dry weight) quantities of bacterial cells. The method avoids the use of specialized equipment and has been used for processing relatively large numbers of samples. The major components of the commercial RNA isolating reagent, Tri-Reagent, are phenol and guanidinium thiocyanate in aqueous solution. The bacterial cell membranes are disrupted with guanidinium thiocyanate, which eliminates the need for mechanical cell disruption (e.g. French press) or heating. LPS and its degradation products, with particular attention paid to its bioactive lipid A portion, were measured and compared with those from the most common conventional extraction method, hot phenol-water. Negative ion quadrupole ion trap and matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry, fatty acid composition analysis by capillary gas chromatography, total and free phosphate by UV spectrophotometry and sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) showed that LPS and lipid A isolated using the Tri-Reagent approach were cleaner and suffered less degradation through loss of phosphate and (or) fatty acyl side chains from lipid A. The Tri-Reagent extraction method generated low free phosphate contamination, 11% of the total phosphate concentration, whereas the hot phenol-water extraction method gave approximately 58% as free, inorganic phosphate. Similar results were observed for the degradation of fatty acyl side chains. The time required by the new method is considerably shorter (two or three days) than that required by conventional hot phenol-water extraction (about two weeks).     

H spin system identifications of S-sulfonated insulin B chain with 2D-NMR

Resonance assignments of the 1H spectrum of insulin are the basis on which to investigate its solution conformation by using NMR method. Owing to the complicated aggregation behaviour of the molecule to give broadened n. m. r. lines, only limited resonance assignments have been reported. S-sulfonated A and B chains of insulin gave 1H spectra with good resolutions. Based on the 500 MHz absolute 2D-COSY spectrum and 400 MHz phase sensitive DQF-COSY, Relayed-COSY and NOESY spectra of B chain recorded in D2O, all of the spin system identifications of the non-labile protons in the S-sulfonated B chain of insulin were reported including the specific resonance assignments of eight residues: B3Asn, B9Ser, B16Tyr, B22Arg, B26Tyr, B27Thr, B28Pro and B29Lys. The pK values of B16 and B26 tyrosine are 10.65 and 10.60 respectively from pH titration.     

Substitution of an Internal Disulfide Bridge with a Diselenide Enhances both Foldability and Stability of Human Insulin

Insulin analogues, mainstays in the modern treatment of diabetes mellitus, exemplify the utility of protein engineering in molecular pharmacology. Whereas chemical syntheses of the individual A and B chains were accomplished in the early 1960s, their combination to form native insulin remains inefficient because of competing disulfide pairing and aggregation. To overcome these limitations, we envisioned an alternative approach: pairwise substitution of cysteine residues with selenocysteine (Sec, U). To this end, Cys^A6 and Cys^A11 (which form the internal intrachain A6–A11 disulfide bridge) were each replaced with Sec. The A chain[C6U, C11U] variant was prepared by solid-phase peptide synthesis; while sulfitolysis of biosynthetic human insulin provided wild-type B chain-di-S-sulfonate. The presence of selenium atoms at these sites markedly enhanced the rate and fidelity of chain combination, thus solving a long-standing challenge in chemical insulin synthesis. The affinity of the Se-insulin analogue for the lectin-purified insulin receptor was indistinguishable from that of WT-insulin. Remarkably, the thermodynamic stability of the analogue at 25 °C, as inferred from guanidine denaturation studies, was augmented (ΔΔG_u ≈0.8 kcal mol⁻¹). In accordance with such enhanced stability, reductive unfolding of the Se-insulin analogue and resistance to enzymatic cleavage by Glu-C protease occurred four times more slowly than that of WT-insulin. 2D-NMR and X-ray crystallographic studies demonstrated a native-like three-dimensional structure in which the diselenide bridge was accommodated in the hydrophobic core without steric clash.     

Insulins in equine urine: qualitative analysis by immunoaffinity purification and liquid chromatography/tandem mass spectrometry for doping control purposes in horse-racing

Insulin is a peptide hormone consisting of two peptide chains (A- and B-chain) that are cross-linked by two disulfide bonds. To obtain improved pharmacokinetic onset of action profiles of insulin treatment in diabetic patients, recombinant long-, intermediate-, and rapid-acting insulin analogs are produced, in which the C-terminal end of the B-chain plays an especially important role.A review of the veterinary literature reveals the low prevalence of equine type I diabetes mellitus, which indicates that the therapeutic use of insulin in racing horses is unlikely. Although there is no unequivocal evidence of an overall performance-enhancing effect of insulin, in human sports the misuse of insulin preparations is reported among elite athletes. The desired effects of insulin include the increase of muscular glycogen prior to sports event or during the recovery phase, in addition to a chalonic action, which increases the muscle size by inhibiting protein breakdown.In the present study urinary insulin was detected in equine samples and differences between equine insulin, human insulin, as well as rapidly acting recombinant insulin variants were examined. The method was based on sample purification by solid-phase extraction (SPE) and immunoaffinity chromatography (IAC), and subsequent analysis by microbore liquid chromatography (LC) and tandem mass spectrometry (MS/MS) using top-down sequencing for the determination of various insulins. Product ion scan experiments of intact proteins and B-chains enabled the differentiation between endogenously produced equine insulin, its DesB30 metabolite, human insulin and recombinant insulin analogs, and the assay allowed the assignment of individual product ions, especially those originating from modified C-termini of B-chains.     

Cleavage of Multiple Disulfide Bonds in Insulin via Gold Cationization and Collision-induced Dissociation

Intact bovine insulin, with its two chains linked via two disulfide linkages, has been used as a model system to study the incorporation of one or more gold cations as means for facilitating the cleavage of multiple disulfide bonds in a tandem mass spectrometry experiment. Gas-phase ion/ion reactions involving Au(I)Cl(2) (-) or Au(III)Cl(4) (-) were used to incorporate either one or two gold cations into multiply-protonated insulin cations, followed by ion trap collision-induced dissociation (CID) of the products. The incorporation of a single gold cation followed by CID showed little evidence for disulfide bond cleavage. Rather, the CID spectra were similar to those acquired for the same charge state with only excess protons present. However, the incorporation of two gold cations, regardless of oxidation state, resulted in efficient cleavage of the disulfide bonds connecting the two chains of insulin. Furthermore, ion trap CID of the insulin complexes containing two gold cations showed more sequence information compared to the complexes containing only one gold cation or no gold cations. The partitioning of the gold cations between the two chains upon CID proved to be largely asymmetric, as both gold cations tended to stay together. There appeared to be a slight preference for both gold cations to partition into the B-chain. However, the relatively low contribution from single chain ions with only one gold ion suggests a degree of cooperativity in the overall mechanism for separation of the two chains.     

The equilibrium fraction of bridging chains and the swelling behavior of ABA triblock copolymer mesophases

The physical cross-linked network due to B blocks bridging different A domains of a microphase separated melt formed by an ABA copolymer in the strong-segregation limit is examined. The system is considered to consist of swollen elements of the same size, each containing an A domain and a B layer anchored to the A domain as loops or bridges. A lattice model and a generator-matrix method are employed to calculate the equilibrium fraction of the bridging B chains of the ABA mesophase and the equilibrium swelling concentration of the B layer in a selective solvent for the planar, cylindrical and spherical A domain structures. The effects of chain length and of two-dimensional surface density of the AB joints are discussed. The equilibrium fraction of the bridging chains as a function of chain stiffness and the equilibrium swelling concentration as a function of the fraction of bridging chains and of the interaction parameter are calculated. In addition, the segment density distributions of both loop and bridging chains for both the pure ABA and the swollen ABA mesophases are provided.     

[B10Glu,B24-Asp-B25]人胰岛素类似物的制备、鉴定与性质研究

采用PCR方法,将人胰岛素分子B链B10位His突变为Glu,在B24和B25位之间插入Asp,构建了[B10Glu,B24-Asp-B25]胰岛素原基因.利用通用型质粒pBV220构建表达载体,在大肠杆菌DH5α中表达,表达蛋白为包含体形式,约占菌体总蛋白的20%～30%.经过复性和凝胶过滤得到胰岛素原融合蛋白.用胰蛋白酶和羧肽酶B酶切,经DEAE离子交换和RP-HPLC纯化得胰岛素突变体类似物.用凝胶过滤法测定了蛋白质分子自身的缔合性质,用圆二色谱测定了构象变化.放射性免疫活性及受体结合活性测定结果表明,突变体分子缔合性明显下降,放免活性和受体结合活性分别约为人胰岛素的73.6%和146%.     

High performance liquid chromatography/electrospray tandem mass spectrometry for phenothiazines with heavy side chains in whole blood

Eleven phenothiazine derivatives with heavy side chains contained in human whole blood have been analyzed by high-performance liquid chromatography (HPLC)/electrospray (ES) tandem mass spectrometry (MS). All compounds gave the base peaks due to [M + 1](+) by HPLC/ES single MS. The product ions formed from each quasi-molecular ion by HPLC/ES tandem MS showed the base peaks due to side chains liberated. The mass chromatography of HPLC/ES tandem MS showed much higher sensitivity than that of HPLC/ES single MS for phenothiazines spiked to whole blood. Therefore, regression equations, detection limits, recovery rates and reproducibility were studied for thiethylperazine, clospirazine and flupentixol spiked to human whole blood by means of mass chromatography of HPLC/ES tandem MS. The three compounds showed good linearity in the range of 2-40 ng/mL with a detection limit of about 0.5 ng/mL. Recoveries of the three compounds spiked to whole blood (2 and 8 ng added to 1 mL whole blood) were 43.4-72.5 %; the coefficients of intraday and interday variations were 3.7-9.3 and 12.6-17.9 %, respectively. Thiethylperazine, clospirazine and flupentixol in whole blood could actually be determined with sufficient sensitivity 3 and 6 h after oral administration of 5-10 mg of each compound in a volunteer.     

Comparison of ion-exchange chromatography, isoelectric precipitation and reversed-phase high-performance liquid chromatography for the separation of individual cardiac myosin light chains.

Three modified procedures for the separation of cardiac myosin light chains are carefully compared. Ion-exchange chromatography gives a purified cardiac myosin light chain 1, whereas light chain 2 is always contaminated by light chain 1. Reversed-phase high-performance liquid chromatography gives the best resolution of these light chains and needs only 20 min for each run. However, it requires pure preparation of myosin light chains before separation. Isoelectric precipitation is the simplest procedure and suitable for large quantities of material. Although it gives the highest yield the separation is not adequate. A modified and rapid procedure for the isolation of cardiac and skeletal total myosin light chains is also presented.     

Formation of insulin fragments by insulin‐degrading enzyme: the role of zinc(II) and cystine bridges

Insulin is the hormone mainly involved in widespread diseases such as diabetes mellitus. It is widely recognized that metal ions such as zinc(II) as well as insulin degradation and insulin fragments are inexplicably linked to the hormone action. Insulin‐degrading enzyme (IDE) has been identified as the main factor of insulin degradation, but it is still unknown the exact way and location at which IDE action toward insulin occurs and how metal ions can modulate this interaction. Interestingly, some insulin fragments have different biological activity from the intact hormone, and it is not clear how they can be generated from insulin. In this work, the role of zinc(II) and cystine bridges in the degradation of insulin by IDE are investigated by high‐performance liquid chromatography‐mass spectrometry (HPLC‐MS), and the experimental conditions at which peculiar insulin fragments having biological activity are formed by the action of IDE are found and discussed. Docking simulations of IDE/insulin A and B chains are in good accordance with the insulin fragments detected by HPLC‐MS. Copyright © 2013 John Wiley & Sons, Ltd.     

Effects of cysteic acid groups on the gas-phase reactivity and dissociation of [M + 4H]4+ ions from insulin chain B

Gas-phase ion/molecule reactions and collision-induced dissociation (CID) were conducted on [M + 4H]4+ of insulin chain B. This Fourier transform mass spectrometry work involved ions from the oxidized peptide (with two cysteic acid residues) and its reduced form (with two cysteine residues). Kinetic behavior during deprotonation and hydrogen/deuterium exchange reactions indicates that insulin B (ox) ions have two distinct structural types. In contrast, insulin B (red) ions have only one major reacting population, which has a more compact structure than the oxidized ions. No significant differences in fragmentation patterns for the two insulin B (ox) populations were observed when CID was performed as a function of deprotonating reaction time. However, markedly different fragmentation was found between [M + 4H]4+ of insulin B (ox) and (red). Therefore, the presence of cysteic acid groups in insulin B (ox) significantly impacts dissociation and presumably structure. This suggests that some insulin B (ox) ions are zwitterionic, with the five basic sites protonated and one cysteic acid group deprotonated. Molecular dynamics calculations revealed several viable structures that are consistent with the experimental results. For example, the most stable form of the reduced ion, which is unprotonated at the His10, is very compact and has lost the alpha-helix of native insulin. Low energy structures for the oxidized ions include a zwitterion with an intraionic interaction between anionic Cyx7 and cationic His10, as well as a nonzwitterionic conformer that lacks a proton at Phe1; both structures retain the alpha-helix. These structures may account for the two experimentally observed isomers, although others are possible. In addition, experiments on oxidized insulin B were conducted from methanolic solution, which may denature the conformation, and pure aqueous solution, which may leave a native conformation. These differences in solvent composition had no effect on the gas-phase results.     

Separation and characterization of silybin, isosilybin, silydianin and silychristin in milk thistle extract by liquid chromatography-electrospray tandem mass spectrometry

A selective and sensitive liquid chromatography/tandem mass spectrometry (LC/MS/MS) method has been developed for the characterization of silymarin in commercially available milk thistle extract. In this study, six main active constituents, including silydianin, silychristin, diastereomers of silybin (silybin A and B) and diastereomers of isosilybin (isosilybin A and B) in silymarin, were completely separated on a YMC ODS-AQ HPLC column using a gradient mobile phase system comprised of ammonium acetate and methanol/water/formic acid. Identification and characterization of the major constituents were based not only on the product ion scan, which provided unique fragmentation information of a selected molecular ion, but also on the specific fragmentation of multiple reaction monitoring (MRM) data, which confirmed the retention times of LC chromatographic peaks. The method was applied in the analysis of human plasma samples in the presence of silymarin and appeared to be suitable for the pharmacokinetic studies in which the discrimination of silymarin constituents is essential.