白细胞介素－2的PEG化

用自制的氨基ＰＥＧ化试剂ｒＩＬ－２进行化学修饰,研究了试剂浓度,溶液ｐＨ,反应时间等与ＰＥｃａ－ｒＩＬ－２产率及ＩＬ－２活性保持之间的关系,建立了一套获得稳定修饰度的ＰＥＧ－ｒＩＬ－２的方法。研究发现,反应时间跟修饰度关系不大;溶液ｐＨ对修饰度有一定的影响,中性ｐＨ以上反应都可进行;而试剂浓度直接决定修饰度的高低,过量越多,修饰度越高,而生物活性保留也越低;但低度修饰,对活性几乎没有影响,可保留活性在９５％左右。     

Modification of surface residues of lysine in immunoglobulin G using the spin marker 2,2,5,5-tetramethyl-3-maleimidopyrrolidine-1-oxyl

Exposed lysine residues of human IgG were modified by a spin-label, 2,2,5,5-tetramethyl-3-male-imidopyrrolidine-1-oxyl at pH 9.2. Under these conditions, the degree of modification was about 10 lysine residues per protein molecule. The ESR spectrum of the spin-labeled immunoglobulin was much more mobile than that of spin-labeled immunoglobulin with the modification degree of about 1 residue that was obtained at pH 7.0. Thus, the sharp increase in the modification degree due to the increase in pH by two units leads to a marked loosening of the tertiary structure of the protein in solution, which is just indicated by the mobile ESR spectrum. Lithium chloride added to the solution of spin-labeled immunoglobulin induces a similar "immobilization" of its ESR spectra as sucrose.     

Capillary electrophoretic behavior of milk proteins in the presence of non-ionic surfactants

The electrophoretic behavior of α-lactalbumin and β-lactoglobulins (A and B) in the presence of non-ionic surfactants was studied by capillary electrophoresis (CE), using a poly(ethylene glycol) coated capillary column. The surfactants (Tween 20, Brij 35 and 78) were used as buffer additives. The separation is based on the difference in the strength of protein–surfactant association complexes, which results in a change of the effective electrophoretic mobility. The modification of the electrophoretic mobilities of proteins was observed and this variation permitted the estimation of the interaction between protein and surfactant. The effect of surfactant type and concentration on the migration behavior of protein in CE is discussed. It is found that the retention behavior of the milk proteins (the α-lactalbumin and the β-lactoglobulins) in CE is very different. The pH of the buffer and the surfactant type influence significantly the protein–surfactant interactions.     

Physicochemical characterization of poly(ethylene glycol)-modified anti-GAD antibodies.

Monoclonal antibodies against glutamic acid decarboxylase (anti-GAD) were modified with poly(ethylene glycol) (PEG), and the resulting conjugates were characterized. Monoclonal anti-GAD antibodies were purified from ATCC HB184 hybridoma cells by either cell culture supernatant or ascites fluid from BALB/c mice. Polyclonal rabbit IgG antibodies were also used as a model protein. Polyclonal rabbit IgG or purified anti-GAD was modified by PEG (MW = 5000 or 20000 Da) through either the lysine residues or through the carbohydrate moiety. Lysine modification was performed in PBS (pH 7.4) or 0.1 M borate (pH 9.2) by adding a molar excess (5-80) of a succinimidyl activated propionic acid terminated mPEG (SPA-PEG) while stirring at room temperature. Carbohydrate modifications were performed in PBS (pH 6.2) by first oxidizing the antibody with sodium periodate followed by incubation with hydrazide-terminated PEG followed by reduction with sodium cyanoborohydride. The degree of modification was assessed by 1H NMR or TNBS (trinitrobenzenesulfonic acid). Circular dichroism (CD) spectra were obtained for lysine-modified rabbit IgG at various degrees of modification ranging from 5 to 60 PEG per antibody. Binding was assessed using an ELISA method with GAD or rabbit anti-mouse-IgG (H+L) coated plates. The TNBS and 1H NMR analysis of the modified antibody showed reasonably similar results from 5 to 60 PEG per antibody. The 1H NMR method showed greater sensitivity at low modifications (below 20:1) and was fairly linear up to about 60 PEG per antibody. The CD spectra of the polyclonal rabbit IgG showed only small differences at variously modified antibody. The binding affinity of anti-GAD is lower for all PEG modifications with respect to unmodified anti-GAD. Modifications at pH 7.4 show lower binding to GAD than modifications at pH 9.2. Binding to GAD or anti-mouse-IgG is decreased as the degree of modification is increased. Lysine modifications showed lower binding to GAD or anti-mouse-IgG than carbohydrate modifications. Binding to GAD or anti-mouse-IgG is lower for PEG20000-modified anti-GAD with respect to PEG5000-modified anti-GAD.     

Identification of the modifying sites of mono-PEGylated salmon calcitonins by capillary electrophoresis and MALDI–TOF mass spectrometry

A capillary electrophoretic method (CE) was developed for the determination of the PEG-modification sites of three positional isomers of mono-PEG modified salmon calcitonins (mono-PEG-sCTs). Resistance to proteolytic degradation on the PEG modification sites resulted in different patterns of CE electropherograms for the tryptic digested mono-PEG-sCTs isomers, and the PEG modification sites were assigned accordingly. The PEG-modification sites were also confirmed directly by determining the molecular masses of the tryptic digested PEG-modified fragments of respective mono-PEG-sCT by the matrix-assisted laser desorption ionization time-of-flight (MALDI–TOF) mass spectrometry.     

Action pattern of Valencia orange PME de-esterification of high methoxyl pectin and characterization of modified pectins

Valencia pectinmethylesterase (PME) fractions, B-PME, containing 36 and 13 kDa protein bands and U-PME, containing a 36 and 27 kDa protein bands, were used to de-esterify original pectin (O-Pec) from 73% degree of esterification (%DE) to 63% (B-Pec) and 61% DE (U-Pec), respectively. Most O-Pec eluted from ion exchange chromatography at low salt concentration and a smaller component eluted at higher ionic strength. B-Pec and U-Pec eluted as one broad peak at higher ionic strength. PME modification did not change molecular weight: O-pectin (134,000 g/mol), U-Pec (133,850 g/mol), and B-Pec (132,250 g/mol). The NMR signal of GG and GGG increased after modification, whereas the signal of EE and EEE decreased. The negative zeta-potential increased with pH for all pectins. U-PME and B-PME created differently modified pectins that vary in degree and length of multiple attacks and fraction of the pectin population that was modified.     

The essential role of a free sulfhydryl group in blocking the cholesteryl site of cholesteryl ester transfer protein (CETP)

Cholesteryl ester transfer protein (CETP) has at least one unpaired sulfhydryl residue, which we have shown previously to be in or near the active site region. We investigated the location of this unpaired cysteine residue(s) of CETP using chemical modification with fluorescent sulfhydryl-specific reagents, limited proteolysis, and amino acid/sequence analysis. The kinetics of labeling CETP by either 2-(4'-maleimidylanilino)-naphthalene-6-sulfonic acid (MIANS) or acrylodan were followed by observing the increase in fluorescence of the bound probes. Labeling was inhibited strongly by preincubation of the CETP with either PNU-617, a competitive inhibitor of cholesteryl ester (CE) transport, and TP2 antibody. In addition, the transfer activities of the substrate CE by the modified CETP's were also inhibited but not competitively. Finally, preincubation of the native protein with N-ethylmaleimide (NEM) resulted in inhibition of activity that was dependent upon the time of exposure of the protein to the alkylating agent. These results provide further evidence that there is a cysteine residue in the active site region of CETP and ligands that either react or bind to this residue produce steric hindrance to CE transfer activity. Finally, although not conclusive, results of the protein chemistry experiments with the modified CETP suggest that the cysteine residue at position 333 is unpaired.     

Cholesteryl ester hydroperoxides are biologically active components of minimally oxidized low density lipoprotein

Oxidation of low density lipoprotein (LDL) occurs in vivo and significantly contributes to the development of atherosclerosis. An important mechanism of LDL oxidation in vivo is its modification with 12/15-lipoxygenase (LO). We have developed a model of minimally oxidized LDL (mmLDL) in which native LDL is modified by cells expressing 12/15LO. This mmLDL activates macrophages inducing membrane ruffling and cell spreading, activation of ERK1/2 and Akt signaling, and secretion of proinflammatory cytokines. In this study, we found that many of the biological activities of mmLDL were associated with cholesteryl ester (CE) hydroperoxides and were diminished by ebselen, a reducing agent. Liquid chromatography coupled with mass spectroscopy demonstrated the presence of many mono- and polyoxygenated CE species in mmLDL but not in native LDL. Nonpolar lipid extracts of mmLDL activated macrophages, although to a lesser degree than intact mmLDL. The macrophage responses were also induced by LDL directly modified with immobilized 12/15LO, and the nonpolar lipids extracted from 12/15LO-modified LDL contained a similar set of oxidized CE. Cholesteryl arachidonate modified with 12/15LO also activated macrophages and contained a similar collection of oxidized CE molecules. Remarkably, many of these oxidized CE were found in the extracts of atherosclerotic lesions isolated from hyperlipidemic apoE(-/-) mice. These results suggest that CE hydroperoxides constitute a class of biologically active components of mmLDL that may be relevant to proinflammatory activation of macrophages in atherosclerotic lesions.     

Allosteric regulation of inducer and operator binding to the lactose repressor

The effects of cysteine modification and variations in pH on the equilibrium parameters for inducer and operator binding to the lactose repressor protein were examined. Operator binding affinity was minimally affected by increasing the pH from 7.5 to 9.2, whereas inducer binding was decreased for both the unliganded protein and the repressor-operator complex over the same range. Inducer binding to the repressor became more cooperative at high pH. The midpoint for the change in inducer affinity and cooperativity was pH 8.3; this value correlates well with cysteine ionization. The differential between repressor-operator affinity in the presence and absence of inducer was significantly decreased by modification of the protein with methyl methanethiosulfonate (MMTS). In contrast to unreacted protein, the inducer binding parameters for MMTS-modified repressor were largely unaffected by pH variation. The free energy for formation of the completely liganded protein was calculated for two pathways; the delta G values for these two independent routes were equivalent only for stoichiometries of four inducers and two operators per repressor molecule. All of the binding data were analyzed quantitatively by using a Monod-Wyman-Changeux two-state model for allosteric regulation. The observed dependences of the isopropyl beta-D-thiogalactoside binding curves on pH, DNA concentration, and MMTS modification were fitted by varying only the equilibrium constant between the two conformational states of the protein. With this analysis, high pH favors the T (high operator/low inducer affinity) state, while modification of cysteine-281 with MMTS elicits a shift into the R (high inducer/low operator affinity) state.(ABSTRACT TRUNCATED AT 250 WORDS)     

Microenvironmental effects on enzyme catalysis. A kinetic study of hydrophobic derivatives of chymotrypsin

The aim of this work was to study the role of hydrophobic interactions in the enzymic activity of chymotrypsin. The amino groups of chymotrypsin were chemically modified by aliphatic aldehydes of various chain lengths - acetaldehyde, butyraldehyde, hexanal - and with two aldehydes of different steric hindrance - benzaldehyde and trimethyl acetaldehyde. After a rapid study of the derivated enzymes, the hexylchymotrypsin has been chosen for its new catalytic properties: the Michaelis constant is not modified and the maximal velocity with N-glutaryl-L-phenylalanine-4-nitroaniline is increased to 164%. The increase is due to the increase of the acylation constant, k2, by 230%. The value of k3 is not modified or less modified. In the modified enzyme, 85% of free amino acids are still able to react with trinitrobenzenesulphonic acid. The optimum pH is shifted by one pH unit towards the alkaline pH. The thermodynamic study shows that the catalytic process itself is not modified. The increase in Vm could be a simple increase of k2 linked to a modification of the site or of the protein. The phenomenon described is very specific and obtained only with one modification, hexanal, and with one enzyme, alpha-chymotrypsin.     

Contribution of haemoglobin and membrane constituents modification to human erythrocyte damage promoted by peroxyl radicals of different charge and hydrophobicity

We have investigated the influence of the free radical initiator characteristics on red blood cell lipid peroxidation, membrane protein modification, and haemoglobin oxidation. 2,2'-Azobis(2-amidinopropane) (AAPH) and 4,4'-azobis(4-cyanovaleric acid) (ACV) were employed as free radical sources. Both azo-compounds are water-soluble, although ACV presents a lowed hydrophilicity, as evaluated from octanol/water partition constants. At physiological pH, they are a di-cation and a di-anion, respectively.

AAPH and ACV readily oxidise purified oxyhemoglobin in a very efficient free radical-mediated process, particularly for ACV-derived radicals, where nearly one heme moiety was modified per radical introduced into the system, suggesting that negatively charged radicals react preferentially at the heme group. The radicals derived from both azo-compounds lead to different oxidation products. Methemoglobin, hemichromes and choleglobin were produced in AAPH-promoted hemoglobin oxidation, while ACV-derived radicals predominantly form hemichromes, with very low production of choleglobin.

Red cell damage was evaluated at the level of hemoglobin and membrane constituents modification, and was expressed in terms of free radical doses. Before the onset of the lytic process, ACV leads to more lipid peroxidation than AAPH, and induces a moderate oxidation of intracellular Hb. This intracellular oxidation is markedly increased if ACV hydrophilicity is decreased by lowering the pH. On the other hand, AAPH-derived radicals are considerable more efficient in promoting protein band 3 modification and cell lysis, without significant intracellular hemoglobin oxidation. These results show that the lytic process is not triggered by lipid peroxidation or hemichrome formation, and suggest that membrane protein modification is the relevant factor leading to red blood cell lysis.     

Surfactant-Modified lipase for the catalysis of the interesterification of triglycerides and fatty acids

The lipase-catalyzed intresterification of triglycerides and fatty acids in n-hexane was studied. Initially, lipase Saiken was modified with a surfactant of sorbitan esters so that its dispersibility in hydrophobic organic media was improved. The surfactant-modified lipase formed in the modification process carried out in a buffer solution has 1,3-positional specificity and predominantly catalyzed the interesterification reaction in a microaqueous n-hexane system. The modification technique converted inactive lipases to very active biocatalysts for the interesterification of triglycerides and fatty acids. The pH and the weight ratio of surfactant to enzyme used during the lipase modification process have shown significant effects in determining the recoveries of the protein and enzyme activity from the buffer solution, the protein content of the modified lipase complex after being freeze dried, and the interesterification activity of the complex. The water content in the reaction solution has strongly influenced the enzyme activity as well as the distribution of the products. (c) 1995 John Wiley & Sons, Inc.     

Contribution of haemoglobin and membrane constituents modification to human erythrocyte damage promoted by peroxyl radicals of different charge and hydrophobicity

We have investigated the influence of the free radical initiator characteristics on red blood cell lipid peroxidation, membrane protein modification, and haemoglobin oxidation. 2,2′-Azobis(2-amidinopropane) (AAPH) and 4,4′-azobis(4-cyanovaleric acid) (ACV) were employed as free radical sources. Both azo-compounds are water-soluble, although ACV presents a lowed hydrophilicity, as evaluated from octanol/water partition constants. At physiological pH, they are a di-cation and a di-anion, respectively.

AAPH and ACV readily oxidise purified oxyhemoglobin in a very efficient free radical-mediated process, particularly for ACV-derived radicals, where nearly one heme moiety was modified per radical introduced into the system, suggesting that negatively charged radicals react preferentially at the heme group. The radicals derived from both azo-compounds lead to different oxidation products. Methemoglobin, hemichromes and choleglobin were produced in AAPH-promoted hemoglobin oxidation, while ACV-derived radicals predominantly form hemichromes, with very low production of choleglobin.

Red cell damage was evaluated at the level of hemoglobin and membrane constituents modification, and was expressed in terms of free radical doses. Before the onset of the lytic process, ACV leads to more lipid peroxidation than AAPH, and induces a moderate oxidation of intracellular Hb. This intracellular oxidation is markedly increased if ACV hydrophilicity is decreased by lowering the pH. On the other hand, AAPH-derived radicals are considerable more efficient in promoting protein band 3 modification and cell lysis, without significant intracellular hemoglobin oxidation. These results show that the lytic process is not triggered by lipid peroxidation or hemichrome formation, and suggest that membrane protein modification is the relevant factor leading to red blood cell lysis.     

Quantitative determination of SH groups in low- and high-molecular-weight compounds by an electron spin resonance method

To quantitatively determine SH groups in high- and low-molecular-weight compounds, a disulfide biradical (RS-SR), where R is imidazoline residue, has been used. The biradical is shown to participate in a thiol-disulfide exchange reaction with compounds containing SH groups. In this case the ESR spectra of the biradical RS-SR and the resulting monoradical R-SH are different. The reaction of the biradical with cysteine, glutathione, and human serum albumin has been studied using the ESR method and the rate constants kf of this reaction have been calculated. Studies of the pH dependence of kf indicate that the thiol-disulfide exchange occurs by reaction with mercaptidione. Protein human serum albumin and hemoglobin have been modified by RS-SR. It has been shown that the treatment of modified proteins with reduced glutathione leads to removal of the radical from the protein; such modifications are thus reversible. The method proposed has been used to quantitatively determine the SH groups of cysteine and glutathione in mouse and rat blood. The method is shown to coincide within experimental error with the determination of glutathione and cysteine by titration with p-chloromercuribenzoate or reaction with Ellman's reagent. This method allows detection of 10(-6)-10(-7) M SH compounds even in colored and highly absorbing samples. The kinetics of the SH group modification can also be determined, leading to deduction about accessibility of the SH group in protein.     

Immobilization and characterization of hemoglobin on modified sporopollenin surfaces

Hemoglobin was covalently immobilized onto modified sporopollenin surface with different functional groups by chemical reactions to enhance binding ability of protein. In this study, the influence of various silane linker molecules on the capacity of protein binding was studied. For this purpose, activated sporopollenin was modified by 3-aminopropyltriethoxysilane (APTS), 3-chloropropyltrimethoxysilane (CPTS) and (3-glycidyloxypropyl)trimethoxysilane (GPTS). Hemoglobin (Hb) was immobilized on modified sporopollenin surfaces in phosphate buffer saline solution (PBS, pH 7.4) at 4°C. Results showed that GPTS modified sporopollenin surfaces resulted in the highest binding capacity for Hb. Micro porosity of samples was observed through scanning electron microscopy (SEM) and thermal behavior of the samples were studied with thermogravimetric analysis (TGA) within a temperature range: 25-900°C. TGA studies demonstrated the advantages of silane modification for high temperature applications and illustrated differences of the structures due to the different tail groups.     

Immobilization of β-galactosidase on modified polypropilene membranes

A new immobilized system: β-galactosidase-modified polypropylene membrane was created. It was obtained 13 different carriers by chemical modification of polypropylene membranes by two stages. The first stage is treatment with K(2)Cr(2)O(7) to receive carboxylic groups on membrane surface. The second stage is treatment with different modified agents ethylendiamine, hexamethylenediamine, hydrazine dihydrochloride, hydroxylamine, o-phenylenediamine, p-phenylenediamine, N,N'-dibenzyl ethylenediamine diacetate to receive amino groups. The quantity of the amino groups, carboxylic groups and the degree of hydrophilicity of unmodified and modified polypropilene membranes were determined. β-Galactosidase was chemically immobilized on the obtained carries by glutaraldehyde. The highest relative activity of immobilized enzyme was recorded at membrane modified with 10% hexamethylenediamine (Membrane 5) - 92.77%. The properties of immobilized β-galactosidase on different modified membranes - pH optimum, temperature optimum, pH stability and thermal stability were investigated and compared with those of free enzyme. The storage stability of all immobilized systems was studied. It was found that the most stable system is immobilized enzyme on Membrane 5. The system has kept 90% of its initial activity at 300th day (pH=6.8; 4°C). The stability of the free and immobilized β-galactosidase on the modified membrane 5 with 10% HMDA in aqueous solutions of alcohols - mono-, diol and triol was studied. The kinetics of enzymatic reaction of free and immobilized β-galactosidase on the modified membrane 5 at 20°C and 40°C and at the optimal pH for both forms of the enzyme were investigated. It was concluded that the modified agent - hexamethylenediamine, with long aliphatic chain ensures the best immobilized β-galactosidase system.     

Characterization of proteins in the human serum proteome.

This paper presents a multidimensional profile of the human serum proteome, produced by a two-dimensional protein fractionation system based on liquid chromatography followed by characterization with capillary electrophoresis (CE). The first-dimension separation was done by chromatofocusing over a pH range from 8.5 to 4.0, where proteins were separated by their isoelectric points (pI). In this dimension, fractions were collected based on pH. The first-dimension pI fractions were then resolved in the second dimension by high-resolution, reversed-phase chromatography with a gradient of trifluoroacetic acid (TFA) in acetonitrile and TFA in water. A selected protein fraction collected from the second dimension by time was characterized by CE for molecular-weight estimation and for presence of isoforms. Molecular-weight estimation was done by sodium dodecyl sulfate capillary gel electrophoresis, where proteins were separated in the range of 10,000-225,000 Da. Detection of isoforms was done by capillary isoelectric focusing over a pH range of 3-10. A selected second-dimension fraction that contained the putative serum iron-binding protein transferrin was analyzed by these two CE techniques for molecular-weight determination and the presence of isoforms. The combination of two-dimensional protein fractionation and CE characterization represents an advanced tool for proteomics.     

Reversible blocking of half-cystine residues of proteins and an irreversible specific deamidation of asparagine-67 of S-sulforibonuclease under mild conditions

For use in protein-folding studies, a rapid procedure for the preparation of octa-S-sulforibonuclease A (SO3-RNase A) with 2-nitro-5-(sulfothio)benzoate is described. The modification is specific for thiols and disulfide bonds. The modified protein was characterized and found to be enzymatically inactive and predominantly conformationally disordered. In the absence of thiols, the modified sulfhydryl groups were found to be stable over the pH range of 2-9. However, when the modified protein is incubated at neutral to slightly alkaline conditions for prolonged periods of time or at elevated temperatures, it undergoes a further (irreversible) modification that decreases its net charge at pH 8.0. Evidence is presented that demonstrates that this additional modification is due to the specific deamidation of asparagine-67. When incubated with an excess of reduced and oxidized glutathiones for 24 h at pH 8.2 and 25 degrees C, the reversible sulfo blocking group was removed, and essentially quantitative (94%) native enzymatic activity was regenerated from both SO3-RNase A and its deamidated derivative (SO3-RNase B). Although the two fully active refolded species differ in their elution behavior on ion-exchange chromatography, they are indistinguishable by many other methods. The significance of this finding for studies of the folding of RNase A is discussed.     

Modification of porcine pancreatic lipase with Z-proline

Porcine pancreatic lipase was modified with Z-proline via the constitution of amide bonds between the free amino groups of lipase and the carboxyl groups of Z-proline, which were activated by 1-ethyl-3-(3-dimethylaminopropyl)-carbodiimide (EDC). Different amounts of Z-proline were bound to lipase. Modification degree was determined by 2,4,6-trinitrobenzene sulphonic acid (TNBS), by means of the decrease in free amino groups on lipase. The reason for choosing Z-proline was its unique structural characteristics, protected amino groups, and its effect on protein conformation by reducing the flexibility of the lipase molecule, thus achieving stabilization against changes in pH and temperature.After the modification, porcine pancreatic lipase was found to have new physicochemical characteristics, such as optimum alkaline pH stability and thermal stability at elevated temperatures.     

Modification of a carboxyl group that appears to cross the permeability barrier in the red blood cell anion transporter

A recently developed method for converting protein carboxyl groups to alcohols has been used to examine the functional role of carboxyl groups in the red blood cell inorganic anion-transport protein (band 3). A major goal of the work was to investigate the carboxyl group that is protonated during the proton-sulfate cotransport that takes place during net chloride-sulfate exchange. Three kinds of evidence indicate that the chemical modification (Woodward's reagent K followed by borohydride) converts this carboxyl to an alcohol. First, monovalent anion exchange is inhibited irreversibly. Second, the modification stimulates sulfate influx into chloride-loaded cells and nearly eliminates the extracellular pH dependence of the sulfate influx. (The stimulated sulfate influx in the modified cells is inhibitable by stilbenedisulfonate.) Third, the proton influx normally associated with chloride-sulfate exchange is inhibited by the modification. These results would all be expected if the titratable carboxyl group were converted into the untitratable, neutral alcohol. In addition to altering the extracellular pH dependence of sulfate influx, the chemical modification removes the intracellular pH dependence of sulfate efflux. The modification is performed under conditions in which the reagent does not cross the permeability barrier. The large effect on the intracellular pH dependence of sulfate transport suggests that a single carboxyl group can at different times be in contact with the aqueous medium on each side of the permeability barrier.