两种人源化单链抗体-尿激酶融合基因的构建与表达

Ｓｃｕ ＰＡ 32Ｋ是单链尿激酶 (Ｓｃｕ ＰＡ)分子的Ｎ端肽段被水解后的产物 ,其分子量小但具有与Ｓｃｕ ＰＡ相同的体内外生物活性[1] 。在过去的工作中 ,本实验室利用噬菌体表面呈现技术筛选到 1株对人纤维蛋白特异的鼠源单链抗体[2 ] ,并构建了鼠抗人交联纤维蛋白单链抗体—Ｓｃｕ ＰＡ 32Ｋ融合基因。为解决该融合基因在大肠杆菌中的高表达问题 ,通过在大肠杆菌中表达构建的一系列融合基因的缺失突变体 ,初步认定Ｓｃｕ ＰＡ 32Ｋ基因中两个连排的大肠杆菌稀有密码子ＡＧＧ(精氨酸 )是影响该融合基因表达的主要因素。用ＰＣＲ定位诱变法…     

Oxidative renaturation of hen egg-white lysozyme in polyethylene glycol-salt aqueous two-phase systems.

Aqueous two-phase systems have been widely used for the separation and concentration of proteins. In this work we investigated the possibility of using aqueous two-phase system for the renaturation of inclusion body proteins by studying the effect of polyethylene glycol (PEG)-salt systems on the oxidative renaturation of hen egg-white lysozyme (HEWL) with guanidinium chloride (GdmCl) present in the system. To accomplish phase separation at moderately low concentrations of polymer and salt, the total GdmCl concentration had to be kept low (<1 M). The unfolded protein exhibited very low solubility under these conditions. In an attempt to increase the solubility of the protein, temperatures of 40, 50, and 60 degrees C were investigated. The effect of PEG molecular weight was also addressed. Best renaturation yields were obtained when using PEG 3400 and working at 50 degrees C. However, the total protein concentration had to be kept at a low level of 0.2 mg/mL. Lowering the total GdmCl concentration in the system resulted in increased aggregation.     

Enhanced protein renaturation by temperature-responsive polymers

The application of temperature-sensitive polymer (PNIPAAm) for the renaturation of beta-lactamase from inclusion bodies was investigated. It was observed that PNIPAAm was more effective than PEG in enhancing protein renaturation. At a concentration of 0.1%, PNIPAAm improved the yield of beta-lactamase activity by 41% from 46. 5 to 65.4 IU/mL, compared to 26% with PEG from 46.5 to 58.7 IU/mL. Kinetic study indicated that PNIPAAm did not significantly affect the initial rate of protein renaturation but did increase final activity yield. In the presence of PEG and PNIPAAm, the activity yields increased with temperature, indicating that hydrophobic interactions between denatured protein and polymer molecules contributed to the enhanced protein renaturation with polymers. The sequential addition approach, aiming at enhancing protein renaturation by reducing local protein concentration during renaturation, was also shown effective in enhancing protein renaturation, especially in the presence of polymers. With the sequential addition approach, the activity yield was increased by 60. 5% from 46.5 to 74.6 IU/mL with PNIPAAm. Similar behavior was also observed with PEG. PNIPAAm exhibited similar behavior as PEG on the renaturation of beta-lactamase in terms of temperature effect and concentration effect, indicating that the mechanism for enhanced protein renaturation for the two polymers might be similar. PNIPAAm exhibits a lower critical solution temperature (LCST) of 32 degrees C and can be effectively separated from aqueous solution and recycled. A protein renaturation process employing PNIPAAm, which offers the advantages of enhanced renaturation efficiency, minimum loss of protein aggregates, and ease of polymers recycling, was proposed.     

Optimized procedure for expression and renaturation of recombinant human bone morphogenetic protein-2 at high protein concentrations

A prokaryotic expression system has been used to produce recombinant human bone morphogenetic protein-2 (rhBMP-2). However, low rhBMP-2 yields and protein loss during purification and renaturation are the hurdles in the clinical application. Previous studies have indicated that variables such as temperature, host cell, salt concentration, and culture time affect the final rhBMP-2 yield. The optimization of these conditions in an Escherichia coli culture yielded 28.258 mg of rhBMP-2 per liter of culture. To reduce rhBMP-2 loss during purification and renaturation, we performed purification before renaturation in the prokaryotic expression system instead of using the traditional renaturation-before-purification approach. rhBMP-2 was separated on a Sephacryl S-300 HR column and eluted from a DEAE-Sepharose Fast Flow column. The collected protein was refolded by dialysis with urea buffer, which was followed by dialysis with ultrapure water. The purified rhBMP-2 dimer significantly increased alkaline phosphatase (ALP) activity and osteogenic activity in the femoral muscle and showed the same level of bone-forming activity as natural BMP-2. This optimized procedure for expression and renaturation of rhBMP-2 has potential clinical applications.     

The renaturation of reduced chymotrypsinogen A in guanidine HCl. Refolding versus aggregation

The refolding and reoxidation of fully reduced and denatured chymotrypsinogen A have been studied in the presence of low concentrations of guanidine HCl or urea. Renaturation yields of 60 to 70% were observed when the reoxidation was facilitated by mixtures of reduced and oxidized glutathione. Refolding occurred within a narrow range of denaturant concentration (1.0 to 1.3 M guanidine HCl and 2 M urea) in which the native protein was shown to be stable, and the reduced protein was shown to regain the correct disulfide pairing. Renatured chymotrypsinogen is indistinguishable from the native zymogen in chromatographic behavior, potential chymotryptic activity, sedimentation coefficient, and spectral properties. The kinetics of renaturation were determined. Some of the protein species obtained at various times of renaturation were characterized as incorrectly oxidized molecules which could be renatured by thiol-catalyzed interchange of disulfide bonds.     

重组人瘦素蛋白纯化鉴定及其单克隆抗体制备

大肠杆菌（E.coli）重组表达获得的重组人瘦素蛋白（rh-leptin）,复性、纯化后进行SDS-PAGE电泳和Western-blot印迹杂交鉴定其免疫学活性,免疫小鼠后制备单克隆抗体,结果表明通过对rh-leptin进行复性和纯化,获得了高纯度的具有免疫学活性的rh-leptin蛋白,并获得一株稳定分泌抗rh-leptin单抗的杂交瘤细胞株。瘦素蛋白的纯化及其单克隆抗体的制备,可供瘦素进一步研究应用。     

Renaturation and stabilization of the telomere-binding activity of Saccharomyces Cdc13(451-693)p by L-arginine.

Production of recombinant proteins can be valuable in studying their biological functions. However, recombinant proteins expressed in Escherichia coli sometimes form undesirable insoluble aggregates. Solubilization and renaturation of these aggregates becomes a problem that one needs to solve. Here we used recombinant Cdc13(451-693)p as example to show the presence of l-arginine during renaturation greatly enhanced the renaturation efficiency. Cdc13p is the single-stranded telomere-binding protein of yeast Saccharomyces cerevisiae. The telomere-binding domain has been mapped within amino acids 451-693 of Cdc13p, Cdc13(451-693)p. Recombinant Cdc13(451-693)p was expressed in E. coli as insoluble protein aggregates. Purification of insoluble Cdc13(451-693)p was achieved by denaturing the protein with 6 M guanidine-HCl and followed by Ni-nitrilotriacetic acid agarose column chromatography. Renaturation of Cdc13(451-693)p to the active form was achieved by dialyzing denatured protein in the presence of l-arginine. Moreover, the presence of l-arginine was also helped in maintaining the telomere-binding activity of Cdc13(451-693)p. Taking together, l-arginine might have a general application in renaturation of insoluble aggregates.     

Control of aggregation in protein refolding: a variety of surfactants promote renaturation of carbonic anhydrase II.

The denaturation and renaturation of carbonic anhydrase II (CAII) has been studied in several laboratories. Both thermodynamic and kinetic evidence support the existence of at least two intermediates between denatured and native protein. Previous studies have shown that on rapid dilution of a CAII solution from 5 M to 1 M guanidinium chloride, aggregation strongly competes with renaturation at higher protein concentrations, suggesting an upper limit for [CAII] of approximately 0.1%. Our experiments show 60% renaturation at 0.4% [CAII] and that aggregate formation is partially reversible. This yield can be substantially increased by several surfactant additives, including simple alkanols as well as micelle-forming surfactants. Effective surfactants (promoters) act by suppressing initial aggregate formation, not by dissolving aggregates. Promoters act on either the first folding intermediate (I1) or oligomers thereof. Eight of the 18 surfactants examined showed promoter activity, and no correlation was evident between promoter activity and chemical structure or surface tension lowering. These results indicate discrimination (molecular recognition) by I1 and/or its oligomers.     

Oxidative renaturation of lysozyme at high concentrations

Newly synthesized cloned gene proteins expressed in bacteria frequently accumulate in insoluble aggregates or inclusion bodies. Active protein can be recovered by solubilization of inclusion bodies followed by renaturation of the solubilized (unfolded) protein. The recovery of active protein is highly dependent on the renaturation conditions chosen. The renaturation process is generally conducted at low protein concentrations (0.01-0.2 mg/mL) to avoid aggregation. We have investigated the potential of successfully refolding reduced and denatured hen egg white lysozyme at high concentrations (1 and 5 mg/mL). By varying the composition of the renaturation media, optimum conditions which kinetically favor proper folding over inactivation were found. Solubilizing agents such as guanidinium chloride (GdmCl) and folding aids such as L-arginine present in low concentrations during refolding effectively enhanced renaturation yields by suppressing aggregation resulting in reactivation yields as high as 95%. Quantitatively the kinetic competition between lysozyme folding and aggregation can be described using first-order kinetics for the renaturation reaction and third-order kinetics for the overall aggregation pathway. The rate constants for both reactions have been found to be strongly dependent on denaturant and thiol concentration. This strategy supercedes the necessity to reactivate proteins at low concentrations using large renaturation volumes. The marked increase in volumetric productivity makes this a viable option for recovering biologically active protein efficiently and in high yield in vitro from proteins produced as inclusion bodies within microbial cells. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 54: 221-230, 1997.     

Purification of KBF1, a common factor binding to both H-2 and beta 2-microglobulin enhancers.

An enhancer binding factor, designated KBF1, has been purified from the nuclear extract of mouse BW5147 thymoma cells by five column chromatography steps including a sequence-specific DNA affinity column. Gel retardation and footprint analysis have shown that purified KBF1 has a binding activity specific for both H-2 and beta 2-microglobulin enhancer sequences. After SDS-polyacrylamide gel electrophoresis of the most purified preparation a 48-kd protein showed, after elution and renaturation, a binding activity to both enhancer sequences. These findings suggest that the expression of both H-2 and beta 2-microglobulin genes utilizes a common regulatory mechanism.     

Denaturation-renaturation of the fibrin-stabilizing factor XIII a-chain isolated from human placenta. Properties of the native and reconstituted protein

The denaturation-renaturation transition between the native and unfolded states of the dimeric blood coagulation factor XIIIa has been examined by far-UV circular dichroism, fluorescence spectroscopy, activity measurements, sedimentation equilibrium analysis, and size exclusion high performance liquid chromatography. Guanidine hydrochloride and urea-dependent denaturation in the absence and in the presence of 5mM dithioerythritol or glutathione (5mM GSH) exhibit biphasic transitions. The first stage represents a sharp transition characterized by a change in secondary structure without subunit dissociation. This step is accompanied by the irreversible loss of biological activity. The second transition reflects the dissociation and complete unfolding of the protein to a random coil. After loss of biological activity no reactivation can be accomplished under any of the following conditions: (i) denaturation and renaturation under reducing or non-reducing conditions, (ii) variation of the protein concentration and temperature, (iii) addition of specific ligands (Ca2+, substrate), (iv) presence of stabilizing and/or destabilizing agents. Attempts to renature the protein under standard conditions (0.1 M Tris/HCl pH 7.5-9.0, 5mM DTE, 5mM EDTA) lead to refolding intermediates which exhibit a strong tendency to aggregate. A soluble product of reconstitution can be obtained by refolding at low protein concentration, low temperature, and in the presence of small amounts of destabilizing agents such as arginine or urea in the renaturation buffer at pH 7.5 to 9. The spectroscopic and hydrodynamic characterization of the partially reconstituted (non-native inactive) protein shows that partially reconstituted factor XIIIa exhibits the fluorescence properties and the dimeric structure of the native protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutant proteins of human interleukin 2. Renaturation yield, proliferative activity and receptor binding

Muteins, i.e. proteins altered by mutation of their genes, of interleukin 2 (Il2) were generated by oligonucleotide-directed mutagenesis in vitro. All acidic and basic residues conserved between man and mouse were exchanged as well as four lipophilic residues contained within four hydrophobic segments of the protein. The muteins were produced in Escherichia coli and submitted to a renaturation and purification protocol, before bioactivity and receptor binding of each of them was determined. All muteins besides two (K44/T125 and Q110/T125) could be renatured and purified. One mutein (K94/T125) exhibited a more than tenfold-improved renaturation yield. One amino exchange (Asp-20 to Asn) resulted in an about 20-fold reduction in proliferative activity and high-affinity receptor binding. The binding to the low-affinity Il2-binding protein (Tac antigen) was unimpaired. A second exchange (Arg-38 to Gln) had no effect on proliferative activity. The binding to both the high- and the low-affinity receptor, however, was reduced about 20-fold. Preliminary trials on the stability of these muteins by guanidinium hydrochloride denaturation studies detected no differences between wild-type interleukin 2 and muteins. It is suggested that Asp-20 forms part of the binding site for the large receptor subunit whereas Arg-38 is involved in the contact site to the small subunit.     

Expression of recombinant human nerve growth factor in Escherichia coli.

Nerve growth factor (NGF) is a neurotrophic factor for basal forebrain cholinergic neurons and may be of benefit in neurodegenerative diseases of humans. A method is described to obtain significant amounts of biologically active recombinant human NGF (rhNGF) in one step. RhNGF was expressed in E. coli and the majority of the protein accumulated in inclusion bodies. It was immunoprecipitated by a serum against mouse NGF. Solubilization of the inclusion bodies was done in 3M guanidine HCl and renaturation was effected by dilution and air oxidation in the presence of 6 microM CuSO4. Recoveries were 10-12 micrograms of rhNGF per ml of bacterial suspension. Its biological activity was tested in a bioassay system employing sympathetic chick embryo ganglia and was inhibited by the monoclonal antibody 27/21 against mouse NGF.     

The N-glycans of jack bean alpha-mannosidase. Structure, topology and function.

The acid hydrolase alpha-mannosidase, which accumulates in plant vacuoles and probably is involved in the catabolism and turnover of N-linked glycoproteins, is itself a glycoprotein with at least one high-mannose-type and one complex-type N-glycan. The puzzling finding that alpha-mannosidase stably carries its own substrate suggests that the N-glycans have unique topologies, and important functions in protein folding, oligomerization or enzyme activity. As a first step towards the elucidation of this enigma, we purified the N-glycans of jack bean alpha-mannosidase and determined their structures by sugar composition analysis, mass spectrometry and 1H-NMR. The structures of two N-glycans were identified in an approximate ratio of one-to-one: a glucose-containing high-mannose-type glycan (Glc1Man9GlcNAc2) and a small xylose- and fucose-containing complex-type glycan (Xyl1Man1Fuc1GlcNAc2). Isolation and sequencing of glycopeptides strongly suggests that one high-mannose-type and one complex-type glycan are linked to specific glycosylation sites of the large alpha-mannosidase subunit. The high-mannose-type glycan, which is a good substrate of the endoglycosidase (endo-H), can only be removed from the enzyme after denaturation and cleavage of disulfide bonds by a reducing agent, suggesting that this glycan is buried within the folded polypeptide and, thus, protected from its hydrolytic activity. Denaturation and reduction of the native enzyme led to a marked decrease in alpha-mannosidase activity. However, the activity could largely be recovered by renaturation in an appropriate renaturation buffer. In contrast, recovery of alpha-mannosidase activity failed when the high-mannose-type glycan was removed by endo-H prior to renaturation, indicating that this glycan appears to be important for enzyme activity.     

Structural, kinetic, and renaturation properties of an induced hydroxypyruvate reductase from Pseudomonas acidovorans.

A hydroxypyruvate reductase has been induced in Pseudomonas acidovorans by growth on glyoxylate. The enzyme has been purified to homogeneity as assessed by the criteria of analytical ultracentrifugation and analytical disc gel electrophoresis. It has a molecular weight of approximately 85,000 and is composed of two identical subunits. The subunits are not interconnected by disulfide bonds although the enzyme has 4 mol of half-cystine per mol of enzyme. The enzyme catalyzes the reversible conversion of hydroxypyruvate to D(minus)-glycerate in the presence of NADH. Glyoxylate cannot replace hydroxypyruvate as a substrate and is a competitive inhibitor of hydroxypyruvate reduction. The activity of the enzyme toward hydroxypyruvate is anion-modulated; the activity of the enzyme toward D(minus)-glycerate is unaffected by anions but is increased by tris-(hydroxymethyl)aminomethane. The subunits of the induced hydroxypyruvate reductase can be renatured. After the enzyme is dissociated in solutions of 6.0 M guanidine hydrochloride containing 0.1 M 2-mercaptoethanol, optimum renaturation occurs when subunits are diluted into a renaturation solvent consisting of 0.04 M Trischloride, pH 7.4, containing 25% glycerol, 25 mM 2-mercaptoethanol, and 0.14 MM NADH. NAD is an inhibitor of renaturation and therefore cannot substitute for NADH. The optimal temperature of dilution and subsequent incubation is 15 degrees, and increases in protein concentration up to 1.2 mg/ml, the highest concentration tested, improve both the rate of renaturation and the yield of active material. The half-time of renaturation at a protein concentration of 1.2 mg/ml was 1 min. The kinetics of renaturation is second order, i.e., is compatible with a bimolecular reaction preducted by the association of two similar subunits. The physical and kinetic parameters of the renatured protein are the same as those of the native enzyme.     

Detection of poly(ADP ribose) polymerase in crude extracts by activity-blot.

We have recently devised an activity-blot procedure permitting the detection, on the same nitrocellulose sheet, of the functional poly(ADP ribose) polymerase (PARP) activity as well as the immunostained active peptide(s) after renaturation of the transferred protein(s). Using this technique we have analyzed the PARP activity in higher and lower eukaryotes directly on crude extracts from cell cultures. This procedure has been extended also to in situ screening of bacterial colonies expressing the PARP enzymatic activity.     

ATP causes small heat shock proteins to release denatured protein.

Small heat-shock proteins (sHSPs) are a ubiquitous family of low molecular mass (15-30 kDa) stress proteins that have been found in all organisms. Under stress, sHSPs such as alpha-crystallin can act as chaperones binding partially denatured proteins and preventing further denaturation and aggregation. Recently, it has been proposed that the function of sHSPs is to stabilize stress-denatured protein and then act cooperatively with other HSPs to renature the partially denatured protein in an ATP-dependent manner. However, the process by which this occurs is obscure. As no significant phosphorylation of alpha-crystallin was observed during the renaturation, the role of ATP is not clear. It is now shown that ATP at normal physiological concentrations causes sHSPs to change their confirmation and release denatured protein, allowing other molecular chaperones such as HSP70 to renature the protein and renew its biological activity. In the absence of ATP, sHSPs such as alpha-crystallin are more efficient than HSP70 in preventing stress-induced protein aggregation. This work also indicates that in mammalian systems at normal cellular ATP concentrations, sHSPs are not effective chaperones.     

Subunit structure and hybrid formation of bovine pyruvate kinases

After denaturing either type M or L pyruvate kinase by guanidine hydrochloride, urea, or low pH, enzymatic activity and quaternary structure can be recovered by diluting the enzyme into buffer containing beta-mercaptoethanol. After denaturation of type M pyruvate kinase by guanidine hydrochloride, the yield and polarization of the intrinsic protein fluorescence, as well as most of the circular dichroism characteristic of the native enzyme, were regained very rapidly, while enzymatic activity was recovered much more slowly. Under the conditions used, about 50% of the original M and 30-50% of the original type L activity were typically recovered. Average half-times for recovery of enzymatic activity were 37 min for type M and 104 min for type L but depended somewhat on the renaturation buffer and on protein concentrations in the renaturation medium. If types M and L pyruvate kinases are renatured together, an approximately random recombination of the two subunits types results in a five-membered hybrid set. We have used this hybridizability to determine the kinetics of reformation of the native tetramer by denaturing each isozyme and beginning its renaturation separately at various times mixing the two isozymes and continuing their renaturation together. These studies indicate that reformation of stable tetramers occurs relatively slowly, qualitatively paralleling the regain of enzymatic activity, and that tetramer formation may be necessary for enzymatic activity. Using a similar technique to test for spontaneous dissociation of the native isozymes in buffer, we find that type L, but not type M, reversibly dissociates into dimers and monomers in buffer solutions. This dissociation is decreased by the presence of the substrate, phosphoenolpyruvate, by Mg2+ ions, or by the allosteric effector, fructose bisphosphate.