大肠杆菌二硫键形成蛋白A（DsbA）研究进展

二硫键形成蛋白A(DisulfidebondformationproteinA,DsbA)是存在于大肠杆菌周质胞腔内的一种参与新生蛋白质折叠过程中催化二硫键形成的折叠酶。综述了DsbA三维结构、进化过程、协助蛋白质体内外复性方面的研究进展。DsbA比硫氧还原蛋白具有更强的氧化性,其强氧化性来自于Cys30残基异常低的pKa值和不稳定的氧化型结构,通过定点突变的研究表明了Cys30残基是DsbA活性中心最关键的氨基酸残基之一。DsbA不论在体内与目标蛋白融合表达还是在体外以折叠酶形式添加,都能有效地催化蛋白质的折叠复性,同时DsbA还具有部分分子伴侣的活性。     

大肠杆菌二硫键形成蛋白A（DsbA）研究进展

二硫键形成蛋白A（Disulfide bond formation protein A,DsbA）是存在于大肠杆菌周质胞腔内的一种参与新生蛋白质折叠过程中催化二硫键形成的折叠酶。综述了DsbA三维结构、进化过程、协助蛋白质体内外复性方面的研究进展。DsbA比硫氧还原蛋白具有更强的氧化性,其强氧化性来自于Cys³⁰残基异常低的pKa值和不稳定的氧化型结构,通过定点突变的研究表明了Cys³⁰残基是DsbA活性中心最关键的氨基酸残基之一。DsbA不论在体内与目标蛋白融合表达还是在体外以折叠酶形式添加,都能有效地催化蛋白质的折叠复性,同时DsbA还具有部分分子伴侣的活性。     

包含体的体外复性策略

外源基因在大肠杆菌中高水平表达时,通常会形成不溶性、无活性的蛋白聚集体即包含体。包含体富含表达的重组蛋白,经分离、变性溶解后须再经过一个合适的复性过程实现变性蛋白的重折叠,才能够得到生物活性蛋白。近年来,发展了许多特异的策略和方法来从包含体中复性重组蛋白。介绍稀释法、透析及分子排阻、固定化金属离子亲和层析、疏水层析复性等策略和进展;物理化学因素、前导肽协助蛋白折叠;人工分子伴侣辅助蛋白折叠及反胶束、多聚物用于蛋白复性。     

重组人蛋白质二硫键异构酶活性片段的克隆与表达纯化策略

蛋白质二硫键异构酶(protein disulfide somerase,PDI)在体内或体外均可以非特异地催化其它蛋白质的二硫键的形成、还原和异构化,进而辅助蛋白的折叠和复性。近来发现PDI还具有非ATP依赖的分子伴侣的功能。鉴于PDI具有的重要功能,拟利用PDI来辅助基因工程产品的复性,如包含体蛋白(尤其是含有二硫键的蛋白),这将为基因工程产品的下游纯化复性,开拓新的思路。PDI含有两个硫氧还蛋白(thioredoxin,TRX)同源区a区和a′区,各含有一个CGHC活性位点,与TRX的CGPC位点同源。a区和a′区各具有50％的二硫键异构     

大肠杆菌L-酒石酸脱氢酶β亚基体外分子交联

为证明高音等提出的蛋白质交联三步假说,通过PCR技术扩增大肠杆菌L-酒石酸脱氢酶β亚基（L—tartrate dehydratase beta subunit,TtdB）野生型与Cys／Ser突变型目的基因,构建带6×His标签的诱导型表达载体pTrcHisC-TtdB。重组蛋白以包含体形式存在,应用TALON固定化金属亲和树脂（Immobilized metal affinity chromatography,IMAC）以变性的方法纯化,通过分步透析逐步去除变性利的方法复性,复性率可达70％。将复性后的两种蛋白通过热诱导去折叠和氧化重折叠方法进行体外蛋白质分子交联实验。SDS—PAGE分析表明：野生型TtdB在其变性的临界温度反应时,出现交联二聚体和多聚体;在氧化重折叠后SDS—PAGE前加入100mmol／LDTT时,交联强度明显减弱。这种DTT打不开的交联即为异肽键交联;若在其氧化重折叠反应液中加入DTT则没有任何交联。突变型TtdB在与野生型TtdB相同的热诱导去折叠条件下,完全没有二聚体和多聚体的形成。这说明分子间二硫键的形成能促进随后分子间异肽键的形成。     

蛋白质的氧化重折叠

经过近几十年来广泛而深入的研究,蛋白质氧化重折叠的机制已得到相当详细的阐明。1在已研究过的蛋白质中,大多数蛋白质都是沿着多途径而非单一、特定的途径进行氧化重折叠,这与折叠能量景观学说是一致的。2正是氨基酸残基间的天然相互作用而不是非天然的相互作用控制蛋白质的折叠过程。这一结论与含非天然二硫键的折叠中间体在牛胰蛋白酶抑制剂（BPTI）折叠中所起的重要作用并非相互排斥,因为后者仅仅是进行链内二硫键重排的化学反应所必需,与控制肽链折叠无直接关系。3根据对BPTI的研究,二硫键曾被认为仅仅具有稳定蛋白质天然结构的作用,既不决定折叠途径也不决定其三维构象。这一观点不适用于其它蛋白质。对凝乳酶原的研究表明,天然二硫键的形成是恢复天然构象的前提。天然二硫键的形成与肽键的正确折叠相辅相成,更具有普遍意义。4在氧化重折叠的早期,二硫键的形成基本上是一个随机过程,随着肽链的折叠二硫键的形成越来越受折叠中间体构象的限制。提高重组蛋白质的复性产率是生物技术领域中的一个巨大的挑战。除了分子聚集外,在折叠过程中所形成的二硫键错配分子是导致低复性率的另一个主要原因。氧化重折叠机制的阐明为解决此问题提供了有益的启示。如上所述,在折叠的后期,二硫键的形成决定于折叠中间体的构象,类天然、有柔性的结构有利于天然二硫键形成和正确折叠,具有这类结构的分子为有效的折叠中间体,最终都能转变为天然产物;而无效折叠中间体往往具有稳定的结构,使巯基、二硫键内埋妨碍二硫键重排,并因能垒的障碍不利于进一步折叠。因此,降低无效折叠中间体的稳定性使之转变为有效折叠中间体是提高含二硫键蛋白质复性率的一条基本原则,实验证明,碱性pH、低温、降低蛋白质稳定性的试剂、蛋白质二硫键异构酶、改变蛋白质一级结构是实现这一原则的有效手段。此外,这里还就氧化重折叠的基础和应用研究的前景进行了讨论。     

包涵体蛋白体外复性的研究进展

外源基因在大肠杆菌中高水平表达时 ,通常会形成无活性的蛋白聚集体即包涵体。包涵体富含表达的重组蛋白 ,经分离、变性溶解后须再经过一个合适的复性过程实现变性蛋白的重折叠 ,才能够得到生物活性蛋白。近年来 ,发展了许多特异的策略和方法来从包涵体中复性重组蛋白。最近的进展包括固定化复性以及用一些低分子量的添加剂等来减少复性过程中蛋白质的聚集 ,提高活性蛋白的产率。     

大肠杆菌L-酒石酸脱氢酶b亚基体外分子交联

通过PCR技术扩增大肠杆菌L-酒石酸脱氢酶b亚基(L-tartrate dehydratase beta subunit, TtdB)野生型与Cys/Ser突变型目的基因, 构建带6×His标签的诱导型表达载体pTrcHisC-TtdB。重组蛋白以包含体形式存在, 应用TALON固定化金属亲和树脂(Immobilized metal affinity chromatography, IMAC)以变性的方法纯化, 通过分步透析逐步去除变性剂的方法复性, 复性率可达70%。将复性后的两种蛋白通过热诱导去折叠和氧化重折叠方法进行体外蛋白质分子交联实验。SDS-PAGE分析表明: 野生型TtdB在其变性的临界温度反应时, 出现交联二聚体和多聚体; 在氧化重折叠后SDS-PAGE前加入100 mmol/L DTT时, 交联强度明显减弱。这种DTT打不开的交联即为异肽键交联; 若在其氧化重折叠反应液中加入DTT则没有任何交联。突变型TtdB在与野生型TtdB相同的热诱导去折叠条件下, 完全没有二聚体和多聚体的形成。     

凝乳酶原Cys45-Cys50二硫键功能的研究

凝乳酶原突变体Cys45Asp/Cys50Ser包含体溶解所需的温度、时间、pH条件均与野生型一样,而且其氧化再折叠行为与野生型类似,在同样的复性条件下最终都能获得正确折叠可活化的分子.这与缺失Cys250-Cys283二硫键的突变体大不相同,说明Cys45-Cys50二硫键对凝乳酶原正确折叠的贡献小于Cys250-Cys283二硫键,但这对二硫键的缺失使假凝乳酶的热稳定性显著下降,说明此二硫键在稳定酶的空间构象中起重要作用、另外,突变体Cys45Asp/Cys50Ser假凝乳酶的水解蛋白酶活性(P)与凝乳活性(C)均较野生型低,但是其C/P值比野生型高1倍.     

二硫键异构酶

天然二硫键的形成是许多蛋白正确折叠中的限速步骤,在稳定蛋白质构象和保持蛋白质活性方面起重要作用。讨论的二硫键异构酶是内质网中一种重要的蛋白折叠催化剂,它催化蛋白二硫键的形成和错误配对二硫键的重排,并有抑制错误折叠蛋白聚集的分子伴侣活性。PDI广泛应用于基因工程上提高外源蛋白表达水平。     

Renaturation of the reduced bovine pancreatic trypsin inhibitor

Refolding of the reduced pancreatic trypsin inhibitor has been investigated using thiol-disulphide exchange with various disulphide reagents to regenerate the three disulphide bonds. Essentially quantitative renaturation was routinely achieved. The refolded inhibitor was indistinguishable from the original protein in interaction with trypsin and chymotrypsin, electrophoretic mobility, and nature of disulphide bonds.The kinetics of refolding using oxidized dithiothreitol to form the disulphide bonds have been studied in some detail. The renaturation reaction is usually of second-order, being first-order in both inhibitor and disulphide reagent concentrations. A short lag period in the appearance of inhibitor activity and the inhibition of the rate, but not the extent, of renaturation by low levels of reduced dithiothreitol suggest the accumulation of metastable intermediates. In addition, heterogeneity of the refolding reaction is apparent at high concentrations of disulphide reagent, with a fraction of the material being only slowly renatured.     

Substitution of serine for non-disulphide-bond-forming cysteine in grass carp (Ctenopharygodon idellus) growth hormone improves in vitro oxidative renaturation

Native grass carp (Ctenopharygodon idellus) growth hormone, has 5 cysteine amino acid residues, forms two disulphide bridges in its mature form. Recombinant grass carp growth hormone, when over-expressed in E. coli, forms inclusion bodies. In vitro oxidative renaturation of guanidine-hydrochloride dissolved recombinant grass carp growth hormone was achieved by sequential dilution and stepwise dialysis at pH 8.5. The redox potential of the refolding cocktail was maintained by glutathione disulphide/glutathione couple. The oxidative refolded protein is heterogeneous, and contains multimers, oligomers and monomers. The presence of non-disulphide-bond-forming cysteine in recombinant grass carp growth hormone enhances intermolecular disulphide bond formation and also nonnative intramolecular disulphide bond formation during protein folding. The non-disulphide-bond-forming cysteine was converted to serine by PCR-mediated site-directed mutagenesis. The resulting 4-cysteine grass carp growth hormone has improved in vitro oxidative refolding properties when studied by gel filtration and reverse phase chromatography. The refolded 4-cysteine form has less hydrophobic aggregate and has only one monomeric isoform. Both refolded 4-cysteine and 5-cysteine forms are active in radioreceptor binding assay.     

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.     

包涵体蛋白的层析复性技术研究进展

包涵体蛋白的复性是生物工程下游技术中的一个重要难题。层析法用于蛋白质复性是一种较新的、适用于大多数蛋白的方法。其原理是将层析技术应用于蛋白质复性和纯化,使变性蛋白质在层析柱上重折叠为正确的空间构象,在洗脱的同时实现部分纯化。本文详细介绍了蛋白质在5种层析柱上的复性方法、原理、应用及研究的新进展,为层析法对蛋白质复性的进一步应用提供依据。     

Protein refolding assisted by self-assembled nanogels as novel artificial molecular chaperone

Molecular chaperone-like activity for protein refolding was investigated using nanogels of self-assembly of cholesterol-bearing pullulan. Nanogels effectively prevented protein aggregation (i.e. carbonic anhydrase and citrate synthase) during protein refolding from GdmCl denaturation. Enzyme activity recovered in high yields upon dissociation of the gel structure in which the proteins were trapped, by the addition of cyclodextrins. The nanogels assisted protein refolding in a manner similar to the mechanism of molecular chaperones, namely by catching and releasing proteins. The nanogels acted as a host for the trapping of refolded intermediate proteins. Cyclodextrin is an effector molecule that controls the binding ability of these host nanogels to proteins. The present nanogel system was also effective at the renaturation of inclusion body of a recombinant protein of the serine protease family.     

蛋白质复性技术研究进展

评述了蛋白质复性研究的科学背景及蛋白质折叠机制的研究现状 ,详细介绍近年来蛋白质复性技术的研究进展 ,包括稀释添加技术和各种辅助因子的作用、固定化辅助因子应用、尺寸排阻色谱和固定化辅助因子色谱等。     

Estimating the potential refolding yield of recombinant proteins expressed as inclusion bodies

Recombinant protein production in bacteria is efficient except that insoluble inclusion bodies form when some gene sequences are expressed. Such proteins must undergo renaturation, which is an inefficient process due to protein aggregation on dilution from concentrated denaturant. In this study, the protein-protein interactions of eight distinct inclusion-body proteins are quantified, in different solution conditions, by measurement of protein second virial coefficients (SVCs). Protein solubility is shown to decrease as the SVC is reduced (i.e., as protein interactions become more attractive). Plots of SVC versus denaturant concentration demonstrate two clear groupings of proteins: a more aggregative group and a group having higher SVC and better solubility. A correlation of the measured SVC with protein molecular weight and hydropathicity, that is able to predict which group each of the eight proteins falls into, is presented. The inclusion of additives known to inhibit aggregation during renaturation improves solubility and increases the SVC of both protein groups. Furthermore, an estimate of maximum refolding yield (or solubility) using high-performance liquid chromatography was obtained for each protein tested, under different environmental conditions, enabling a relationship between "yield" and SVC to be demonstrated. Combined, the results enable an approximate estimation of the maximum refolding yield that is attainable for each of the eight proteins examined, under a selected chemical environment. Although the correlations must be tested with a far larger set of protein sequences, this work represents a significant move beyond empirical approaches for optimizing renaturation conditions. The approach moves toward the ideal of predicting maximum refolding yield using simple bioinformatic metrics that can be estimated from the gene sequence. Such a capability could potentially "screen," in silico, those sequences suitable for expression in bacteria from those that must be expressed in more complex hosts.     

In vitro folding and thermodynamic stability of an antibody fragment selected in vivo for high expression levels in Escherichia coli cytoplasm.

We recently isolated a mutant of a human anti-beta-galactosidase single chain antibody fragment (scFv) able to fold at high levels in Escherichia coli cytoplasm. When targeted to the periplasm, this mutant and the wild-type scFv are both expressed at comparable levels in a soluble, active and oxidized form. If a reducing agent is added to the growth medium, only the mutant scFv is still able to fold, showing that in vivo aggregation is a direct consequence of the lack of disulphide bond formation and not of the cellular localization. In vitro denaturation/renaturation experiments show that the mutant protein is more stable than the wild-type scFv. Furthermore, refolding kinetics under reducing conditions show that the mutant folds faster than the wild-type protein. Aggregation does not proceed from the native or unfolded conformation of the protein, but from a species only present during the unfolding/refolding transition. In conclusion, the in vivo properties of the mutant scFv can be explained by, first, an increase in the stability of the protein in order to tolerate the removal of the two disulphide bonds and, second, a modification of its folding properties that reduces the kinetic competition between folding and aggregation of a reduced folding intermediate.     

Refolding of therapeutic proteins produced in Escherichia coli as inclusion bodies

Overexpression of cloned or synthetic genes in Escherichia coli often results in the formation of insoluble protein inclusion bodies. Within the last decade, specific methods and strategies have been developed for preparing active recombinant proteins from these inclusion bodies. Usually, the inclusion bodies can be separated easily from other cell components by centrifugation, solubilized by denaturants such as guanidine hydrochloride (Gdn-HCl) or urea, and then renatured through a refolding process such as dilution or dialysis. Recent improvements in renaturation procedures have included the inhibition of aggregation during refolding by application of low molecular weight additives and matrix-bound renaturation. These methods have made it possible to obtain high yields of biologically active proteins by taking into account process parameters such as protein concentration, redox conditions, temperature, pH, and ionic strength.     

Protein renaturation with simultaneous purification by protein folding liquid chromatography: recent developments

Protein folding liquid chromatography (PFLC) is a powerful tool for protein refolding with simultaneous purification. We review its recent progress in liquid chromatography and molecular biology, primarily involving the validation of PFLC refolding of proteins containing multiple disulphide bonds, the application of mixed-mode chromatography, PFLC in molecular biology. Representative examples are described.