Disulfide bonds and the stability of globular proteins.

An understanding of the forces that contribute to stability is pivotal in solving the protein-folding problem. Classical theory suggests that disulfide bonds stabilize proteins by reducing the entropy of the denatured state. More recent theories have attempted to expand this idea, suggesting that in addition to configurational entropic effects, enthalpic and native-state effects occur and cannot be neglected. Experimental thermodynamic evidence is examined from two sources: (1) the disruption of naturally occurring disulfides, and (2) the insertion of novel disulfides. The data confirm that enthalpic and native-state effects are often significant. The experimental changes in free energy are compared to those predicted by different theories. The differences between theory and experiment are large near 300 K and do not lend support to any of the current theories regarding the stabilization of proteins by disulfide bonds. This observation is a result of not only deficiencies in the theoretical models but also from difficulties in determining the effects of disulfide bonds on protein stability against the backdrop of numerous subtle stabilizing factors (in both the native and denatured states), which they may also affect.     

层析辅助体外复性含有多对二硫键的融合蛋白质

为建立一种基于阴离子交换介质辅助的含多对二硫键的抗凝溶栓双功能水蛭素12肽-瑞替普酶融合蛋白质 (HV12p-rPA) 的复性方法,采用Q Sepharose XL作为层析复性介质,通过正交实验考察蛋白质上样量、流速、脲梯度、洗脱液中精氨酸浓度、脲浓度、pH、还原型及氧化型谷胱甘肽等因素对复性过程的影响,探索最佳层析复性条件。结果表明：脲梯度、上样量及精氨酸浓度是影响复性的3个主要因素。脲梯度是复性成功的关键,上样量增大时复性蛋白质比活降低,精氨酸辅助HV12p-rPA复性的最佳浓度为1 mol/L。创建了脲、pH双梯度下的阴离子交换层析辅助HV12p-rPA的复性方法,复性后蛋白质的溶栓比活达到46 520 IU/mg,抗凝比活达到9 980 ATU/mg,与稀释复性方法相比,该方法能使复性蛋白质的溶栓比活提高14~15倍,抗凝比活提高7~8倍。     

Probing protein folding and stability using disulfide bonds

Disulfide bonds are required to stabilize the folded conformations of many proteins. The rates and equilibria of processes involved in disulfide bond formation and breakage can be manipulated experimentally and can be used to obtain important information about protein folding and stability. A number of experimental procedures for studying these processes, and approaches to interpreting the resulting data, are described here.     

乳糖诱导高分子量重组蛛丝蛋白发酵培养基优化

在M9培养基的基础上,以乳糖为诱导剂,对基因重组蛛丝蛋白工程菌pNSR32/BL21(DE3)的发酵培养基进行了优化。利用单因子实验和正交试验优化出表达高分子量重组蛛丝蛋白的最优培养基配方,结果表明：优化的碳源为0.3%的甘油,氮源为3%的酵母膏、0.75％的蛋白胨和0.05％(NH4)2SO4及少量的无机盐。优化培养基有利于菌体的生长和目的蛋白的表达,表达重组蛛丝蛋白达总蛋白量的20%。     

Complete localization of disulfide bonds in GM2 activator protein.

Lysosomal degradation of ganglioside GM2 by hexosaminidase A requires the presence of a small, non-enzymatic cofactor, the GM2-activator protein (GM2AP). Lack of functional protein leads to the AB variant of GM2-gangliosidosis, a fatal lysosomal storage disease. Although its possible mode of action and functional domains have been discussed frequently in the past, no structural information about GM2AP is available so far. Here, we determine the complete disulfide bond pattern of the protein. Two of the four disulfide bonds present in the protein were open to classical determination by enzymatic cleavage and mass spectrometry. The direct localization of the remaining two bonds was impeded by the close vicinity of cysteines 136 and 138. We determined the arrangement of these disulfide bonds by MALDI-PSD analysis of disulfide linked peptides and by partial reduction, cyanylation and fragmentation in basic solution, as described recently (Wu F, Watson JT, 1997, Protein Sci 6:391-398).     

蛛丝蛋白基因在大肠杆菌中表达研究

利用大腹园蛛基因组文库筛选获得一段693 bp基因片段,经分析该段基因处于鞭毛状丝基因重复区域,且其中包含了一个完整的重复框架。通过基因密码子优化,在其3′和5′端分别融合蛋白质亲和层析标签,克隆于pET30LIC表达载体中,在不同的大肠杆菌中进行表达试验。实验结果显示:经过密码子优化,融合目的蛋白基因在BL21(DE3)中得到了高效表达,产量达到25~30mg/L,纯化产物纯度达90%以上。SDS-PAGE和W estern-b lotting检测目的融合蛋白均与预期蛋白大小一致。     

Disulfide crosslinks to probe the structure and flexibility of a designed four-helix bundle protein.

The introduction of disulfide crosslinks is a generally useful method by which to identify regions of a protein that are close together in space. Here we describe the use of disulfide crosslinks to investigate the structure and flexibility of a family of designed 4-helix bundle proteins. The results of these analyses lend support to our working model of the proteins' structure and suggest that the proteins have limited main-chain flexibility.     

含分子内佐剂的SARS-CoV-2 RBD域重组蛋白制备及免疫效果评价北大核心CSCD

制备含破伤风毒素肽(tetanus toxin,TT)、促吞噬肽(tuftsin)和新型冠状病毒刺突蛋白(spike,S蛋白)受体结合域(receptor-binding domain,RBD)的融合蛋白,探讨分子内佐剂对RBD蛋白体液免疫和细胞免疫效果的影响。将破伤风毒素肽、促吞噬肽与S蛋白RBD区域通过柔性多肽串联,密码子优化后构建重组载体,原核表达纯化制备重组S-TT-tuftsin蛋白,与铝佐剂混合后免疫BALB/c小鼠,对其体液及细胞免疫效果进行评价。重组S-TT-tuftsin蛋白以包涵体形式表达,离子交换层析纯化后采用梯度透析进行复性,复性蛋白经Dot blotting鉴定,可与新冠亚单位疫苗(安徽智飞公司)免疫后人血清发生反应。小鼠免疫实验结果表明,免疫35 d时抗体水平到达平台期,含分子内佐剂重组蛋白(铝佐剂)免疫小鼠后血清ELISA抗体效价高达1︰66240,显著高于S-RBD蛋白(铝佐剂)免疫小鼠抗体效价(P<0.05)。同时,含分子内佐剂重组蛋白刺激小鼠产生更强的淋巴细胞增殖能力,刺激指数可达4.71±0.15,相较于S-RBD蛋白的刺激指数1.83±0.09具有显著性差异(P<0.0001)。分子内佐剂破伤风毒素肽和促吞噬肽可显著增强新冠S蛋白RBD域的体液免疫和细胞免疫效果,可为新冠亚单位疫苗和其他病毒亚单位疫苗的研制提供理论基础和参考。     

Modeling the role of disulfide bonds in protein folding: Entropic barriers and pathways

The role of disulfide bonds in directing protein folding is studied using lattice models. We find that the stability and the specificity of the disulfide bond interactions play quite different roles in the folding process: Under some conditions, the stability decreases the overall rate of folding; the specificity, however, by yielding a simpler connectivity of intermediates, always increases the rate of folding. This conclusion is intimately related to the selection mechanism entailed by entropic driving forces, such as the loop formation probability, and entropic barriers separating the native and the many native-like metastable states. The folding time is found to be a minimum for a certain range of the effective disulfide bond interaction. Examination of a model, which allows for the formation of disulfide bonded intermediates, suggests that folding proceeds via a threestage multiple pathways kinetics. We show that there are pathways to the native state involving only native-like intermediates, as well as those that are mediated by nonnative intermediates. These findings are interpreted in terms of the appropriate energy landscape describing the barriers connecting low energy conformations. The consistency of our conclusions with several experimental studies is also discussed. © 1995 Wiley-Liss, Inc.     

Nanoparticle self-assembly by a highly stable recombinant spider wrapping silk protein subunit

Artificial spider silk proteins may form fibers with exceptional strength and elasticity. Wrapping silk, or aciniform silk, is the toughest of the spider silks, and has a very different protein composition than other spider silks. Here, we present the characterization of an aciniform protein (AcSp1) subunit named W₁, consisting of one AcSp1 199 residue repeat unit from Argiope trifasciata. The structural integrity of recombinant W₁ is demonstrated in a variety of buffer conditions and time points. Furthermore, we show that W₁ has a high thermal stability with reversible denaturation at ∼71 °C and forms self-assembled nanoparticle in near-physiological conditions. W₁ therefore represents a highly stable and structurally robust module for protein-based nanoparticle formation.     

Native and modeled disulfide bonds in proteins: knowledge-based approaches toward structure prediction of disulfide-rich polypeptides

Structure prediction and three-dimensional modeling of disulfide-rich systems are challenging due to the limited number of such folds in the structural databank. We exploit the stereochemical compatibility of substructures in known protein structures to accommodate disulfide bonds in predicting the structures of disulfide-rich polypeptides directly from disulfide connectivity pattern and amino acid sequence in the absence of structural homologs and any other structural information. This knowledge-based approach is illustrated using structure prediction of 40 nonredundant bioactive disulfide-rich polypeptides such as toxins, growth factors, and endothelins available in the structural databank. The polypeptide conformation could be predicted in 35 out of 40 nonredundant entries (87%). Nonhomologous templates could be identified and models could be obtained within 2 A deviation from the query in 29 peptides (72%). This procedure can be accessed from the World Wide Web (http://www.ncbs.res.in/ approximately faculty/mini/dsdbase/dsdbase.html).     

Functionalized silk assembled from a recombinant spider silk fusion protein (Z‐4RepCT) produced in the methylotrophic yeast Pichia pastoris

Functional biological materials are a growing research area with potential applicability in medicine and biotechnology. Using genetic engineering, the possibility to introduce additional functions into spider silk‐based materials has been realized. Recently, a recombinant spider silk fusion protein, Z‐4RepCT, was produced intracellularly in Escherichia coli and could after purification self‐assemble into silk‐like fibers with ability to bind antibodies via the IgG‐binding Z domain. In this study, the use of the methylotrophic yeast Pichia pastoris for production of Z‐4RepCT has been investigated. Temperature, pH and production time were influencing the amount of soluble Z‐4RepCT retrieved from the extracellular fraction. Purification of secreted Z‐4RepCT resulted in a mixture of full‐length and degraded silk proteins that failed to self‐assemble into fibers. A position in the C‐terminal domain of 4RepCT was identified as being subjected to proteolytic cleavage by proteases in the Pichia culture supernatant. Moreover, the C‐terminal domain was subjected to glycosylation during production in P. pastoris. These observed alterations of the CT domain are suggested to contribute to the failure in fiber assembly. As alternative approach, Z‐4RepCT retrieved from the intracellular fraction, which was less degraded, was used and shown to retain ability to assemble into silk‐like fibers after enzymatic deglycosylation.     

On-column refolding of an insoluble His6-tagged recombinant EC-SOD overexpressed in Escherichia coli

The EC-SOD cDNA was cloned by polymerase chain reaction (PCR) and inserted into the Escherichia coli expression plasmid pET-28a( ) and transformed into E. coli BL21 (DE3). The corresponding protein that was overexpressed as a recombinant His6-tagged EC-SOD was present in the form of inactive inclusion bodies. This structure was first solubilized under denaturant conditions (8.0 M urea). Then, after a capture step using immobilized metal affinity chromatography (IMAC), a gradual refolding of the protein was performed on-column using a linear urea gradient from 8.0 M to 1.5 M in the presence of glutathione (GSH) and oxidized glutathione (GSSG). The mass ratio of GSH to GSSG was 4:1. The purified enzyme was active,showing that at least part of the protein was properly refolded. The protein was made concentrated by ultrafiltration, and then isolated using Sephacryl S-200 HR. There were two protein peaks in the A280 profile.Based on the results of electrophoresis, we concluded that the two fractions were formed by protein subunits of the same mass, and in the fraction where the molecular weight was higher, the dimer was formed through the disulfide bond between subunits. Activities were detected in the two fractions, but the activity of the dimer was much higher than that of the single monomer. The special activities of the two fractions were found to be 3475 U/mg protein and 510 U/mg protein, respectively.     

Engineering antibody fragments to fold in the absence of disulfide bonds

Disulfide bonds play a critical role in the stabilization of the immunoglobulin β-sandwich sandwich. Under reducing conditions, such as those that prevail in the cytoplasm, disulfide bonds do not normally form and as a result most antibodies expressed in that compartment (intrabodies) accumulate in a misfolded and inactive state. We have developed a simple method for the quantitative isolation of antibody fragments that retain full activity under reducing conditions from large mutant libraries. In E. coli, inactivation of the cysteine oxidoreductase DsbA abolishes protein oxidation in the periplasm, which leads to the accumulation of scFvs and other disulfide-containing proteins in a reduced form. Libraries of mutant scFvs were tethered onto the inner membrane of dsbA cells and mutants that could bind fluorescently labeled antigen in the reducing periplasm were screened by Anchored Periplasmic Expression (APEx; Harvey et al., Proc Natl Acad Sci USA 2004;101:9193–9198.). Using this approach, we isolated scFv antibody variants that are fully active when expressed in the cytoplasm or when the four Cys residues that normally form disulfides are substituted by Ser residues.     

Disulfide bond as a structural determinant of prion protein membrane insertion

Conversion of the normal soluble form of prion protein, PrP (PrP^C), to proteinase K-resistant form (PrP^Sc) is a common molecular etiology of prion diseases. Proteinase K-resistance is attributed to a drastic conformational change from α-helix to β-sheet and subsequent fibril formation. Compelling evidence suggests that membranes play a role in the conformational conversion of PrP. However, biophysical mechanisms underlying the conformational changes of PrP and membrane binding are still elusive. Recently, we demonstrated that the putative transmembrane domain (TMD; residues 111–135) of Syrian hamster PrP penetrates into the membrane upon the reduction of the conserved disulfide bond of PrP. To understand the mechanism underlying the membrane insertion of the TMD, here we explored changes in conformation and membrane binding abilities of PrP using wild type and cysteine-free mutant. We show that the reduction of the disulfide bond of PrP removes motional restriction of the TMD, which might, in turn, expose the TMD into solvent. The released TMD then penetrates into the membrane. We suggest that the disulfide bond regulates the membrane binding mode of PrP by controlling the motional freedom of the TMD.     

Expression, purification, and biochemical characterization of a recombinant Iectin of Sarcocystis muris (Apicomplexa) cyst merozoites

The mature major microneme protein of Sarcocystis muris cyst merozoites, which is known as a dimeric lectin with high affinity to galactose and some of its derivatives, was expressed in Escherichia coli as a histidine-tagged fusion protein. The recombinant polypeptide, which was recognized by a monoclonal antibody directed against the native lectin, was purified from inclusion bodies after solubilization and refolding, using a combination of metal chelate and lactose affinity chromatography. The apparent molecular mass of the refolded polypeptide as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoreses was 16 kDa, whereas gel filtration chromatography clearly demonstrated that the recombinant protein, like its native counterpart, exists as a homodimer of two non-covalently associated subunits. Inhibition of haemagglutination suggests that the combining site of the recombinant lectin recognizes N-acetyl-galactosamine as the dominant sugar, thus confirming the correct folding of the monosaccharide combining site in the renatured lectin. To the best of our knowledge, this work represents the first reported detailed characterization of a recombinant lectin from apicomplexan parasites, and may contribute to a better understanding of the process of host cell recognition and invasion by these obligate intracellular protozoa.     

Folding recombinant spider‐silk in H2O: Effect of osmolytes on the solution conformation of a 15‐repeat spider‐silk mimetic

The folding of a recombinant spider silk protein‐polymer in the presence of the tri‐methylamine osmolytes TMANO and Betaine in 80% H₂O is reported. Circular dichroism measurements (CD) reveal an increase in α‐helical secondary structure with increasing osmolyte concentrations, as determined by an increase in ellipticity at 222 nm. Consistent with this observation, the signal for random coil sampling, observed at 205 nm, is greatly reduced with increasing trimethylamine. Fluorescence spectra of a single tyrosine positioned within the conserved 33‐amino acid repeat primary sequence (of the spider‐silk mimetic) complements the conformational changes observed by CD. Importantly, there is a correlation between the number of Alkyl‐groups (CH₃‐) on the amine of the osmolyte and enhanced helicity of the 15‐repeat silk‐mimetic for the osmolytes tested, ie TMANO, Betaine, Sarcosine and Glycine. These preliminary results are applicable to storing and processing recombinant silk sequences in H₂O, an important mile‐stone for widespread use of recombinant silk polymers.     

Folding in vitro of bovine pancreatic trypsin inhibitor in the presence of proteins of the endoplasmic reticulum.

The rates of folding and disulfide bond formation in reduced BPTI were measured in vitro in the presence and absence of total protein from the endoplasmic reticulum. The rates were increased substantially by the endoplasmic reticulum proteins, but only to the extent expected from the known content and activity of protein-disulfide-isomerase. No effects of added ATP or Ca2+ were observed, even though protein-disulfide-isomerase binds Ca2+ tightly.     

Native disulfide bonds greatly accelerate secondary structure formation in the folding of lysozyme.

To assess the respective roles of local and long-range interactions during protein folding, the influence of the native disulfide bonds on the early formation of secondary structure was investigated using continuous-flow circular dichroism. Within the first 4 ms of folding, lysozyme with intact disulfide bonds already had a far-UV CD spectrum reflecting large amounts of secondary structure. Conversely, reduced lysozyme remained essentially unfolded at this early folding time. Thus, native disulfide bonds not only stabilize the cfinal conformation of lysozyme but also provide, in early folding intermediates, the necessary stabilization that favors the formation of secondary structure.