Stable constitution of artificial oil body for the refolding of IGF1

Over-expression of oleosin-fused IGF1 results in the formation of insoluble aggregates in Escherichia coli occupying 35% of total proteins. In this study, a method based on artificial oil body (AOB) was applied to obtain active IGF1, insulin-like growth factor 1, from its insoluble form in one step. The stability of AOB emulsions constituted with soybean oleosin was maximized in the optimal composition of TAG (97.04%, wt/wt), PL (1.14%, wt/wt), and oleosin-UbIGF1 (1.82%, wt/wt) at pH 7.5 and at 25°C. Upon sonication, the mixture comprising plant oil and the insoluble fusion protein was readily assembled into AOBs. After peptide cleavage mediated by endopeptidase, the IGF1 free of fusion tags was liberated and then recovered. Subsequently, IGF1 self-refolded on AOB was obtained with high yield of 63.2 mg/g dry cell. This on-AOB refolding can be applied to the development of bacterial expression and purification of other active recombinant proteins.     

Facilitative production of an antimicrobial peptide royalisin and its antibody via an artificial oil-body system

Royalisin found in the royal jelly of Apis mellifera is an antimicrobial peptide (AMP). It has a molecular weight of 5.5 kDa, which contains six cysteine residues. In this study, royalisin was overexpressed in Escherichia coli AD494 (DE3) as two oleosin-fusion proteins for preparation of its antibodies and functional purification. The recombinant royalisin, fused with oleosin central hydrophobic domain in both N- and C-termini, was reconstituted with triacylglycerol and phospholipids to form artificial oil bodies (AOBs). The AOBs were then purified to raise the antibodies. These antibodies could recognize both the native and recombinant royalisins, but not oleosin. Another oleosin-intein S-fusion protein was purified by AOBs system, and royalisin was subsequently released from the AOBs through self-splicing of the intein. The recombinant royalisin exhibited high antibacterial activity, which suggested that it was refolded to its functional structure. These results demonstrated that AOBs system is an efficient method to functionally express and purify small AMPs. In addition, it also provides a facile platform for the production of antibodies against small peptides.     

Optimized expression, solubilization and purification of nuclear inclusion protein b of cardamom mosaic virus

All RNA viruses encode an RNA-dependent RNA polymerase (RdRP) that is required for replication of the viral genome. Nuclear inclusion b (NIb) gene codes for the RdRp in Potyviridae viruses. In this study, expression, solubilization and purification of NIb protein of Cardamom mosaic virus (CdMV) is reported. The objective of the present study was to express and purify the NIb protein of CdMV on a large scale for structural characterization, as the structure of the RdRp from a plant virus is yet to be determined. However, the expression of NIb protein with hexa-histidine tag in Escherichia coli led to insoluble aggregates. Out of all the approaches [making truncated versions to reduce the size of protein; replacing an amino acid residue likely to be involved in hydrophobic intermolecular interactions with a hydrophilic one; expressing the protein along with chaperones; expression in Origami cells for proper disulphide bond formation, in E. coli as a fusion with maltose-binding protein (MBP) and in Nicotiana tabacum] to obtain the RdRp in a soluble form, only expression in E. coli as a fusion with MBP and its expression in N. tabacum were successful. The NIb expressed in plant or as a fusion with MBP in E. coli can be scaled up for further work.     

Statistical optimization of one-step immobilization process for recombinant endoglucanase from Clostridium thermocellum

Endoglucanase CelA from Clostridium thermocellum (CtCelA) is a thermophilic endo-β-1,4-glucanase and has a low solubility when expressed in Escherichia coli. To make industrial application of CtCeA more appealing, artificial oil bodies (AOBs) was implemented for one-step renaturation and immobilization of recombinant CtCelA. CtCelA was first fused with oleosin (Ole-CtCelA), a structural protein of plant seed oils. Ole-CtCelA was overexpressed in E. coli, and its insoluble form was recovered and mixed with plant oils to assemble AOBs. Moreover, the Box–Behnken design and the central composite design were employed to optimize the condition for assembly of AOBs and the enzymatic reaction condition, respectively. Consequently, the approach led to the resumption of active CtCelA on AOBs. CtCelA-bound AOBs exhibited an optimum activity at 69 °C and pH 6.3 while the immobilized protein remained stable for several hours at 70 °C and after 5 repeated uses. Overall, it indicates a promise of this novel approach for direct processing and immobilization of recombinant CtCelA.     

Expression of cDNA for batroxobin, a thrombin-like snake venom enzyme

The cloned cDNA for batroxobin has been expressed in E. coli. Batroxobin could only be obtained as intracellular aggregates of fusion proteins, fused with a small peptide. To obtain the mature batroxobin, the recognition sequence for thrombin was inserted between the peptide and the mature batroxobin. This fusion protein accumulated in an insoluble form and could easily be purified. After site-specific cleavage of the fusion protein with thrombin, recombinant batroxobin was isolated by preparative electrophoresis. Batroxobin with enzymatic activity was obtained by the refolding of recombinant batroxobin.     

Increasing the yield of soluble recombinant protein expressed in E. coli by induction during late log phase

Recombinant mammalian proteins expressed in E. coli can be difficult to purify in high yield in a soluble and functional form. Various techniques have been described to prevent proteolysis of expressed proteins and/or their sequestering as insoluble aggregates within inclusion bodies. We report conditions for expressing recombinant proteins from E. coli that significantly enhanced the yield of soluble and functional protein. We demonstrate high-yield recovery of a native, high-molecular-weight RNA binding protein without the aid of fusion protein sequence. The principle factor that increased protein yield was the induction of protein expression in a late log phase culture, although reduced temperature during the induction and a low IPTG concentration also contributed to a higher yield.     

Refolding and simultaneous purification by three-phase partitioning of recombinant proteins from inclusion bodies

Many recombinant eukaryotic proteins tend to form insoluble aggregates called inclusion bodies, especially when expressed in Escherichia coli. We report the first application of the technique of three-phase partitioning (TPP) to obtain correctly refolded active proteins from solubilized inclusion bodies. TPP was used for refolding 12 different proteins overexpressed in E. coli. In each case, the protein refolded by TPP gave either higher refolding yield than the earlier reported method or succeeded where earlier efforts have failed. TPP-refolded proteins were characterized and compared to conventionally purified proteins in terms of their spectral characteristics and/or biological activity. The methodology is scaleable and parallelizable and does not require subsequent concentration steps. This approach may serve as a useful complement to existing refolding strategies of diverse proteins from inclusion bodies.     

Enhanced soluble protein expression using two new fusion tags

Production of soluble recombinant proteins is vital for structure-function analysis and therapeutic applications. Unfortunately, when expressed in a heterologous host, such as Escherichia coli, most proteins are expressed as insoluble aggregates. Two new fusion partners have been identified to address these solubility problems. One of the tags was derived from a bacteriophage T7 protein kinase and the other one from a small E. coli chaperone, Skp. We have expressed a panel of insoluble human proteins including Hif1alpha, IL13, and folliculin as fusion proteins using these tags. Most of these fusion proteins were able to be expressed in a soluble form and could be purified by virtue of a Strep-tag II installed at the amino-terminal end of the fusion partners. In addition, we show that some of these proteins remained soluble after removal of the fusion tags by a site-specific protease. The results with these tags compare favorably to results with the most commonly used solubility tags described in the literature. Therefore, these two new fusion tags have the potential to express soluble proteins when fused with many recalcitrant proteins.     

Comparative evaluation of two purification methods of anti-CD19-c-myc-His6-Cys scFv

Different chromatographic methods have been used to purify bacterially expressed single chain antibodies in soluble or insoluble form. Here, we compared two methods for purification of anti-CD19-c-myc-His6-Cys scFv expressed in Escherichia coli as soluble protein. The protein-L-agarose purification method is a one step purification method that yielded significant amounts of pure protein compared to the two-step Ni-NTA-agarose plus Resource 15S purification method. However, the protein-L purification method exhibited an additional lower molecular weight protein contaminant. Based on results from in vitro gel digestion, mass spectrometry and database search results, we confirmed that the lower molecular weight protein contaminant, which could not be purified by Ni-NTA-agarose and 15S column method, is a degraded product of the full length scFv construct.     

Efficient solubilization of inclusion bodies

The overexpression of recombinant proteins in Escherichia coli leads in most cases to their accumulation in the form of insoluble aggregates referred to as inclusion bodies (IBs). To obtain an active product, the IBs must be solubilized and thereafter the soluble monomeric protein needs to be refolded. In this work we studied the solubilization behavior of a model-protein expressed as IBs at high protein concentrations, using a statistically designed experiment to determine which of the process parameters, or their interaction, have the greatest impact on the amount of soluble protein and the fraction of soluble monomer. The experimental methodology employed pointed out an optimum balance between maximum protein solubility and minimum fraction of soluble aggregates. The optimized conditions solubilized the IBs without the formation of insoluble aggregates; moreover, the fraction of soluble monomer was approximately 75% while the fraction of soluble aggregates was approximately 5%. Overall this approach guarantees a better use of the solubilization reagents, which brings an economical and technical benefit, at both large and lab scale and may be broadly applicable for the production of recombinant proteins.     

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.     

Affinity purification of insoluble recombinant fusion proteins containing glutathione-S-transferase

Prokaryotic expression of polypeptides as fusion proteins with glutathione-S-transferase has recently been reported as a one-step means of purifying recombinant protein. The usefulness of the glutathione-S-transferase/glutathioneagarose system, however, is significantly limited by the frequent synthesis of recombinant proteins in insuluble form by Escherichia coli. We have found that for 5 separate fusion proteins containing glutathione-S-transferase and different domains of the large cystic fibrosis transmembrane conductance regulator, all were packaged in insoluble form by E. coli. Insolubility of these products made them inaccessible to one-step purification utilizing this scheme requires proper folding of recombinant glutathione-S-transferase to allow recognition on glutathione affinity agarose, we investigated the suitability of several alternative approaches for converting insoluble recombinant fusion proteins to a soluble form amenable to glutathione-agarose affinity purification. Low-temperature induction of fusion protein synthesis, but not incubation with anion-exchange resins, led to improved one-step purification of glutathione-S-transferase fusion proteins from E. coli cell lysate using mild, nondenaturing conditions. Solubilization in 8 mol/L urea, but not with other chaotropic agents or detergents, also allowed preparative yields of affinity-purified fusion protein. These techniques increase the usefulness of this recombinant protein purification scheme, and should be broadly applicable to diverse polypeptides synthesized as fusions with glutathione-S-transferase.     

Expression and purification of bioactive soluble murine stem cell factor from recombinant Escherichia coli using thioredoxin as fusion partner

Stem cell factor (SCF) known as the c-kit ligand, plays important roles in spermatogenesis, melanogenesis and early stages of hematopoiesis. As for the latter, SCF is essential for growth and expansion of hematopoietic stem and progenitor cells. We herein describe the production of recombinant murine SCF from Escherichia coli as soluble thioredoxin-fusion protein. The formation of insoluble and inactive inclusion bodies, usually observed when SCF is expressed in E. coli, was almost entirely prevented. After purification based on membrane adsorber technology, the fusion protein was subsequently cleaved by TEV protease in order to release mature mSCF. Following dialysis and a final purification step, the target protein was isolated in high purity. Bioactivity of mSCF was proven by different tests (MTT analogous assay, long-term proliferation assay) applying a human megakaryocytic cell line. Furthermore, the biological activity of the uncleaved fusion protein was tested as well. We observed a significant activity, even though it was less than the activity displayed by the purified mSCF. In summary, avoiding inclusion body formation we present an efficient production procedure for mSCF, one of the most important stem cell cytokines.     

Differential down-regulation of protein kinase C selectively affects IgE-dependent exocytosis and inositol trisphosphate formation.

Recombinant Mu gam gene protein (Mu GAM) synthesized in Escherichia coli accumulates in the form of insoluble inclusion bodies which, after cell lysis and low-speed centrifugation, can be recovered in the pellet fraction. This property was utilized in a purification procedure for Mu GAM based on guanidine hydrochloride denaturation-renaturation followed by a single DEAE-cellulose chromatographic step. The purified Mu GAM was shown by nitrocellulose-filter-binding experiments to bind with high affinity to linear double-stranded DNA and more weakly to supercoiled and single-stranded forms. Mu GAM protects linear DNA from degradation by a variety of exonucleases, but only weakly inhibits endonuclease activity. These results are in accord with a model of Mu GAM conferring protection from exonuclease activity by binding to the ends of DNA.     

Bacterial expression and refolding of human trypsinogen

The expression of recombinant trypsinogens from different mammalian origins in Escherichia coli typically leads to the formation of insoluble aggregates. This work describes the high level expression of human trypsinogen 1 in E. coli using the T7 expression system. Direct expression of trypsinogen was not possible, but the N-terminal fusion of the first 11 amino acids of the T7 protein 10 resulted in an expression level of 200 mg g(-1) bacterial dry mass. A refolding procedure was optimized, and a method using continuous feed of denatured product was developed. Thus the working concentration of trypsinogen could be raised four-fold, while the yield of active protein could be maintained at 20-35%. The refolded trypsinogen was converted to trypsin by autocatalytic activation, and the utility for the detachment of mammalian cells in culture was proven.     

The N-domain of Escherichia coli phosphoglycerate kinase is a novel fusion partner to express aggregation-prone heterologous proteins

As a fusion partner to express aggregation-prone heterologous proteins, we investigated the efficacy of Escherichia coli phosphoglycerate kinase (ePGK) that consists of two functional domains (N- and C-domain) and reportedly has a high structural stability. When the full-length ePGK (F-ePGK) was used as a fusion partner, the solubility of the heterologous proteins increased, but some of them still had a large fraction of insoluble aggregates. Surprisingly, the fusion expression using the N-domain of ePGK (N-ePGK) made the insoluble fraction significantly reduce to less than 10% for all the heterologous fusion proteins tested. Also, we evaluated the efficacy of N-ePGK in making the target proteins be expressed with their own native function or structure. It was found that of human ferritin light chain, bacterial arginine deiminase, human granulocyte colony stimulating factor were synthesized evidently with the self-assembly function, L-arginine-degrading activity, and the correct secondary structure, respectively, through the fusion expression using N-ePGK. These results indicate that N-ePGK is a highly potent fusion partner that can be widely used for the synthesis of a variety of heterologous proteins in E. coli.     

Expression of porcine pancreatic phospholipase A2. Generation of active enzyme by sequence-specific cleavage of a hybrid protein from Escherichia coli.

The cDNA coding for the porcine pancreatic prophospholipase A2 (proPLA) has been cloned and expressed in E. coli. Expression of proPLA could only be obtained in the form of intracellular aggregates after fusing the 15 kDa proPLA to a large (greater than or equal to 45 kDa) bacterial peptide. The fusion protein was readily purified from cell lysates, and specifically cleaved. Cleavage of the fusion protein was achieved with either hydroxylamine (at Asn/Gly sequences in the denatured protein), or trypsin (between the pro- and the mature PLA in the renatured fusion protein). The former method releases a proPLA-like enzyme, while the latter directly yields PLA. Renaturation of the fusion protein was made possible by the use of a recently reported new S-sulphonation method. The released (pro)PLA was purified (yields of 2-3 mg/ltr of culture medium), and showed identical properties compared to native (pro)PLA.     

促进原核表达蛋白可溶性的研究进展

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Gateway vectors for the production of combinatorially-tagged His6-MBP fusion proteins in the cytoplasm and periplasm of Escherichia coli

Many proteins that accumulate in the form of insoluble aggregates when they are overproduced in Escherichia coli can be rendered soluble by fusing them to E. coli maltose binding protein (MBP), and this will often enable them to fold in to their biologically active conformations. Yet, although it is an excellent solubility enhancer, MBP is not a particularly good affinity tag for protein purification. To compensate for this shortcoming, we have engineered and successfully tested Gateway destination vectors for the production of dual His6MBP-tagged fusion proteins in the cytoplasm and periplasm of E. coli. The MBP moiety improves the yield and solubility of its fusion partners while the hexahistidine tag (His-tag) serves to facilitate their purification. The availability of a vector that targets His6MBP fusion proteins to the periplasm expands the utility of this dual tagging approach to include proteins that contain disulfide bonds or are toxic in the bacterial cytoplasm.