The soluble expression of the human renin binding protein using fusion partners: A comparison of ubiquitin,thioredoxin, maltose binding protein and NusA

human renin binding protein (hRnBp), showingN-acetylglucosamine-2-epimerase activity, was over-expressed inE. coli, but was mainly present as an inclusion body. To improve its solubility and activity, ubiquitin (Ub), thioredoxin (Trx), maltose binding protein (MBP) and NusA, were used as fusion partners. The comparative solubilities of the fusion proteins were, from most to least soluble: NusA, MBP, Trx, Ub. Only the MBP fusion did not significantly reduce the activity of hRnBp, but enhanced the stability. The Origami (DE3), permitting a more oxidative environment for the cytoplasm inE. coli, helped to increase its functional activity.     

Enhanced soluble expression of recombinant Flavobacterium heparinum heparinase I in Escherichia coli by fusing it with various soluble partners

Heparinase I (HepA) was originally isolated from Flavobacterium heparinum (F. heparinum) and specifically cleaves heparin/heparan sulfate in a site-dependent manner, showing great promise for producing low molecular weight heparin (LMWH). However, expressing recombinant HepA is extremely difficult in Escherichia coli because it suffers from low yields, insufficient purity and insolubility. In this paper, we systematically cloned and fused the HepA gene to the C-terminus of five soluble partners, including translation initiation factor 2 domain I (IF2), glutathione S-transferase (GST), maltose-binding protein (MBP), small ubiquitin modifying protein (SUMO) and N-utilization substance A (NusA), to screen for their abilities to improve the solubility of recombinant HepA when expressed in E. coli. A convenient two-step immobilized metal affinity chromatography (IMAC) method was utilized to purify these fused HepA hybrids. We show that, except for NusA, the fusion partners dramatically improved the soluble expression of recombinant HepA, with IF2-HepA and SUMO-HepA creating almost completely soluble HepA (98% and 94% of expressed HepA fusions are soluble, respectively), which is the highest yield rate published to the best of our knowledge. Moreover, all of the fusion proteins show comparable biological activity to their unfused counterparts and could be used directly without removing the fusion tags. Together, our results provide a viable option to produce large amounts of soluble and active recombinant HepA for manufacturing.     

The novel Fh8 and H fusion partners for soluble protein expression in Escherichia coli: a comparison with the traditional gene fusion technology

The Escherichia coli host system is an advantageous choice for simple and inexpensive recombinant protein production but it still presents bottlenecks at expressing soluble proteins from other organisms. Several efforts have been taken to overcome E. coli limitations, including the use of fusion partners that improve protein expression and solubility. New fusion technologies are emerging to complement the traditional solutions. This work evaluates two novel fusion partners, the Fh8 tag (8 kDa) and the H tag (1 kDa), as solubility enhancing tags in E. coli and their comparison to commonly used fusion partners. A broad range comparison was conducted in a small-scale screening and subsequently scaled-up. Six difficult-to-express target proteins (RVS167, SPO14, YPK1, YPK2, Frutalin and CP12) were fused to eight fusion tags (His, Trx, GST, MBP, NusA, SUMO, H and Fh8). The resulting protein expression and solubility levels were evaluated by sodium dodecyl sulfate polyacrylamide gel electrophoresis before and after protein purification and after tag removal. The Fh8 partner improved protein expression and solubility as the well-known Trx, NusA or MBP fusion partners. The H partner did not function as a solubility tag. Cleaved proteins from Fh8 fusions were soluble and obtained in similar or higher amounts than proteins from the cleavage of other partners as Trx, NusA or MBP. The Fh8 fusion tag therefore acts as an effective solubility enhancer, and its low molecular weight potentially gives it an advantage over larger solubility tags by offering a more reliable assessment of the target protein solubility when expressed as a fusion protein.     

Solubility-enhancing proteins MBP and NusA play a passive role in the folding of their fusion partners

It is well established that certain highly soluble proteins have the ability to enhance the solubility of their fusion partners. However, very little is known about how different solubility enhancers compare in terms of their ability to promote the proper folding of their passenger proteins. We compared the ability of two well-known solubility enhancers, Escherichia coli maltose-binding protein (MBP) and N utilization substance A (NusA), to improve the solubility and promote the proper folding of a variety of passenger proteins that are difficult to solubilize. We used an intracellular processing system to monitor the solubility of these passenger proteins after they were cleaved from MBP and NusA by tobacco etch virus protease. In addition, the biological activity of some fusion proteins was compared to serve as a more quantitative indicator of native structure. The results indicate that MBP and NusA have comparable solubility-enhancing properties. Little or no difference was observed either in the solubility of passenger proteins after intracellular processing of the MBP and NusA fusion proteins or in the biological activity of solubilized passenger proteins, suggesting that the underlying mechanism of solubility enhancement is likely to be similar for both the proteins, and that they play a passive role rather than an active one in the folding of their fusion partners.     

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.     

Escherichia coli fusion carrier proteins act as solubilizing agents for recombinant uncoupling protein 1 through interactions with GroEL

Fusing recombinant proteins to highly soluble partners is frequently used to prevent aggregation of recombinant proteins in Escherichia coli. Moreover, co-overexpression of prokaryotic chaperones can increase the amount of properly folded recombinant proteins. To understand the solubility enhancement of fusion proteins, we designed two recombinant proteins composed of uncoupling protein 1 (UCP1), a mitochondrial membrane protein, in fusion with MBP or NusA. We were able to express soluble forms of MBP-UCP1 and NusA-UCP1 despite the high hydrophobicity of UCP1. Furthermore, the yield of soluble fusion proteins depended on co-overexpression of GroEL that catalyzes folding of polypeptides. MBP-UCP1 was expressed in the form of a non-covalent complex with GroEL. MBP-UCP1/GroEL was purified and characterized by dynamic light scattering, gel filtration, and electron microscopy. Our findings suggest that MBP and NusA act as solubilizing agents by forcing the recombinant protein to pass through the bacterial chaperone pathway in the context of fusion protein.     

Soluble expression of archaeal proteins in Escherichia coli by using fusion-partners

Expression of archaeal proteins in soluble form is of importance because archaeal proteins are usually produced as insoluble inclusion bodies in Escherichia coli. In this study, we investigated the use of soluble fusion tags to enhance the solubility of two archaeal proteins, d-gluconate dehydratase (GNAD) and 2-keto-3-deoxy-D-gluconate kinase (KDGK), key enzymes in the glycolytic pathway of the thermoacidophilic archaeon Sulfolobus solfataricus. These two proteins were produced as inclusion bodies in E. coli when polyhistidine was used as a fusion tag. To reduce inclusion body formation in E. coli, GNAD and KDGK were fused with three partners, thioredoxin (Trx), glutathione-S-transferase (GST), and N-utilization substance A (NusA). With the use of fusion-partners, the solubility of the archaeal proteins was remarkably enhanced, and the soluble fraction of the recombinant proteins was increased in this order: Trx>GST>NusA. Furthermore, In the case of recombinant KDGKs, the enzyme activity of the Trx-fused proteins was 200-fold higher than that of the polyhistidine-fusion protein. The strategy presented in this work may contribute to the production of other valuable proteins from hyperthermophilic archaea in E. coli.     

hTNFR1在大肠杆菌中可溶性表达及纯化

将人源肿瘤坏死因子Ⅰ型受体（hTNFR1）基因克隆到pET-22b表达载体,成功构建了重组表达质粒pETH1,电转到Escherichia coli BL21（DE3）表达菌株中进行摇瓶发酵。实现了hTNFR1在大肠杆菌表达系统中的重组表达。但目的蛋白全部以包涵体的形式存在于沉淀中。为了提高hTNFR1在大肠杆菌中的可溶性表达,融合标签和分子伴侣两种策略被实施用于辅助hTNFR1的可溶性表达。结果表明,在hTNFR1的N端融合NusA标签后,hTNFR1的可溶性有一定提高;在NusA-hTNFR1基础上,过表达了7种分子伴侣,筛选出tig分子伴侣对hTNFR1蛋白可溶性表达有明显的促进作用,可溶性表达量约占总量的90％;对优化后的hTNFR1表达系统的可溶性蛋白进行Ni-NTA亲和层析纯化后,TEV蛋白酶酶切去除N端的NusA标签,结合Western blot分析鉴定,获得了大量高纯度的hTNFR1蛋白。研究结果为进一步研究hTNFR1的生理学活性及其在疾病治疗方面的应用奠定了良好基础。     

High level soluble production of functional ribonuclease inhibitor in Escherichia coli by fusing it to soluble partners

Ribonuclease inhibitor (RI) is a 50-kDa cytosolic scavenger of pancreatic-type ribonucleases which inhibits ribonucleolytic activity. Expression of recombinant RI is extremely difficult to reach high levels in soluble form in the cytoplasm of Escherichia coli. Here, we utilized five N-terminal fusion partners to improve the soluble expression of RI. Among these five fusion partners which have been screened, maltose-binding protein (MBP), N-utilization substance A (NusA) and translation initiation factor 2 domain I (IF2) have greatly improved the soluble expression level of recombinant murine RI under the drive of T7 promoter, while glutathione S-transferase (GST) and small ubiquitin modifying protein (SUMO) were much less efficient. All these RI-fusion proteins remained to be highly active in inhibiting RNase A activity. Furthermore, all fusion tags can be efficiently removed by enterokinase digestion to generate native RI which results the highest yield to date (>30mg of native RI per liter culture). And a convenient two-step immobilized metal affinity chromatography (IMAC) method has been implemented in our study, comparing with the traditional RNase A affinity chromatography method.     

Production of soluble human interleukin-6 in cytoplasm by fed-batch culture of recombinant E. coli

The major objective of this study is to identify fed-batch culture conditions optimal for the production of human interleukin-6 (hIL-6) in a soluble form. Five different expression vectors were constructed for the expression of hIL-6 and hIL-6s fused with NusA, maltose binding protein (MBP), thioredoxin (Trx) or ubiquitin (Ubi). A series of flask cultures were conducted in LB medium at 37 degrees C. The intact hIL-6 was expressed mostly in the form of inclusion body. More than 95% of the hIL-6 fused with NusA (NusA/hIL-6) and about 90% of MBP/hIL-6 were expressed in a soluble form, whereas Trx/hIL-6 and Ubi/hIL-6 were expressed mostly in the form of inclusion body. Based on this result, NusA was selected as the fusion partner for the production of hIL-6 in the subsequent experiments. A series of pH-stat fed-batch cultures of an E. coli BL21(DE3) transformed with a NusA/hIL-6 expression vector were conducted in a bioreactor with a working volume of about 3 L. As the amount of nitrogen source was increased in the feeding medium, more soluble NusA/hIL-6 was produced, while the total amount was not significantly changed. Under the best conditions tested, about 90% of NusA/hIL-6 was produced in the soluble form. In this case, the concentration of soluble NusA/hIL-6 was 7.5 g/L with a volumetric productivity of 0.43 g/L-h.     

Single amino acid substitutions on the surface of Escherichia coli maltose-binding protein can have a profound impact on the solubility of fusion proteins

Proteins are commonly fused to Escherichia coli maltose-binding protein (MBP) to enhance their yield and facilitate their purification. In addition, the stability and solubility of a passenger protein can often be improved by fusing it to MBP. In a previous comparison with two other highly soluble fusion partners, MBP was decidedly superior at promoting the solubility of a range of aggregation-prone proteins. To explain this observation, we proposed that MBP could function as a general molecular chaperone in the context of a fusion protein by binding to aggregation-prone folding intermediates of passenger proteins and preventing their self-association. The ligand-binding cleft in MBP was considered a likely site for peptide binding because of its hydrophobic nature. We tested this hypothesis by systematically replacing hydrophobic amino acid side chains in and around the cleft with glutamic acid. None of these mutations affected the yield or solubility of MBP in its unfused state. Each MBP was then tested for its ability to promote solubility when fused to three passenger proteins: green fluorescent protein, p16, and E6. Mutations within the maltose-binding cleft (W62E, A63E, Y155E, W230E, and W340E) had little or no effect on the solubility of the fusion proteins. In contrast, three mutations near one end of the cleft (W232E, Y242E, and I317E) dramatically reduced the solubility of the same fusion proteins. The mutations with the most profound effect on solubility were shown to reduce the global stability of MBP.     

Escherichia coli maltose-binding protein is uncommonly effective at promoting the solubility of polypeptides to which it is fused.

Although it is usually possible to achieve a favorable yield of a recombinant protein in Escherichia coli, obtaining the protein in a soluble, biologically active form continues to be a major challenge. Sometimes this problem can be overcome by fusing an aggregation-prone polypeptide to a highly soluble partner. To study this phenomenon in greater detail, we compared the ability of three soluble fusion partners--maltose-binding protein (MBP), glutathione S-transferase (GST), and thioredoxin (TRX)--to inhibit the aggregation of six diverse proteins that normally accumulate in an insoluble form. Remarkably, we found that MBP is a far more effective solubilizing agent than the other two fusion partners. Moreover, we demonstrated that in some cases fusion to MBP can promote the proper folding of the attached protein into its biologically active conformation. Thus, MBP seems to be capable of functioning as a general molecular chaperone in the context of a fusion protein. A model is proposed to explain how MBP promotes the solubility and influences the folding of its fusion partners.     

A combined strategy improves the solubility of aggregation-prone single-chain variable fragment antibodies

Recombinant single-chain variable fragment (scFv) antibodies have wide applications in the areas of biotechnology and medicine. However, there is currently no universal expression-purification system for generating different soluble scFvs. In this study, A15 and E34, two genes coding scFvs against human IL-17A, were fused with N-terminal signal peptide sequences pelB or STII, or with highly hydrophilic tags Trx, NusA, or MBP, respectively. These constructs were expressed in Escherichia coli. We found that the scFvs fused with either NusA or MBP showed a higher solubility than fused with signal peptides or Trx. The scFvs were aggregated when the NusA or MBP was removed by thrombin. Interestingly, we observed a reduction of precipitation when the fusion proteins were expressed in Origami B(DE3)pLysS cells but not in BL21(DE3)pLysS. Because cleaving the tags resulted in the aggregation of scFvs, several solubility-enhancing additives were added in the digestion buffer and only L-arginine (Arg) or Tween20 promoted the solubility. After an affinity chromatography, the scFvs were separated from the tags with the purity up to 90%. The final yield of scFvs from the scFv-MBP system was approximately 8.9 mg/L of culture medium and 1.5 mg/g of wet weight cells, which was 1.6-fold higher than the yield from the scFv-NusA system. The obtained scFvs exhibited normal binding affinities and activities after endotoxin removal. In conclusion, we describe a strategy combining the fusion tags, the Escherichia coli with oxidizing bacterial cytoplasm, and the solubility-enhancing additives for expressing and purifying the soluble and functional scFvs.     

Heterologous protein expression using a novel stress-responsive protein of E. coli RpoA as fusion expression partner

E. coli proteome response to the stressor 2-HEDS was analyzed through two-dimensional gel electrophoresis (2-DE), and we identified DNA-directed RNA polymerase α-subunit (RpoA) as stress-responsive protein. Even under stress situation where the total number of soluble proteins decreased by 9.8%, the synthesis level of RpoA was increased 1.5-fold. As a fusion expression partner as well as solubility enhancer, RpoA facilitated the folding and increased significantly the solubility of many aggregation-prone heterologous proteins (human minipro-insulin, human epidermal growth factor, human prepro-ghrelin, human interleukin-2, human activation induced cytidine deaminase, human glutamate decarboxylase, Pseudomonas putida cutinase, human ferritin light chain, human granulocyte colony-stimulating factor, and cold inflammatory syndrome1 protein Nacht domain) in E. coli cytoplasm. Due probably to intrinsic high folding efficiency and/or chaperone-like activity, RpoA was very effective in shielding interactive surfaces of heterologous proteins that are associated with non-specific protein–protein interaction leading to the formation of inclusion bodies. RpoA was also well suited for the production of biologically active fusion mutant of Pseudomonas putida cutinase that is of much biotechnological and commercial interest.     

New fusion protein systems designed to give soluble expression in Escherichia coli.

Three native E. coli proteins-NusA, GrpE, and bacterioferritin (BFR)-were studied in fusion proteins expressed in E. coli for their ability to confer solubility on a target insoluble protein at the C-terminus of the fusion protein. These three proteins were chosen based on their favorable cytoplasmic solubility characteristics as predicted by a statistical solubility model for recombinant proteins in E. coli. Modeling predicted the probability of soluble fusion protein expression for the target insoluble protein human interleukin-3 (hIL-3) in the following order: NusA (most soluble), GrpE, BFR, and thioredoxin (least soluble). Expression experiments at 37 degrees C showed that the NusA/hIL-3 fusion protein was expressed almost completely in the soluble fraction, while GrpE/hIL-3 and BFR/hIL-3 exhibited partial solubility at 37 degrees C. Thioredoxin/hIL-3 was expressed almost completely in the insoluble fraction. Fusion proteins consisting of NusA and either bovine growth hormone or human interferon-gamma were also expressed in E. coli at 37 degrees C and again showed that the fusion protein was almost completely soluble. Starting with the NusA/hIL-3 fusion protein with an N-terminal histidine tag, purified hIL-3 with full biological activity was obtained using immobilized metal affinity chromatography, factor Xa protease cleavage, and anion exchange chromatography.     

N-terminal domains of native multidomain proteins have the potential to assist de novo folding of their downstream domains in vivo by acting as solubility enhancers

The fusion of soluble partner to the N terminus of aggregation-prone polypeptide has been popularly used to overcome the formation of inclusion bodies in the E. coli cytosol. The chaperone-like functions of the upstream fusion partner in the artificial multidomain proteins could occur in de novo folding of native multidomain proteins. Here, we show that the N-terminal domains of three E. coli multidomain proteins such as lysyl-tRNA synthetase, threonyl-tRNA synthetase, and aconitase are potent solubility enhancers for various C-terminal heterologous proteins. The results suggest that the N-terminal domains could act as solubility enhancers for the folding of their authentic C-terminal domains in vivo. Tandem repeat of N-terminal domain or insertion of aspartic residues at the C terminus of the N-terminal domain also increased the solubility of fusion proteins, suggesting that the solubilizing ability correlates with the size and charge of N-terminal domains. The solubilizing ability of N-terminal domains would contribute to the autonomous folding of multidomain proteins in vivo, and based on these results, we propose a model of how N-terminal domains solubilize their downstream domains.     

Active inclusion body formation using Paenibacillus polymyxa PoxB as a fusion partner in Escherichia coli

Overexpression of Paenibacillus polymyxa PoxB in Escherichia coli induced the formation of inclusion bodies. An enzyme assay showed that the inclusion bodies exhibited PoxB activity, indicating that they were biologically active. Fusion of GFP and Bacillus subtilis AmyE to the C-terminus of the PoxB also induced the formation of biologically active aggregates when they were overexpressed in E. coli. Therefore, P. polymyxa PoxB can be used as a fusion partner to promote the formation of active inclusion bodies in E. coli.     

Comparison of SUMO fusion technology with traditional gene fusion systems: enhanced expression and solubility with SUMO

Despite the availability of numerous gene fusion systems, recombinant protein expression in Escherichia coli remains difficult. Establishing the best fusion partner for difficult-to-express proteins remains empirical. To determine which fusion tags are best suited for difficult-to-express proteins, a comparative analysis of the newly described SUMO fusion system with a variety of commonly used fusion systems was completed. For this study, three model proteins, enhanced green fluorescent protein (eGFP), matrix metalloprotease-13 (MMP13), and myostatin (growth differentiating factor-8, GDF8), were fused to the C termini of maltose-binding protein (MBP), glutathione S-transferase (GST), thioredoxin (TRX), NUS A, ubiquitin (Ub), and SUMO tags. These constructs were expressed in E. coli and evaluated for expression and solubility. As expected, the fusion tags varied in their ability to produce tractable quantities of soluble eGFP, MMP13, and GDF8. SUMO and NUS A fusions enhanced expression and solubility of recombinant proteins most dramatically. The ease at which SUMO and NUS A fusion tags were removed from their partner proteins was then determined. SUMO fusions are cleaved by the natural SUMO protease, while an AcTEV protease site had to be engineered between NUS A and its partner protein. A kinetic analysis showed that the SUMO and AcTEV proteases had similar KM values, but SUMO protease had a 25-fold higher kcat than AcTEV protease, indicating a more catalytically efficient enzyme. Taken together, these results demonstrate that SUMO is superior to commonly used fusion tags in enhancing expression and solubility with the distinction of generating recombinant protein with native sequences.