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.     

AtJ1, a mitochondrial homologue of theEscherichia coli DnaJ protein

The nucleotide sequence of a cDNA clone fromArabidopsis thaliana ecotype Columbia was determined, and the corresponding amino sequence deduced. The open reading frame encodes a protein, AtJ1, of 368 residues with a molecular mass of 41 471 Da and an isoelectric point of 9.2. The predicted sequence contains regions homologous to the J- and cysteine-rich domains ofEscherichia coli DnaJ, but the glycine/phenylalanine-rich region is not present. Based upon Southern analysis,Arabidopsis appears to have a singleatJ1 structural gene. A single species of mRNA, of 1.5 kb, was detected whenArabidopsis poly(A)⁺ RNA was hybridized with theatJ1 cDNA. The function ofatJ1 was tested by complementation of adnaJ deletion mutant ofE. coli, allowing growth in minimal medium at 44°C. The AtJ1 protein was expressed inE. coli as a fusion with the maltose binding protein. This fusion protein was purified by amylose affinity chromatography, then cleaved by digestion with the activated factor X protease. The recombinant AtJ1 protein was purified to electrophoretic homogeneity.In vitro, recombinant AtJ1 stimulated the ATPase activity of bothE. coli DnaK and maize endosperm cytoplasmic Stress70. The deduced amino acid sequence of AtJ1 contains a potential mitochondrial targeting sequence at the N-terminus. Radioactive recombinant AtJ1 was synthesized inE. coli and purified. When the labeled protein was incubated with intact pea cotyledon mitochondria, it was imported and proteolytically processed in a reaction that depended upon an energized mitochondrial membrane.Abbreviations MBP maltose binding protein - PCR polymerase chain reaction - Stress70c the cytosolic member of the 70 kDA family of stress-related proteins     

Fusion with maltose-binding protein (MBP) affects neither RNA N-glycosidase activity nor immunogenicity of karasurin-A, a ribosome-inactivating protein from Trichosanthes kirilowii var. japonica

A genomic clone encoding mature karasurin-A (KRNA), a ribosome-inactivating protein from Trichosanthes kirilowii var. japonica, was efficiently expressed in E. coli using an expression cassette vector pMAL-c2. The resultant recombinant KRNA fused with maltose-binding protein (MBP) was recovered from the soluble fraction of the bacterial cells and purified to near homogeneity after one round of the affinity chromatography. Neither the karasurin precursor retaining both N- and C-terminal peptides, nor the protein with the N-terminal peptide was successufully produced even as a MBP-fusion. The protein with its C-terminal peptide was over-produced but was recovered in an insoluble fraction. Both the recombinant MBP-KRNA fusion protein and recombinant KRNA with MBP removed were as active as the native KRNA from root tubers. The immunogenicity of the recombinant KRNA was also unaffected by fusion with MBP.     

Maltose binding protein facilitates high-level expression and functional purification of the chemokines RANTES and SDF-1alpha from Escherichia coli

The chemokines RANTES (regulated on activation, normal T cell expressed and secreted) and SDF-1α (stromal cell-derived factor-1α) are important regulators of leukocyte trafficking and homing. Chemokines form insoluble inclusion bodies when expressed in Escherichia coli (E. coli), resulting in low yields of soluble protein. We have developed a novel chemokine expression system that generates a high amount of soluble protein and uses a simple purification scheme. We cloned different types of RANTES and SDF-1α fused to either maltose binding protein (MBP) or glutathione-S-transferase (GST) and expressed the fusion proteins in E. coli under various conditions. We found that the yield of soluble chemokine is influenced by the type of fusion partner. Fusion to MBP resulted in a higher yield of total and soluble chemokine compared to GST. Under optimized conditions, the yield of soluble MBP–RANTES and MBP–SDF-1α was 2.5- and 4.5-fold higher than that of the corresponding GST-fusion protein, respectively. Recombinant chemokine fusion proteins exhibited specific binding activity to chemokine receptors. These results demonstrate that the use of MBP-fusion proteins may provide an approach to generating high yields of soluble and functional chemokines, such as RANTES and SDF-1α.     

Single-step purification of proteins of interest from proteolytically cleaved recombinant maltose-binding protein (MBP) fusion proteins by selective immunoprecipitation of MBP

The maltose binding protein (MBP) fusion protein system is a versatile tool to express and isolate recombinant proteins inE. coli. In this system, MBP fusion proteins are efficiently isolated from whole cell lysate using amylose conjugated agarose beads and then eluted by competition with free maltose. Since MBP is a rather large molecule (∼42 kDa), for further experiments, the MBP part is usually proteolytically cleaved from the fusion protein and subsequently removed by ion-exchange chromatography or rebinding to amylose columns after washing out excess and MBP-bound maltose. In the present study, we have developed an improved method for the removal of cleaved MBP, which is advantageous over conventional methods. In this method, factor Xa cleaved MBP fusion proteins were incubated with Sepharose beads conjugated with MBP specific monoclonal antibodies and then precipitated by centrifugation, resulting in highly purified proteins in the supernatant.     

Overproduction of AgfA subunit of Salmonella enteritidis as a MBP-fusion protein in E. coli

To study the characteristics of recombinant thin aggregative fimbriae of salmonella and to develop a vaccine for salmonella infections, the AgfA subunit gene was amplified from Salmonella entiritidis using PCR. Maltose binding protein (MBP)-AgfA fusion protein was over-produced in E. coli and purified. Antibody against MBP-AgfA was prepared and its immunogenicity was studied.     

Expression of aChlamydia anticarbohydrate single-chain antibody as a maltose binding fusion protein

A single-chain antibody fragment has been constructed for an antibody that binds to theChlamydia specific carbohydrate structure of the lipopolysaccharide. Single-chain protein was expressed and secreted into the periplasmic space ofE. coli as a fusion protein with the maltose binding protein. The fusion protein was purified in one step by virtue of its ability to bind to maltose. In a sandwich ELISA, the eluted protein boundChlamydia lipopolysaccharide, which demonstrates that the single-chain protein domain will function as part of a fusion protein. The expression of maltose binding fusion proteins into the periplasmic space could be used for production of other single-chain antibodies or protein fragments requiring appropriate folding and disulfide bond formation.     

Expression of foreign proteins in<Emphasis Type="Italic"> Escherichia coli</Emphasis> by fusing with an archaeal FK506 binding protein

Improper protein-folding often results in inclusion-body formation in a protein expression system using Escherichia coli. To express such proteins in the soluble fraction of E. coli cytoplasm, we developed an expression system by fusing the target protein with an archaeal FK506 binding protein (FKBP). It has been reported that an archaeal FKBP from a hyperthermophilic archaeon, Thermococcus sp. KS-1 (TcFKBP18), possesses not only peptidyl–prolyl cis–trans isomerase activity, but also chaperone-like activity to enhance the refolding yield of an unfolded protein by suppressing irreversible protein aggregation. To study the effect of this fusion strategy with FKBP on the expression of foreign protein in E. coli, a putative rhodanese (thiosulfate sulfurtransferase) from a hyperthermophilic archaeon and two mouse antibody fragments were used as model target proteins. When they were expressed alone in E. coli, they formed insoluble aggregates. Their genes were designed to be expressed as a fusion protein by connecting them to the C-terminal end of TcFKBP18 with an oligopeptide containing a thrombin cleavage site. By fusing TcFKBP18, the expression of the target protein in the soluble fraction was significantly increased. The percentage of the soluble form in the expressed protein reached 10–28% of the host soluble proteins. After purification and protease digestion of the expressed antibody fragment–TcFKBP18 fusion protein, the cleaved antibody fragment (single-chain Fv) showed specific binding to the antigen in ELISA. This indicated that the expressed antibody fragment properly folded to the active form.     

A useful epitope tag derived from maltose binding protein

Maltose binding protein (MBP) is used in recombinant protein expression as an affinity and solubility tag. The monoclonal antibody B48 binds MBP tightly and has no cross‐reactivity to other proteins in an Escherichia coli lysate. This high level of specificity suggested that MBP contains an epitope that could prove useful as a purification and visualization tag for proteins expressed in E. coli. To discover the MBP epitope, a co‐crystal structure was determined for MBP bound to its antibody and four amino acids of MBP were identified as critical for the binding interaction. Fusions of various fragments of MBP to the glutathione S‐transferase protein were engineered in order to identify the smallest fragment still recognized by the α‐MBP antibody. Stabilization of the epitope via mutational engineering resulted in a minimized 14 amino‐acid tag.     

Overproduction and purification of Lon protease fromEscherichia coli using a maltose-binding protein fusion system

Lon protease, which plays a major role in degradation of abnormal proteins inEscherichia coli, was overproduced and efficiently purified using the maltose-binding protein (MBP) fusion vector. The MBP-Lon fusion protein was expressed in a soluble form inE. coli and purified to homogeneity by amylose resin in a single step. Lon protease was split from MBP by cleaving a fusion point between MBP and Lon with factor Xa and purified by amylose resin and subsequent gel filtration. In this simple method, Lon protease was purified to homogeneity. Purified MBP-Lon fusion protein and Lon protease showed similar breakdown activities with a peptide (succinyl-l-phenylalanyl-l-leucyl-phenylalanyl--d-methoxynaphthylamide) and protein (-casein) in the presence of ATP. Therefore, the gene-fusion approach described in this study is useful for the production of functional Lon protease. MBP-Lon fusion protein, which both binds to the amylose resin and has ATP-dependent protease activity, should be especially valuable for its application in the degradation of abnormal proteins by immobilized enzymes.     

The interplay between effector binding and allostery in an engineered protein switch

The protein design rules for engineering allosteric regulation are not well understood. A fundamental understanding of the determinants of ligand binding in an allosteric context could facilitate the design and construction of versatile protein switches and biosensors. Here, we conducted extensive in vitro and in vivo characterization of the effects of 285 unique point mutations at 15 residues in the maltose‐binding pocket of the maltose‐activated β‐lactamase MBP317‐347. MBP317‐347 is an allosteric enzyme formed by the insertion of TEM‐1 β‐lactamase into the E. coli maltose binding protein (MBP). We find that the maltose‐dependent resistance to ampicillin conferred to the cells by the MBP317‐347 switch gene (the switch phenotype) is very robust to mutations, with most mutations slightly improving the switch phenotype. We identified 15 mutations that improved switch performance from twofold to 22‐fold, primarily by decreasing the catalytic activity in the absence of maltose, perhaps by disrupting interactions that cause a small fraction of MBP in solution to exist in a partially closed state in the absence of maltose. Other notable mutations include K15D and K15H that increased maltose affinity 30‐fold and Y155K and Y155R that compromised switching by diminishing the ability of maltose to increase catalytic activity. The data also provided insights into normal MBP physiology, as select mutations at D14, W62, and F156 retained high maltose affinity but abolished the switch's ability to substitute for MBP in the transport of maltose into the cell. The results reveal the complex relationship between ligand binding and allostery in this engineered switch.     

Properties of soluble fusions between mammalian aspartic proteinases and bacterial maltose-binding protein

The mammalian aspartic proteinases procathepsin D and pepsinogen form insoluble inclusion bodies when expressed in bacteria. They become soluble but nonnative when synthesized as fusions to the carboxy terminus of E. coli maltose-binding protein (MBP). Since these nonnative states of the two aspartic proteinases showed no tendency to form insoluble aggregates, their biophysical properties were analyzed. The MBP portions were properly folded as shown by binding to amylose, but the aspartic proteinase moieties failed to bind pepstatin and lacked enzymatic activity, indicating that they were not correctly folded. When treated with proteinase K, only the MBP portion of the fusions was resistant to proteolysis. The fusion between MBP and cathepsin D had increased hydrophobic surface exposure compared to the two unfused partners, as determined by bis-ANS binding. Ultracentrifugal sedimentation analysis of MBP–procathepsin D and MBP–pepsinogen revealed species with very large and heterogeneous sedimentation values. Refolding of the fusions from 8 M urea generated proteins no larger than dimers. Refolded MBP–pepsinogen was proteolytically active, while only a few percent of renatured MBP–procathepsin D was obtained. The results suggest that MBP–aspartic proteinase fusions can provide a source of soluble but nonnative folding states of the mammalian polypeptides in the absence of aggregation.     

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.     

Improving aquaporin Z expression in <Emphasis Type="Italic">Escherichia coli</Emphasis> by fusion partners and subsequent condition optimization

Aquaporin Z (AqpZ), a typical orthodox aquaporin with six transmembrane domains, was expressed as a fusion protein with TrxA in E. coli in our previous work. In the present study, three fusion partners (DsbA, GST and MBP) were employed to improve the expression level of this channel protein in E. coli. The result showed that, compared with the expression level of TrxA-AqpZ, five- to 40-fold increase in the productivity of AqpZ with fusion proteins was achieved by employing these different fusion partners, and MBP was the most efficient fusion partner to increase the expression level. By using E. coli C43 (DE3)/pMAL-AqpZ, the effects of different expression conditions were investigated systematically to improve the expression level of MBP-AqpZ in E. coli. The high productivity of MBP-AqpZ (200 mg/l) was achieved under optimized conditions. The present work provides a novel approach to improve the expression level of membrane proteins in E. coli.     

YptV2p,a membrane-associated small G protein abundant during embryogenesis in the green algaVolvox carteri

Summary The multicellular fresh-water algaVolvox carteri contains at least six small G protein-encoding genes (ypt genes) whose products are probably involved in intracellular vesicle transport. Four of them, YptV1, YptV3, YptV4, and YptV5, have been isolated and characterized previously. Here we report the cloning ofyptV2 cDNA, the production of recombinant His-tagged YptV2p protein (reYptV2p) inE. coli, and the analysis of its GTPase activity and intracellular localization. YptV2p is predominantly present in dividingVolvox embryos. It is a membrane-associated protein which is localized to the cell periphery (plasma membrane or plasma-membrane-associated vesicles), probably by a lipid moiety. Purified,E. coli-expressed YptV2p binds GTP specifically, and has a typically low intrinsic GTPase activity (k_cat=0.004/min), which is enhanced by a GTPase activating protein activity present inVolvox. Our observations suggest a role of YptV2p in secretion, with a peak during the rapid cleavages of theVolvox embryo.Abbreviations GAP GTPase-activating protein - re recombinant     

High-level expression of recombinant human FK-binding protein from a fusion precursor

The human peptidyl-prolyl isomerase FK-binding protein (FKBP) was cloned as a fusion partner with CMP-KDO synthetase (CKS), and the resultant construct was characterized as an improved high-expression source for FKBP. The CKS-FKBP fusion was expressed as a soluble protein at levels approaching 1 gm/L inEscherichia coli fermentations. The fusion protein was purified to near homogeneity by a one-step ammonium sulfate fractionation of whole cell lysate. After selective cleavage, the fusion precursor produced yields approaching 300 mg of purified FKBP per liter of harvested culture, a 30 to 60-fold increase over that observed for a nonfusion construct. Selective cleavage of the fusion partners was accomplished using either hydroxylamine or specific, limited proteolysis. Once separated from the CKS fusion partner, the FKBP was isolated in a single step by either reversed-phase HPLC or chromatography on Q-Sepharose. For comparison of physical and chemical properties, a nonfusion construct of recombinant human FKBP was expressed inE. coli and isolated. The purified FKBPs exhibited expected SDS-PAGE molecular weights and N-terminal sequences. The proteins had similar proton NMR spectra and binding to [³H]FK-506. The fusion construct, CKS-FKBP, was also found to bind [³H]FK-506. These data indicate that FKBP fused to the C-terminus of CKS folds independently of the fusion partner and suggests the fused FKBP adopts a conformation resembling that of the native protein.     

Expression, Purification, and Characterization of a Catalytically Active Human Cytochrome P450 1A2:Rat NADPH-Cytochrome P450 Reductase Fusion Protein

An enzymatically active human cytochrome P450 (P450) 1A2:rat NADPH-P450 reductase fusion protein was purified and partially characterized following heterologous expression inEscherichia coli. A cDNA was engineered to include the coding sequence for human P450 1A2 at its 5′ end (up to but not including the stop codon) fused in-frame to the coding sequence for a truncated (soluble) rat NADPH-P450 reductase at its 3′ end via an oligonucleotide sequence encoding the hydrophilic dipeptide Ser–Thr. This fusion plasmid was expressed inE. coliand the recombinant protein was purified from the detergent-solubilized membrane fraction via sequential DEAE, ADP–agarose, and hydroxylapatite chromatographies. The purified protein has the spectral characteristics of human P450 1A2 and cytochromecreduction activity comparable to rabbit NADPH-P450 reductase. The fusion protein catalyzed 7-ethoxyresorufinO-deethylation and phenacetinO-deethylation to appreciable levels in the presence of NADPH and phospholipid. While these activities were comparable to those of other such P450:NADPH-P450 reductase fusion proteins, they were lower than those of the system reconstituted from its individual hemoprotein and flavoprotein components. Nevertheless, the production of a functional, catalytically self-sufficient monooxygenase inE. colienhances the prospect of using bacterial systems for production and characterization of human P450 drug metabolites as well as for biodegradation of chemicals in the environment.     

Soluble expression,purification, and characterization of recombinant human flotillin-2 (reggie-1) in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Large scale production of recombinant human flotillin-2 (reggie-1) is desirable for structural and biochemical studies. However, as the major lipid rafts specific hydrophobic protein, flotillin-2 was difficult to be expressed as soluble and functional form in prokaryotic system. In this study, we first cloned and expressed human flotillin-2 in Escherichia coli with five different fusion tags: poly-histidine, glutathione S-transferase (GST), thioredoxin (TRX), N-Utilization substance (NusA) and maltose binding protein (MBP). We screened the expression level and solubility of the five flotillin-2 fusion proteins, the best MBP tagged flotillin-2 was then large scale produced. The optimized purification procedure included two steps of chromatography: Ni-NTA affinity chromatography and anion exchange chromatography. The typical yield was 36.0 mg soluble and functional recombinant flotillin-2 from 1 L of culture medium with purity above 97%. The activity of recombinant flotillin-2 was verified by pull-down assay with flotillin-1, showing that the purified recombinant flotillin-2 can specifically interact with flotillin-1. The circular dichroism (CD) spectroscopy showed that recombinant flotillin-2 had a very stable secondary structure dominated by α-helix, β-turn and random structure.     

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.