Recombinant production of self-assembling SZ-structured peptides using SUMO as a fusion partner

ABSTRACT: BACKGROUND: Self-assembling peptides that form nanostructured hydrogels are important biomaterials for tissue engineering scaffolds. The P11-family of peptides includes, P11-4 (QQRFEWEFEQQ) and the complementary peptides P11-13 (EQEFEWEFEQE) and P11-14 (QQOrnFOrnWOrnFOrnQQ). These form self-supporting hydrogels under physiological conditions (pH 7.4, 140 mM NaCl) either alone (P11-4) or when mixed (P11-13 and P11-14). We report a SUMO-peptide expression strategy suitable for allowing release of native sequence peptide by SUMO protease cleavage. RESULTS: We have expressed SUMO-peptide fusion proteins from pET vectors by using autoinduction methods. Immobilised metal affinity chromatography was used to purify the fusion protein, followed by SUMO protease cleavage in water to release the peptides, which were recovered by reverse phase HPLC. The peptide samples were analysed by electrospray mass spectrometry and self-assembly was followed by circular dichroism and transmission electron microscopy. CONCLUSIONS: The fusion proteins were produced in high yields and the beta-structured peptides were efficiently released by SUMO protease resulting in peptides with no additional amino acid residues and with recoveries of 46% to 99%. The peptides behaved essentially the same as chemically synthesised and previously characterised recombinant peptides in self-assembly and biophysical assays.     

Enrichment of fermentation media and optimization of expression conditions for the production of EAK(16) peptide as fusions with SUMO

EAK(16) (AEAEAKAKAEAKAEAK) belongs to a novel class of self-assembling peptides, which is being investigated in research and industry. SUMO belongs to the ubiquitin class of proteins and is a promising fusion partner currently in use. In this study, EAK(16) peptide fusions with hexa-histidine tagged SUMO have been constructed using Escherichia coli based pET expression vector. Intracellular expression of the SUMO-EAK(16) fusion using LB media has been optimized. Low-cost complex media (fungal autolysates, wheat and gluten hydrolysates) produced via a novel wheat-based biorefinery have been used as alternative fermentation media to LB. Shake flask cultures using either enriched LB or complex wheat-derived media containing 2 g/L of glucose resulted in intracellular SUMO-EAK(16) fusion protein production of approximately 250 mg/L fermentation volume which corresponded to 30-35% of the total bacterial protein expressed being the fusion protein. Fusion protein productivities up to five times higher were achieved when using a bioreactor.     

Expressing antimicrobial peptide cathelicidin-BF in Bacillus subtilis using SUMO technology

Small ubiquitin-related modifier (SUMO) technology has been widely used in Escherichia coli expression systems to produce antimicrobial peptides. However, E. coli is a pathogenic bacterium that produces endotoxins and can secrete proteins into the periplasm, forming inclusion bodies. In our work, cathelicidin-BF (CBF), an antimicrobial peptide purified from Bungarus fasciatus venom, was produced in a Bacillus subtilis expression system using SUMO technology. The chimeric genes his-SUMO-CBF and his-SUMO protease 1 were ligated into vector pHT43 and expressed in B. subtilis WB800N. Approximately 22 mg of recombinant fusion protein SUMO-CBF and 1 mg of SUMO protease 1 were purified per liter of culture supernatant. Purified SUMO protease 1 was highly active and cleaved his-SUMO-CBF with an enzyme-to-substrate ratio of 1:40. Following cleavage, recombinant CBF was further purified by affinity and cation exchange chromatography. Peptide yields of ~3 mg/l endotoxin-free CBF were achieved, and the peptide demonstrated antimicrobial activity. This is the first report of the production of an endotoxin-free antimicrobial peptide, CBF, by recombinant DNA technology, as well as the first time purified SUMO protease 1 with high activity has been produced from B. subtilis. This work has expanded the application of SUMO fusion technology and may represent a safe and efficient way to generate peptides and proteins in B. subtilis.     

An improved SUMO fusion protein system for effective production of native proteins

Expression of recombinant proteins as fusions with SUMO (small ubiquitin-related modifier) protein has significantly increased the yield of difficult-to-express proteins in Escherichia coli. The benefit of this technique is further enhanced by the availability of naturally occurring SUMO proteases, which remove SUMO from the fusion protein. Here we have improved the exiting SUMO fusion protein approach for effective production of native proteins. First, a sticky-end PCR strategy was applied to design a new SUMO fusion protein vector that allows directional cloning of any target gene using two universal cloning sites (Sfo1 at the 5'-end and XhoI at the 3'-end). No restriction digestion is required for the target gene PCR product, even the insert target gene contains a SfoI or XhoI restriction site. This vector produces a fusion protein (denoted as His(6)-Smt3-X) in which the protein of interest (X) is fused to a hexahistidine (His(6))-tagged Smt3. Smt3 is the yeast SUMO protein. His(6)-Smt3-X was purified by Ni(2+) resin. Removal of His(6)-Smt3 was performed on the Ni(2+) resin by an engineered SUMO protease, His(6)-Ulp1(403-621)-His(6). Because of its dual His(6) tags, His(6)-Ulp1(403-621)-His(6) exhibits a high affinity for Ni(2) resin and associates with Ni(2+) resin after cleavage reaction. One can carry out both fusion protein purification and SUMO protease cleavage using one Ni(2+)-resin column. The eluant contains only the native target protein. Such a one-column protocol is useful in developing a better high-throughput platform. Finally, this new system was shown to be effective for cloning, expression, and rapid purification of several difficult-to-produce authentic proteins.     

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.     

Biodiversity in aerobic granule membrane bioreactor at high organic loading rates

Antibacterial peptide CM4 (ABP-CM4) is a small cationic peptide with broad-spectrum activities against bacteria, fungi, and tumor cells, which may possibly be used as an antimicrobial agent. We report here the application of small ubiquitin-related modifier (SUMO) fusion technology to the expression and purification of cationic antibacterial peptide ABP-CM4. The fusion protein expressed in a soluble form was purified to a purity of 90% by Ni-IDA chromatography and 112 mg protein of interest was obtained per liter of fermentation culture. After the SUMO–CM4 fusion protein was cleaved by the SUMO protease at 30 °C for 1 h, the cleaved sample was re-applied to a Ni-IDA. Finally, about 24 mg recombinant CM4 was obtained from 1 l fermentation culture with no less than 96% purity and the recombinant CM4 had similar antimicrobial properties to the synthetic CM4. Thus, the SUMO-mediated peptide expression and purification system potentially could be employed for the production of recombinant cytotoxic peptides.     

SUMO fusions and SUMO-specific protease for efficient expression and purification of proteins

SUMO (small ubiquitin-related modifier) modulates protein structure and function by covalently binding to the lysine side chains of the target proteins. Yeast cells contain two SUMO proteases, Ulp1 and Ulp2, that cleave sumoylated proteins in the cell. Ulp1 (SUMO protease 1) processes the SUMO precursor to its mature form and also de-conjugates SUMO from side chain lysines of target proteins. Here we demonstrate that attachment of SUMO to the N-terminus of under-expressed proteins dramatically enhances their expression in E. coli. SUMO protease 1 was able to cleave a variety of SUMO fusions robustly and with impeccable specificity. Purified recombinant SUMO-GFPs were efficiently cleaved when any amino acid, except proline, was in the+1 position of the cleavage site. The enzyme was active over a broad range of buffer and temperature conditions. Purification of certain recombinant proteins is accomplished by production of Ub-fusions from which Ub can be subsequently removed by de-ubiquitinating enzymes (DUBs). However, DUBs are unstable enzymes that are difficult to produce and inexpensive DUBs are not available commercially. Our findings demonstrate that SUMO protease 1/SUMO-fusion system may be preferable to DUB/Ub-fusion. Enhanced expression and solubility of proteins fused to SUMO combined with broad specificity and highly efficient cleavage properties of the SUMO protease 1 indicates that SUMO-fusion technology will become a useful tool in purification of proteins and peptides.     

Systematic analysis of fusion and affinity tags using human aspartyl-tRNA synthetase expressed in E. coli

Fusion and affinity tags are popular tools for the expression of mammalian proteins in bacteria. To facilitate the selection of expression approaches, a systematic comparison was performed. We cloned, sequenced, and expressed in Escherichia coli ubiquitin- and SUMO-hDRS fusion proteins with biotin- or 6xHis-tags. The tagging of hDRS with ubiquitin or SUMO was necessary to express properly folded and biologically active enzyme. Similar enhancement of hDRS activity was obtained by fusion to ubiquitin or SUMO. Ubiquitin, SUMO, biotin, and hexahistidine tags did not appreciably interfere with hDRS activity. Fusion proteins were specifically cleaved without altering the N-terminal of hDRS. After cleavage hDRS remained soluble and active with a specific activity comparable to that of the fused protein. Similar activity was observed with biotin- and 6xHis-tagging of hDRS. Higher purity but significantly lower yields of hDRS were obtained using biotin-tagging. Overall we demonstrated ubiquitin and SUMO fusion proteins similarly enhanced the proper folding of hDRS expressed in E. coli. In comparison to previous expressions of hDRS as a GST fusion, ubiquitin, and SUMO fusions provided higher yields and easier purification and cleavage.     

N(pro) fusion technology to produce proteins with authentic N termini in E. coli

We describe a prokaryotic expression system using the autoproteolytic function of N(pro) from classical swine fever virus. Proteins or peptides expressed as N(pro) fusions are deposited as inclusion bodies. On in vitro refolding by switching from chaotropic to kosmotropic conditions, the fusion partner is released from the C-terminal end of the autoprotease by self-cleavage, leaving the target protein with an authentic N terminus. A tailor-made N(pro) mutant called EDDIE, with increased in vitro and decreased in vivo cleavage rates, has enabled us to express proinsulin, domain-D of staphylococcal protein A, hepcidin, interferon-alpha1, keratin-associated protein 10-4, green fluorescent protein, inhibitorial peptide of senescence-evasion-factor, monocyte chemoattractant protein-1 and toxic gyrase inhibitor, among others. This N(pro) expression system can be used as a generic tool for the high-level production of recombinant toxic peptides and proteins (up to 12 g/l) in Escherichia coli without the need for chemical or enzymatic removal of the fusion tag.     

Construction of a high sensitive Escherichia coli alkaline phosphatase reporter system for screening affinity peptides

An enzyme-linker-peptide fusion protein reporter system was constructed for sensitive analysis of affinity of peptide ligands to their receptor. An E. coli alkaline phosphatase (EAP) mutant enzyme with high catalytic activity was selected as the reporter protein. Interaction of affinity peptide and streptavidin was applied as demonstration of the method. Three affinity peptides, strep-tag I (SI), strep-tag II (SII) and streptavidin binding peptide (SBP) were genetically fused to the C-terminal of EAP respectively, with an insertion of a flexible linker peptide in between. The enzyme activity of the EAP fusions showed no obvious change. After expression and purification, the EAP-affinity peptide fusions were applied to the streptavidin modified surface. Binding of the fusions to the surface through interaction of affinity peptides to streptavidin was indicated by color generated from conversion of the substrate by EAP. The relative affinity and specificity of each affinity peptides to the immobilized streptavidin were then evaluated with high sensitivity and broad detection range. This method may be used for effective high-throughput screening of high affinity peptide from the peptide pool.     

Ubiquitin-intein and SUMO2-intein fusion systems for enhanced protein production and purification

Although most commonly used for protein production, expression of soluble and functional recombinant protein in Escherichia coli is still a major challenge. The development and application of fusion tags that can facilitate protein expression and solubility partly solve this problem, however, under most circumstance, the fusion tags have to be removed by proteases in order to use the proteins. Because the tag removal using proteases increases cost and introduces extra purification steps, it remains a significant problem that must be resolved before being widely used in industry production. Ubiquitin and SUMO have been successfully used to enhance protein expression and solubility. In the last decades, intein has also been widely used in protein production for its self-cleavage property, which could help to remove the fusion tag without any protease. Here, we take the advantages of ubiquitin, SUMO2 and intein in protein expression. We constructed tandem ubiquitin-intein and SUMO2-intein fusion tags, and chose human MMP13 (amino acid 104-274) and eGFP as the passenger proteins that fused to the C-terminus of the tags. These constructs were expressed in E. coli and both MMP13 and eGFP expression and solubility were evaluated. Both tags showed the ability to enhance the solubility of MMP13 and eGFP and improve the expression of eGFP, and the SUMO2-intein having a more significant effect. Both ubiquitin-intein-eGFP and SUMO2-intein-eGFP were purified using Ni-NTA column chromatography and self-cleavaged by changing pH. The recombinant un-tagged eGFP were released and eluted with high homogeneity. In summary, ubiquitin-intein and SUMO2-intein are convenient and useful fusion tags that can enhance the expression, solubility and improve the purification process of the model heterologous protein and these tags may have a good prospect in protein production.     

Production of Bioactive Human Beta-Defensin-4 in <Emphasis Type="Italic">Escherichia coli</Emphasis> Using SUMO Fusion Partner

The human beta defensins-4 (hBD4) exhibit a broad range of antimicrobial properties and are thought to be ideal therapeutic agents because of their potential ability to circumvent the problems of acquired resistance often observed with other antimicrobial therapies. We report here the application of small ubiquitin-related modifier (SUMO) fusion technology to the expression and purification of cationic antibacterial peptide hBD4. The fusion protein expressed in a soluble form was purified to a purity of 90% by Ni-IDA chromatography and 637 mg protein of interest was obtained per liter of fermentation culture. After the SUMO-hBD4 fusion protein was cleaved by the SUMO protease at 30 °C for 1 h, the cleaved sample was re-applied to a Ni-IDA. Finally, about 166 mg recombinant hBD4 was obtained from 1 L fermentation culture with no less than 96% purity and the recombinant hBD4 had similar antimicrobial properties to the synthetic hBD4. Thus, the SUMO-mediated peptide expression and purification system potentially could be employed for the production of recombinant cytotoxic peptides.     

Heterologous protein export in Escherichia coli: influence of bacterial signal peptides on the export of human interleukin 1 beta

Expression plasmids carrying the coding sequence of mature human interleukin 1 beta (IL 1 beta) linked either to a Met start codon, or fused to different efficient Escherichia coli secretion signal sequences, have been constructed. In the latter case, we used signal peptides derived either from an outer membrane protein (OmpA) or from a periplasmic protein (PhoA). The synthesis of IL1 beta from these fusions was investigated in an otherwise strictly isogenic context using identical conditions of derepression and culture media. The Met-IL1 beta fusion produced a soluble cytoplasmic protein which could be released from the cells by osmotic shock whereas the OmpA and PhoA fusions were always insoluble. The extent of sOmpA-IL1 beta maturation was found to vary from 50 to 100%, mainly depending on the medium used, whereas no significant maturation of the signal peptide could be detected in the case of the sPhoA-IL1 beta fusion. Immuno-electron microscopy revealed that the sOmpA-IL1 beta fusion was targeted to the inner membrane, whereas the sPhoA-IL1 beta fusion remained within the cytoplasm and thus did not appear to enter the secretion pathway. Amplifying the E. coli signal peptidase lep gene on a multicopy plasmid did not improve signal peptide removal from sOmpA-IL1 beta. Moreover, these E. coli secretion vectors allowed us to produce, in high levels, IL1 beta fragments which otherwise could not be stably accumulated within the cytoplasmic compartment.     

Harnessing synthetic biology to enhance heterologous protein expression

The ability to express heterologous proteins in microbial hosts is crucial for many areas of research and technology. In most cases, however, successful expression and purification of the desired protein require fusion to another protein. To date, all fusion partners have been chosen from natural sequences, which evolved for other purposes, and may not be optimal fusion partners. However, the rise of synthetic biology and protein design make it possible to design and optimize fusion proteins using novel sequences that did not arise in nature. Here, we describe a series of De novo Expression Enhancer Proteins (DEEPs) that facilitate high‐level expression and facile purification of heterologous proteins and peptides. To test the DEEP system, a de novo protein was fused to several target proteins covering a range of sizes and solubilities. In all cases, fusions to DEEP outperformed fusions to SUMO, a commonly used natural fusion partner. The availability of novel proteins that can be engineered for specific fusion applications could be beneficial to enhance the expression of a wide range of heterologous proteins.     

SUMO蛋白酶的发酵和纯化工艺的研究

目前, 小分子肽多需要进行融合表达,虽然有GST标签等表达体系,但是表达产物切割时仍留有多余氨基酸,影响小分子肽的功能;SUMO蛋白酶对SUMO融合表达系统表达的重组蛋白进行切割时没有多余氨基酸残留,因此成为蛋白切割工具的热点。利用基因工程技术构建重组His-Ulp1/pET3c/BL21（DE3）工程菌株,用摇瓶优化表达条件,摸索高密度发酵工艺和不同层析纯化工艺条件。结果表明,经1.0mmol/L的IPTG 30℃诱导表达6h,表达效果最好。罐发酵后菌体SDSPAGE分析表达量可达24.39%,通过CM Sepharose Fast Flow阳离子交换一步层析可获得纯度大于98%的SUMO蛋白酶,每升发酵液可获得355mg的SUMO蛋白酶纯品。Western blot分析表明,UlP1能与6×His抗体产生免疫反应。为日后大规模产业化生产奠定了基础。     

A fusion protein system for the recombinant production of short disulfide-containing peptides

A recombinant fusion protein system for the production, oxidation, and purification of short peptides containing a single disulfide bond is described. The peptides are initially expressed in Escherichia coli as a fusion to an engineered mutant of the N-terminal SH2 domain of the intracellular phosphatase, SHP-2. This small protein domain confers several important properties which facilitate the production of disulfide-containing peptides: (i) it is expressed at high levels in E. coli; (ii) it can be purified via a hexahistidine tag and reverse-phase HPLC; (iii) it contains no endogenous cysteine residues, allowing the formation of an intrapeptide disulfide bond while still attached to the fusion partner; (iv) it is highly soluble in native buffers, facilitating the production of very hydrophobic peptides and the direct use of fusion products in biochemical assays; (v) it contains a unique methionine residue at the junction of the peptide and fusion partner to facilitate peptide cleavage by treatment with cyanogen bromide (CNBr). This method is useful for producing peptides, which are otherwise difficult to prepare through traditional chemical synthesis approaches, and this has been demonstrated by preparing a number of hydrophobic disulfide-containing peptides derived from phage-display libraries.     

Enhanced protein expression in mammalian cells using engineered SUMO fusions: secreted phospholipase A2

SUMOylation, the covalent attachment of SUMO (small ubiquitin-like modifier), is a eukaryotic post-translational event that has been demonstrated to play a critical role in several biological processes. When used as an N-terminal tag or fusion partner, SUMO has been shown to enhance functional protein production significantly by improving folding, solubility, and stability. We have engineered several SUMOs and, through their fusion, developed a system for enhancing the expression and secretion of complex proteins. To demonstrate the fidelity of this fusion technology, secreted phospholipase A(2) proteins (sPLA(2)) were produced using HEK-293T and CHO-K1 cells. Five mouse sPLA(2) homologs were expressed and secreted in mammalian cell cultures using SUMO or SUMO-derived, N-terminal fusion partners. Mean and median increases of 43- and 18-fold, respectively, were obtained using novel SUMO mutants that are resistant to digestion by endogenous deSUMOylases.     

In vivo analysis of a fluorescent SUMO fusion in transgenic Drosophila

Sumoylation, the covalent attachment of SUMO, a 90 amino acid peptide related to ubiquitin, is a major modulator of protein functions. Fluorescent SUMO protein fusions have been used in cell cultures to visualize SUMO in vivo but not in multicellular organisms. We generated a transgenic line of Drosophila expressing an mCherry-SUMO fusion. We analyzed its pattern in vivo in salivary gland nuclei expressing Venus-HP1 to recognize the different chromatin components (Chromocenter, chromosome IV). We compared it to SUMO immunostaining on squashed polytene chromosomes and observed similar patterns. In addition to the previously reported SUMO localizations (chromosome arms and chromocenter), we identify 2 intense binding sites: the fourth chromosome telomere and the DAPI-bright band in the region 81F.     

Expression and purification of human urodilatin by small ubiquitin-related modifier fusion in Escherichia coli

To prevent in vivo degradation, small peptides are usually expressed in fusion proteins from which target peptides can be released by proteolytic or chemical reagents. In this report, small ubiquitin-related modifier (SUMO) linked with a hexa-histidine tag was used as a fusion partner for the production of recombinant human urodilatin, a hormone for the treatment of acute decompensated heart failure. The fusion protein, which was overexpressed mainly as inclusion bodies in Escherichia coli, constituted about 25% of the total cell proteins. After purification by Ni-sepharose affinity chromatography and renaturation in refolding buffer, the fusion protein was cleaved with SUMO protease 1. Urodilatin was separated from the fusion partner by the subtractive chromatography using Ni-sepharose once again, and then further purified with reverse-phase high performance liquid chromatography. In vitro activity assay demonstrated that the recombinant urodilatin had a potent vasodilatory effect on rabbit aortic strips with an EC₅₀ of 1.77 ± 0.53 μg/ml, which was similar to that of the synthetic urodilatin standard. The expression strategy presented in this study allows convenient high yield and easy purification of small recombinant peptides with native sequences. Z. Sun and Z. Xia contribute equally to the work.