High level expression and purification of recombinant 3ABC non-structural protein of foot-and-mouth disease virus using SUMO fusion system.

The detection of antibody to non-structural protein (NSP) of Foot-and-mouth disease virus (FMDV) is the reliable diagnostic method for differentiating infected from vaccinated animals (DIVA). For this purpose, the detection of antibodies to non-structural 3ABC protein is suitable for identification of virus activity in the animals exposed to FMDV infection. However, large-scale production of recombinant 3ABC protein is challenging due to the formation of inclusion bodies in Escherichia coli and low yield due to protein aggregation during in vitro refolding. In this study, 3ABC gene was fused with SUMO (small ubiquitin-like modifiers) fusion system which significantly enhanced expression of recombinant 3ABC protein in E. coli. The solubility of the recombinant 6xHis-SUMO 3ABC fusion protein was improved by mild detergent treatment and purified through Ni-NTA chromatography under non-denaturing conditions which yielded 9 mg protein obtained from 1-L bacterial fermentation culture. The diagnostic potential of recombinant 3ABC protein was also tested by ELISA that provided reliable diagnostic performance (DSn = 92%, DSp = 94%) upon comparison with commercially available kit. The thermal stability of fusion protein was also tested which presented reliable performance at different temperatures. In conclusion, we presented SUMO fusion for the enhanced expression in E. coli and purification of active recombinant 3ABC protein using non-denaturing conditions without refolding steps. This protein can be used as a suitable diagnostic antigen to detect antibodies following FMDV infection.

Protocol for Biochemical Analysis and Structure Determination of the ZZ Domain of the E3 Ubiquitin Ligase HERC2.

Since its discovery, several ligands of the ZZ domain have been identified; however, molecular and structural information underlying binding of these ligands remains limited. Here, we describe a protocol for biochemical and structural analysis of the ZZ domain of human E3 ubiquitin ligase HERC2 (HERC2ZZ) and its interaction with its ligands: the N-terminal tails of histone H3 and SUMO1. This methodology could be applied for characterization of binding activities of other histone readers. For complete details on the use and execution of this protocol, please refer to Liu et al. (2020).

Expression and purification of an immunogenic SUMO-OmpC fusion protein of Salmonella Typhimurium in Escherichia coli.

Salmonella is found to be a major causes of food borne diseases globally. Poultry products contaminated with this pathogen is one of the major sources of infections in humans. Outer membrane protein C (OmpC) of Salmonella Typhimurium is a promising DNA vaccine candidate to mitigate Salmonella infection in poultry. However, the large-scale production of bioactive recombinant OmpC (rOmpC) protein is hindered due to the formation of inclusion bodies in Escherichia coli. The objective of this work was to attain high level expression of rOmpC protein, purify and evaluate its functional properties. The ompC gene was optimized and fused with small ubiquitin-related modifier (SUMO) gene for high level expression as soluble protein. The fusion protein with ~58 kDa molecular weight was observed on SDS-PAGE gel. The expression levels of rOmpC fusion protein reached maximum of 38% of total soluble protein (TSP) after 8 h of 0.2% rhamnose induction. Protein purification was carried out using nickel nitrilotriacetic acid (Ni-NTA) purification column. Western blot were performed to analyse expression and immunoreactivity of rOmpC fusion protein. The results indicate that SUMO fusion system is ideal for large scale production of functional rOmpC fusion protein expression in E. coli.

Cloning and high-level SUMO-mediated fusion expression of a serine protease inhibitor from Hyphantria cunea Drury that exhibits activity against papain.

Insect-derived serine protease inhibitors (serpins) exhibit multiple inhibitory activities. Todate some functional roles for serpins in Hyphantria cunea Drury have been identified. Here, new functional features of the H. cunea serine protease inhibitor (dHC-serpin) were characterized. In this study, the cDNA encoding serpin was amplified from H. cunea (dHC) pupa fat body total RNA using RT-PCR. The full-length dHC-serpin cDNA encoded a protein of 440 amino acids with a predicted 19-amino acid signal peptide and a 421-amino acid functional domain. The functional domain was cloned into a pSUMO vector and transformed into Escherichia coli, resulting in the production of a pSUMO-dHC-serpin fusion protein. The soluble form of this protein was then purified by Ni-IDA chromatography. The SUMO-dHC-serpin fusion protein was then cleaved using a SUMO protease and purified again by Ni-IDA chromatography. dHC-serpin did not inhibit trypsin, elastase, proteinase K or cathepsin B, but strongly inhibited papain. The inhibitor retained its inhibitory activity over a broad range of pH (pH 2-12), temperature (20-50 °C), and DTT concentration (up to 100 mM). A complete loss of inhibitory activity was observed at pH 13 and 70 °C. Serpins generally serve as inhibitors that use a mobile reactive center loop (RCL) as bait to trap protease targets. dHC-serpin, like others serpins, binds papain using the RCL structure.

Recombinant Production and Characterization of SAC, the Core Domain of Par-4, by SUMO Fusion System.

Prostate apoptosis response-4 (Par-4), an anticancer protein that interacts with cell surface receptor GRP78, can selectively suppress proliferation and induce apoptosis of cancer cells. The core domain of Par-4 (aa 137-195), designated as SAC, is sufficient to inhibit tumor growth and metastasis without harming normal tissues and organs. Nevertheless, the anticancer effects of SAC have not been determined in ovarian cancer cells. Here, we developed a novel method for producing native SAC in Escherichia coli using a small ubiquitin-related modifier (SUMO) fusion system. This fusion system not only greatly improved the solubility of target protein but also enhanced the expression level of SUMO-SAC. After purified by Ni-NTA affinity chromatography, SUMO tag was cleaved from SUMO-SAC fusion protein using SUMO protease to obtain recombinant SAC. Furthermore, we simplified the purification process by combining the SUMO-SAC purification and SUMO tag cleavage into one step. Finally, the purity of recombinant SAC reached as high as 95% and the yield was 25 mg/L. Our results demonstrated that recombinant SAC strongly inhibited proliferation and induced apoptosis in ovarian cancer cells SKOV-3. Immunofluorescence analysis and competitive binding reaction showed that recombinant SAC could specifically induce apoptosis of SKOV-3 cells through combination with cell surface receptor, GRP78. Therefore, we have developed an effective strategy for expressing bioactive SAC in prokaryotic cells, which supports the application of SAC in ovarian cancer therapy.

High Resolution X-ray Diffraction Dataset for Bacillus licheniformis Gamma Glutamyl Transpeptidase-acivicin complex: SUMO-Tag Renders High Expression and Solubility.

Gamma glutamyl transpeptidase, (GGT) is a ubiquitous protein which plays a central role in glutathione metabolism and has myriad clinical implications. It has been shown to be a virulence factor for pathogenic bacteria, inhibition of which results in reduced colonization potential. However, existing inhibitors are effective but toxic and therefore search is on for novel inhibitors, which makes it imperative to understand the interactions of various inhibitors with the protein in substantial detail. High resolution structures of protein bound to different inhibitors can serve this purpose. Gamma glutamyl transpeptidase from Bacillus licheniformis is one of the model systems that have been used to understand the structure-function correlation of the protein. The structures of the native protein (PDB code 4OTT), of its complex with glutamate (PDB code 4OTU) and that of its precursor mimic (PDB code 4Y23) are available, although at moderate/low resolution. In the present study, we are reporting the preliminary analysis of, high resolution X-ray diffraction data collected for the co-crystals of B. licheniformis, Gamma glutamyl transpeptidase, with its inhibitor, Acivicin. Crystals belong to the orthorhombic space group P212121 and diffract X-ray to 1.45 Å resolution. This is the highest resolution data reported for all GGT structures available till now. The use of SUMO fused expression system enhanced yield of the target protein in the soluble fraction, facilitating recovery of protein with high purity. The preliminary analysis of this data set shows clear density for the inhibitor, acivicin, in the protein active site.

Analysis of Protein Sumoylation.

Sumoylation, wherein small ubiquitin-like modifier (SUMO) proteins are covalently attached to specific lysine residues of target proteins, plays an important role in regulating many diverse cellular processes via its control of the functional properties of the modified proteins. Identification of new sumoylated proteins is expected to expand understanding of the role this modification has in cell function. This unit describes two different assays for determining whether a particular protein is sumoylated: the first method employs immunoprecipitation of the protein followed by SUMO immunoblot. The second involves incubating the protein (either an in vitro translation product or a purified recombinant protein) with a reconstituted in vitro sumoylation reaction followed by examination for increased molecular-weight bands in SDS-PAGE as sumoylated forms of the protein. Either of these approaches can also be used to determine the sumoylated lysine residue(s) by comparing modification of the normal protein versus lysine-to-arginine substitutions of potential sumoylation sites, which once determined allows analysis of the effect of sumoylation on the protein's function.

Production of aggregation prone human interferon gamma and its mutant in highly soluble and biologically active form by SUMO fusion technology.

The Escherichia coli expression system is a preferable choice for production of recombinant proteins. A disadvantage of this system is the target protein aggregation in "inclusion bodies" (IBs) that further requires solubilisation and refolding, which is crucial for the properties and the yield of the final product. In order to prevent aggregation, SUMO fusion tag technology has been successfully applied for expression of eukaryotic proteins, including human interferon gamma (hIFNγ) that was reported, however, with no satisfactory biological activity. We modified this methodology for expression and purification of both the wild type hIFNγ and an extremely prone to aggregation mutant hIFNγ-K88Q, whose recovery from IBs showed to be ineffective upon numerous conditions. By expression of the N-terminal His-SUMO fusion proteins in the E. coli strain BL21(DE3)pG-KJE8, co-expressing two chaperone systems, at 24 °C a significant increase in solubility of both target proteins (1.5-fold for hIFNγ and 8-fold for K88Q) was achieved. Two-step chromatography (affinity and ion-exchange) with on-dialysis His-SUMO-tag cleavage was applied for protein purification that yielded 6.0-7.0mg/g wet biomass for both proteins with >95% purity and native N-termini. The optimised protocol led to increased yields from 5.5 times for hIFNγ up to 100 times for K88Q in comparison to their isolation from IBs. Purified hIFNγ showed preserved thermal stability and antiproliferative activity corresponding to that of the native reference sample (3 × 10(7)IU/mg). The developed methodology represents an optimised procedure that can be successfully applied for large scale expression and purification of aggregation-prone proteins in soluble native form.

SUMO-fusion, purification, and characterization of a (+)-zizaene synthase from Chrysopogon zizanioides.

An uncharacterized plant cDNA coding for a polypeptide presumably having sesquiterpene synthase activity, was expressed in soluble and active form. Two expression strategies were evaluated in Escherichia coli. The enzyme was fused to a highly soluble SUMO domain, in addition to being produced in an unfused form by a cold-shock expression system. Yields up to ∼325 mg/L(-1) were achieved in batch cultivations. The 6x-His-tagged enzyme was purified employing an Ni(2+)-IMAC-based procedure. Identity of the protein was established by Western Blot analysis as well as peptide mass fingerprinting. A molecular mass of 64 kDa and an isoelectric point of pI 4.95 were determined by 2D gel electrophoresis. Cleavage of the fusion domain was possible by digestion with specific SUMO protease. The synthase was active in Mg(2+) containing buffer and catalyzed the production of (+)-zizaene (syn. khusimene), a precursor of khusimol, from farnesyl diphosphate. Product identity was confirmed by GC-MS and comparison of retention indices. Enzyme kinetics were determined by measuring initial reaction rates for the product, using varying substrate concentrations. By assuming a Michaelis-Menten model, kinetic parameters of KM = 1.111 µM (±0.113), vmax = 0.3245 µM min(-1) (±0.0035), kcat = 2.95 min(-1), as well as a catalytic efficiency kcat/KM = 4.43 × 10(4) M(-1)s(-1) were calculated. Fusion to a SUMO moiety can substantially increase soluble expression levels of certain hard to express terpene synthases in E. coli. The kinetic data determined for the recombinant synthase are comparable to other described plant sesquiterpene synthases and in the typical range of enzymes belonging to the secondary metabolism. This leaves potential for optimizing catalytic parameters through methods like directed evolution.

Chromatin modification by SUMO-1 stimulates the promoters of translation machinery genes.

SUMOylation of transcription factors and chromatin proteins is in many cases a negative mark that recruits factors that repress gene expression. In this study, we determined the occupancy of Small Ubiquitin-like MOdifier (SUMO)-1 on chromatin in HeLa cells by use of chromatin affinity purification coupled with next-generation sequencing. We found SUMO-1 localization on chromatin was dynamic throughout the cell cycle. Surprisingly, we observed that from G1 through late S phase, but not during mitosis, SUMO-1 marks the chromatin just upstream of the transcription start site on many of the most active housekeeping genes, including genes encoding translation factors and ribosomal subunit proteins. Moreover, we found that SUMO-1 distribution on promoters was correlated with H3K4me3, another general chromatin activation mark. Depletion of SUMO-1 resulted in downregulation of the genes that were marked by SUMO-1 at their promoters during interphase, supporting the concept that the marking of promoters by SUMO-1 is associated with transcriptional activation of genes involved in ribosome biosynthesis and in the protein translation process.

Expression, purification and preliminary NMR characterization of isotopically labeled wild-type human heterotrimeric G protein αi1.

Molecular-level investigation of proteins is increasingly important to researchers trying to understand the mechanisms of signal transmission. Heterotrimeric G proteins control the activation of many critical signal transmission cascades and are also implicated in numerous diseases. As part of a longer-term investigation of intramolecular motions in RGS and Gα proteins in their apo and complexed forms, we have successfully developed a protocol for preparing milligram quantities of highly purified, isotopically labeled wild-type human Gα(i1) (hGα(i1)) subunit for NMR studies. High levels of expression in Escherichia coli can be attributed to the use of the SUMO fusion protein system, a bacterial strain that produces rare codons, supplementation of minimal medium with small quantities of isotopically labeled rich medium and a lowered induction temperature. Purification of hGα(i1) utilized affinity and size exclusion chromatography, and protein activity was confirmed using fluorescence-based GTP-binding studies. Preliminary NMR analysis of hGα(i1) has shown that high-quality spectra can be obtained at near-physiological temperatures, whereas lower temperature spectra display numerous weak and broadened peaks, providing preliminary evidence for widespread µs-ms timescale exchange. In an effort to further optimize the NMR spectra we prepared a truncated form of hGα(i1) (hGα(i1)-Δ31) in which the 31-residue unstructured N-terminus was removed. This resulted in further improvements in spectral quality by eliminating high-intensity peaks that obscured resonances from structured segments of the protein. We plan to use hGα(i1)-Δ31 in future investigations of protein dynamics by NMR spectroscopy to gain insight into the role of these motions in RGS/Gα binding selectivity.

SUMO mediating fusion expression of antimicrobial peptide CM4 from two joined genes in Escherichia coli.

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. To improve the expression level of CM4 in Escherichia coli, two tandem repeats of CM4 genes were cloned into the vector pSUMO to construct an expression vector pSUMO-2CM4. The fusion protein SUMO-2CM4, purified by Ni(2+)-chelating chromatography, was cleaved by hydroxylamine hydrochloride to release recombinant CM4. After the cleaved sample was re-applied to a Ni-IDA column, finally, about 48 mg recombinant CM4 was obtained from 1 L bacterial culture with no less than 96% purity, which was the highest yield of CM4 reported so far.

Rational conversion of affinity reagents into label-free sensors for Peptide motifs by designed allostery.

Optical biosensors for short peptide motifs, an important class of biomarkers, have been developed based on "affinity clamps", a new class of recombinant affinity reagents. Affinity clamps are engineered by linking a peptide-binding domain and an antibody mimic domain based on the fibronectin type III scaffold, followed by optimization of the interface between the two. This two-domain architecture allows for the design of allosteric coupling of peptide binding to fluorescence energy transfer between two fluorescent proteins attached to the affinity clamp. Coupled with high affinity and specificity of the underlying affinity clamps and rationally designed mutants with different sensitivity, peptide concentrations in crude cell lysate were determined with a low nanomolar detection limit and over 3 orders of magnitude. Because diverse affinity clamps can be engineered, our strategy provides a general platform to generate a repertoire of genetically encoded, label-free sensors for peptide motifs.

In vivo identification of human small ubiquitin-like modifier polymerization sites by high accuracy mass spectrometry and an in vitro to in vivo strategy.

The length and precise linkage of polyubiquitin chains is important for their biological activity. Although other ubiquitin-like proteins have the potential to form polymeric chains their identification in vivo is challenging and their functional role is unclear. Vertebrates express three small ubiquitin-like modifiers, SUMO-1, SUMO-2, and SUMO-3. Mature SUMO-2 and SUMO-3 are nearly identical and contain an internal consensus site for sumoylation that is missing in SUMO-1. Combining state-of-the-art mass spectrometry with an "in vitro to in vivo" strategy for post-translational modifications, we provide direct evidence that SUMO-1, SUMO-2, and SUMO-3 form mixed chains in cells via the internal consensus sites for sumoylation in SUMO-2 and SUMO-3. In vitro, the chain length of SUMO polymers could be influenced by changing the relative amounts of SUMO-1 and SUMO-2. The developed methodology is generic and can be adapted for the identification of other sumoylation sites in complex samples.

Characterization of a new SUMO-1 nuclear body (SNB) enriched in pCREB, CBP, c-Jun in neuron-like UR61 cells.

The neuron-like UR61 cell is a stable PC12 subline that contains a mouse N-ras oncogene. Dexamethasone (Dex) treatment induces a neuron-like differentiation, which is associated with neuritogenesis and nuclear expression of the glucocorticoid receptor and c-Jun. In differentiated UR61 cells, small ubiquitin-like modifiers 1 (SUMO-1) is concentrated in a new category of SUMO-1 nuclear bodies (SNBs) distinct from promyelocytic leukemia (PML) bodies by their large size and absence of PML protein. SNBs are 1 to 3 mum in diameter and exhibit a fine granular texture by electron microscopy. They are free of splicing factors and transcription foci and show spatial associations with Cajal bodies. In addition to SUMO-1 and the E2-conjugating enzyme Ubc9, which is essential for sumoylation, SNBs concentrate the transcriptional regulators CBP, CREB, and c-Jun. Moreover, transfection experiments demonstrate that SNBs accumulate the active conjugating form of SUMO-1 but not the conjugation defective variant of SUMO-1, supporting that SNBs are sites of sumoylation. Our results suggest that SNBs play a role in the control of the nucleoplasmic concentration of transcription regulators involved in neuroprotection and survival of the UR61 cells.

Identification of SUMO-protein conjugates.

Modification of proteins by covalent attachment of ubiquitin and the ubiquitin-like modifier SUMO are widespread regulatory events of all eukaryotic cells. SUMOylation has received much attention, because several identified targets play prominent roles, in particular, in cell signaling, gene expression, and DNA repair. Notably, only a very small fraction of a substrate is usually SUMOylated at steady-state levels, which could be because modification is reversible and transient. Because of the low level of modification, SUMOylated proteins are often overlooked or sometimes misinterpreted as a less important fraction of a protein pool. Here we discuss procedures that can circumvent identification problems and describe methods for their verification.