Simulation of large-scale production of a soluble recombinant protein expressed in Escherichia coli using an intein-mediated purification system

Inteins are self-cleavable proteins that under reducing conditions can be cleaved from a recombinant target protein. Industrially, an intein-based system could potentially reduce production costs of recombinant proteins by facilitating a highly selective affinity purification using an inexpensive substrate such as chitin. In this study, SuperPro Designer was used to simulate the large-scale recovery of a soluble recombinant protein expressed in Escherichia coli using an intein-mediated purification process based on the commercially available IMPACT system. The intein process was also compared with a conventional process simulated by SuperPro. The intein purification process initially simulated was significantly more expensive than the conventional process, primarily owing to the properties of the chitin resin and high reducing-agent (dithiothreitol [DTT]) raw material cost. The intein process was sensitive to the chitin resin binding capacity, cleavage efficiency of the intein fusion protein, the size of the target protein relative to the intein tag, and DTT costs. An optimized intein purification process considerably reduced costs by simulating an improved chitin resin and alternative reducing agents. Thus, to realize the full potential of intein purification processes, research is needed to improve the properties of chitin resin and to find alternative, inexpensive raw materials.     

Expression and Purification of an Antimicrobial Peptide by Fusion with Elastin-like Polypeptides in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Different carrier molecules have been fused to antimicrobial polypeptides (AMPs) to facilitate recombinant protein expression and purification. Some of them have improved the stability of AMPs and reduced the toxicity to host cells, but most current strategies still have some problems to be solved such as poor yield, low purity, high expense, time-consumption, and difficulty in scaling-up. Here, we introduced the elastin-like polypeptides (ELPs) as a fusion partner to express an antimicrobial polypeptide halocidin18 (Hal18). By the reversible soluble–insoluble phase transition, 69 mg of the fusion protein were purified from 1 l of culture medium with the purity of nearly 95%. After cleavage with hydroxylamine, the ELP’s tag was easily separated from Hal18 in the next round of inverse transition cycle and Hal18 (1.7 mg, ∼1.9 kDa) was mainly found in the supernatant with a recovery of about 47% and purity of 60%. Antimicrobial activity showed that Hal18 had strong antimicrobial activity against Escherichia coli and Micrococcus luteus but weak activity against Pichia pastoris.     

Capture and release of proteins on the nanoscale by stimuli-responsive elastin-like polypeptide "switches"

This article describes the fabrication and characterization of stimulus-responsive elastin-like polypeptide (ELP) nanostructures grafted onto omega-substituted thiolates that were patterned onto gold surfaces by dip-pen nanolithography (DPN). In response to external stimuli such as changes in temperature or ionic strength, ELPs undergo a switchable and reversible, hydrophilic-hydrophobic phase transition at a lower critical solution temperature (LCST). We exploited this phase transition behavior to reversibly immobilize a thioredoxin-ELP (Trx-ELP) fusion protein onto the ELP nanopattern above the LCST. Subsequent binding of an anti-thioredoxin monoclonal antibody (anti-Trx) to the surface-captured thioredoxin showed the presentation of the immobilized protein in a sterically accessible orientation in the nanoarray. We also showed that the resulting Trx-ELP/anti-Trx complex formed above the LCST could be reversibly dissociated below the LCST. These results demonstrate the intriguing potential of ELP nanostructures as generic, reversible, biomolecular switches for on-chip capture and release of a small number (order 100-200) of protein molecules in integrated, nanoscale bioanalytical devices. We also investigated the molecular mechanism underlying this switch by measuring the height changes that accompany the binding and desorption steps and by adhesion force spectroscopy using atomic force microscopy.     

Semisynthesis and folding of the potassium channel KcsA

In this contribution we describe the semisynthesis of the potassium channel, KcsA. A truncated form of KcsA, comprising the first 125 amino acids of the 160-amino acid protein, was synthesized using expressed protein ligation. This truncated form corresponds to the entire membrane-spanning region of the protein and is similar to the construct previously used in crystallographic studies on the KcsA protein. The ligation reaction was carried out using an N-terminal recombinant peptide alpha-thioester, corresponding to residues 1-73 of KcsA, and a synthetic C-terminal peptide corresponding to residues 74-125. Chemical synthesis of the C-peptide was accomplished by optimized Boc-SPPS techniques. A dual fusion strategy, involving glutathione-S-transferase (GST) and the GyrA intein, was developed for recombinant expression of the N-peptide alpha-thioester. The fusion protein, expressed in the insoluble form as inclusion bodies, was refolded and then cleaved successively to remove the GST tag and the intein, thereby releasing the N-peptide alpha-thioester. Following chemical ligation, the KcsA polypeptide was folded into the tetrameric state by incorporation into lipid vesicles. The correctness of the folded state was verified by the ability of the KcsA tetramer to bind to agitoxin-2. To our knowledge, this work represents the first reported semisynthesis of a polytopic membrane protein and highlights the potential application of native chemical ligation and expressed protein ligation for the (semi)synthesis of integral membrane proteins.     

Simple protein purification through affinity adsorption on regenerated amorphous cellulose followed by intein self-cleavage

A simple, low-cost, and scalable protein purification method was developed by using a biodegradable regenerated amorphous cellulose (RAC) with a binding capacity of up to 365 mg protein per gram of RAC. The recombinant protein with a cellulose-binding module (CBM) tag can be specifically adsorbed by RAC. In order to avoid using costly protease and simplify purification process, a self-cleavage intein was introduced between CBM and target protein. The cleaved target protein can be liberated from the surface of RAC by intein self-cleavage occurring through a pH change from 8.0 to 6.5. Four recombinant proteins (green fluorescence protein, phosphoglucomutase, cellobiose phosphorylase, and glucan phosphorylase) have been purified successfully.     

Labeling proteins with small molecules by site-specific posttranslational modification

We report here the development of a general strategy for site-specific labeling of proteins with small molecules by posttranslational modification enzyme, phosphopantetheinyl transferase Sfp. The target proteins are expressed as fusions to the peptide carrier protein (PCP) excised from nonribosomal peptide synthetase, and Sfp catalyzes the covalent modification of a specific serine residue on PCP by the small molecule-phosphopantetheinyl conjugate. The labeling reaction proceeds with high specificity and efficiency, targeting PCP fusion proteins in the cell lysate. The PCP tag has been shown to be compatible with various proteins, and Sfp-catalyzed PCP modification, compatible with various small-molecule probes conjugated to coenzyme A, highlighting the potential of the PCP tag for site-specific protein labeling with small molecules.     

Purification of recombinant proteins by chemical removal of the affinity tag

The efficient removal of a N-or C-terminal purification tag from a fusion protein is necessary to obtain a protein in a pure and active form, ready for use in human or animal medicine. Current techniques based on enzymatic cleavage are expensive and result in the presence of additional amino acids at either end of the proteins, as well as contaminating proteases in the preparation. Here we evaluate an alternative method to the one-step affinity/protease purification process for large-scale purification. It is based upon the cyanogen bromide (CNBr) cleavage at a single methionine placed in between a histidine tag and aPlasmodium falciparum antigen. The C-terminal segment of the circumsporozoite polypeptide was expressed as a fusion protein with a histidine tag inEscherichia coli purified by Ni-NAT agarose column chromatography and subsequently cleaved by CNBr to obtain a polypeptide without any extraneous amino acids derived from the cleavage site or from the affinity purification tag. Thus, a recombinant protein is produced without the need for further purification, demonstrating that CNBr cleavage is a precise, efficient, and low-cost alternative to enzymatic digestion, and can be applied to large-scale preparations of recombinant proteins.     

Spatially addressable chemoselective C-terminal ligation of an intein fusion protein from a complex mixture to a hydrazine-terminated surface

Protein immobilization on surfaces is useful in many areas of research, including biological characterization, antibody purification, and clinical diagnostics. A critical limitation in the development of protein microarrays and heterogeneous protein-based assays is the enormous amount of work and associated costs in the purification of proteins prior to their immobilization onto a surface. Methods to address this problem would simplify the development of interfacial diagnostics that use a protein as the recognition element. Herein, we describe an approach for the facile, site-specific immobilization of proteins on a surface without any preprocessing or sample purification steps that ligates an intein fusion protein at its C-terminus by reaction with a hydrazine group presented by a surface. Furthermore, we demonstrate that this methodology can directly immobilize a protein directly from cell lysate onto a protein-resistant surface. This methodology is also compatible with soft lithography and inkjet printing so that one or more proteins can be patterned on a surface without the need for purification.     

Identification of the binding of sceptrin to MreB via a bidirectional affinity protocol

A bidirectional affinity system was used to screen for marine natural products that bound to Escherichia coli proteins. A system was developed and applied to isolate the natural product sceptrin from an Agelas conifera extract and its affinity partner MreB from E. coli lysate. The use of a dual immunoaffinity fluorescent (IAF) tag permitted this process to co-immunoprecipitate the bacterial equivalent of actin, MreB, from E. coli lysate. MreB was subsequently validated as a target for sceptrin using a resistance mapping approach. The combination of these studies suggests that natural products and their protein targets can be isolated in concert using a melody of forward and reverse affinity matrices. While the structure of sceptrin was elucidated by NMR analysis, the bulk of effort was conducted without knowing the structure of the natural product, thereby elevating a key bottleneck in the development of high-throughput methods for natural product discovery.     

Elastin-calmodulin scaffold for protein microarray fabrication

In this work, we report a new method to reversibly immobilize proteins to a surface in a functionally active orientation directly from cell lysate by employing a fusion protein consisting of a thermal-responsive elastin (ELP) domain as the surface anchor and a calcium-responsive calmodulin (CalM) domain for protein capturing. Incorporation of an M13 tag into recombinant proteins enables not only easy surface immobilization but also direct purification from cell lysates. The feasibility of concept was demonstrated using the M13-tagged yellow fluorescent protein (M13-YFP). The ELP-CalM functionalized surfaces were shown to capture M13-YFP directly from cell lysate through the specific calmodulin-M13 association in a calcium-dependent manner. We also demonstrated that immobilization is reversible; the bound proteins were released from the surface in the presence of EDTA.     

Protein semi-synthesis in living cells

Incorporation of chemical probes into proteins is a powerful way to elucidate biological processes and to engineer novel function. Here we describe an approach that allows ligation of synthetic molecules to target proteins in an intracellular environment. A cellular protein is genetically tagged with one-half of a split intein. The complementary half is linked in vitro to the synthetic probe, and this fusion is delivered into cells using a transduction peptide. Association of the intein halves in the cytosol triggers protein trans-splicing, resulting in the ligation of the probe to the target protein through a peptide bond. This process is specific and applicable to cytosolic and integral membrane proteins. The technology should allow cellular proteins to be elaborated with a variety of abiotic probes.     

An Atypical Naturally Split Intein Engineered for Highly Efficient Protein Labeling

Protein trans‐splicing catalyzed by split inteins is a powerful technique for assembling a polypeptide backbone from two separate parts. However, split inteins with robust efficiencies and short fragments suitable for peptide synthesis are rare and have mostly been artificially created. The novel split intein AceL‐TerL was identified from metagenomic data and characterized. It represents the first naturally occurring, atypically split intein. The N‐terminal fragment of only 25 amino acids is the shortest natural intein fragment to date and was easily amenable to chemical synthesis with a fluorescent label. Optimal protein trans‐splicing activity was observed at low temperatures. Further improved mutants were selected by directed protein evolution. The engineered intein variants with up to 50‐fold increased rates showed unprecedented efficiency in chemically labeling of a diverse set of proteins. These inteins should prove valuable tools for protein semi‐synthesis and other intein‐related biotechnological applications.     

Genetically engineered peptide fusions for improved protein partitioning in aqueous two-phase systems. Effect of fusion localization on endoglucanase I of Trichoderma reesei

Genetic engineering has been used for fusion of the peptide tag, Trp-Pro-Trp-Pro, on a protein to study the effect on partitioning in aqueous two-phase systems. As target protein for the fusions the cellulase, endoglucanase I (endo-1,4-beta-Dglucan-4-glucanohydrolase, EC 3.2.1.4, EGI, Cel7B) of Trichoderma reesei was used. For the first time a glycosylated two-domain enzyme has been utilized for addition of peptide tags to change partitioning in aqueous two-phase systems. The aim was to find an optimal fusion localization for EGI. The peptide was (1) attached to the C-terminus end of the cellulose binding domain (CBD), (2) inserted in the glycosylated linker region, (3) added after a truncated form of EGI lacking the CBD and a small part of the linker. The different constructs were expressed in the filamentous fungus T. reesei under the gpdA promoter from Aspergillus nidulans. The expression levels were between 60 and 100 mg/l. The partitioning behavior of the fusion proteins was studied in an aqueous two-phase model system composed of the thermoseparating ethylene oxide (EO)-propylene oxide (PO) random copolymer EO-PO (50:50) (EO50PO50) and dextran. The Trp-Pro-Trp-Pro tag was found to direct the fusion protein to the top EO50PO50 phase. The partition coefficient of a fusion protein can be predicted with an empirical correlation based on independent contributions from partitioning of unmodified protein and peptide tag in this model system. The fusion position at the end of the CBD, with the spacer Pro-Gly, was shown to be optimal with respect to partitioning and tag efficiency factor (TEF) was 0.87, where a fully exposed tag would have a TEF of 1.0. Hence, this position can further be utilized for fusion with longer tags. For the other constructs the TEF was only 0.43 and 0.10, for the tag fused to the truncated EGI and in the linker region of the full length EGI, respectively.     

Design of an intein that can be inhibited with a small molecule ligand

Protein splicing is a process in which an intervening sequence, the intein, catalyzes its own excision out of a larger polypeptide precursor by joining the flanking sequences, the exteins, with a native peptide bond. Inteins are almost completely promiscuous toward the nature of their extein sequences and can be inserted into virtually any host protein. The intein-mediated formation of a peptide bond between two polypeptides offers great potential to modulate protein structure and, hence, protein function on the post-translational level. In this work, we report the design of an intein that can be inhibited by the addition of a specific small molecule ligand. Our design strategy involved the generation of a trans-splicing intein, in which the intein domain is split into two-halves that are located on two separate polypeptides, each joined with the respective N- or C-terminal extein. To turn these fragments into an active intein with an incorporated "off" switch, each was fused at its newly created terminus with the F36M mutant of FKBP12, referred to as the FM domain. The F36M substitution was reported to effect a homodimerization of the usually monomeric FKBP12 protein; however, addition of the small molecule ligand, rapamycin, or synthetic derivatives thereof leads to a dissociation of the dimer. This phenomenon was exploited by first reconstituting the active intein on the basis of FM domain dimerization. Second, addition of the small molecule ligand prevented formation of the active intein complex and inhibited protein trans-splicing. This intein exhibited unexpected kinetic properties and provides a new and potentially very general means to control protein function on the post-translational level.     

Interfacial phase transition of an environmentally responsive elastin biopolymer adsorbed on functionalized gold nanoparticles studied by colloidal surface plasmon resonance

The change in optical properties of colloidal gold upon aggregation has been used to develop an experimentally convenient colorimetric method to study the interfacial phase transition of an elastin-like polypeptide (ELP), a thermally responsive biopolymer. Gold nanoparticles, functionalized with a self-assembled monolayer (SAM) of mercaptoundecanoic acid onto which an ELP was adsorbed, exhibit a characteristic red color due to the surface plasmon resonance (SPR) of individual colloids. Raising the solution temperature from 10 degrees C to 40 degrees C thermally triggered the hydrophilic-to-hydrophobic phase transition of the adsorbed ELP resulting in formation of large aggregates due to interparticle hydrophobic interaction. Formation of large aggregates caused a change in color of the colloidal suspension from red to violet due to coupling of surface plasmons in aggregated colloids. The surface phase transition of the ELP was reversible, as seen from the reversible change in color upon cooling the suspension to 10 degrees C. The formation of colloidal aggregates due to the interfacial phase transition of adsorbed ELP was independently verified by dynamic light scattering of ELP-modified gold colloids as a function of temperature. Colloidal SPR provides a simple and convenient colorimetric method to study the influence of the solution environment, interfacial properties, and grafting method on the transition properties of ELPs and other environmentally responsive polymers at the solid-water interface.     

An Isotope‐Coded Fluorogenic Cross‐Linker for High‐Performance Target Identification Based on Photoaffinity Labeling

A photoaffinity labeling (PAL)‐based method for the rapid identification of target proteins is presented in which a high‐performance chemical tag, an isotope‐coded fluorescent tag (IsoFT), can be attached to the interacting site by irradiation. Labeled peptides can be easily distinguished among numerous proteolytic digests by sequential detection with highly sensitive fluorescence spectroscopy and mass spectrometry. Subsequent MS/MS analysis provides amino acid sequence information with a higher depth of coverage. The combination of PAL and heterogeneous target‐selecting techniques significantly reduces the amount of time and protein required for identification. An additional photocleavable moiety successfully accelerated proteomic analysis using cell lysate. This method is a widely applicable approach for the rapid and accurate identification of interacting proteins.     

Small Ubiquitin-Like Modifier Protein 3 Enhances the Solubilization of Human Bone Morphogenetic Protein 2 in <Emphasis Type="Italic">E. coli</Emphasis>

Small ubiquitin-like modifier (SUMO) fusion technology is widely used in the production of heterologous proteins from prokaryotic system to aid in protein solubilization and refolding. Due to an extensive clinical application of human bone morphogenetic protein 2 (hBMP2) in bone augmentation, total RNA was isolated from human gingival tissue and mature gene was amplified through RT-PCR, cloned (pET21a), sequence analyzed, and submitted to GenBank (Accession no. KF250425). To obtain soluble expression, SUMO3 was tagged at the N-terminus of hBMP2 gene (pET21a/SUMO3-hBMP2), transferred in BL21 codon+, and ~?40% soluble expression was obtained on induction with IPTG. The dimerized hBMP2 was confirmed with Western blot, native PAGE analysis, and purified by fast protein liquid chromatography with 0.5 M NaCl elution. The cleavage of SUMO3 tag from hBMP2 converted it to an insoluble form. Computational 3D structural analysis of the SUMO3-hBMP2 was performed and optimized by molecular dynamic simulation. Protein-protein interaction of SUMO3-hBMP2 with BMP2 receptor was carried out using HADDOCK and inferred stable interaction. The alkaline phosphatase assay of SUMO3-hBMP2 on C2C12 cells showed maximum 200-ng/ml dose-dependent activity. We conclude that SUMO3-tagged hBMP2 is more suited for generation of soluble form of the protein and addition of SUMO3 tag does not affect the functional activity of hBMP2.     

Temperature triggered self-assembly of polypeptides into multivalent spherical micelles

We report herein thermally responsive elastin-like polypeptides (ELPs) in a linear AB diblock architecture with an N-terminal peptide ligand that self-assemble into spherical micelles when heated slightly above body temperature. A series of 10 ELP block copolymers (ELP(BC)'s ) with different molecular weights and hydrophilic-to-hydrophobic block ratios were genetically synthesized by recursive directional ligation. The self-assembly of these polymers from unimers into micelles was investigated by light scattering, fluorescence spectroscopy, and cryo-TEM. These ELP(BC)'s undergo two phase transitions as a function of solution temperature: a unimer-to-spherical micelle transition at an intermediate temperature and a micelle-to-bulk aggregate transition at a higher temperature when the hydrophilic-to-hydrophobic block ratio is between 1:2 and 2:1. The critical micelle temperature is controlled by the length of the hydrophobic block, and the size of the micelle is controlled by both the total ELP(BC) length and hydrophilic-to-hydrophobic block ratio. These polypeptide micelles display a critical micelle concentration in the range 4-8 microM demonstrating the high stability of these structures. These studies have also identified a subset of ELP(BC)'s bearing terminal peptide ligands that are capable of forming multivalent spherical micelles that present multiple copies of the ligand on their corona in the clinically relevant temperature range 37-42 degrees C and target cancer cells. These ELP(BC)'s may be useful for drug targeting by thermally triggered multivalency. More broadly, the design rules uncovered by this study should be applicable to the design of other thermally reversible nanoparticles for diverse applications in medicine and biology.     

Direct site-selective covalent protein immobilization catalyzed by a phosphopantetheinyl transferase

Immobilization of proteins onto solid supports is important in the preparation of functional protein microarrays and in the development of bead-based bioassays, biosensors, and industrial biocatalysts. In order to generate the stable, functional, and homogeneous materials required for these applications, attention has focused on methods that enable the efficient and site-specific covalent immobilization of recombinant proteins onto a wide range of platforms. To this end, the phosphopantetheinyl transferase Sfp was employed to catalyze the direct immobilization of recombinant proteins bearing the small, genetically encoded ybbR tag onto surfaces functionalized with CoA. Using mass spectrometry, it was shown that the Sfp catalyzes immobilization of a model acyl carrier protein (ACP) onto CoA-derivatized PEGA resin beads through specific covalent bond formation. Luciferase (Luc) and glutathione-S-transferase (GST) ybbR-fusion proteins were similarly immobilized onto PEGA resin retaining high levels of enzyme activity. This strategy was also successfully applied for the immobilization of the ACP, as well as ybbR-Luc, -GST, and -thioredoxin fusion proteins, on hydrogel microarray slides. Overall, the Sfp-catalyzed surface ligation is mild, quantitative, and rapid, occurring in a single step without prior chemical modification of the target protein. Immobilization of the target proteins directly from a cell lysate mixture was also demonstrated.     

Temperature-responsive protein pores

We describe temperature-responsive protein pores containing single elastin-like polypeptide (ELP) loops. The ELP loops were placed within the cavity of the lumen of the alpha-hemolysin (alphaHL) pore, a heptamer of known crystal structure. The cavity is roughly spherical with a molecular surface volume of about 39,500 A3. In an applied potential, the wild-type alphaHL pore remained open for long periods. In contrast, the ELP loop-containing alphaHL pores exhibited transient current blockades, the nature of which depended on the length and sequence of the inserted loop. Together with similar results obtained with poly(ethylene glycols) covalently attached within the cavity, the data suggest that the transient current blockades are caused by excursions of ELP into the transmembrane beta-barrel domain of the pore. Below its transition temperature, the ELP loop is fully expanded and blocks the pore completely, but reversibly. Above its transition temperature, the ELP is dehydrated and the structure collapses, enabling a substantial flow of ions. Potential applications of temperature-responsive protein pores in medical biotechnology are discussed.