A simplified method for purification of recombinant soluble DnaA proteins

An improved, simplified method for the purification of recombinant, tagged DnaA proteins is described. The presented protocol allowed us to purify soluble DnaA proteins from two different bacterial species: Helicobacter pylori and Streptomyces coelicolor, but it can most likely also be used for the isolation of DnaA proteins from other bacteria, as it was adapted for Mycobacterium tuberculosis DnaA. The isolation procedure consists of protein precipitation with ammonium sulphate followed by affinity chromatography. The composition of the buffers used at each purification step is crucial for the successful isolation of the recombinant DnaA proteins. The universality of the method in terms of its application to differently tagged proteins (His-tagged or GST-tagged) as well as different properties of purified proteins (e.g., highly aggregating truncated forms) makes the protocol highly useful for all studies requiring purified and active DnaA proteins.     

Single step purification of a series of wheat recombinant proteins with expanded bed absorption chromatography

Expanded bed absorption chromatography (EBA) was used to improve and simplify the purification of several wheat recombinant proteins. Binding and elution conditions were set to allow the purification of the over expressed protein in a single step. In comparison with our previous multi step protocol, same purity was obtained while EBA required less time (one day instead of five) and gave a higher yield (63% instead of 10%). This new procedure was then used for the successful purification of five other wheat ns-LTP. Despite their important polymorphism (identity from 44 to 97 %-pHi from 8 to 10), the EBA protocol allowed their purification in a single step.     

Single-step recovery and solid-phase refolding of inclusion body proteins using a polycationic purification tag

A strategy for purification of inclusion body-forming proteins is described, in which the positively charged domain Z(basic) is used as a fusion partner for capture of denatured proteins on a cation exchange column. It is shown that the purification tag is selective under denaturing conditions. Furthermore, the new strategy for purification of proteins from inclusion bodies is compared with the commonly used method for purification of His(6)-tagged inclusion body proteins. Finally, the simple and effective means of target protein capture provided by the Z(basic) tag is further successfully explored for solid-phase refolding. This procedure has the inherited advantage of combining purification and refolding in one step and offers the advantage of eluting the concentrated product in a suitable buffer.     

A unified method for purification of basic proteins

Protein purification is still very empirical, and a unified method for purifying proteins without an affinity tag is not available yet. In the postgenomic era, functional genomics, however, strongly demands such a method. In this paper we have formulated a unique method that can be applied for purifying any recombinant basic protein from Escherichia coli. Here, we have found that if the pH of the buffer is merely one pH unit below the isoelectric point (pI) of the recombinant proteins, most of the latter bind to the column. This result supports the Henderson-Hasselbalch principle. Considering that E. coli proteins are mostly acidic, and based on the pI determined theoretically, apparently all recombinant basic proteins (at least pI−1 ? 6.94) may be purified from E. coli in a single step using a cation-exchanger resin, SP-Sepharose, and a selected buffer pH, depending on the pI of the recombinant protein. Approximately, two-fifths of human proteome, including many if not all nucleic acid-interacting proteins, have a pI of 7.94 or higher; virtually all these 12,000 proteins may be purified using this method in a single step.     

A novel method for the purification of low soluble recombinant C-type lectin proteins

Snake venoms contain a complex mixture of many biological molecules including proteins. The purification of recombinant proteins is a key step in studying their function and structure with affinity chromatography as the common method used in their purification. In bacterial expression systems, hydrophobic recombinant proteins are usually precipitated into inclusion bodies, and contaminants are typically associated with tagged proteins after purification. The purpose of this study was to develop a procedure to purify hydrophobic recombinant proteins without an affinity tag. Snake venom mature C-type lectin-like proteins (CLPs) with a tag were cloned, expressed, and purified by repeated sonication and wash steps. The effects of the signal peptide on the expression and solubility of the recombinant protein were investigated. The CLPs in washed inclusion bodies were solubilized and refolded by dialysis. The CLPs without a tag were successfully purified with a yield 38 times higher than the traditional method, and inhibited blood platelet aggregation with an IC(50) of 100.57μM in whole blood. This novel procedure is a rapid, and inexpensive method to purify functional recombinant hydrophobic CLPs from snake venoms useful in the development of drug therapies.     

A genetically encodable microtag for chemo-enzymatic derivatization and purification of recombinant proteins

Efficient separation of recombinant polypeptides from proteins of the expression host and their subsequent derivatisation with functional chemical groups is essential for the success of many biological applications. Numerous tag systems have been developed to facilitate the purification procedure but only limited progress has been made in development of generic methods for targeted modification of proteins with functional groups. In this work, we present a novel 6 amino acid long C-terminal protein tag that can be selectively modified with functionalized derivatives of farnesyl isoprenoids by protein farnesyltransferase. The reaction could be performed in complex protein mixtures without detectable unspecific labeling. We demonstrate that this modification can be used to purify the target protein by over 800-fold in a single purification step using phase partitioning. Moreover, we show that the fluorescent group could be used to monitor the interaction of the derivatized proteins with other polypeptides.     

9-kDa acidic and basic nsLTP-like proteins are secreted in the culture-medium conditioned by somatic embryogenesis in Cichorium

Direct somatic embryogenesis was induced in leaf fragments of the Cichorium ‘474’ genotype. Addition of glycerol to the induction medium allowed a relative synchronization of the first division of the embryogenic cells that only occurs after transfer at day 5 to a medium without glycerol. The abundant presence of 9-kDa extracellular proteins in the culture-medium conditioned by somatic embryogenesis is reported here. Such proteins were also secreted when embryogenesis was initiated in root but were never detected when a non-embryogenic genotype was used as control under the same conditions of culture. Among these proteins, one basic and one acidic isoform were separated through cation-exchange chromatography. Both proteins were recognized by an antiserum raised against the carrot EP2 non-specific lipid transfer protein (nsLTP). In addition, the partial N-terminal amino acid sequence of each isoform showed similarities with nsLTPs of different plant species. The presence of the acidic nsLTP-like protein was concomitant with the obtention of embryogenic cells during the induction step. The basic form was shown to have only accumulated during the expression step when first divisions of embryogenic cells have occurred. These results allowed us to report, for the first time, the secretion of a 9-kDa acidic nsLTP-like protein in the culture-medium conditioned by plant embryogenic cells.     

Cloning,expression and two-step purification of recombinant His-tag enhanced green fluorescent protein over-expressed in Escherichia coli

In this report, we describe a two-step chromatographic procedure for the purification of His-tag EGFP by immobilized metal affinity expanded bed adsorption (IMAEBA) as the capture step and size exclusion chromatography as the polishing step. The use of proteins including a histidine-tag facilitates their subsequent purification after expression in many microorganisms. This meets the needs of scientific researchers as well as industrialists in purifying recombinant proteins. The procedure described allowed the obtention of 230 mg pure EGFP from 1 l simple batch culture with a recovery of 90%.     

Tandem affinity purification of functional TAP-tagged proteins from human cells

Tandem affinity purification (TAP) is a generic two-step affinity purification protocol for isolation of TAP-tagged proteins together with associated proteins. We used bacterial artificial chromosome to heterologously express TAP-tagged murine Sgo1 protein in human HeLa cells. This allowed us to test the functionality of the Sgo1-TAP protein by RNA interference-mediated depletion of the endogenous human Sgo1. Here, we present an optimized protocol for purification of TAP-tagged Sgo1 protein as well as KIAA1387 from HeLa cells with detailed instructions. The purification protocol can be completed in 1 day and it should be applicable to other proteins.     

Expression and purification of soluble E-Syt2: Low protein stability impedes tag removal

Affinity tags are valuable tools for high-throughput protein isolation in automated screenings or downstream processing approaches and are also widely used in laboratory applications for quick and easy access to many proteins. Here, we describe the preparative purification of soluble extended synaptotagmin 2 (rE-Syt2) at bench scale for basic structural and functional studies. Due to the low protein stability, a classical purification procedure without affinity tag was more powerful than isolation of His₍₆₎-tagged rE-Syt2 and subsequent proteolytic tag-removal. Furthermore, expression analysis of truncated rE-Syt2 variants suggested a concept of interdependent-domain organization in proteins containing multiple C2 domains.     

tRNA-assisted overproduction of eukaryotic ribosomal proteins

Structural studies of eukaryotic ribosomes are complicated by the tendency of their constituent proteins to be expressed at very low levels in Escherichia coli. We find that this is mainly due to their exceptionally high content of AGA/AGG arginine codons, which are poorly utilized by the bacterial translational machinery. In fact, we could overcome this limitation by the combined use of a T7 RNA polymerase expression vector and a plasmid carrying the E. coli gene argU, which encodes the minor tRNA(Arg) species that reads AGA/AGG codons. In this system, five cytoplasmic ribosomal proteins from three different eukaryotic lineages (Saccharomyces cerevisiae S8, L13, and L14; Arabidopsis thaliana L13; and Homo sapiens L7) could be overexpressed to up to 50% of total bacterial protein and were purified to homogeneity in tens of milligrams amounts. The purification procedure simply involved metal affinity chromatography followed, in some cases, by an additional heparin chromatography step. Recombinant polypeptides bound RNA with high affinity (K(d) between 50 and 300 nM). This novel overexpression/purification strategy will allow the production of high amounts of most eukaryotic ribosomal proteins in a form suitable for structural and functional studies. Coupled with recently completed and ongoing whole-genome sequencing projects, it will facilitate the molecular characterization of the eukaryotic ribosome.     

Fully automated protein purification

Obtaining highly purified proteins is essential to begin investigating their functional and structural properties. The steps that are typically involved in purifying proteins can include an initial capture, intermediate purification, and a final polishing step. Completing these steps can take several days and require frequent attention to ensure success. Our goal was to design automated protocols that would allow the purification of proteins with minimal operator intervention. Separate methods have been produced and tested that automate the sample loading, column washing, sample elution and peak collection steps for ion exchange, metal affinity, hydrophobic interaction, and gel filtration chromatography. These individual methods are designed to be coupled and run sequentially in any order to achieve a flexible and fully automated protein purification protocol.     

Topogenesis of heterologously expressed fragments of the human Y4 GPCR

Fragments of large membrane proteins have the potential to facilitate structural analysis by NMR, but their folding state remains a concern. Here we determined the quality of folding upon heterologous expression for a series of N- or C-terminally truncated fragments of the human Y4 G-protein coupled receptor, amounting to six different complementation pairs. As the individual fragments lack a specific function that could be used to ascertain proper folding, we instead assessed folding on a basic level by studying their membrane topology and by comparing it to well-established structural models of GPCRs. The topology of the fragments was determined using a reporter assay based on C-terminal green fluorescent protein- or alkaline phosphatase-fusions. N-terminal fusions to Lep or Mistic were used if a periplasmic orientation of the N-terminus of the fragments was expected based on predictions. Fragments fused to Mistic expressed at comparably high levels, whereas Lep fusions were produced to a much lower extent. Though none of the fragments exclusively adopted one orientation, often the correct topology predominated. In addition, systematic analysis of the fragment series suggested that the C-terminal half of the Y4 receptor is more important for adopting the correct topology than the N-terminal part. Using the detergent dodecylphosphocholine, selected fragments were solubilized from the membrane and proved sufficiently stable to allow purification. Finally, as a first step toward reconstituting a functional receptor from two fragments, we observed a physical interaction between complementing fragments pairs upon co-expression.     

Large quantities of recombinant PR-5 proteins from the extracellular matrix of tobacco: Rapid production of microbial-recalcitrant proteins

A procedure for the extraction of large quantities of PR-5 proteins that have been recalcitrant to microbial-based expression systems is described. Targeting of the recombinant proteins to the extracellular matrix allowed efficient protein extraction by a vacuum infiltration/centrifugation system. Approximately 1 kg of fresh leaves from transgenic tobacco plants overexpressing either truncated osmotin (Liu et al., 1996) or A9 fromAtriplex nummularia L. (Casas et al., 1991) yielded between 3 and 5 mg of purified proteins that fully retained their antifungal activity. The entire system of overexpression, extraction, and purification could be easily scaled up for the production of several grams of protein.     

Cortical and Hippocampal Neurons from Truncated Tau Transgenic Rat Express Multiple Markers of Neurodegeneration

Transition of protein tau from physiologically unfolded to misfolded state represent enigmatic step in the pathogenesis of tauopathies including Alzheimer’s disease (AD). Major molecular events playing role in this process involve truncation and hyperphosphorylation of tau protein, which are accompanied by redox imbalance followed by functional deterioration of neuronal network. Recently we have developed transgenic rat model showing that expression of truncated tau causes neurofibrillary degeneration similar to that observed in brain of AD sufferers. Consequently we tested cortical and hippocampal neuronal cultures extracted from this model as a convenient tool for development of molecules able to target the mechanisms leading to and/or enhancing the process of neurodegeneration. Here we document three major pathological features typical for tauopathies and AD in cortical and hippocampal neurons from transgenic rat in vitro. First, an increased accumulation of human truncated tau in neurons; second, the hyperphosphorylation of truncated tau on the epitopes characteristic of AD (Ser202/Thr205 and Thr231); and third, increased vulnerability of the neurons to nitrative and oxidative stress. Our results show that primary neurons expressing human truncated tau could represent a cellular model for targeting tau related pathological events, namely, aberrant tau protein accumulation, tau hyperphosphorylation, and oxidative/nitrative damage. These characteristics make the model particularly suitable for detailed study of molecular mechanisms of tau induced neurodegeneration and easily applicable for drug screening.     

An alternative use of basic pGEX vectors for producing both N- and C-terminal fusion proteins for production and affinity purification of antibodies

Glutathione S-transferase (GST) fusion proteins are widely used in protein production for pure immunogens, protein-protein, and DNA-protein interaction studies. Using basic pGEX vectors, foreign DNA is introduced to the C-terminus of the GST gene and the produced fusion proteins are C-terminally orientated. However, because the orientation of foreign polypeptides may have a very important role in the correct folding of the produced polypeptides, N-terminal fusion proteins are needed to express especially the N-terminus of the foreign polypeptide. Here, we introduce a novel use of the basic pGEX vectors for the production of N-terminal fusion proteins. In this procedure, PCR generated DNA fragments were cloned into the N-terminus of the GST gene in a unique EcoNI site located down-stream of the ATG initiation codon. The N-terminal fusion proteins were expressed in high quantities, easily solubilized, and affinity purified using our modification of current purification protocols. We also introduce here a new modification of the affinity purification of antibodies using covalently crosslinked GST and fusion proteins to glutathione-agarose beads. Our procedure was tested successfully for producing antibodies against both N- and C-terminus of the luteinizing hormone/chorionic gonadotropin receptor.     

Heparin-binding proteins of human seminal plasma: purification and characterization

Human seminal plasma (HuSP) contains several proteins that bind heparin and related glycosaminoglycans. Heparin binding proteins (HBPs) from seminal plasma have been shown to participate in modulation of capacitation or acrosome reaction and thus have been correlated with fertility in some species. However, these have not been studied in detail in human. The objective of this study was to purify major HBPs from HuSP in order to characterize these proteins. HBPs were isolated by affinity-chromatography on Heparin-Sepharose column, purified by reverse-phase high-performance liquid chromatography (RP-HPLC) and Size-exclusion chromatography and checked for purity on sodium-dodecyl PAGE (SDS-PAGE). Identification of HBPs was done by matrix-assisted laser desorption-ionization-time-of-flight-mass spectrometry (MALDI-TOF-MS). Here we report the purification and identification of seven HBPs in seminal fluid. The major HBPs are lactoferrin and its fragments, semenogelin I fragments, semenogelin II, prostate specific antigen, homolog of bovine seminal plasma-proteins (BSP), zinc finger protein (Znf 169) and fibronectin fragments. In this study we are reporting for the first time the purification and identification of BSP-homolog and Znf 169 from HuSP and classified them as HBPs. Here we report the purification of seven clinically important proteins from human seminal fluid through heparin affinity chromatography and RP-HPLC, in limited steps with higher yield.     

Affinity purification of insoluble recombinant fusion proteins containing glutathione-S-transferase

Prokaryotic expression of polypeptides as fusion proteins with glutathione-S-transferase has recently been reported as a one-step means of purifying recombinant protein. The usefulness of the glutathione-S-transferase/glutathioneagarose system, however, is significantly limited by the frequent synthesis of recombinant proteins in insuluble form by Escherichia coli. We have found that for 5 separate fusion proteins containing glutathione-S-transferase and different domains of the large cystic fibrosis transmembrane conductance regulator, all were packaged in insoluble form by E. coli. Insolubility of these products made them inaccessible to one-step purification utilizing this scheme requires proper folding of recombinant glutathione-S-transferase to allow recognition on glutathione affinity agarose, we investigated the suitability of several alternative approaches for converting insoluble recombinant fusion proteins to a soluble form amenable to glutathione-agarose affinity purification. Low-temperature induction of fusion protein synthesis, but not incubation with anion-exchange resins, led to improved one-step purification of glutathione-S-transferase fusion proteins from E. coli cell lysate using mild, nondenaturing conditions. Solubilization in 8 mol/L urea, but not with other chaotropic agents or detergents, also allowed preparative yields of affinity-purified fusion protein. These techniques increase the usefulness of this recombinant protein purification scheme, and should be broadly applicable to diverse polypeptides synthesized as fusions with glutathione-S-transferase.     

Effects of L-arginine on solubilization and purification of plant membrane proteins

Biochemical analysis of membrane proteins is problematic at the level of solubilization and/or purification because of their hydrophobic nature. Here, we developed methods for efficient solubilization and purification of membrane proteins using L-arginine. The addition of 100 mM of basic amino acids (L-arginine, L-lysine, and L-ornithine) to a detergent-containing solubilization buffer enhanced solubilization (by 2.6-4.3 fold) of a model membrane protein-polygalacturonic acid synthase. Of all the amino acids, arginine was the most effective additive for solubilization of this membrane protein. Arginine addition also resulted in the best solubilization of other plant membrane proteins. Next, we examined the effects of arginine on purification of a model membrane protein. In anion-exchange chromatography, the addition of arginine to the loading and elution buffers resulted in a greater recovery of a membrane protein. In ultrafiltration, the addition of arginine to a protein solution significantly improved the recovery of a membrane protein. These results were thought to be due to the properties of arginine that prevent aggregation of hydrophobic proteins. Taken together, the results of our study showed that arginine is useful for solubilization and purification of aggregate-prone membrane proteins.     

A simple and sensitive method for the purification and peptide mapping of proteins solubilized from densonucleosis virus with sodium dodecyl sulfate

An efficient method for the proteolysis and subsequent analysis of dansylated viral (or other) proteins solubilized with sodium dodecyl sulfate (SDS), after their purification using SDS electrophoresis, is described. The dansylation of proteins or the by-products of the reaction do not interfere in this technique. This very simple technique has important advantages over other methods for the purification and characterization of proteins. The method used indicates that the four viral proteins of densonucleosis virus originate at least partially from a common DNA sequence.