Improved partitioning in aqueous two-phase system of tyrosine-tagged recombinant lactate dehydrogenase

The partitioning of Bacillus stearothermophilus lactate dehydrogenase (LDH) in an aqueous two-phase system was studied. Particularly, the influence of tyrosine tags on the partitioning was evaluated. The hydrophobic effect, caused by the addition of tyrosine residues, was determined in a system based on dextran and the thermoseparating ethylene oxide-propylene oxide random copolymer (EO30PO70). Five different LDH variants were constructed with N-terminal tags containing tyrosines (Y3 and Y6), tyrosines and prolines (Y3P2 and Y6P2), and only prolines (P2). LDH fused with tags containing tyrosines increased the partitioning coefficient, and the more tyrosines added to the protein, the larger improvement in partitioning. When prolines were added between the tyrosine-rich tag and the protein, a further increased partitioning was obtained. The enhanced partitioning was attributed to the rigid structure of the proline, which in turn led to an increase in the exposure of the tag to the surroundings. The best tyrosine tag, Y6P2, increased the partition coefficient four times and additionally, a higher thermostability was observed.     

Effect of protein structure and/or conformation on the dityrosine cross-linking induced by haem-hydrogen peroxide

BackgroundHaem, an essential cofactor in aerobic organisms, can cause oxidative stress and impose toxic effects on tissues and organs. It can induce aggregation of proteins via dityrosine cross-linking and cause neurodegenerative diseases. Although dityrosine cross-linking in many proteins induced by haem has been reported, not all the proteins have the same effect or the efficiency of cross-linking varies, while the reason has not been clarified.MethodsThe correlation of protein structure/conformation with its aggregation tendency via dityrosine induced by hematin (oxidized form of haem) in the presence of hydrogen peroxide (H₂O₂) was studied through reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), fluorescence and circular dichroism (CD) measurements, and the mechanism was investigated by performing UV–Vis absorbance, Raman spectroscopy and low-temperature electron spin resonance (ESR) experiments.ResultsIt was found that proteins in unstructured state are more readily to be cross-linked via dityrosine formation by hematin-H₂O₂. The unstructured protein without steric effect can coordinate with hematin to form six-coordinated protein-hematin complex, in which the produced tyrosyl radicals by H₂O₂ are with high tendency to dimerize to form dityrosine.ConclusionsOur results demonstrate that protein structure/conformation can affect its coordination state with haem, and the tendency of reaction of two tyrosyl radicals, further influencing the yield and efficiency of dityrosine cross-linking in the presence of H₂O₂.General significanceThis research can help to deepen our understanding of the protein aggregation and inactivation mechanisms in varied sophisticated conditions, and especially give us the new insight into the toxic effects under haem stress.     

C termini of the Escherichia coli mechanosensitive ion channel (MscS) move apart upon the channel opening

Heptameric YggB is a mechanosensitive ion channel (MscS) from the inner membrane of Escherichia coli. We demonstrate, using the patch clamp technique, that cross-linking of the YggB C termini led to irreversible inhibition of the channel activities. Application of Ni(2+) to the YggB-His(6) channels with the hexahistidine tags added to the ends of their C termini also resulted in a marked but reversible decrease of activities. Western blot revealed that YggB-His(6) oligomers are more stable in the presence of Ni(2+), providing evidence that Ni(2+) is coordinated between C termini from different subunits of the channel. Intersubunit coordination of Ni(2+) affecting channel activities occurred in the channel closed conformation and not in the open state. This may suggest that the C termini move apart upon channel opening and are involved in the channel activation. We propose that the as yet undefined C-terminal region may form a cytoplasmic gate of the channel. The results are discussed and interpreted based on the recently released quaternary structure of the channel.     

Characterization of Helicobacter pylori nickel metabolism accessory proteins needed for maturation of both urease and hydrogenase

Previous studies demonstrated that two accessory proteins, HypA and HypB, play a role in nickel-dependent maturation of both hydrogenase and urease in Helicobacter pylori. Here, the two proteins were purified and characterized. HypA bound two Ni(2+) ions per dimer with positive cooperativity (Hill coefficient, approximately 2.0). The dissociation constants K(1) and K(2) for Ni(2+) were 58 and 1.3 microM, respectively. Studies on purified site-directed mutant proteins in each of the five histidine residues within HypA, revealed that only one histidine residue (His2) is vital for nickel binding. Nuclear magnetic resonance analysis showed that this purified mutant version (H2A) was similar in structure to that of the wild-type HypA protein. A chromosomal site-directed mutant of hypA (in the codon for His2) lacked hydrogenase activity and possessed only 2% of the wild-type urease activity. Purified HypB had a GTPase activity of 5 nmol of GTP hydrolyzed per nmol of HypB per min. Site-directed mutagenesis within the lysine residue in the conserved GTP-binding motif of HypB (Lys59) nearly abolished the GTPase activity of the mutant protein (K59A). In native solution, both HypA and HypB exist as homodimers with molecular masses of 25.8 and 52.4 kDa, respectively. However, a 1:1 molar mixture of HypA plus HypB gave rise to a 43.6-kDa species composed of both proteins. A 43-kDa heterodimeric HypA-HypB complex was also detected by cross-linking. The cross-linked adduct was still observed in the presence of 0.5 mM GTP or 1 microM nickel or when the mutant version of HypA (altered in His2) and HypB (altered in Lys59) were tested. Individually, HypA and HypB formed homodimeric cross-linked adducts. An interaction between HypA and the Hp0868 protein (encoded by the gene downstream of hypA) could not be detected via cross-linking, although such an interaction was predicted by yeast two-hybrid studies. In addition, the phenotype of an insertional mutation within the Hp0868 gene indicated that its presence is not critical for either the urease or the hydrogenase activity.     

Intramolecular cross-linking in the native JHBP molecule

Juvenile hormone binding protein (JHBP) acts as a shuttle, carrying one of the most crucial hormones for insect development to target tissues. We have found that although the JHBP molecule does not contain tryptophan residues, it exhibits a weak fluorescence maximum near 420nm upon excitation at 315nm. Gel filtration experiments performed in denaturing conditions and ESI-MS analyses excluded the possibility that some low molecular ligand was bound to the protein molecules. Further UV and CD spectroscopy studies, as well as immunoblotting, showed that the unusual JHBP optical properties were due to dityrosine intramolecular cross-linking. These bridges were detected both in native and recombinant protein molecules. We believe that in Galleria mellonella hemolymph the DT generation occurs via ROS-mediated oxidation leading to the formation of cross-linked JHBP monomers. MS analyses of peptides generated after JHBP proteolysis indicated, that the dityrosine bridge occurs between the Y128 and Y130 residues.     

A central role for intermolecular dityrosine cross-linking of fibrinogen in high molecular weight advanced oxidation protein product (AOPP) formation

Background

Advanced oxidation protein products (AOPPs) are dityrosine cross-linked and carbonyl-containing protein products formed by the reaction of plasma proteins with chlorinated oxidants, such as hypochlorous acid (HOCl). Most studies consider human serum albumin (HSA) as the main protein responsible for AOPP formation, although the molecular composition of AOPPs has not yet been elucidated. Here, we investigated the relative contribution of HSA and fibrinogen to generation of AOPPs.

Methods

AOPP formation was explored by SDS-PAGE, under both reducing and non-reducing conditions, as well as by analytical gel filtration HPLC coupled to fluorescence detection to determine dityrosine and pentosidine formation.

Results

Following exposure to different concentrations of HOCl, HSA resulted to be carbonylated but did not form dityrosine cross-linked high molecular weight aggregates. Differently, incubation of fibrinogen or HSA/fibrinogen mixtures with HOCl at concentrations higher than 150 μM induced the formation of pentosidine and high molecular weight (HMW)-AOPPs (> 200 kDa), resulting from intermolecular dityrosine cross-linking. Dityrosine fluorescence increased in parallel with increasing HMW-AOPP formation and increasing fibrinogen concentration in HSA/fibrinogen mixtures exposed to HOCl. This conclusion is corroborated by experiments where dityrosine fluorescence was measured in HOCl-treated human plasma samples containing physiological or supra-physiological fibrinogen concentrations or selectively depleted of fibrinogen, which highlighted that fibrinogen is responsible for the highest fluorescence from dityrosine.

Conclusions

A central role for intermolecular dityrosine cross-linking of fibrinogen in HMW-AOPP formation is shown.

General significance

These results highlight that oxidized fibrinogen, instead of HSA, is the key protein for intermolecular dityrosine formation in human plasma.     

Intra- and intermolecular transfers of protein radicals in the reactions of sperm whale myoglobin with hydrogen peroxide

Reaction of sperm whale metmyoglobin (SwMb) with H2O2 produces a ferryl (MbFeIV=O) species and a protein radical and leads to the formation of oligomeric products. The ferryl species is maximally formed with one equivalent of H2O2, and the maximum yields of the dimer (28%) and trimer (17%) with 1 or 2 eq. Co-incubation of the SwMb Y151F mutant with native apoSwMb and H2O2 produced dimeric products, which requires radical transfer from the nondimerizing Y151F mutant to apoSwMb. Autoreduction of ferryl SwMb to the ferric state is biphasic with t = 3.4 and 25.9 min. An intramolecular autoreduction process is implicated at low protein concentrations, but oligomerization decreases the lifetime of the ferryl species at high protein concentrations. A fraction of the protein remained monomeric. This dimerization-resistant protein was in the ferryl state, but after autoreduction it underwent normal dimerization with H2O2. Proteolytic digestion established the presence of both dityrosine and isodityrosine cross-links in the oligomeric proteins, with the isodityrosine links primarily forged by Tyr151-Tyr151 coupling. The tyrosine content decreased by 47% in the dimer and 14% in the recovered monomer, but the yields of isodityrosine and dityrosine in the dimer were only 15.2 and 6.8% of the original tyrosine content. Approximately 23% of the lost tyrosines therefore have an alternative but unknown fate. The results clearly demonstrate the concurrence of intra- and intermolecular electron transfer processes involving Mb protein radicals. Intermolecular electron transfers that generate protein radicals on bystander proteins are likely to propagate the cellular damage initiated by the reaction of metalloproteins with H2O2.     

Tobacco mitochondrial small heat shock protein NtHSP24.6 adopts a dimeric configuration and has a broad range of substrates

There is a broad range of different small heat shock proteins (sHSPs) that have diverse structural and functional characteristics. To better understand the functional role of mitochondrial sHSP, NtHSP24.6 was expressed in Escherichia coli with a hexahistidine tag and purified. The protein was analyzed by non-denaturing PAGE, chemical cross-linking and size exclusion chromatography and the H6NtHSP24.6 protein was found to form a dimer in solution. The in vitro functional analysis of H6NtHSP24.6 using firefly luciferase and citrate synthase demonstrated that this protein displays typical molecular chaperone activity. When cell lysates of E. coli were heated after the addition of H6NtHSP24.6, a broad range of proteins from 10 to 160 kD in size remained in the soluble state. These results suggest that NtHSP24.6 forms a dimer and can function as a molecular chaperone to protect a diverse range of proteins from thermal aggregation.     

Localisation of the PsbH subunit in photosystem II: a new approach using labelling of His-tags with a Ni(2+)-NTA gold cluster and single particle analysis

Photosystem II core dimers were isolated from the green alga Chlamydomonas reinhardtii by Ni(2+)-affinity chromatography exploiting a 6 x His tag located at the N terminus of the PsbH protein. This protein is predicted to have a single transmembrane helix. In order to identify the location of PsbH within the photosystem II complex, the His-tagged core dimers were labelled using a Ni(2+)-NTA gold cluster and subjected to electron microscopy and image analysis. This new method enabled us to identify the location of the labelled His tag by statistical analysis of electron micrographs of the gold-labelled photosystem II complex. Comparison of these data with electron and X-ray crystallographic analysis of photosystem II indicates that the N terminus of PsbH is close to the two transmembrane helices of cytochrome b(559). Our analysis suggests that this approach is a powerful method to locate specific proteins within multisubunit complexes like photosystem II when crystallographic analysis is of insufficient resolution to directly identify amino acid side-chains. Moreover, it can be combined with cross-linking studies, and here we demonstrate that PsbH is a near neighbour of PsbX, which is consistent with the latter subunit being located close to the alpha and beta-subunits of cytochrome b(559). However, cross-linking between PsbH and PsbW was not detected despite the fact that the latter cross-linked with the alpha-subunit of cytochrome b(559).     

Partitioning and characterization of tyrosine-tagged green fluorescent proteins in aqueous two-phase systems

The green fluorescent protein GFPuv has been genetically engineered to investigate the influence of N-terminal tyrosine extensions in aqueous two-phase systems. Fusions in the N-terminus affected the protein expression, and tags containing three tyrosines and prolines influenced the expression favorably. This effect is probably due to changes in mRNA stability, because the amounts of corresponding mRNAs correlated with the amounts of GFPuv proteins. The partitioning was investigated in two different aqueous two-phase systems, a two-polymer system composed of EO30PO70/dextran and a PEG/salt system with potassium phosphate. Partitioning in the PEG/salt system generally was more favorable than in the EO30PO70/dextran system. Tags with three tyrosines resulted in higher partitioning toward the EO30PO70- and PEG-rich phases, respectively. The effect of adding proline residues to the tag was also investigated, and the partitioning effect of the tag was enhanced when prolines were included in the tags with three tyrosines. The best tyrosine tag, Y3P2, increased the partition coefficient 5 times in the PEG/salt system. Thermoseparation of the EO30PO70 phase allowed recovery of 83% Y3P2-GFPuv protein in a water phase.     

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.     

Cross-linking approach to affinity capture of protein complexes from chaotrope-solubilized cell lysates

Affinity capture methods are widely used for isolation and analysis of protein complexes. Short peptide tags fused to the protein of interest normally facilitate straightforward purification and detection of interacting proteins. We investigated the suitability of applying C-terminally hexahistidine-tagged interleukin-12 (IL-12) alpha- and beta-chains as "bait" proteins for cocapturing novel binding partners using heterologous recombinant human embryonic kidney-293 (HEK-293) cell lines. The beta-chain, but not the alpha-chain, extracted from cell lysates was capable of binding to the Ni(2+)-nitrilotriacetic acid affinity resin under nondenaturing conditions. Retention of the alpha-chain on this matrix was dependent on treatment of cell lysates with high concentrations of chaotropes such as urea. Since under these conditions any noncovalent protein associations are destroyed, prior cross-linking of proteins interacting with the alpha-chain in intact cells was required. The use of the thiol-cleavable cross-linker 3,3'-dithiobis(succinimidyl proprionate) facilitated dissociation of alpha-chain-binding proteins by means of dithiothreitol following purification. Using this approach we were able to demonstrate a strong interaction between the endoplasmic reticulum chaperone calreticulin (CRT) and the IL-12 alpha-chain that was confirmed in a reciprocal anti-CRT immunoprecipitation assay. The assay presented here provides a simple approach to exposing concealed hexahistidine tags while retaining native noncovalent protein interactions and should be generally applicable in a range of pull-down or affinity capture methods aiming at analysis of protein complexes.     

Fcγ1 fragment of IgG1 as a powerful affinity tag in recombinant Fc-fusion proteins: immunological,biochemical and therapeutic properties

Affinity tags are vital tools for the production of high-throughput recombinant proteins. Several affinity tags, such as the hexahistidine tag, maltose-binding protein, streptavidin-binding peptide tag, calmodulin-binding peptide, c-Myc tag, glutathione S-transferase and FLAG tag, have been introduced for recombinant protein production. The fragment crystallizable (Fc) domain of the IgG1 antibody is one of the useful affinity tags that can facilitate detection, purification and localization of proteins and can improve the immunogenicity, modulatory effects, physicochemical and pharmaceutical properties of proteins. Fcγ recombinant forms a group of recombinant proteins called Fc-fusion proteins (FFPs). FFPs are widely used in drug discovery, drug delivery, vaccine design and experimental research on receptor–ligand interactions. These fusion proteins have become successful alternatives to monoclonal antibodies for drug developments. In this review, the physicochemical, biochemical, immunological, pharmaceutical and therapeutic properties of recombinant FFPs were discussed as a new generation of bioengineering strategies.     

ATP-independent thermoprotective activity of Nicotiana tabacum heat shock protein 70 in Escherichia coli

To study the functioning of HSP70 in Escherichia coli, we selected NtHSP70-2 (AY372070) from among three genomic clones isolated in Nicotiana tabacum. Recombinant NtHSP70-2, containing a hexahistidine tag at the amino-terminus, was constructed, expressed in E. coli, and purified by Ni(2+) affinity chromatography and Q Sepharose Fast Flow anion exchange chromatography. The expressed fusion protein, H(6)NtHSP70-2 (hexahistidine-tagged Nicotiana tabacum heat shock protein 70-2), maintained the stability of E. coli proteins up to 90 degrees C. Measuring the light scattering of luciferase (luc) revealed that NtHSP70-2 prevents the aggregation of luc without ATP during high-temperature stress. In a functional bioassay (1 h at 50 degrees C) for recombinant H(6)NtHSP70-2, E. coli cells overexpressing H(6)NtHSP70-2 survived about seven times longer than those lacking H(6)NtHSP70-2. After 2 h at 50 degrees C, only the E. coli overexpressing H(6)NtHSP70-2 survived under such conditions. Our NtHSP70-2 bioassays, as well as in vitro studies, strongly suggest that HSP70 confers thermo-tolerance to E. coli.     

His tag effect on solubility of human proteins produced in Escherichia coli: a comparison between four expression vectors

We have compared four different vectors for expression of proteins with N- or C-terminal hexahistidine (His6) tags in Escherichia coli by testing these on 20 human proteins. We looked at a total recombinant protein production levels per gram dry cell weight, solubility of the target proteins, and yield of soluble and total protein when purified by immobilized metal ion affinity purification. It was found that, in general, both N- and C-terminal His6 tags have a noticeable negative affect on protein solubility, but the effect is target protein specific. A solubilizing fusion tag was able to partly counteract this negative effect. Most target proteins could be purified under denaturing conditions and about half of the proteins could be purified under physiological conditions. The highest protein production levels and yield of purified protein were obtained from a construct with C-terminal His tag. We also observe a large variation in cell growth rate, which we determined to be partly caused by the expression vectors and partly by the targets. This variation was found to be independent of the production level, solubility and tertiary structure content of the target proteins.     

Dityrosine as a product of oxidative stress and fluorescent probe

Summary. Dityrosine can be a natural component of protein structure, a product of environmental stress, or a product of in vitro protein modification. It is both a cross-link and a fluorescent probe that reports structural and functional information on the cross-linked protein molecule. Diverse reactions produce tyrosyl radicals, which in turn may couple to yield dityrosine. Identification and quantitation of dityrosine in protein hydrolysates usually employs reversed phase high pressure liquid chromatography (RP-HPLC) or gas chromatography. RP-HPLC of protein hydrolysates that have been derivatized with dabsyl chloride gives a complete amino acid analysis that includes dityrosine and 3-nitrotyrosine. Calmodulin, which contains a single pair of tyrosyl residues, undergoes both photoactivated and enzyme-catalyzed dityrosine formation. Polarization measurements, employing the intrinsic fluorescence of dityrosine, and catalytic activity determinations show how different patterns of inter- and intramolecular cross-linking affect the interactions of calmodulin with Ca²⁺ and enzymes.     

Intermolecular cross-linking of Na+-Ca2+ exchanger proteins: evidence for dimer formation

The cardiac Na (+)-Ca (2+) exchanger (NCX1) is modeled to contain nine transmembrane segments (TMS) with a pair of oppositely oriented, conserved sequences called the alpha-repeats that are important in ion transport. Residue 122 in the alpha-1 repeat is in proximity to residue 768 in TMS 6, and the two residues can be cross-linked . During studies on the substrate specificity of this intramolecular cross-link, we found evidence that NCX1 can form dimers. At 37 degrees C in the absence of extracellular Na (+), copper phenanthroline catalyzes disulfide bond formation between cysteines at position 122 in adjacent NCX1 proteins. Dimerization was confirmed by histidine tag pull-down experiments that demonstrate the association of untagged NCX1 with histidine-tagged NCX1. Dimerization occurs along a face of the protein that includes parts of the alpha-1 and alpha-2 repeats as well as parts of TMS 1 and TMS 2. We do not see cross-linking between residues in TMS 5, TMS 6, or TMS 7. These data provide the first evidence for dimer formation by the Na (+)-Ca (2+) exchanger.     

Peroxidase catalysed cross-linking of an intrinsically unstructured protein via dityrosine bonds in the oocyst wall of the apicomplexan parasite, Eimeria maxima

Apicomplexan parasites such as Eimeria maxima possess a resilient oocyst wall that protects them upon excretion in host faeces and in the outside world, allowing them to survive between hosts. The wall is formed from the contents of specialised organelles – wall-forming bodies – found in macrogametes of the parasites. The presence of dityrosine in the oocyst wall suggests that peroxidase-catalysed dityrosine cross-linking of tyrosine-rich proteins from wall-forming bodies forms a matrix that is a crucial component of oocyst walls. Bioinformatic analyses showed that one of these tyrosine-rich proteins, EmGAM56, is an intrinsically unstructured protein, dominated by random coil (52–70%), with some α-helix (28–43%) but a relatively low percentage of β-sheet (1–11%); this was confirmed by nuclear magnetic resonance and circular dichroism. Furthermore, the structural integrity of EmGAM56 under extreme temperatures and pH indicated its disordered nature. The intrinsic lack of structure in EmGAM56 could facilitate its incorporation into the oocyst wall in two ways: first, intrinsically unstructured proteins are highly susceptible to proteolysis, explaining the several differently-sized oocyst wall proteins derived from EmGAM56; and, second, its flexibility could facilitate cross-linking between these tyrosine-rich derivatives. An in vitro cross-linking assay was developed using a recombinant 42 kDa truncation of EmGAM56. Peroxides, in combination with plant or fungal peroxidases, catalysed the rapid formation of dityrosine cross-linked polymers of the truncated EmGAM56, as determined by western blotting and HPLC, confirming this protein’s propensity to form dityrosine bonds.     

Expression and one-step purification of recombinant proteins using an alternative episomal vector for the expression of N-tagged heterologous proteins in Pichia pastoris

Here we report the construction of an alternative episomal vector, pBGP3, which allows the expression of heterologous proteins with N-terminal hexahistidine and myc-epitope tags in Pichia pastoris. To test the usefulness of pBGP3, four cellulases from termites were expressed. Production was confirmed by activity assays and Western blot using anti-c-Myc antibody. Purification was performed by single-step Ni(2+)-affinity chromatography, which confirmed the efficiency of pBGP3.