Immunological comparison of recombinant shrimp allergen Pen m 4, produced in Pichia pastoris and Escherichia coli.

Shellfish are a leading cause of allergies worldwide, affecting about one-tenth of the general population. The sarcoplasmic calcium-binding protein, also known as allergen Pen m 4, is an important factor in shrimp allergies. Our objective was to assess the most effective techniques for producing a recombinant Pen m 4 protein as a potential tool for diagnosing shrimp allergies. In this study, for the first time, we produced a functional recombinant Pen m 4 protein in a eukaryotic system, Pichia pastoris, and analyzed it against Escherichia coli-produced equivalents in enzyme-linked immunosorbent and reverse-phase protein microarray assays. A dual tag system based on the maltose-binding protein was successfully used to increase the yield of Pen m 4 by 1.3-2.3-fold in both bacteria and yeast, respectively. Immunological characterization showed that N-glycosylation is neither crucial for the folding of Pen m 4 nor its recognition by specific IgE. However, the Ca2+-depletion assay indicated a dependence on calcium ion presence in blood samples. Results demonstrate how a comparative analysis can elucidate essential allergen manufacturing points. In conclusion, E. coli-produced Pen m 4 protein fused with the maltose-binding protein should be the preferred option for further studies in Penaeus monodon allergy diagnostics.

Purification of recombinant trichodysplasia spinulosa-associated polyomavirus VP1-derived virus-like particles using chromatographic techniques.

Trichodysplasia spinulosa-associated polyomavirus (TSPyV) has been linked to a rare and recently characterized skin disease occurring in immunocompromised patients. In analogy with other polyomaviruses, the major capsid protein VP1 of TSPyV can self-assemble into virus-like particles (VLPs). VLPs are increasingly applied for the vaccination and diagnostics. Mostly, non-scalable and labor intensive ultracentrifugation-based techniques are used for the purification of VLPs. In this work, we developed a purification procedure for TSPyV VP1 VLPs based on two chromatographic steps, ion-exchange monolith and core bead chromatography. Prior to chromatography, ammonium sulfate precipitation was used for the initial purification of TSPyV VP1 VLPs from yeast lysate. The VLPs were further purified using CIMmultus QA ion-exchange monolith in bind-elute mode. Most of TSPyV VP1 VLPs bound to the monolith and were subsequently eluted by a linear NaCl gradient. After ion-exchange monolith chromatography, the purity of TSPyV VP1 protein was about 75%. The final purification step of TSPyV VP1 VLPs was core bead chromatography using Capto Core 700 resin in flow-through mode. After core bead chromatography, 42% of TSPyV VP1 protein was recovered with a purity of 93%. The assembly of purified TSPyV VP1 protein into VLPs approximately 45-50 nm in diameter was confirmed by electron microscopy analysis. The purification procedure for TSPyV VP1 VLPs described here could be a scalable alternative to the conventional ultracentrifugation-based purification methods.

Effect of surface histidine mutations and their number on the partitioning and refolding of recombinant human granulocyte-colony stimulating factor (Cys17Ser) in aqueous two-phase systems containing chelated metal ions.

High-level expression of recombinant proteins in Escherichia coli frequently leads to the formation of insoluble protein aggregates, termed inclusion bodies. In order to recover a native protein from inclusion bodies, various protein refolding techniques have been developed. Column-based refolding methods and refolding in aqueous two-phase systems are often an attractive alternative to dilution refolding due to simultaneous purification and improved refolding yields. In this work, the effect of surface histidine mutations and their number on the partitioning and refolding of recombinant human granulocyte-colony stimulating factor Cys17Ser variant (rhG-CSF (C17S)) from solubilized inclusion bodies in aqueous two-phase systems polyethylene glycol (PEG)-dextran, containing metal ions, chelated by dye Light Resistant Yellow 2KT (LR Yellow 2KT)-PEG derivative, was investigated. Human G-CSF is a growth factor that regulates the production of mature neutrophilic granulocytes from the precursor cells. Initially, the role of His156 and His170 residues in the interaction of rhG-CSF (C17S) with Cu(II), Ni(II) and Hg(II) ions, chelated by LR Yellow 2KT-PEG, was investigated at pH 7.0 by means of affinity partitioning of purified, correctly folded rhG-CSF (C17S) mutants. It was determined that both His156 and His170 mutations reduced the affinity of rhG-CSF (C17S) for chelated Cu(II) ions at pH 7.0. His170 mutation significantly reduced the affinity of protein for chelated Ni(II) ions. However, histidine mutations had only a small effect on the affinity of protein for Hg(II) ions. The influence of His156 and His170 mutations on the refolding of rhG-CSF (C17S) from solubilized inclusion bodies in aqueous two-phase systems PEG-dextran, containing chelated Ni(II) and Hg(II) ions, was investigated. Reversible interaction of protein mutants with chelated metal ions was used for refolding in aqueous two-phase systems. Both histidine mutations resulted in a significant decrease of protein refolding efficiency in two-phase systems containing chelated Ni(II) ions, while in the presence of chelated Hg(II) ions their effect on protein refolding was negligible. Refolding studies of rhG-CSF variants with different number of histidine mutations revealed that a direct correlation exists between the number of surface histidine residues and refolding efficiency of rhG-CSF variant in two-phase systems containing chelated Ni(II) ions. This method of protein refolding in aqueous two-phase systems containing chelated metal ions should be applicable to other recombinant proteins that contain accessible histidine residues.

Purification of recombinant virus-like particles of porcine circovirus type 2 capsid protein using ion-exchange monolith chromatography.

Diseases associated with porcine circovirus type 2 (PCV2) infection are having a severe economic impact on swine-producing countries. The PCV2 capsid (Cap) protein expressed in eukaryotic systems self-assemble into virus-like particles (VLPs) which can serve as antigens for diagnostics or/and as vaccine candidates. In this work, conventional adsorbents as well as a monolithic support with large pore sizes were examined for the chromatographic purification of PCV2 Cap VLPs from clarified yeast lysate. Q Sepharose XL was used for the initial separation of VLPs from residual host nucleic acids and some host cell proteins. For the further purification of PCV2 Cap VLPs, SP Sepharose XL, Heparin Sepharose CL-6B and CIMmultus SO3 monolith were tested. VLPs were not retained on SP Sepharose XL. The purity of VLPs after chromatography on Heparin Sepharose CL-6B was only 4-7% and the recovery of VLPs was 5-7%. Using ion-exchange chromatography on the CIMmultus SO3 monolith, PCV2 Cap VLPs with the purity of about 40% were obtained. The recovery of VLPs after chromatography on the CIMmultus SO3 monolith was 15-18%. The self-assembly of purified PCV2 Cap protein into VLPs was confirmed by electron microscopy. Two-step chromatographic purification procedure of PCV2 Cap VLPs from yeast lysate was developed using Q Sepharose XL and cation-exchange CIMmultus SO3 monolith.

Mutation of surface-exposed histidine residues of recombinant human granulocyte-colony stimulating factor (Cys17Ser) impacts on interaction with chelated metal ions and refolding in aqueous two-phase systems.

Site directed mutagenesis of Cys17-->Ser17 form of recombinant human granulocyte colony stimulating factor (rhG-CSF C17S) for sequential replacing of surface His(43) and His(52) with alanine was used to identify residues critical for the protein interaction with metal ions, in particular Ni(2+) chelated by dye Light Resistant Yellow 2 KT (LR Yellow 2KT)-polyethyleneglycol (PEG), and refolding after partitioning of inclusion bodies in aqueous two-phase systems. Strong binding of rhG-CSF (C17S) to PEG-LR Yellow 2KT-Cu(II) complex allowed for the adoption of affinity chromatography on Sepharose-LR Yellow 2KT-Cu(II) that appeared to be essential for the rapid isolation of mutated forms of rhG-CSF. Efficiency of that purification stage is exemplified by isolation of rhG-CSF (C17S, H43A) and rhG-CSF (C17S, H43A, H52A) mutants in correctly folded and highly purified state. Affinity partitioning of rhG-CSF histidine mutants was studied in aqueous two-phase systems containing Cu(II), Ni(II) and Hg(II) chelated by LR Yellow 2KT-PEG at pH 7.0 and Cu(II)-at pH 5.0. It was determined, that affinity of rhG-CSF mutants for metal ions decreased in the order of C17S>C17S, H43A>C17S, H43A, H52A for Cu(II), and C17S=C17S, H43A>C17S, H43A, H52A for Ni(II) ions, while affinity of all rhG-CSF mutants for Hg(II) ions was of the same order of magnitude. Influence of His(43) and His(52) mutation on protein refolding was studied by partitioning of the respective inclusion body extract in aqueous two-phase systems containing Ni(II) and Hg(II) ions. Data on rhG-CSF histidine mutant partitioning and refolding indicated, that His(52) mutation is crucial for the strength of protein interaction with chelated Ni(II) ions and refolding efficiency.