Urh Černigoj

A multimodal histamine ligand for chromatographic purification of plasmid DNA.

To exploit different chromatographic modes for efficient plasmid DNA (pDNA) purification a novel monolithic chromatographic support bearing multimodal histamine (HISA) groups was developed and characterized. Electrostatic charge of HISA groups depends on the pH of the mobile phase, being neutral above pH 7 and becoming positively charged below. As a consequence, HISA groups exhibit predominantly ion-exchange character at low pH values, which decreases with titration of the HISA groups resulting in increased hydrophobicity. This feature enabled separation of supercoiled (sc) pDNA from other plasmid isoforms (and other process related impurities) by adjusting salt or pH gradient. The dynamic binding capacity (DBC) for a 5.1kbp large plasmid at pH 5 was 4.0 mg/ml under low salt binding conditions, remaining relatively high (3.0 mg/ml) even in the presence of 1.0 M NaCl due to the multimodal nature of HISA ligand. Only slightly lower DBC (2.7 mg/ml) was determined under preferentially hydrophobic conditions in 3.0 M (NH(4))(2)SO(4), pH 7.4. Open circular and sc pDNA isoforms were baseline separated in descending (NH(4))(2)SO(4) gradient. Furthermore, an efficient plasmid DNA separation was possible both on analytical as well as on preparative scale by applying the descending pH gradient at a constant concentration (above 3.0 M) of (NH(4))(2)SO(4).

Histamine monolith versatility to purify supercoiled plasmid deoxyribonucleic acid from Escherichia coli lysate.

Preparation of high quantities of supercoiled plasmid DNA of pharmaceutical grade purity is a research area where intensive investigation is being performed. From this standpoint, several downstream methods have been proposed, among them the monolithic chromatographic strategies owing to excellent mass transfer properties of monolithic supports and their high binding capacity for large biomolecules. The present study explores the physicochemical properties of histamine ligand in a supercoiled plasmid DNA purification process from an Escherichia coli clarified lysate, where the emphasis is given to the elution strategy that allows higher selectivity and efficient removal of other impurities besides the open circular isoform. The combination of high NaCl concentration and acidic pH allowed the elimination of 89% of RNA during the preparative loading of the lysate sample. The results of the purification strategy with ascending sodium chloride gradient revealed that 97% of supercoiled plasmid DNA was recovered with a purity degree of 99%. In addition, using a combined purification strategy with ascending sodium chloride (capture step) and then descending ammonium sulfate (polishing step) gradient, it was achieved a lower supercoiled plasmid DNA recovery yield of 79% with a purity degree of 92%, although the dynamic binding capacity under these conditions was higher than in the previous strategy. A significant reduction of host contents, such as proteins, RNA and genomic DNA, was obtained in both purification strategies. Accordingly, histamine is a useful and versatile ligand that allows the desirable supercoiled plasmid purification with high yield and purity level.

Rapid quantification of supercoiled plasmid deoxyribonucleic acid using a monolithic ion exchanger

The demand for high-purity supercoiled plasmid DNA to be applied as a vector for new therapeutic strategies, such as gene therapy or DNA vaccination has increased in the last years. Thus, it is necessary to implement an analytical technique suitable to control the quality of the supercoiled plasmid as a pharmaceutical product during the manufacturing process. The present study describes a new methodology to quantify and monitor the purity of supercoiled plasmid DNA by using a monolithic column based on anion-exchange chromatography. This analytical method with UV detection allows the separation of the plasmid isoforms by combining a NaCl stepwise gradient. The specificity, linearity, accuracy, reproducibility and repeatability of the method have been evaluated, and the lower quantification and detection limits were also established. The validation was performed according to the guidelines, being demonstrated that the method is precise and accurate for a supercoiled plasmid concentration up to 200μg/mL. The main advantage achieved by using this monolithic column is the possibility to quantify the supercoiled plasmid in a sample containing other plasmid topologies, in a 4min experiment. This column also permits the assessment of the supercoiled plasmid DNA present in more complex samples, allowing to control its quality throughout the bioprocess. Therefore, these findings strengthen the possibility of using this monolithic column associated with a powerful analytical method to control the process development of supercoiled plasmid DNA production and purification for therapeutic applications.

Towards automation in protein digestion: Development of a monolithic trypsin immobilized reactor for highly efficient on-line digestion and analysis

Reducing experimental variability, limiting contamination and increasing automation are essential goals in the development of reliable analytical platforms for mass spectrometry (MS)-based proteomics. In this work novel trypsin-based monolithic immobilized enzyme reactors (tryp-IMERs), obtained by covalent immobilization on convective interaction media (CIMac™) analytical columns (5mm×5.2mm I.D.), were developed. Notwithstanding the small dimensions, column format allowed the insertion in common high performance liquid chromatography (HPLC) systems, thus avoiding the use of expensive micro- or nano-platforms. Monolith pore diameter and surface chemistry were optimized to achieve high digestion efficiency even with high molecular weight proteins and to avoid protein/peptide adsorption, peak broadening and sample loss. A full characterization of the tryp-IMERs was undertaken to select the best protocol for preparation and type of trypsin. Optimization of the operational and storage conditions was carried out by an off-line approach. On-line studies were performed by setting a multidimensional analytical platform, which included the tryp-IMER, a trapping column, an analytical C4 column and a high resolution hybrid mass spectrometer (ESI-Q-TOF). In the optimized conditions rapid protein digestion (90±9s), high protein coverage (≥60%) and high score values were achieved for five selected sample proteins (cytochrome c, myoglobin and albumins from different sources) differing in molecular size, isoelectric point and accessibility to cleavage sites as well as for a protein mixture of 200ng. The best performing tryp-IMERs showed high sensitivity down to the pmole level. The platform also resulted suitable for the analysis of high-molecular weight proteins such as a pool of human immunoglobulins G (hIgG) and for the high molecular weight fraction of human plasma proteins, which were digested in less than two minutes to an extent similar to that achieved by overnight incubation in a classical in solution protocol. Finally, underestimated key procedural issues were also highlighted during the study. Such aspects are of general interest both for tryp-IMER users and tryp-IMER developers.

Characterization of methacrylate chromatographic monoliths bearing affinity ligands

We investigated effect of immobilization procedure and monolith structure on chromatographic performance of methacrylate monoliths bearing affinity ligands. Monoliths of different pore size and various affinity ligands were prepared and characterized using physical and chromatographic methods. When testing protein A monoliths with different protein A ligand densities, a significant nonlinear effect of ligand density on dynamic binding capacity (DBC) for IgG was obtained and accurately described by Langmuir isotherm curve enabling estimation of protein A utilization as a function of ligand density. Maximal IgG binding capacity was found to be at least 12mg/mL exceeding theoretical monolayer adsorption value of 7.8mg/mL assuming hexagonal packing and IgG hydrodynamic diameter of 11nm. Observed discrepancy was explained by shrinkage of IgG during adsorption on protein A experimentally determined through calculated adsorbed IgG layer thickness of 5.4nm from pressure drop data. For monoliths with different pore size maximal immobilized densities of protein A as well as IgG dynamic capacity linearly correlates with monolith surface area indicating constant ligand utilization. Finally, IgGs toward different plasma proteins were immobilized via the hydrazide coupling chemistry to provide oriented immobilization. DBC was found to be flow independent and was increasing with the size of bound protein. Despite DBC was lower than IgG capacity to immobilized protein A, ligand utilization was higher.

Titanium dioxide nanoparticle coating of polymethacrylate-based chromatographic monoliths for phosphopetides enrichment.

Metal oxide affinity chromatography has been one of the approaches for specific enrichment of phosphopeptides from complex samples, based on specific phosphopeptide adsorption forming bidentate chelates between phosphate anions and the surface of a metal oxide, such as TiO2, ZrO2, Fe2O3, and Al2O3. Due to convective mass transfer, flow-independent resolution and high dynamic binding capacity, monolith chromatographic supports have become important in studies where high resolution and selectivity are required. Here, we report the first synthesis and characterization of immobilisation of rutile TiO2 nanoparticles onto organic monolithic chromatographic support (CIM-OH-TiO2). We demonstrate the specificity of CIM-OH-TiO2 column for enrichment of phosphopeptides by studying chromatographic separation of model phosphorylated and nonphosphorylated peptides as well as proving the phosphopeptide enrichment of digested bovine α-casein. The work described here opens the possibility for a faster, more selective enrichment of phosphopeptides from biological samples that will enable future advances in studying protein phosphorylation.

Depletion of human serum albumin in embryo culture media for in vitro fertilization using monolithic columns with immobilized antibodies.

Affinity depletion of abundant proteins such as HSA is an important stage in routine sample preparation prior to MS/MS analysis of biological samples with high range of concentrations. Due to the charge competition effects in electrospray ion source that results in discrimination of the low‐abundance species, as well as limited dynamic range of MS/MS, restricted typically by three orders of magnitude, the identification of low‐abundance proteins becomes a challenge unless the sample is depleted from high‐concentration compounds. This dictates a need for developing efficient separation technologies allowing fast and automated protein depletion. In this study, we performed evaluation of a novel immunoaffinity‐based Convective Interaction Media analytical columns (CIMac) depletion column with specificity to HSA (CIMac‐αHSA). Because of the convective flow‐through channels, the polymethacrylate CIMac monoliths afford flow rate independent binding capacity and resolution that results in relatively short analysis time compared with traditional chromatographic supports. Seppro IgY14 depletion kit was used as a benchmark to control the results of depletion. Bottom‐up proteomic approach followed by label‐free quantitation using normalized spectral indexes were employed for protein quantification in G1/G2 and cleavage/blastocyst in vitro fertilization culture media widely utilized in clinics for embryo growth in vitro. The results revealed approximately equal HSA level of 100 ± 25% in albumin‐enriched fractions relative to the nondepleted samples for both CIMac‐αHSA column and Seppro kit. In the albumin‐free fractions concentrated 5.5‐fold by volume, serum albumin was identified at the levels of 5–30% and 20–30% for the CIMac‐αHSA and Seppro IgY14 spin columns, respectively.

Reversible entrapment of plasmid deoxyribonucleic acid on different chromatographic supports.

HPLC based analytical assay is a powerful technique that can be used to efficiently monitor plasmid DNA (pDNA) purity and quantity throughout the entire purification process. Anion exchange monolithic and non-porous particle based stationary phases were used to study the recovery of the different pDNA isoforms from the analytical column. Three differently sized pDNA molecules of 3.0kbp, 5.2kbp and 14.0kbp were used. Plasmid DNA was injected onto columns under the binding conditions and the separation of the isoforms took place by increasing the ionic strength of the elution buffer. While there was no substantial decrease of the recovered supercoiled and linear isoforms of the pDNA with the increase of the plasmid size and with the increase of the flow rate (recoveries in all cases larger than 75%), a pronounced decrease of the oc isoform recovery was observed. The entrapment of the oc pDNA isoform occurred under non-binding conditions as well. The partial oc isoform elution from the column could be achieved by decreasing the flow rate of the elution mobile phase. The results suggested a reversible entrapment of the oc isoform in the restrictions within the pores of the monolithic material as well as within the intra-particle space of the non-porous particles. This phenomenon was observed on both types of the stationary phase morphologies and could only be connected to the size of a void space through which the pDNA needs to migrate. A prediction of reversible pDNA entrapment was successfully estimated with the calculation of Peclet numbers, Pe, which defines the ratio between a convective and diffusive mass transport.

Production of β-Lactoglobulin hydrolysates by monolith based immobilized trypsin reactors

Tryptic hydrolysis of β‐Lactoglobulin (β‐Lg) is attracting more and more attention due to the reduced allergenicity and the functionality of resulting hydrolysates. To produce hydrolysates in an economically viable way, immobilized trypsin reactors (IMTRs), based on polymethacrylate monolith with pore size 2.1 μm (N1) and 6 μm (N2), were developed and used in a flow‐through system. IMTRs were characterized in terms of permeability and enzymatic activity during extensive usage. N1 showed twice the activity compared with N2, correlating well with its almost two times higher amount of immobilized trypsin. N2 showed high stability over 18 cycles, as well as over more than 30 weeks during storage. The efficiency of IMTRs on hydrolyzing β‐Lg was compared with free trypsin, and the resulting hydrolysates were analyzed by MALDI‐TOF/MS. The final hydrolysis degree by N1 reached 9.68% (86.58% cleavage sites) within 4 h, while only around 6% (53.67% cleavage sites) by 1.5 mg of free trypsin. Peptides analysis showed the different preference between immobilized trypsin and free trypsin. Under the experimental conditions used in this study, the potential cleavage site Lys135‐Phe136 was resistant against the immobilized trypsin in N1.

Sample displacement chromatography of plasmid DNA isoforms.

Sample displacement chromatography (SDC) is a chromatographic technique that utilises different relative binding affinities of components in a sample mixture and has been widely studied in the context of peptide and protein purification. Here, we report a use of SDC to separate plasmid DNA (pDNA) isoforms under overloading conditions, where supercoiled (sc) isoform acts as a displacer of open circular (oc) or linear isoform. Since displacement is more efficient when mass transfer between stationary and mobile chromatographic phases is not limited by diffusion, we investigated convective interaction media (CIM) monoliths as stationary phases for pDNA isoform separation. CIM monoliths with different hydrophobicities and thus different binding affinities for pDNA (CIM C4 HLD, CIM-histamine and CIM-pyridine) were tested under hydrophobic interaction chromatography (HIC) conditions. SD efficiency for pDNA isoform separation was shown to be dependent on column selectivity for individual isoform, column efficiency and on ammonium sulfate (AS) concentration in loading buffer (binding strength). SD and negative mode elution often operate in parallel, therefore negative mode elution additionally influences the efficiency of the overall purification process. Optimisation of chromatographic conditions achieved 98% sc pDNA homogeneity and a dynamic binding capacity of over 1mg/mL at a relatively low concentration of AS. SDC was successfully implemented for the enrichment of sc pDNA for plasmid vectors of different sizes, and for separation of linear and and sc isoforms, independently of oc:sc isoform ratio, and flow-rate used. This study therefore identifies SDC as a promising new approach to large-scale pDNA purification, which is compatible with continuous, multicolumn chromatography systems, and could therefore be used to increase productivity of pDNA production in the future.