Publications
2004
E. G. Vlakh, A. Tappe, C. Kasper, T. B. Tennikova
Journal of Chromatography B, 810 (2004) 15–23
Plasminogen activators are the proteases which convert plasminogen into plasmin dissolving, in its turn, the major component of blood clots, fibrin. They are extremely useful in heart attack therapy. Modern and most appropriate way of scaled up production of these valuable proteins is gene engineering. In this case, a separation and a purification of target product become the important steps of the whole process. Recently developed affinity chromatography on short monolithic columns seems to be a very attractive method for these purposes. High speed of a process prevents the protein’s denaturation due to temperature or/and solvents influence. The better mass transfer mechanism (convection rather than diffusion) allows considering only biospecific complexing as time limiting step. Specificity of several synthetic peptides to plasminogen activators have been studied by affinity chromatography on short monolithic columns. Peptide ligands were synthesized by conventional solid phase peptide synthesis (SPPS). The immobilization procedure was carried out as a one step process at static conditions. The results of quantitative evaluation of such affinity interactions were compared with those established for plasminogen that is the natural affinity counterpart to both proteases. Additionally, some of investigated peptides were synthesized directly on GMA–EDMA disks and their affinity properties were compared with those established for the case of immobilized ligands. The possibility of using of synthetic peptidyl ligands for plasminogen activators isolation from native cell supernatant and model protein mixtures has been demonstrated.
E. Vlakh, N. Ostryanina, A. Jungbauer, T. Tennikova
Journal of Biotechnology 107 (2004) 275–284
Present report demonstrates the examples of practical application of sorbents obtained via direct solid phase peptide synthesis (SPPS) on GMA-EDMA monoliths (CIM® Disks, BIA Separations, d.o.o., Ljubljana, Slovenia). Several peptidyl complementary to recombinant tissue plasminogen activator (t-PA) ligands have been synthesized using Fmoc-chemistry. This approach affords to get directly sorbents for affinity chromatography avoiding a cleavage of synthesized peptides from a carrier following by their isolation, analysis and purification. The affinity binding parameters were found from experimental frontal analysis data. The results have been compared with those established for CIM® affinity sorbents obtained by immobilization of the same but preliminarily synthesized on convenient resin, cleaved and purified ligands on the disks using one step reaction with epoxy groups of monolithic material. It has been shown that the affinity constants of these two kinds of sorbent did not vary significantly. Directly obtained affinity sorbents have been used for fast and efficient on-line analysis as well as semi-preparative isolation of recombinant t-PA from crude cellular supernatant.
M. Bartolini, V. Cavrini, V. Andrisano
Journal of Chromatography A, 1031 (2004) 27–34(2004) 27–34
The development and characterization of a human recombinant acetylcholinesterase (hrAChE) micro-immobilized-enzyme reactor (IMER), prepared by using an in situ immobilization procedure is reported. hrAChE was covalently immobilized on an ethylenediamine (EDA) monolithic convective interaction media (CIM) disk (12mm x 3mm i.d.), previously derivatized with glutaraldehyde. The optimal conditions for the immobilization were: 12 μg of enzyme dissolved in 800 μl of phosphate buffer (50 mM, pH 6.0). The mixture was gently agitated overnight at 4 °C. The resulting Schiff bases were reduced by cyanoborohydride and the remaining aldehydic groups were condensed with monoethanolamine. Under these conditions, 0.22 U of hrAChE were immobilized with retention of 3.0% of the initial enzymatic activity. The activity of the immobilized hrAChE was stable for over 60 days. The activity and kinetic parameters of the hrAChE micro-IMER were investigated by inserting the micro-IMER in a HPLC system and it was demonstrated that the enzyme retained its activity. The micro-IMER was characterized in terms of units of immobilized enzyme and best conditions for immobilization yield. IMERs were compared for their relative enzyme stability, immobilized units, yield and aspecific matrix interactions. The effect of AChE inhibitors was evaluated by the simultaneous injection of each inhibitor with the substrate. The relative IC50 values were found in agreement with those derived by the conventional kinetic spectrophotometric method. In comparison with previously developed AChE-based IMERs, AChE monolithic micro-IMER showed advantages in terms of reduction of analysis time (2 min), lower aspecific matrix interactions and lower backpressure. Included in a HPLC system, it can be used for the rapid screening of new compounds’ inhibitory potency. The advantages over the conventional methods are the increased enzyme stability and system automation which allows a large number of compounds to be analyzed in continuous.
K. Benčina, A. Podgornik, A. Štrancar, M. Benčina
Journal of Separation Science 2004, 27, 811-818
Monolithic Convective Interaction Media (CIM) have been activated with epoxide and imidazole carbamate functionalities and used as supports for covalent immobilization of protein A, deoxyribonuclease I, and trypsin. The efficiency of immobilization for these proteins was determined from the amount of bound IgG, degradation of DNA, and hydrolysis of Nα-benzoyl-L-arginine ethyl ester, respectively. The respective biological activities of trypsin and the binding capacity of protein A immobilized via imidazole carbamate groups were 11.45 and 2.25 times higher than those obtained for epoxide matrix while they were practically equal for deoxyribonuclease I. The kinetics of immobilization was studied in detail for trypsin under dynamic conditions and revealed that the enzyme immobilized via imidazole carbamate groups already reached its highest activity in 5 min. In contrast, a much longer time was required for immobilization via epoxy groups.
2003
K. Branović, A. Buchacher, M. Barut, A. Štrancar, D. Josić
Journal of Chromatography B, 790 (2003) 175–182
It has been shown in a previous study that monolithic columns can be used for downstream processing of different concentrates of clotting factor IX [K. Branović et al., J. Chromatogr. A 903 (2000) 21]. This paper demonstrates that such supports are useful tools also at an early stage of the purification process of factor IX from human plasma. Starting with the eluate after solid-phase extraction with DEAE-Sephadex, the use of monolithic columns has allowed much better purification than that achieved with conventional anion-exchange supports. The period of time required for separation is also much reduced. In up-scaling experiments, separations are carried out with 8, 80 and 500 ml columns. A volume of 1830 ml of DEAE-Sephadex eluate, containing a total of 27.6 g of protein and 48.500 IU of factor IX is applied to the 500 ml monolithic column. This corresponds to a separation on a pilot scale. The results of this separation after up-scaling are comparable to those obtained with the 8 ml column on a laboratory scale.
I. Mihelič, A. Podgornik, T. Koloini
Journal of Chromatography A, 987 (2003) 159–168
This work investigates the influence of temperature on the binding capacity of bovine serum albumin (BSA), soybean trypsin inhibitor and l-glutamic acid to a CIM® (DEAE) weak anion-exchange disk monolithic column. The binding capacity was determined experimentally under dynamic conditions using frontal analysis. The effect on the dynamic binding capacity of dimers present in the BSA solution has been evaluated and a closed-loop frontal analysis was used to determine the equilibrium binding capacities. The binding capacity for both BSA and soybean trypsin inhibitor increased with increasing temperature. In the case of l-glutamic acid, an increase in the binding capacity was observed with temperature up to 20 °C. A further increase in temperature caused a decrease of the dynamic binding capacity.
R. Hahn, E. Berger, K. Pflegerl, A. Jungbauer
Anal. Chem. 2003, 75, 543-548
When small ligands are immobilized onto a porous chromatography medium, only a limited number of binding sites contributes to the interaction with the target molecule. The main part of the ligand molecules is distributed on sites that are not accessible for the target protein due to steric hindrance. To direct the ligand into a well-accessible position, the ligand was conjugated to a large molecule that acted as a placeholder during the immobilization step. Then the placeholder molecule was cleaved off and washed out. Two linear peptides with affinity for lysozyme and human blood coagulation factor VIII, respectively, were studied as model systems. The protected peptide ligand was covalently linked to a 20-kDa poly(ethylene glycol) molecule containing an acid-labile linker. After selective deprotection of the peptide and purification, immobilization of this conjugate on a preactivated chromatography matrix was performed alternatively through the free N-terminus, the ε-amino group of lysine, or the sulfohydryl group of cysteine. After the immobilization reaction, the spacer molecule and remaining protecting groups were cleaved off and the gels were tested by affinity chromatography. This novel immobilization technique substantially increased the binding capacity and the ligand utilization for the target protein, and site-specific immobilization could be demonstrated.
M. Vodopivec, A. Podgornik, M. Berovič, A. Štrancar
Journal of Chromatography B, 795 (2003) 105-113
The immobilization of the enzymes citrate lyase, malate dehydrogenase, isocitrate dehydrogenase and lactate dehydrogenase to CIM monolithic supports was performed. The long-term stability, reproducibility, and linear response range of the immobilized enzyme reactors were investigated along with the determination of the kinetic behavior of the enzymes immobilized on the CIM monoliths. The Michaelis–Menten constant Km and the turnover number k3 of the immobilized enzymes were found to be flow-unaffected. Furthermore, the Km values of the soluble and immobilized enzyme were found to be comparable. Both facts indicate the absence of a diffusional limitation in immobilized CIM enzyme reactors.
2002
K. Pflegerl, A. Podgornik, E. Berger, A. Jungbauer
J. Comb. Chem. 2002, 4, 33-37
Solid-phase peptide synthesis was performed on glycidyle methacrylate-co-ethylene dimethacrylate monoliths using Fmoc chemistry. The native epoxy groups were amino-functionalized by reaction with ethylenediamine or ammonia ions. A peptide directed against human blood coagulation factor VIII was synthesized as a model peptide. Amino acid analysis revealed the correct amino acid ratio as present in the sequence. The ligand density of 5 μmol/mL was equal to that achieved with conventional peptide immobilization via epoxy groups. These supports were directly used as peptide affinity chromatography matrixes. The functionality of the CIM monolithic supports was proven by affinity chromatography of factor VIII. The ammonia-functionalized support performed with low hydrophobicity and did not show unspecific adsorption of proteins.
K. Branović, G. Lattner, M. Barut, A. Štrancar, D. Josić, A. Buchacher
Journal of Immunological Methods 9211 (2002) 20;271(1-2):47-58
Transferrin and albumin are often present in immunoglobulin G (IgG) concentrates and are considered as impurities. Therefore, it is important to determine their concentration in order to obtain a well-characterized biological product. Here, we describe their determination based on conjoint liquid chromatography (CLC). The established method combines two different chromatographic modes in one step: affinity and ion-exchange chromatography (IEC) combined in one column. Therefore, two CIM Protein G and one CIM quaternary amine (QA) monolithic disks were placed in series in one housing forming a CLC monolithic column. Binding conditions were optimized in a way that immunoglobulins were captured on the CIM Protein G disks, while transferrin and albumin were bound on the CIM QA disks. Subsequently, transferrin and albumin were eluted separately by a stepwise gradient with sodium chloride, whereas immunoglobulins were released from the Protein G ligands by applying low pH. A complete separation of all three proteins was achieved in less than 5 min. The method permits the quantification of albumin and transferrin in IgG concentrates and has been successfully validated.
T. V. Gupalova, O. V. Lojkina, V. G. Palagnuk, A. A. Totolian, T.B. Tennikova
Journal of Chromatography A, 949 (2002) 185–193
The recombinantly produced different forms of protein G, namely monofunctional immunoglobulin G (IgG) binding, monofunctional serum albumin (SA) binding and bifunctional IgG/SA binding proteins G, are compared with respect to their specific affinities to blood IgG and SA. The affinity mode of the recently developed high-performance monolithic disk chromatography has been used for fast quantitative investigations. Using single affinity disks as well as two discs stacked into one separation unit, one order of magnitude in adsorption capacities for IgG and SA were found both for monofunctional and bifunctional protein G forms used as specific affinity ligands. However, despite the adsorption difference observed, the measured dissociation constants of the affinity complexes seemed to be very close. The analytical procedure developed can be realized within a couple of minutes. Up-scaling of the developed technology was carried out using another type of monolithic materials, i.e. CIM® affinity tubes.
N. D. Ostryanina, G. P. Vlasov, T. B. Tennikova
Journal of Chromatography A, 949 (2002) 163–171
High-performance monolithic disk chromatography (HPMDC), including its affinity mode, is a very efficient method for fast separations of biological molecules of different sizes and shapes. In this paper, protein and peptide ligands, immobilized on the inner surface of thin, monolithic supports (Convective Interaction Media or CIM® disks), have been used to develop methods for fast, quantitative affinity fractionation of pools of polyclonal antibodies from blood sera of rabbits, immunized with complex protein–peptide conjugates. The combination of several disks with different affinity functionalities in the same cartridge enables the separation of different antibodies to be achieved within a few minutes. The apparent dissociation constants of affinity complexes were determined by frontal analysis. Variation of elution flow rate over a broad range does not affect the affinity separation characteristics. Indifferent synthetic peptides used as biocompatible spacers do not change the affinity properties of the ligands. The highly reproducible results of immunoaffinity HPMDC are compared with data obtained by widely used enzyme-linked immunosorbent assay.
K. Pflegerl,A. Podgornik, E. Berger, A. Jungbauer
J. Comb. Chem. 2002, 4, 33-37
Solid-phase peptide synthesis was performed on glycidyle methacrylate-co-ethylene dimethacrylate monoliths using Fmoc chemistry. The native epoxy groups were amino-functionalized by reaction with ethylenediamine or ammonia ions. A peptide directed against human blood coagulation factor VIII was synthesized as a model peptide. Amino acid analysis revealed the correct amino acid ratio as present in the sequence. The ligand density of 5 μmol/mL was equal to that achieved with conventional peptide immobilization via epoxy groups. These supports were directly used as peptide affinity chromatography matrixes. The functionality of the CIM monolithic supports was proven by affinity chromatography of factor VIII. The ammonia-functionalized support performed with low hydrophobicity and did not show unspecific adsorption of proteins.
N. D. Ostryanina, G. P. Vlasov, T. B. Tennikova
Journal of Chromatography A, 949 (2002) 163–171
High-performance monolithic disk chromatography (HPMDC), including its affinity mode, is a very efficient method for fast separations of biological molecules of different sizes and shapes. In this paper, protein and peptide ligands, immobilized on the inner surface of thin, monolithic supports (Convective Interaction Media or CIM® disks), have been used to develop methods for fast, quantitative affinity fractionation of pools of polyclonal antibodies from blood sera of rabbits, immunized with complex protein–peptide conjugates. The combination of several disks with different affinity functionalities in the same cartridge enables the separation of different antibodies to be achieved within a few minutes. The apparent dissociation constants of affinity complexes were determined by frontal analysis. Variation of elution flow rate over a broad range does not affect the affinity separation characteristics. Indifferent synthetic peptides used as biocompatible spacers do not change the affinity properties of the ligands. The highly reproducible results of immunoaffinity HPMDC are compared with data obtained by widely used enzyme-linked immunosorbent assay.
H. Podgornik, A. Podgornik
Enzyme and Microbial Technology 31 (2002) 855–861
The possibility of covalent attachment of LiP H2 and LiP H8 to CIM monoliths was studied. Due to negligible diffusional resistance, they can be useful tools to study characteristics of the immobilized lignin peroxidase (LiP). Immobilization to epoxy groups was performed using alkaline conditions (borate-phosphate buffer; pH 7.5). Characteristics of immobilized LiP were compared and factors that influence their biologic activity were evaluated using flow through experiments. Enzyme kinetics was determined via oxidation of veratryl alcohol (VA) into veratraldehyde (Vald). While VA oxidation rate increased by increasing flow rate (up to 1.5 ml/min) for LiP H2, it was almost constant in a wide flow rate range for LiP H8. This observation together with the stepwise deactivation of the enzyme by consecutive experiments was ascribed to accumulation of the formed Vald inside the support. Calculated kinetic parameters showed 3–5 times higher Km value for VA for both tested isoforms in comparison to free enzyme. The catalytic constant was found to be approximately 0.5 s-1 for both isoforms. Immobilized LiP H8 was used for decolorization of azo dye Mahogany.
A. Podgornik, T. B. Tennikova
Advances in Biochemical Engineering/ Biotechnology, 2002, Vol. 76, 167-206
In the last decade there were many papers published on the study of enzyme catalyzed reactions performed in so-called chromatographic reactors. The attractive feature of such systems is that during the course of the reaction the compounds are already separated, which can drive the reaction beyond the thermodynamic equilibrium as well as remove putative inhibitors. In this chapter, an overview of such chromatographic bioreactor systems is given. Besides, some immobilization techniques to improve enzyme activity are discussed together with modern chromatographic supports with improved hydrodynamic characteristics to be used in this context.
H. Podgornik, A. Podgornik
Enzyme and Microbial Technology 31 (2002) 855–861
The possibility of covalent attachment of LiP H2 and LiP H8 to CIM monoliths was studied. Due to negligible diffusional resistance, they can be useful tools to study characteristics of the immobilized lignin peroxidase (LiP). Immobilization to epoxy groups was performed using alkaline conditions (borate-phosphate buffer; pH 7.5). Characteristics of immobilized LiP were compared and factors that influence their biologic activity were evaluated using flow through experiments. Enzyme kinetics was determined via oxidation of veratryl alcohol (VA) into veratraldehyde (Vald). While VA oxidation rate increased by increasing flow rate (up to 1.5 ml/min) for LiP H2, it was almost constant in a wide flow rate range for LiP H8. This observation together with the stepwise deactivation of the enzyme by consecutive experiments was ascribed to accumulation of the formed Vald inside the support. Calculated kinetic parameters showed 3–5 times higher Km value for VA for both tested isoforms in comparison to free enzyme. The catalytic constant was found to be approximately 0.5 s−1 for both isoforms. Immobilized LiP H8 was used for decolorization of azo dye Mahogany.
2001
R. Hahn, A. Podgornik, M. Merhar, E. Schallaun, A. Jungbauer
Anal. Chem. 2001, 73, 5126-5132
An affinity monolith with a novel immobilization strategy was developed leading to a tailored pore structure. Hereby the ligand is conjugated to one of the monomers of the polymerization mixture prior to polymerization. After the polymerization, a monolithic structure was obtained either ready to use for affinity chromatography or ready for coupling of additional ligand to further increase the binding capacity. The model ligand, a peptide directed against lysozyme, was conjugated to glycidyl methacrylate prior to the polymerization. With this conjugate, glycidyl methacrylate, and ethylene dimethacrylate, a monolith was formed and tested with lysozyme. A better ligand presentation was achieved indicated by the higher affinity constant compared to a conventional sorbent.
D. Josić, A. Buchacher
J. Biochem. Biophys. Methods 49 (2001) 153–174
Monoliths are useful chromatographic supports, as their structure allows improved mass transport. This results in fast separation. Once the ligand of interest has been immobilized, chromatographic separation can also be accomplished in affinity mode. Ligands with low molecular mass have been shown to be the easiest to immobilize. Nowadays, ligands with low molecular mass are often designed by combinatorial chemical techniques. In addition, many applications have been described where ligands with high molecular mass, such as Proteins A and G, antibodies, lectins and receptors are used.
The immobilization of an enzyme on the monolithic support creates a flow-through reactor. Small proteins, such as carbonic anhydrase, can be directly immobilized on the support. However, in the case of large molecules, the active center of the enzyme is no longer accessible at all or only to a limited degree. An improvement can be achieved by introducing a spacer, which allows maximum enzymatic conversion. Fast conversion of substrates with high molecular mass has been investigated with immobilized trypsin. It was shown that in case of high-molecular-mass substrates, the conversion rate depends very much on the flow-rate. Most applications described have been performed on an analytical or semi-preparative scale. However, the technical problems of up-scaling are close to being definitely solved, enabling enzymatic conversion on a preparative scale in the future.
D. Josić, A. Buchacher
J. Biochem. Biophys. Methods 49 (2001) 153–174
Monoliths are useful chromatographic supports, as their structure allows improved mass transport. This results in fast separation. Once the ligand of interest has been immobilized, chromatographic separation can also be accomplished in affinity mode. Ligands with low molecular mass have been shown to be the easiest to immobilize. Nowadays, ligands with low molecular mass are often designed by combinatorial chemical techniques. In addition, many applications have been described where ligands with high molecular mass, such as Proteins A and G, antibodies, lectins and receptors are used.
The immobilization of an enzyme on the monolithic support creates a flow-through reactor. Small proteins, such as carbonic anhydrase, can be directly immobilized on the support. However, in the case of large molecules, the active center of the enzyme is no longer accessible at all or only to a limited degree. An improvement can be achieved by introducing a spacer, which allows maximum enzymatic conversion. Fast conversion of substrates with high molecular mass has been investigated with immobilized trypsin. It was shown that in case of high-molecular-mass substrates, the conversion rate depends very much on the flow-rate. Most applications described have been performed on an analytical or semi-preparative scale. However, the technical problems of up-scaling are close to being definitely solved, enabling enzymatic conversion on a preparative scale in the future.