Purification of influenza deoxyribonucleic acid-based vaccine using agmatine monolith.

Lately, researchers have made several efforts to improve vaccine production to fight highly contagious respiratory diseases like influenza. One of the most promising options for reducing the impact of this virus is DNA vaccination. However, a large quantity of highly pure plasmid DNA (pDNA) is necessary to attain this goal. The present work describes the production and purification of the plasmid NTC7482-41H-VA2HA expressing influenza virus hemagglutinin using an agmatine monolith. This ligand was chosen to purify supercoiled (sc) pDNA from complex lysates because of its versatile multimodal character. Its natural intervention in several biological systems together with its similarity with the highly studied arginine ligand allowed the development of a simpler and more specific purification process. Agmatine works under two strategies: descending ammonium sulfate gradient and ascending sodium chloride gradient. Furthermore, pH manipulation revealed an important role in pDNA isoforms selectivity. Dynamic binding capacity (DBC) experiments were performed varying different parameters and showed an increase with pDNA concentration, while high flow rate and high pH had the opposite effect. Sc pDNA was purified with high yield and was efficient with respect to cell transfection and cell viability. This monolith showed to be appropriate to purify the plasmid NTC7482-41H-VA2HA, providing a valuable tool for pDNA influenza vaccines preparation.

Aromatic ligands for plasmid deoxyribonucleic acid chromatographic analysis and purification: an overview.

The aromatic ring systems are among the most stable chemical structures known and in combination with many other chemical groups, they can originate an extraordinary variety of molecules, with interesting chemical and physical properties. Many aromatic molecules have been applied for the purification of various biomolecules, such as proteins, carbohydrates and nucleic acids. Combining aromatic chromatography with optimized production, extraction and clarification procedures, can offer a number of advantages for pharmaceutical plasmid DNA (pDNA) purification. This review focuses on pDNA chromatographic purification and analysis using aromatic ligands. The goal is to give an updated view of all existing aromatic ligands, their main characteristics, applicability and technical features of the chromatographic methods in which they have been applied. Also, a critical assessment of each method is performed as well as a comparison of the different procedures, their key features and limitations.

Negative pseudo-affinity chromatography for plasmid DNA purification using berenil as ligand.

The present study, reports the utilization of berenil as ligand in a negative pseudo-affinity chromatographic step to purify the plasmid pVAX1-LacZ from Escherichia coli clarified lysates. The chromatographic support was prepared by coupling berenil to epoxy-activated Sepharose and was qualitatively and quantitatively characterized using scanning electron microscopy, Fourier transformed infrared spectroscopy and elemental analysis. The clarified lysate was loaded onto the berenil-Sepharose support with 0.55M of ammonium sulphate in the eluent, achieving the immediate elution of plasmid DNA. The impurities tightly bound to the support, were eluted after decreasing the salt concentration to 0M. The overall process enabled the recovery of 87% of loaded plasmid DNA with a HPLC purity of ≫99% and according to FDA specifications. This method represents an alternative approach to the previous utilization of the same chromatographic pseudo-affinity support in a positive mode. It uses lower amounts of salt and one-step chromatographic procedure, resulting in smaller operating time and costs and representing an alternate procedure for plasmid DNA purification.

Dynamic binding capacity and specificity of 3,8-diamino-6-phenylphenanthridine-Sepharose support for purification of supercoiled plasmid deoxyribonucleic acid.

Affinity chromatography represents a sole technique in purification of different biomolecules. The specific recognition between affinity ligands and target biomolecules has a major role in the specificity of the process. Therefore, choosing the right ligand is a crucial step for the development of a successful purification system. This work describes the application of the DNA intercalator 3,8-diamino-6-phenylphenanthridine (DAPP) as a chromatographic affinity ligand for the specific separation and purification of supercoiled plasmid DNA (pDNA). The support was prepared by coupling DAPP onto an epoxy-activated Sepharose matrix, using mild conditions and resulting in a ligand density of 0.15mmolDAPP/g derivatized Sepharose. The characterization of DAPP-Sepharose support in terms of dynamic binding capacity was achieved by studying the effect of plasmid DNA concentration and flow rate on pDNA adsorption. The maximum capacity value of 336.75µgpDNA/mL gel was obtained at 1mL/min with a pDNA concentration of 150µg/mL. Moreover, the values did not vary significantly with the variation of flow rate. In addition, the DAPP-Sepharose showed a high affinity towards pDNA as quantified by the respective dissociation constant (Kd=2.29±0.195×10(-7)M). The support was also tested for the purification of two plasmid molecules with different sizes (pVAX1-LacZ and pCAMBIA-1303, with 6.05kbp and 12.361kbp, respectively) from clarified Escherichia coli lysate solutions. Total retention of all lysate components was achieved without any added salt to the eluent buffer. The selective elution of impurities and supercoiled pDNA was accomplished simply by the addition of small amounts of salt to the buffer solution. The yield for pCAMBIA-1303 was 65% and for pVAX1-LacZ was 94%, with all host impurity levels in accordance with the requirements established by the regulatory agencies.

Specific recognition of supercoiled plasmid DNA by affinity chromatography using the intercalator DAPP as ligand.

Small molecules that bind DNA with high specificity present a promising opportunity for application as chromatographic ligands for plasmid DNA (pDNA) purification. This research used the intercalator 3,8-diamino-6-phenylphenanthridine (DAPP) as an immobilized ligand for the specific separation of supercoiled (sc) pDNA by affinity chromatography. The results showed that the protonated DAPP-Sepharose support has a great affinity for sc pDNA isoform, separating it from the less active open circular and linear isoforms. All pDNA isoforms were retained in the column using 10mM acetate buffer pH 5. Selective elution of oc and linear isoforms was achieved with 0.22M of sodium chloride in the same buffer. Finally, increasing the concentration to 0.55M led to the elution of the sc isoform. The binding of pDNA to DAPP-Sepharose varies in function of pH, and the stability of the protonated DAPP-DNA complex decreases with increasing salt concentration.

Purification of plasmid DNA from clarified and non-clarified Escherichia coli lysates by berenil pseudo-affinity chromatography.

In this study, berenil was tested as a ligand, specifically to purify plasmids of different sizes pVAX1-LacZ (6.05 Kbp) and pCAMBIA-1303 (12.361 Kbp) from clarified Escherichia coli alkaline lysates. For this purpose, chromatographic experiments were performed using Sepharose derivatized with berenil. The results showed that both pDNA molecules are completely purified using lower amounts of salt in the eluent than those previously reported for other pseudo-affinity and hydrophobic interaction chromatography based processes. Total retention of all lysate components was achieved with 1.3M ammonium sulphate in the eluent buffer and pDNA elution was obtained by decreasing the salt concentration to 0.55 M. All impurities were eluted after decreasing the concentration to 0M. The recovery yield for pCAMBIA-1303 (45%) was lower than that obtained for pVAX1-LacZ (85%), however the larger pDNA showed a higher purity level. Purification of pVAX1-LacZ was also performed using non-clarified E. coli process streams, replacing the clarification step with a second chromatographic run on the berenil-Sepharose. Using the same binding and elution conditions as before, a pure plasmid sample was obtained with a 33% yield and with all host impurity levels in accordance with the requirements established by the regulatory agencies. These results suggest that this chromatographic method is a promising alternative to purify pDNA for therapeutic use.

Specific berenil-DNA interactions: an approach for separation of plasmid isoforms by pseudo-affinity chromatography.

Small molecules, like some antibiotics and anticancer agents that bind DNA with high specificity, can represent a relevant alternative as ligands in affinity processes for plasmid DNA (pDNA) purification. In the current study, pDNA binding affinities of berberine, berenil, kanamycin, and neomycin were evaluated by a competitive displacement assay with ethidium bromide using a fluorimetric titration technique. The binding between pDNA and ethidium bromide was tested in different buffer conditions, varying the type and the salt concentration, and was performed in both the absence and presence of the studied compounds. The results showed that the minor groove binder berenil has the higher pDNA binding constant. Chromatographic experiments using a derivatized column with berenil as ligand showed a total retention of pDNA using 1.3M ammonium sulfate in eluent buffer. A selective separation of supercoiled and open circular isoforms was achieved by further decreasing the salt concentration to 0.6M and then to 0M. These results suggest a promising application of berenil as ligand for specific purification of pDNA supercoiled isoform by pseudo-affinity chromatography.