Publications
2021
Tomas Kostelec, Rok Sekirnik, Anže Martinčič Celjar, Kristina Šprinzar Nemec, Andreja Gramc Livk, Pete Gagnon, Aleš Štrancar
BioProcess International, June 2021
Abstract:
COVID-19 has focused a spotlight on the ability of mRNA technology to accelerate vaccine development and approval. That same technology can hasten development and approval of other therapeutic classes, including cancer immunotherapy, protein replacement, and gene therapy. Fulfilling those opportunities imposes significant challenges on process developers and manufacturers to improve existing processes. Scale-up to produce millions of doses (tens of kilograms) compounds those challenges. Furthermore, every step of the journey requires high-performance analytical methods, to ensure patient safety and maximize productivity.
Artaches A. Kazarian, Wesley Barnhart, Iain D.G. Campuzano, Jeremy Cabrera, Theodore Fitch, Jason Long, Kelvin Sham, Bin Wu, Justin K. Murray
Journal of Chromatography A,Volume 1634, 2020
Abstract:
The current study investigates a method for purification of the G-quadruplex secondary structure, naturally formed by a guanine-rich 21-mer oligonucleotide strand using a monolithic convective interaction media quaternary amine (CIM-QA) column under ion-exchange conditions. The monolithic support was initially evaluated on a preparative scale against a highly efficient TSKgel SuperQ-5PW ion-exchange support designed for oligonucleotide purification. The CIM analogue demonstrated clear advantages over the particle based support on the basis of rapid separation times, while also affording high purity of the G-quadruplex. Various parameters were investigated including the type of mobile phase anion, cation, pH and injection load to induce and control quadruplex formation, as well as enhance chromatographic separation and final purity. Potassium afforded the most prominent quadruplex formation, yet sodium allowed for the highest resolution and purity to be achieved with a 30 mg injection on an 8 ml CIM-QA monolithic column. This method was applied to purify in excess of 300 mg of the quadruplex, with excellent retention time precision of under 1% RSD. Native mass spectrometry was utilized to confirm the identity of the intact G-quadruplex under non denaturing conditions, while ion-pairing reversed-phase methods confirmed the presence of the single stranded oligonucleotide in high purity (92%) under denaturing conditions.
The key advantage of the purification method enables isolation of the G-quadruplex in its native state on a milli-gram scale, allowing structural characterization to further our knowledge of its role and function. The G-quadruplex can also be subsequently denaturated at elevated temperature causing single strand formation if additional reactions are to be pursued, such as annealing to form a duplex, and evaluation in in vitro or in vivo studies.
Thanaporn Liangsupree, Evgen Multia, Marja-Liisa Riekkola
Journal of Chromatography A, Volume 1636, 2021
Abstract
Extracellular vesicles (EVs) are heterogenous membrane-bound vesicles released from various origins. EVs play a crucial role in cellular communication and mediate several physiological and pathological processes, highlighting their potential therapeutic and diagnostic applications. Due to the rapid increase in interests and needs to elucidate EV properties and functions, numerous isolation and separation approaches for EVs have been developed to overcome limitations of conventional techniques, such as ultracentrifugation. This review focuses on recently emerging and modern EV isolation and separation tech- niques, including size-, charge-, and affinity-based techniques while excluding ultracentrifugation and precipitation-based techniques due to their multiple limitations. The advantages and drawbacks of each technique are discussed together with insights into their applications. Emerging approaches all share sim- ilar features in terms of being time-effective, easy-to-operate, and capable of providing EVs with suitable and desirable purity and integrity for applications of interest. Combination and hyphenation of techniques have been used for EV isolation and separation to yield EVs with the best quality. The most recent de- velopment using an automated on-line system including selective affinity-based trapping unit and asym- metrical flow field flow fractionation allows reliable isolation and fractionation of EV subpopulations from human plasma.
Attachments
2020
by Simon Staubach, Pete Gagnon, Katja Vrabec, Tjaša Lojpur, Sebastijan Peljhan, Bernd Giebel and Aleš Štrancar
BioProcess International, 2020
Abstract:
The traditional classification of extracellular vesicles (EVs) includes three types: exosomes, microvesicles, and apoptotic vesicles. Each type arises from a distinct origin and exhibits distinct characteristics. The problem is that their size ranges overlap and that the major surface proteins presented by exosomes also are present on the surfaces of microvesicles and apoptotic bodies. This makes it a challenge for process developers to identify the vesicle fraction that best serves a particular exosome therapy. Anion-exchange chromatography (AEC) can fractionate EVs into populations of different composition. This article highlights the complementarity of two analytical methods for characterizing distinctions among EV populations separated by AEC: imaging flow cytometry (IFCM) and size-exclusion chromatography.
E. Multia, T. Liangsupree, M. Jussila, J. Ruiz-Jimenez, M. Kemell and M. Riekkola
Analytical Chemistry, 2020
Abstract:
An automated on-line isolation and fractionation system including controlling software was developed for selected nanosized biomacromolecules from human plasma by on-line coupled immunoaffinity chromatography asymmetric flow field-flow fractionation (IAC-AsFlFFF). The on-line system was versatile, only different monoclonal antibodies, anti-apolipoprotein B-100, anti-CD9, or anti-CD61, were immobilized on monolithic disk columns for isolation of lipoproteins and extracellular vesicles (EVs). The platelet-derived CD61-positive EVs and CD9-positive EVs, isolated by IAC, were further fractionated by AsFlFFF to their sizebased subpopulations (e.g., exomeres and exosomes) for further analysis. Field-emission scanning electron microscopy elucidated the morphology of the subpopulations, and 20 free amino acids and glucose in EV subpopulations were identified and quantified in the ng/mL range using hydrophilic interaction liquid chromatography-tandem mass spectrometry (HILIC-MS/MS). The study revealed that there were significant differences between EV origin and size-based subpopulations. The on-line coupled IAC-AsFlFFF system was successfully programmed for reliable execution of 10 sequential isolation and fractionation cycles (37−80 min per cycle) with minimal operator involvement, minimal sample losses, and contamination. The relative standard deviations (RSD) between the cycles for human plasma samples were 0.84−6.6%.
Attachments
U. Černigoj, A. Štrancar
DNA Vaccines. Methods in Molecular Biology, vol 2197, pp 167-192
Abstract
Purification of high-quality plasmid DNA in large quantities is a crucial step in its production for therapeutic use and is usually conducted by different chromatographic techniques. Large-scale preparations require the optimization of yield and homogeneity, while maximizing removal of contaminants and preserving molecular integrity. The advantages of Convective Interaction Media® (CIM®) monolith stationary phases, including low backpressure, fast separation of macromolecules, and flow-rate-independent resolution qualified them to be used effectively in separation of plasmid DNA on laboratory as well as on large scale. A development and scale-up of plasmid DNA downstream process based on chromatographic monoliths is described and discussed below. Special emphasis is put on the introduction of process analytical technology principles and tools for optimization and control of a downstream process.
P. Gagnon, B. Goričar, Š. Peršič, U. Černigoj, A. Štrancar
Cell & Gene Therapy Insights 2020; 6(7), 1035–1046
Abstract:
One of the barriers to development of industrial purification platforms for large mRNA has been an inadequate selection of high-performing capture-purification tools. Hybridization-affinity uses a polythymidine (Oligo dT) ligand to base-pair with the polyadenine tail of mRNA. It can be used for capture but it cannot discriminate dsRNA (double-stranded) from ssRNA (single-stranded) and it supports only brief cleaning with 100 mM sodium hydroxide. Traditional anion exchangers elute only mRNA smaller than about 500 bases unless the columns are heated to 50–70°C. Hydrophobic interaction chromatography (HIC) and reverse phase chromatography (RPC) separate ssRNA from dsRNA and short transcripts, but their sensitivity to fouling by proteins and aggregates makes them better suited for polishing than for capture. Better capture options are needed to meet the needs of large clinical trials, scale-up, and manufacture of vaccines. Beyond that, a new spectrum of gene therapy treatments await. This article introduces two new capture options that both eliminate dsRNA, DNA, and proteins in a wash step, then provide high-resolution polishing of ssRNA in an elution gradient at ambient temperature. One represents a new class of anion exchangers. The other exploits hydrogen bonding. Both support prolonged exposure to 1 M sodium hydroxide. Easy transition to either HIC or RPC provides high-resolution orthogonal polishing.
M. Morani, T.Duc Mai, Z. Krupova, P. Defrenaix, E. Multia, M. Riekkola, M. Taverna
Analytica Chimica Acta 1128 (2020) 45-51
Abstract
This work reports on the development of the first capillary electrophoresis methodology for the elucidation of extracellular vesicles’ (EVs) electrokinetic distributions. The approach is based on capillary electrophoresis coupled with laser-induced fluorescent (LIF) detection for the identification and quantification of EVs after their isolation. Sensitive detection of these nanometric entities was possible thanks to an ‘inorganic-species-free’ background electrolyte. This electrolyte was made up of weakly charged molecules at very high concentrations to stabilize EVs, and an intra-membrane labelling approach was used to prevent EV morphology modification. The limit of detection for EVs achieved using the developed CE-LIF method method reached 8 × 10⁹ EVs/mL, whereas the calibration curve was acquired from 1.22 × 10¹⁰ to 1.20 × 10¹¹ EVs/mL. The CE-LIF approach was applied to provide the electrokinetic distributions of various EVs of animal and human origins, and visualize different EV subpopulations from our recently developed high-yield EV isolation method.
Pete Gagnon, Katja Vrabec, Tjaša Lojpur, and Aleš Štrancar
BioProcess International, 18 (4) April 2020
Abstract
Exosomes are a subject of rapidly growing therapeutic interest in the biopharmaceutical industry for two principal reasons. The first reason is that they are the primary communicators of instructions from source cells to target cells. Exosome surface features define their destination. They recognize complementary features on target cells, dock with them, and deliver their programmed instructions in the form of microRNA. The second reason is that exosomes are immunologically silent. As normal human cell products, and by contrast with gene therapy vectors such as virus particles, exosomes bypass the issue of triggering an immune response that might interfere with therapy.
Source cells include stem cells, which is why exosomes are of particular interest in the field of regenerative medicine. Recent research documenting the ability of exosomes to reverse the effects of severe strokes highlights their potential. It also underlines the need for scalable purification technology to advance these products through clinical trials and on to licensed manufacture. A platform approach was a major factor in the initial and continuing success of monoclonal antibodies. Exosomes likewise represent an extended family of individual products with similar properties. It stands to reason that a platform approach will prove equally valuable for exosomes. In this article we describe initial efforts toward that goal.
2019
Calef Sánchez-Trasviña, Marco Rito-Palomares, and José González-Valdez
Advances in Polymer Technology, Volume 2019, December 12 2019, 10 pages
Abstract
PEGylated or polyethylene glycol-modified proteins have been used as therapeutic agents in different diseases. However, the major drawback in their procurement is the purification process to separate unreacted proteins and the PEGylated species. Several efforts have been done to separate PEGylation reactions by chromatography using different stationary phases and modified supports. In this context, this study presents the use of chromatographic monoliths modified with polyethylene glycol (PEG) to separate PEGylated Ribonuclease A (RNase A). To do this, Convective Interaction Media (CIM) Ethylenediamine (EDA) monolithic disks were PEGylated using three PEG molecular weights (1, 10, and 20 kDa). The PEGylated monoliths were used to separate PEGylated RNase A modified, as well, with three PEG molecular weights (5, 20, and 40 kDa) by hydrophobic interaction chromatography. Performance results showed that Bovine Serum Albumin (BSA) can bind to PEGylated monoliths and the amount of bound BSA increases when ammonium sulfate concentration and flow rate increase. Furthermore, when PEGylated RNase A was loaded into the PEGylated monoliths, PEG-PEG interactions predominated in the separation of the different PEGylated species (i.e., mono and di-PEGylated). It was also observed that the molecular weight of grafted PEG chains to the monolith impacts strongly in the operation resolution. Interestingly, it was possible to separate, for the first time, isomers of 40 kDa PEGylated RNase A by hydrophobic interaction chromatography. This technology, based on PEGylated monoliths, represents a new methodology to efficiently separate proteins and PEGylated proteins. Besides, it could be used to separate other PEGylated molecules of biopharmaceutical or biotechnological interest.
Evgen Multia, Crystal Jing Ying Tear, Mari Palviainen, Pia Siljander, Marja-Liisa Riekkola
Analytica Chimica Acta (2019).
Published online 2019 Sep 11.
A new, fast and selective immunoaffinity chromatographic method including a methacrylate-based convective interaction media (CIM®) disk monolithic column, immobilized with anti-human CD61 antibody, was developed for the isolation of CD61-containing platelet-derived extracellular vesicles (EVs) from plasma. The isolated EVs were detected and size characterized by asymmetrical flow field-flow fractionation (AsFlFFF) with multi-angle light-scattering (MALS) and dynamic light-scattering (DLS) detection, and further confirmed by nanoparticle tracking analysis (NTA) and transmission electron microscopy (TEM). The isolation procedure took only 19 min and the time can be even further decreased by increasing the flow rate. The same immunoaffinity chromatographic procedure, following AsFlFFF allowed also the isolation and characterization of platelet-derived EVs from plasma in under 60 min. Since it is possible to regenerate the anti-CD61 disk for multiple uses, the methodology developed in this study provides a viable substitution and addition to the conventional EV isolation procedures.
Keywords: Immunoaffinity chromatography, Isolation, Monolithic disk column, Extracellular vesicles, Platelet-derived vesicles, CD61
This discussion introduces new analytical approaches that enable in-line chromatographic detection of exosomes. One approach can discriminate extracellular vesicles from nonvesicle contaminants, and one potentially can discriminate exosomes from other vesicles. Examples illustrate how they enable development of more effective and better documented purification methods. The special qualifications of monolithic chromatography media for exosome purification are discussed. New process tools designed to accommodate some of the special challenges of exosome purification are introduced.
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Attachments
2018
Miladys Limonta, Lourdes Zumalacarregui, Urska Vidic, Nika Lendero Krajnc
The main component of the Center for Genetic Engineering and Biotechnology (CIGB) candidate vaccine against Hepatitis C virus (HCV) is the pIDKE2 plasmid. The current designed downstream process for the production of pIDKE2 fulfils all regulatory requirements and renders the required quantities of pharamceutical-grade plasmid DNA (pDNA)with 95% purity. The advantages of this procedure include high plasmid purity and the elimination of undesirable additives. such as toxic organic extractants and animal-derived enzymes. However, yields and consequently the productivity of the process are low. Previous work demonstrated that the most critical step of the process is the reverse phase chromatography, where conventional porous particle resins are used. Therefore, to increase the process productivity alternative technologies such as membranes and chromatographic monoliths were tested as alternative options for this critical step. Here, a comparison between the behaviours of CIM® C4-HLD and Sartobind phenyl matrices was performed.
Attachments
2015
A.M. Almeida, J.A. Queiroz, F. Sousa, A. Sousa
Journal of Chromatography B, 978–979 (2015) 145–150
The progress of DNA vaccines is dependent on the development of suitable chromatographic procedures to successfully purify genetic vectors, such as plasmid DNA. Human Papillomavirus is associated with the development of tumours due to the oncogenic power of E6 and E7 proteins, produced by this virus. The supercoiled HPV-16 E6/E7 plasmid-based vaccine was recently purified with the arginine monolith, with 100% of purity, but only 39% of recovery was achieved. Therefore, the present study describes the application of experimental design tools, a newly explored methodology in preparative chromatography, in order to improve the supercoiled plasmid DNA recovery with the arginine monolith, maintaining the high purity degree. In addition, the importance and influence of pH in the pDNA retention to the arginine ligand was also demonstrated. The Composite Central Face design was validated and the recovery of the target molecule was successfully improved from 39% to 83.5%, with an outstanding increase of more than double, while maintaining 100% of purity.
Zunyang Ke, Yu Wang and Zhongming Li
Anion-exchange chromatography is a key capture step in downstream processing plasmid DNA (pDNA). Separation of pDNA using traditional particle-based anion-exchange supports is usually slow and has a low capacity for pDNA due to steric exclusion effects. Due to convective mass transfer properties, and large flow-through channels for binding large biomolecules, monoliths have been shown to provide a fast and efficient alternative for pDNA purification. This study describes the use of monoliths for purification of a therapeutic pDNA vaccine against multidrug resistant tuberculosis (MDR TB).
Attachments
Urh Černigoj, Urška Martinuč, Sara Cardoso, Rok Sekirnik, Nika Lendero Krajnc, Aleš Štrancar
Sample displacement chromatography (SDC) is a chromatographic technique that utilises different rela-tive binding affinities of components in a sample mixture and has been widely studied in the context ofpeptide and protein purification. Here, we report a use of SDC to separate plasmid DNA (pDNA) isoformsunder overloading conditions, where supercoiled (sc) isoform acts as a displacer of open circular (oc) orlinear isoform. Since displacement is more efficient when mass transfer between stationary and mobilechromatographic phases is not limited by diffusion, we investigated convective interaction media (CIM)monoliths as stationary phases for pDNA isoform separation. CIM monoliths with different hydrophobic-ities and thus different binding affinities for pDNA (CIM C4 HLD, CIM-histamine and CIM-pyridine) weretested under hydrophobic interaction chromatography (HIC) conditions. SD efficiency for pDNA isoformseparation was shown to be dependent on column selectivity for individual isoform, column efficiencyand on ammonium sulfate (AS) concentration in loading buffer (binding strength). SD and negative modeelution often operate in parallel, therefore negative mode elution additionally influences the efficiencyof the overall purification process. Optimisation of chromatographic conditions achieved 98% sc pDNAhomogeneity and a dynamic binding capacity of over 1 mg/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, whichis compatible with continuous, multicolumn chromatography systems, and could therefore be used toincrease productivity of pDNA production in the future.
Attachments
2014
F. W. Krainer, R. Pletzenauer, L. Rossetti, C. Herwig, A. Glieder, O. Spadiut
Protein Expression and Purification 95 (2014) 104–112
The plant enzyme horseradish peroxidase (HRP) is used in several important industrial and medical applications, of which especially biosensors and diagnostic kits describe an emerging field. Although there is an increasing demand for high amounts of pure enzyme preparations, HRP is still isolated from the plant as a mixture of different isoenzymes with different biochemical properties. Based on a recent next generation sequencing approach of the horseradish transcriptome, we produced 19 individual HRP isoenzymes recombinantly in the yeast Pichia pastoris. After optimizing a previously reported 2-step purification strategy for the recombinant isoenzyme HRP C1A by substituting an unfavorable size exclusion chromatography step with an anion exchange step using a monolithic column, we purified the 19 HRP isoenzymes with varying success. Subsequent basic biochemical characterization revealed differences in catalytic activity, substrate specificity and thermal stability of the purified HRP preparations. The preparations of the isoenzymes HRP A2A and HRP A2B were found to be highly interesting candidates for future applications in diagnostic kits with increased sensitivity.
F. W. Krainer, R. Pletzenauer, L. Rossetti, C. Herwig, A. Glieder, O. Spadiut
Protein Expression and Purification 95 (2014) 104–112
The plant enzyme horseradish peroxidase (HRP) is used in several important industrial and medical applications, of which especially biosensors and diagnostic kits describe an emerging field. Although there is an increasing demand for high amounts of pure enzyme preparations, HRP is still isolated from the plant as a mixture of different isoenzymes with different biochemical properties. Based on a recent next generation sequencing approach of the horseradish transcriptome, we produced 19 individual HRP isoenzymes recombinantly in the yeast Pichia pastoris. After optimizing a previously reported 2-step purification strategy for the recombinant isoenzyme HRP C1A by substituting an unfavorable size exclusion chromatography step with an anion exchange step using a monolithic column, we purified the 19 HRP isoenzymes with varying success. Subsequent basic biochemical characterization revealed differences in catalytic activity, substrate specificity and thermal stability of the purified HRP preparations. The preparations of the isoenzymes HRP A2A and HRP A2B were found to be highly interesting candidates for future applications in diagnostic kits with increased sensitivity.
2013
M. Bartolini, I. W. Wainer, C. Bertucci, V. Andrisano
Journal of Pharmaceutical and Biomedical Analysis 73 (2013) 77-81
Adenosine nucleotides are involved as substrates or co-factors in several biochemical reactions, catalyzed by enzymes, which modulate energy production, signal transduction and cell proliferation. We here report the development and optimization of an ion exchange liquid chromatography (LC) method for the determination of ATP, ADP and AMP. This method is specifically aimed at the determination of the ATP-ase activity of human heat shock protein 90 (Hsp90), a molecular chaperone that has emerged as target enzyme in cancer therapy. Separation of the three nucleotides was achieved in a 15-min run by using a disk shaped monolithic ethylene diamine stationary phase of small dimensions (2 mm × 6 mm i.d.), under a three-solvent gradient elution mode and UV detection at 256 nm. The described direct LC method resulted highly specific as a consequence of the baseline separation of the three adenosine nucleotides and could be applied to the determination of the enzymatic activity of ADP/ATP generating or consuming enzymes (such as kinases). Furthermore, comparison of the LOD and LOQ values of the LC method with those obtained with the malachite green assay, which is one of the most used indirect screening methodologies for ATP-ase activity, showed that the LC method has a similar range of application without presenting the drawbacks related to contamination by inorganic phosphate ions and glycerol, which are present in Hsp90 commercial samples.
F. Ibrahim, C. Andre, R. Aljhni, T. Gharbi, Y. C. Guillaume
Journal of Molecular Catalysis B: Enzymatic 94 (2013) 136-140
Acetylcholinesterase (AChE) is a serine protease that hydrolyzes the neurotransmitter acetylcholine. Here, the effects of hydroxyl radical (OH•) and nitric oxide (NO) on AChE activity were studied using a biochromatographic process. The enzyme was immobilized on an ethylenediamine (EDA) monolithic convective interaction media (CIM) disk. The AChE enzymatic mechanism was demonstrated from the chromatographic peak shape. A decrease in AChE activity was observed for each concentration of NO, while OH• dot radical formation led to an increase in the rate of enzymatic catalysis. Michaelis–Menten and Lineweaver–Burk plots were obtained in the presence or absence of the free radicals and their effects on Km and Vmax were evaluated. Our results indicated classical deactivation/activation kinetics without significant influence on the rate of substrate binding. The variation in transition state energies (ΔΔGES) induced by the free radicals indicated that a conformational change was occurring in the active site, while changes in the binding site were negligible. These results clearly demonstrate the direct role of OH• dot and NO on AChE activity and confirm the role they may play in Alzheimer's disease.