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2021

The recently demonstrated efficacy of mRNA-based Covid-19 vaccines has shown promise of this therapeutic format, but also highlighted the need for higher efficiency of mRNA production to meet enormous needs for global vaccine supply.

Typical mRNA production process involves three key steps: 1) plasmid DNA (pDNA) production in supercoiled (sc) isoform, linearization and purification, 2) in-vitro transcription (IVT) reaction and 3) mRNA purification.

Here we present a chromatographic toolbox and mRNA IVT synthesis for integrated mRNA production from pDNA to mRNA purification, including in-process analytics. This high yield process reduces the overall number of purification steps required, improves recoveries, results in extra low protein impurity and allows for very efficient dsRNA removal.

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The IVT reaction is one of the most expensive steps in mRNA production process and its optimization to reach high mRNA yield is of key importance Standard mRNA quantification techniques like absorbance and fluorescence based assays are time consuming and cannot be performed at line as the IVT reaction progresses In addition, other reaction components like nucleotides and pDNA interfere in the analytical results and reduce the method’s accuracy A new approach shown here uses CIMac PrimaS™ analytical HPLC column to separate and quantify several key IVT components with a very short run time, enabling fast “at line” tracking

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Optimizing processing steps in sc pDNA isolation is critical for obtaining good process yields as well as high product purity. HPLC with convective chromatography media (e.g. monolith) offers a rapid analytical method to characterize complex biomolecular mixtures and gives immediate feedback during process development. E coli lysis represents such a challenging step, where multiple critical quality attributes need to be identified and critical processing parameters optimized. This approach leads to better yields and product purity, allowing for simplified downstream steps. A new PATfix analytical HPLC platform presented here uses CIMac pDNA column, to separate and characterize plasmid from impurities, allowing for easy optimization of key parameters such as RNA removal.

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In mRNA production process, downstream purification of in vitro transcription (IVT) reaction often relies on precipitation methods which cannot provide resolution, recovery, or reproducibility to consistently produce a safe and effective product with good process economics. mRNA is a large biomolecule (mass of 1000 nt is ~ 150 kDa and >100 nm in diameter) for which porous particle chromatography lacks the ability to support high capacity and throughput to achieve good process economics. Convective flow chromatography media (e.g. monoliths) is an optimal platform for purification. A fully scalable chromatographic purification process is presented for a posttranscriptionally capped in vitro transcribedmRNA.

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2020

HPLC with convective chromatography media (e.g.monolith) offers a rapid analytical method to characterise complex mixtures. Transcription reaction used for production of mRNA represents such a mixture, with components varying in size, chemical and physical properties. A new analytical HPLC approach (PATfix) presented here uses CIMacPrimaS to separate IVT components such as triphosphate-nucleotides (NTPs), enzymes, DNA template and RNA in a very short gradient.

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Linearised pDNA is currently the starting point of In-Vitro-Transcription processes to synthesize mRNA. Large scale purification protocols for manufacturing of pDNA used for Gene Therapy applications typically include two chromatography steps. The first step captures both linear, open circular and supercoiled pDNA species. The polishing step enriches supercoiled pDNA, while discarding other isoforms. We describe a single-step-capture strategy to maximize the recovery of pDNA for further linearization.

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The increasing demand for messenger RNA (mRNA) as a therapeutic product requires larger production scales and more efficient extraction techniques. In this poster, fast and efficient way to purify poly-adenylated mRNA using affinity chromatography on CIMmultus™ Oligo dT column is presented.

The poly-adenylated tail of mRNA interacts with covalently bound oligo dT ligands in high-salt loading conditions, where electrostatic repulsion between negatively charged backbones of both, mRNA and oligo dT, are reduced and H-bonding in T-A base pair is emphasized. High salt concentration additionally screens out attractive electrostatic interactions between mRNA and other components in the process sample, thus facilitating aggregate reduction in purified product.

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2004

The availability of sufficient quantities of quality DNA is always a crucial point in DNA based methods, i.e. for PCR, DNA sequencing, Southern blotting, and microarrays [1]. The same is true for the PCR-based methods for detection of genetically modified food [2]. During the production chain foods passes several physical, biological, and chemical processes, which all negatively influences on the quantity of available DNA. The phenomenon is especially expressive when high temperature treatment is performed at low pH [3]. The existing methods for DNA isolation from food cannot always fulfill the expectations of quantity and quality of isolated DNA. Furthermore they usually include 100 mg of sample and are difficult to scale-up [4]. Four major chromatographic modes are used for the separation of DNA: size-exclusion, anion-exchange, ion-pair reversephased, and slalom chromatography. Of these, anion-exchange chromatography combined with micropellicular packing is described as the most prominent technique so far [1].
Anion-exchange CIM® (Convective Interaction Media) monolithic columns allow fast and flow unaffected separation of several biomolecules, including nucleic acids [5].

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2003

Traces of DNA in RNA samples represent impurities that could affect results of mRNA quantification and cDNA synthesis. In most cases, the DNA impurities in RNA samples are removed using enzyme deoxyribonuclease (DNase), which specifically breaks down DNA. In order to avoid the addition of DNase into the analyzing sample, the use of immobilized DNase on solid support is recommended. Because of the DNA size, very few supports available on the market enable efficient interaction between immobilized enzyme and DNA.

In recent years a new group of supports named monoliths was introduced. Because of enhanced exchange between mobile and stationary phase separation and bioconversion processes are significantly accelerated. Therefore also the efficiency of DNA removal using immobilised enzyme might be competitive to the degradation with free enzyme.

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The availability of sufficient quantities of quality DNA is always a crucial point in DNA based methods, i.e. for PCR, DNA sequencing, Southern blotting, and microarrays [1]. The same is true for the PCR-based methods for detection of genetically modified food [2]. During the production chain foods passes several physical, biological, and chemical processes, which all negatively influences on the quantity of available DNA. The phenomenon is especially expressive when high temperature treatment is performed at low pH [3].

The existing methods for DNA isolation from food cannot always fulfill the expectations of quantity and quality of isolated DNA. Furthermore they usually include 100 mg of sample and are difficult to scale-up [4]. Four major chromatographic modes are used for the separation of DNA: size-exclusion, anion-exchange, ion-pair reversephased, and slalom chromatography. Of these, anion-exchange chromatography combined with micropellicular packing is described as the most prominent technique so far [1].

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The availability of sufficient quantities of quality DNA is always a crucial point in DNA-based methods, i.e. for PCR, DNA sequencing, Southern blotting, and microarrays [1]. The same is true for the PCR-based methods of GMO detection in food [2]. During the production chain foods passes several physical, biological, and chemical processes, which all negatively influences on the quantity of available DNA. The phenomenon is especially expressive when high temperature treatment is performed at low pH [3].

The existing methods, for DNA isolation from food, cannot always fulfill the expectations of quantity and quality of isolated DNA. Furthermore they usually include 100 mg of sample and are difficult to scale-up [4]. Four major chromatographic modes are used for the separation of DNA: size-exclusion, anionexchange, ion-pair reverse-phased, and slalom chromatography. Of these, anionexchange chromatography combined with micropellicular packing is described as the most prominent technique so far [1].

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2000

Strains of the anaerobic bacterial genus are thought to play an important role in fiber degradation. sp. Mz5 was previously isolated from the rumen of a black and white Friesian cow and its xylanolytic activity was proved to be at least 1,65 times higher than the activities of all of the compared well known xylan-degrading rumen bacterial species and strains (1). High xylanolytic activity was the reason for partial isolation of its xylanases in order to study their special characteristics and possible biotechnological applications later.

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1999

Synthetic oligonucleotides play an important role as novel therapeutic agents.

One of the most important, but also very time-consuming steps in synthetic oligonucleotides production is their purification. Due to their high-resolution power, reversed-phase and ion-exchange chromatography are the most widely used techniques for these purposes. For the reversed-phase separations oligonucleotides need to be kept as 5'-O-dimethoxytrityl derivatives until the purification process is completed and only then the detritylation takes place. Both these steps lower the yield of the production process. In the contrary, ion-exchange chromatography offers applications to deprotected oligonucleotides directly and that is the reason why this chromatography mode is more preferred.

Convective Interaction Media (CIM) are newly developed polymerbased monolithic supports allowing high resolution separations which can be carried out within seconds in the case of analytical units - disks. This is due to predominantly convective mass transport of biomolecules between the mobile and stationary phase and very low dead volumes. Additionally, the dynamic binding capacity is not affected by high flow rates.

In this work weak (DEAE) anion-exchange CIM supports have been successfully applied for the analysis and purification of synthetic oligonucleotides.

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CIM® supports are novel monolithic chromatographic supports. In contrast to conventional particle based chromatographic supports they consist of a single porous polymer. The pores form a highly interconnected network, which enables the flow of the mobile phase through the monolith. Molecules to be separated are transported to the surface by the convection. Since the diffusion is not a bottleneck any more, also the resolution and the dynamic capacity of the monolith are flow independent and an average analysis time is typically below one minute. Furthermore, CIM® columns were successfully applied for the purification of proteins directly from the fermentation broth.

Manganese peroxidases (MnP) and lignin peroxidases (LiP) are a family of glicosilated hemo-proteins, which are excreted into the growth medium during the idiophasic growth of the white rot fungus Phanerochaete chrysosporium. They are both involved in the lignin degradation. For their analysis and separation from the growth medium, HPLC is commonly applied. Besides the separation by Na-acetate concentration gradient (2), also the chromatofocusing can be used (3). A fast method for LiP isoenzyme separation from the growth medium of P. chrysosporium using CIM™ QA disk monolithic columns has been recently developed (1). A modified method was tested on the growth medium containing MnP isoenzymes.

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The aim of our work was to study the direct monitoring and purification of proteins from the fermentation broth using ion-exchange CIM® supports. Therefore, we studied the possibility of monitoring and purifying lignin peroxidase extracelular protein isoforms produced by the fungus Phanerochaete chrysosporium. These isoenzymes which also differ in their catalytic properties are able to partially depolymerize lignin and to oxidise several xenobiotics.

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The white rot fungus Phanerochaete chrysosporium under nitrogen or carbon limitation produces extracellular lignin peroxidases (LiP). They are able to partially depolymerize lignin and to oxidize several xenobiotics (DDT, PCB, PAH, etc.). By HPLC separation and isoelectric focusing multiple molecular forms of LiP have been isolated from the culture filtrate. For the isolation of LiP from the growth medium, mostly the HPLC technique with ion exchange Mono-Q or DEAE columns is used. The medium should be dialyzed before separation and usually also concentrated. Medium freezing is used to remove mucilaginous polysaccharides which disturb separation. The whole procedure is time consuming and information about isoenzyme content and their relative amounts in the growth medium is delayed for at least 1 day. HPLC separation itself lasts nearly an hour. For the separation of LiP isoenzymes from the culture filtrate, we used the monolithic stationary phase with weak (DEAE-diethylamine) and strong (QA-quaternary amine) ion exchange groups commercially available under trademark CIM (Convective Interaction Media). CIM supports are glycidyl methacrylate based monolithic porous polymer supports. As such they differ from conventional particle shaped chromatographic supports. The liquid is forced to flow through the support channels. Molecules to be separated are transported mainly by convection resulting in travelling times shorter for at least an order of magnitude. As a consequence the resolution as well as the binding capacity remain unaffected with the flow rate and a shorter analysis time can be achieved. This effect is even more pronounced in the case of large molecules such as proteins, which have a low diffusion coefficient. As such, CIM units can be advantageous also for lignin peroxidase isoenzymes separation and purification.

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1998

White rot fungus Phanerochaete chrysosporium produces under nitrogen limitation extracellular lignin peroxidases (LiP). They are able to partially depolymerize lignin and to oxidise several xenobiotics (DDT, PCB, PAH,…) and synthetic dyes. Trough HPLC separation and isoelectric focusing multiple molecular forms of LiP have been determined and isolated from the culture filtrate. Depending on growth conditions, separation technique, strain employed and culture age 2-15 different LiP izoenzymes were observed in culture media of Phanerochaete chrysosporium. They are structurally similar but differ in stability, quantity and in catalytic properties. For the isolation of LiP from growth medium, mostly the procedure employing HPLC ionexchange columns as shown on Scheme 1 is used. For the separation of LiP isoenzymes from the culture filtrate, we used CIM (Convective Interaction Media) units. Their advantage is very fast separation of macromolecules due to their particular threedimensional structure. In contrast to particle supports containing closed pores, CIM units consist of monolith porous material containing flow through pores. Therefore, macromolecules to be separated are transported to the active site by convection rather than by diffusion. As a consequence, the separation resolution and dynamic binding capacity are flow independent. As such CIM units can be advantageous also for lignin peroxidase isoenzymes separation and purification.

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