Increasing yield of in vitro transcription reaction with at‐line high pressure liquid chromatography monitoring

Self Cite

Messenger RNA (mRNA) has emerged as a modality with immense therapeutic potential. Recent innovations in production process of mRNA call for procedures to isolate pure mRNA drug substance (DS) with high yield, high capacity, scalability, and compatibility with GMP production systems. Novel RNA modalities, such as circular RNA (circRNA), have further driven the need for non‐affinity capture possibilities which are already widely used in the biopharmaceutical industry, for example, in monoclonal antibody processing. The principle that multimodal ion exchange/hydrogen bonding chromatography can be used to separate mRNA from in vitro transcription components has recently been demonstrated. Here, we apply and refine this approach to be suitable for scalable purification of multiple mRNA constructs with sufficient yields, purity, and stability, for use in mRNA production process. Binding capacity of the PrimaS‐modified monolithic chromatographic column for mRNA enabled up to 7 mg/mL product isolation in a single chromatographic run, with 98% recovery and room temperature stability of the eGFP mRNA demonstrated for up to 28 days. This approach is independent of construct size or the presence of polyadenylic acid tail and is applicable for capture of a wide variety of RNAs, including mRNA, self‐amplifying RNA, circRNA, and with optimization also smaller RNAs such as transfer RNA and others.

Section: Purification Developmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Scalable multimodal weak anion exchange chromatographic purification for stable mRNA drug substance

Megušar,

Miklavčič,

Korenč

et al. 2023

Self Cite

“…Prior to analysis, the samples were diluted with double deionised water to achieve the loading of 55 ng of nucleic acids per well. AGE was conducted with 1% agarose gels at 100 V for 60 min or 100 V for 120 min and stained with Sybr Gold from Thermo Fisher Scientific (Waltham, MA, USA) [27].…”

Section: Agarose Gel Electrophoresismentioning

confidence: 99%

Effect of plasmid DNA isoforms on preparative anion exchange chromatography

Kralj,

Kodermac,

Bergoč

et al. 2023

Self Cite

Increased need for plasmid DNA (pDNA) with sizes above 10 kbp (large pDNA) in gene therapy and vaccination brings the need for its large‐scale production with high purity. Chromatographic purification of large pDNA is often challenging due to low process yields and column clogging, especially using anion‐exchanging columns. The goal of our investigation was to evaluate the mass balance and pDNA isoform composition at column outlet for plasmids of different sizes in combination with weak anion exchange (AEX) monolith columns of varying channel size (2, 3 and 6 µm channel size). We have proven that open circular pDNA (OC pDNA) isoform is an important driver of reduced chromatographic performance in AEX chromatography. The main reason for the behaviour is the entrapment of OC pDNA in chromatographic supports with smaller channel sizes. Entrapment of individual isoforms was characterised for porous beads and convective monolithic columns. Convective entrapment of OC pDNA isoform was confirmed on both types of stationary phases. Porous beads in addition showed a reduced recovery of supercoiled pDNA (on an 11.6 kbp plasmid) caused by diffusional entrapment within the porous structure. Use of convective AEX monoliths or membranes with channel diameter >3.5 µm has been shown to increase yields and prevent irreversible pressure build‐up and column clogging during purification of plasmids at least up to 16 kbp in size.

“…Purity and/or isoform composition requirements vary depending on the application of the pDNA. High purity of SC pDNA isoform is required in gene therapy platforms, whereas isoform composition is usually not defined for the preparation of IVT mRNA production, where linearization step follows the pDNA purification [5][6][7]. In any case, pDNA must be purified from all other contaminants present in the E. coli lysate, such as cell debris, RNA, residual proteins and genomic DNA.…”

Section: Introductionmentioning

confidence: 99%

Analytical separation of plasmid DNA isoforms using anion exchanging chromatographic monoliths with 6 µm channels

Pavlin,

Černigoj,

Bavčar

et al. 2023

High‐performance liquid chromatography (HPLC)‐based analytical assays are used to effectively monitor purity and quantity of plasmid DNA (pDNA) throughout the purification process. However, the phenomenon of physical entrapment of open circular (OC) isoforms pDNA inside narrow channels of chromatographic support decreases its accuracy and precision and the effect increases with pDNA size. The purpose of the study was to develop a chromatographic method for accurate analytical separation between isoforms of <16 kbp pDNA using weak anion exchanging monolithic column with large (6 µm) convective channels. Purified samples of 4.7 and 15.4 kbp large pDNA with known isoform composition were prepared and their isoforms separated in ascending salt gradient. Both OC and supercoiled (SC) isoforms were baseline separated at a flow rate below 0.5 mL min−1 in a guanidinium chloride (GdnCl) gradient with a ≥95% OC pDNA elution recovery. However, these chromatographic conditions increased 2 times the peak width for linear (LIN) pDNA isoform compared to the results using monoliths with 1.4 µm channel size. If other chaotropic agents, such as urea or thiocyanate (SCN), were added to Gdn ions, the elution volume for LIN isoform decreased. Optimization of combined GdnCl/GdnSCN gradient for pDNA elution resulted in a simple and robust chromatographic method, where OC–LIN and LIN–SC pDNA (up to 15 kbp size) were separated with resolution above 1.0 and above 2.0, respectively. The accessibility and general acceptance of anion exchange chromatography for pDNA analytics give the newly developed method a great potential for in‐process control monitoring of pDNA production processes.