Increasing yield of in vitro transcription reaction with at-line HPLC monitoring.

ABSTRACT

The COVID-19 pandemic triggered an unprecedented rate of development of mRNA vaccines, which are produced by in vitro transcription reactions. The latter has been the focus of intense development to increase productivity and decrease cost. Optimization of IVT depends on understanding of the impact of individual reagents on the kinetics of mRNA production and the consumption of building blocks, which is hampered by slow, low-throughput, end-point analytics. We implemented a workflow based on rapid at-line HPLC monitoring of consumption of NTPs with concomitant production of mRNA, with a sub-3 min read-out, allowing for adjustment of IVT reaction parameters with minimal lag. IVT was converted to fed-batch resulting in doubling the reaction yield compared to batch IVT protocol, reaching 10 mg/mL for multiple constructs. When coupled with exonuclease digestion, HPLC analytics for quantification of mRNA was extended to monitoring capping efficiency of produced mRNA. When HPLC monitoring was applied to production of an ARCA-capped mRNA construct, which requires an approximate 41 ARCAGTP ratio, the optimized fed-batch approach achieved productivity of 9 mg/mL with 79% capping. The study provides a methodological platform for optimization of factors influencing IVT reactions, converting the reaction from batch to fed-batch mode, determining reaction kinetics, which are critical for optimization of continuous addition of reagents, thereby paving the way towards continuous manufacturing of mRNA. This article is protected by copyright. All rights reserved.