Mechanistic modeling of in vitro transcription incorporating effects of magnesium pyrophosphate crystallization

Author(s)

Stover, Nathan Merica; Ganko, Krystian; Braatz, Richard D

Abstract

The in vitro transcription (IVT) reaction used in the production of messenger RNA vaccines and therapies remains poorly quantitatively understood. Mechanistic modeling of IVT could inform reaction design, scale‐up, and control. In this work, we develop a mechanistic model of IVT to include nucleation and growth of magnesium pyrophosphate crystals and subsequent agglomeration of crystals and DNA. To help generalize this model to different constructs, a novel quantitative description is included for the rate of transcription as a function of target sequence length, DNA concentration, and T7 RNA polymerase concentration. The model explains previously unexplained trends in IVT data and quantitatively predicts the effect of adding the pyrophosphatase enzyme to the reaction system. The model is validated on additional literature data showing an ability to predict transcription rates as a function of RNA sequence length.

Date issued

2024-09

URI

https://hdl.handle.net/1721.1/157673

Department

Massachusetts Institute of Technology. Department of Chemical Engineering

Journal

Biotechnology and Bioengineering

Publisher

Wiley

Citation

Stover, Nathan Merica, Ganko, Krystian and Braatz, Richard D. 2024. "Mechanistic modeling of in vitro transcription incorporating effects of magnesium pyrophosphate crystallization." Biotechnology and Bioengineering, 121 (9).

Version: Final published version