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Auteurs principaux: Stover, Nathan M., De Bock, Marieke, Chen, Julie, Rosenfeld, Jacob, Royo, Maria del Carme Pons, Myerson, Allan S., Braatz, Richard D.
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2504.07212
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author Stover, Nathan M.
De Bock, Marieke
Chen, Julie
Rosenfeld, Jacob
Royo, Maria del Carme Pons
Myerson, Allan S.
Braatz, Richard D.
author_facet Stover, Nathan M.
De Bock, Marieke
Chen, Julie
Rosenfeld, Jacob
Royo, Maria del Carme Pons
Myerson, Allan S.
Braatz, Richard D.
contents The in vitro transcription reaction (IVT) is of growing importance for the manufacture of RNA vaccines and therapeutics. While the kinetics of the microscopic steps of this reaction (promoter binding, initiation, and elongation) are well studied, the rate law of overall RNA synthesis that emerges from this system is unclear. In this work, we show that a model that incorporates both initiation and elongation steps is essential for describing trends in IVT kinetics in conditions relevant to RNA manufacturing. In contrast to previous reports, we find that the IVT reaction can be either initiation- or elongation-limited depending on solution conditions. This initiation-elongation model is also essential for describing the effect of salts, which disrupt polymerase-promoter binding, on transcription rates. Polymerase-polymerase interactions during elongation are incorporated into our modeling framework and found to have nonzero but unidentifiable effects on macroscopic transcription rates. Finally, we develop an extension of our modeling approach to quantitatively describe and experimentally evaluate RNA- and DNA-templated mechanisms for the formation of double-stranded RNA (dsRNA) impurities. We show experimental results that indicate that an RNA-templated mechanism is not appropriate for describing macroscopic dsRNA formation in the context of RNA manufacturing.
format Preprint
id arxiv_https___arxiv_org_abs_2504_07212
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Emergent kinetics of in vitro transcription from interactions of T7 RNA polymerase and DNA
Stover, Nathan M.
De Bock, Marieke
Chen, Julie
Rosenfeld, Jacob
Royo, Maria del Carme Pons
Myerson, Allan S.
Braatz, Richard D.
Molecular Networks
The in vitro transcription reaction (IVT) is of growing importance for the manufacture of RNA vaccines and therapeutics. While the kinetics of the microscopic steps of this reaction (promoter binding, initiation, and elongation) are well studied, the rate law of overall RNA synthesis that emerges from this system is unclear. In this work, we show that a model that incorporates both initiation and elongation steps is essential for describing trends in IVT kinetics in conditions relevant to RNA manufacturing. In contrast to previous reports, we find that the IVT reaction can be either initiation- or elongation-limited depending on solution conditions. This initiation-elongation model is also essential for describing the effect of salts, which disrupt polymerase-promoter binding, on transcription rates. Polymerase-polymerase interactions during elongation are incorporated into our modeling framework and found to have nonzero but unidentifiable effects on macroscopic transcription rates. Finally, we develop an extension of our modeling approach to quantitatively describe and experimentally evaluate RNA- and DNA-templated mechanisms for the formation of double-stranded RNA (dsRNA) impurities. We show experimental results that indicate that an RNA-templated mechanism is not appropriate for describing macroscopic dsRNA formation in the context of RNA manufacturing.
title Emergent kinetics of in vitro transcription from interactions of T7 RNA polymerase and DNA
topic Molecular Networks
url https://arxiv.org/abs/2504.07212