Johannes Keisers, Lorenzo Vito Dal Zovo, Norbert Kern, Luca Ciandrini
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Biologically relevant finite-size effects in a driven lattice gas with particle pausing and dynamical defects
In this article we present a comprehensive study of the totally asymmetric
simple exclusion process with pausing particles (pTASEP), a model initially
introduced to describe RNAP dynamics during transcription. We extend previous
mean-field approaches and demonstrate that the pTASEP is equivalent to the
exclusion process with dynamical defects (ddTASEP), thus broadening the scope
of our investigation to a larger class of problems related to transcription and
translation. We extend the mean-field theory to the open boundary case,
revealing the system's phase diagram and critical values of entry and exit
rates. However, we identify a significant discrepancy between theory and
simulations in a region of the parameter space, indicating severe finite-size
effects. To address this, we develop a single-cluster approximation that
captures the relationship between current and lattice size, providing a more
accurate representation of the system's dynamics. Finally, we extend our
approach to open boundary conditions, demonstrating its applicability in
different scenarios. Our findings underscore the importance of considering
finite-size effects, often overlooked in the literature, when modelling
biological processes such as transcription and translation.
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