Journal
PHYSICAL CHEMISTRY CHEMICAL PHYSICS
Volume 23, Issue 38, Pages 21399-21406Publisher
ROYAL SOC CHEMISTRY
DOI: 10.1039/d1cp03665c
Keywords
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Funding
- Welch Foundation [C-1559]
- NSF [PHY-2019745, MCB-1941106]
- Center for Theoretical Biological Physics - NSF [PHY-2019745]
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Transcription, a fundamental biological process, has been found to exhibit dynamic behavior of alternating between productive and inactive phases, known as transcriptional bursting. Despite significant attention from researchers, the microscopic origin and biological functions of transcriptional bursting remain unclear.
In recent years, it has been experimentally established that transcription, a fundamental biological process that involves the synthesis of messenger RNA molecules from DNA templates, does not proceed continuously as was expected. Rather, it exhibits a distinct dynamic behavior of alternating between productive phases when RNA molecules are actively synthesized and inactive phases when there is no RNA production at all. The bimodal transcriptional dynamics is now confirmed to be present in most living systems. This phenomenon is known as transcriptional bursting and it attracts significant amounts of attention from researchers in different fields. However, despite multiple experimental and theoretical investigations, the microscopic origin and biological functions of the transcriptional bursting remain unclear. Here we discuss the recent developments in uncovering the underlying molecular mechanisms of transcriptional bursting and our current understanding of them. Our analysis presents a physicochemical view of the processes that govern transcriptional bursting in living cells.
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