Please use this identifier to cite or link to this item: https://biore.bio.bg.ac.rs/handle/123456789/374
Title: Features of CRISPR-cas regulation key to highly efficient and temporally-specific crRNA production
Authors: Rodić, Anđela 
Blagojevic, Bojana
Djordjevic, Magdalena
Severinov, Konstantin
Đorđević, Marko 
Keywords: Biophysical modeling;CRISPR regulation;CRISPR-Cas activation;CrRNA generation;Pre-crRNA processing
Issue Date: 3-Nov-2017
Journal: Frontiers in Microbiology
Abstract: 
© 2017 Rodic, Blagojevic, Djordjevic, Severinov and Djordjevic. Bacterial immune systems, such as CRISPR-Cas or restriction-modification (R-M) systems, affect bacterial pathogenicity and antibiotic resistance by modulating horizontal gene flow. A model system for CRISPR-Cas regulation, the Type I-E system from Escherichia coli, is silent under standard laboratory conditions and experimentally observing the dynamics of CRISPR-Cas activation is challenging. Two characteristic features of CRISPR-Cas regulation in E. coli are cooperative transcription repression of cas gene and CRISPR array promoters, and fast non-specific degradation of full length CRISPR transcripts (pre-crRNA). In this work, we use computational modeling to understand how these features affect the system expression dynamics. Signaling which leads to CRISPR-Cas activation is currently unknown, so to bypass this step, we here propose a conceptual setup for cas expression activation, where cas genes are put under transcription control typical for a restriction-modification (R-M) system and then introduced into a cell. Known transcription regulation of an R-M system is used as a proxy for currently unknown CRISPR-Cas transcription control, as both systems are characterized by high cooperativity, which is likely related to similar dynamical constraints of their function. We find that the two characteristic CRISPR-Cas control features are responsible for its temporally-specific dynamical response, so that the system makes a steep (switch-like) transition from OFF to ON state with a time-delay controlled by pre-crRNA degradation rate. We furthermore find that cooperative transcription regulation qualitatively leads to a cross-over to a regime where, at higher pre-crRNA processing rates, crRNA generation approaches the limit of an infinitely abrupt system induction. We propose that these dynamical properties are associated with rapid expression of CRISPR-Cas components and efficient protection of bacterial cells against foreign DNA. In terms of synthetic applications, the setup proposed here should allow highly efficient expression of small RNAs in a narrow time interval, with a specified time-delay with respect to the signal onset.
URI: https://biore.bio.bg.ac.rs/handle/123456789/374
ISSN: 1664-302X
DOI: 10.3389/fmicb.2017.02139
Appears in Collections:Journal Article

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