Dynamics of the quorum sensing switch: stochastic and non-stationary effects

Weber, Marc; Buceta, Javier

doi:10.1186/1752-0509-7-6

Cited by 59 publications

(81 citation statements)

References 52 publications

(63 reference statements)

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“…They argued that such core principles do exist, which is why mathematical modelling remains a powerful tool for understanding the regulation of QS. Employing mathematical tools to study QS has given rise to a wide range of mathematical models: while the autoinducer production and its binding to the regulator protein may be explained deterministically (Dockery and Keener 2001;Nilsson et al 2001), binding of the autoinducer/regulator protein to a promoter region of DNA is often examined stochastically (Goryachev et al 2005;Müller et al 2008;Weber and Buceta 2013). Models involving the spatial effects of the environment, e.g.…”

Section: Staphylococcus Aureusmentioning

confidence: 99%

Mathematical Modelling of Bacterial Quorum Sensing: A Review

2016

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Bacterial quorum sensing (QS) refers to the process of cell-to-cell bacterial communication enabled through the production and sensing of the local concentration of small molecules called autoinducers to regulate the production of gene products (e.g. enzymes or virulence factors). Through autoinducers, bacteria interact with individuals of the same species, other bacterial species, and with their host. Among QS-regulated processes mediated through autoinducers are aggregation, biofilm formation, bioluminescence, and sporulation. Autoinducers are therefore "master" regulators of bacterial lifestyles. For over 10 years, mathematical modelling of QS has sought, in parallel to experimental discoveries, to elucidate the mechanisms regulating this process. In this review, we present the progress in mathematical modelling of QS, highlighting the various theoretical approaches that have been used and discussing some of the insights that have emerged. Modelling of QS has benefited almost from the onset of the involvement of experimentalists, with many of the papers which we review, published in non-mathematical journals. This review therefore attempts to give a broad overview of the topic to the mathematical biology community, as well as the current modelling efforts and future challenges.B Judith Pérez-Velázquez

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Section: Staphylococcus Aureusmentioning

confidence: 99%

Mathematical Modelling of Bacterial Quorum Sensing: A Review

2016

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“…The latter can be experimentally achieved by different means such as modifying the affinity of the ribosome binding sites and/or modulating the so-called bursting size [29]. In fact, an intriguing question is how cells can robustly coordinate in a population in the presence of noise [30][31][32].…”

Section: Introductionmentioning

confidence: 99%

The cellular Ising model: a framework for phase transitions in multicellular environments

Weber

Buceta

2016

J. R. Soc. Interface.

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Inspired by the Ising model, we introduce a gene regulatory network that induces a phase transition that coordinates robustly the behaviour of cell ensembles. The building blocks of the design are the so-called toggle switch interfaced with two quorum sensing modules, Las and Lux. We show that as a function of the transport rate of signalling molecules across the cell membrane the population undergoes a spontaneous symmetry breaking from cells individually switching their phenotypes to a global collective phenotypic organization. By characterizing the critical behaviour, we reveal some properties, such as phenotypic memory and hypersensitivity, with relevance in the field of synthetic biology. We argue that our results can be extrapolated to other multicellular systems and be a generic framework for collective decision-making processes.

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“…Two proteins named LuxI and LuxR have been proved to be essential in quorum-sensing activity and control of bioluminescence in V. fischeri. This LuxI/LuxR regulatory system controls gene expression by quorum sensing in many Gram-negative bacteria [7]. There are also various types of homologous regulatory system in different bacterial species that have been shown to work as quorum-sensing systems controlling global cell density-dependent gene expression [2].…”

Section: The Acyl-homoserine Lactone Networkmentioning

confidence: 99%

Role of quorum-sensing molecules in infections caused by Gram-negative bacteria and host cell response

Gowda

Marie

2014

Reviews in Medical Microbiology

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Gram-negative bacteria communicate among themselves by cell-to-cell signaling molecules that are essential not only for interaction within the cell population, but also for host-pathogen interactions during infections. Pseudomonas aeruginosa and Acinetobacter baumannii are opportunistic Gram-negative pathogens associated with a broad range of acute and chronic infections, as well as causing severe nosocomial problems. The quorum-sensing signaling system controls not only multiple virulence determinants such as the assembly of virulence factors essential for colonizing and perseverance in different environmental conditions, but also interference with the host core signaling pathways. We discuss the quorum-sensing role in host response during infections, focusing on the collision of quorum-sensing molecules with the immune response and host cell apoptosis modulation pathways. The pathways used during the infectious course could open new perspectives for the expansion of specific antimicrobial strategies based on communication control of this extremely adaptable and resistant opportunistic pathogen.

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Dynamics of the quorum sensing switch: stochastic and non-stationary effects

Cited by 59 publications

References 52 publications

Mathematical Modelling of Bacterial Quorum Sensing: A Review

Mathematical Modelling of Bacterial Quorum Sensing: A Review

The cellular Ising model: a framework for phase transitions in multicellular environments

Role of quorum-sensing molecules in infections caused by Gram-negative bacteria and host cell response

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