Your search keyword '"Tsimring, Lev S."' showing total 6 results

1. Flavin-based metabolic cycles are integral features of growth and division in single yeast cells.

Author

Baumgartner, Bridget L., O’Laughlin, Richard, Jin, Meng, Tsimring, Lev S., Hao, Nan, and Hasty, Jeff

Published

2018

2. Rapid and tunable post-translational coupling of genetic circuits.

Author

Prindle, Arthur, Selimkhanov, Jangir, Li, Howard, Razinkov, Ivan, Tsimring, Lev S., and Hasty, Jeff

Subjects

*GENE regulatory networks, *SYNTHETIC biology, *BIOTECHNOLOGY, *WATER purification, *CELLULAR signal transduction, *BACTERIAL proteins

Abstract

One promise of synthetic biology is the creation of genetic circuitry that enables the execution of logical programming in living cells. Such 'wet programming' is positioned to transform a wide and diverse swathe of biotechnology ranging from therapeutics and diagnostics to water treatment strategies. Although progress in the development of a library of genetic modules continues apace, a major challenge for their integration into larger circuits is the generation of sufficiently fast and precise communication between modules. An attractive approach is to integrate engineered circuits with host processes that facilitate robust cellular signalling. In this context, recent studies have demonstrated that bacterial protein degradation can trigger a precise response to stress by overloading a limited supply of intracellular proteases. Here we use protease competition to engineer rapid and tunable coupling of genetic circuits across multiple spatial and temporal scales. We characterize coupling delay times that are more than an order of magnitude faster than standard transcription-factor-based coupling methods (less than 1 min compared with ∼20-40 min) and demonstrate tunability through manipulation of the linker between the protein and its degradation tag. We use this mechanism as a platform to couple genetic clocks at the intracellular and colony level, then synchronize the multi-colony dynamics to reduce variability in both clocks. We show how the coupled clock network can be used to encode independent environmental inputs into a single time series output, thus enabling frequency multiplexing (information transmitted on a common channel by distinct frequencies) in a genetic circuit context. Our results establish a general framework for the rapid and tunable coupling of genetic circuits through the use of native 'queueing' processes such as competitive protein degradation. [ABSTRACT FROM AUTHOR]

Published

2014

3. A sensing array of radically coupled genetic 'biopixels'.

Author

Prindle, Arthur, Samayoa, Phillip, Razinkov, Ivan, Danino, Tal, Tsimring, Lev S., and Hasty, Jeff

Subjects

*SYNTHETIC biology, *LIQUID crystal displays, *REMOTE sensing, *ROBUST control, *BIOSENSORS, *HEAVY metals

Abstract

Although there has been considerable progress in the development of engineering principles for synthetic biology, a substantial challenge is the construction of robust circuits in a noisy cellular environment. Such an environment leads to considerable intercellular variability in circuit behaviour, which can hinder functionality at the colony level. Here we engineer the synchronization of thousands of oscillating colony 'biopixels' over centimetre-length scales through the use of synergistic intercellular coupling involving quorum sensing within a colony and gas-phase redox signalling between colonies. We use this platform to construct a liquid crystal display (LCD)-like macroscopic clock that can be used to sense arsenic via modulation of the oscillatory period. Given the repertoire of sensing capabilities of bacteria such as Escherichia coli, the ability to coordinate their behaviour over large length scales sets the stage for the construction of low cost genetic biosensors that are capable of detecting heavy metals and pathogens in the field. [ABSTRACT FROM AUTHOR]

Published

2012

4. A fast, robust and tunable synthetic gene oscillator.

Author

Stricker, Jesse, Cookson, Scott, Bennett, Matthew R., Mather, William H., Tsimring, Lev S., and Hasty, Jeff

Subjects

*SYNTHETIC biology, *GENETIC regulation, *COMPUTATIONAL biology, *GENOMICS, *ORGANELLE formation, *ESCHERICHIA coli, *BACTERIAL genetics, *COMPUTER network architectures, *RESEARCH methodology

Abstract

One defining goal of synthetic biology is the development of engineering-based approaches that enable the construction of gene-regulatory networks according to ‘design specifications’ generated from computational modelling. This approach provides a systematic framework for exploring how a given regulatory network generates a particular phenotypic behaviour. Several fundamental gene circuits have been developed using this approach, including toggle switches and oscillators, and these have been applied in new contexts such as triggered biofilm development and cellular population control. Here we describe an engineered genetic oscillator in Escherichia coli that is fast, robust and persistent, with tunable oscillatory periods as fast as 13 min. The oscillator was designed using a previously modelled network architecture comprising linked positive and negative feedback loops. Using a microfluidic platform tailored for single-cell microscopy, we precisely control environmental conditions and monitor oscillations in individual cells through multiple cycles. Experiments reveal remarkable robustness and persistence of oscillations in the designed circuit; almost every cell exhibited large-amplitude fluorescence oscillations throughout observation runs. The oscillatory period can be tuned by altering inducer levels, temperature and the media source. Computational modelling demonstrates that the key design principle for constructing a robust oscillator is a time delay in the negative feedback loop, which can mechanistically arise from the cascade of cellular processes involved in forming a functional transcription factor. The positive feedback loop increases the robustness of the oscillations and allows for greater tunability. Examination of our refined model suggested the existence of a simplified oscillator design without positive feedback, and we construct an oscillator strain confirming this computational prediction. [ABSTRACT FROM AUTHOR]

Published

2008

5. Metabolic gene regulation in a dynamically changing environment.

Author

Bennett, Matthew R., Pang, Wyming Lee, Ostroff, Natalie A., Baumgartner, Bridget L., Nayak, Sujata, Tsimring, Lev S., and Hasty, Jeff

Subjects

*NATURAL selection, *CELLS, *GENETIC regulation, *SACCHAROMYCES cerevisiae, *MICROFLUIDICS, *GALACTOSE, *CARBON, *FREQUENCY response, *BIOLOGICAL variation

Abstract

Natural selection dictates that cells constantly adapt to dynamically changing environments in a context-dependent manner. Gene-regulatory networks often mediate the cellular response to perturbation, and an understanding of cellular adaptation will require experimental approaches aimed at subjecting cells to a dynamic environment that mimics their natural habitat. Here we monitor the response of Saccharomyces cerevisiae metabolic gene regulation to periodic changes in the external carbon source by using a microfluidic platform that allows precise, dynamic control over environmental conditions. We show that the metabolic system acts as a low-pass filter that reliably responds to a slowly changing environment, while effectively ignoring fast fluctuations. The sensitive low-frequency response was significantly faster than in predictions arising from our computational modelling, and this discrepancy was resolved by the discovery that two key galactose transcripts possess half-lives that depend on the carbon source. Finally, to explore how induction characteristics affect frequency response, we compare two S. cerevisiae strains and show that they have the same frequency response despite having markedly different induction properties. This suggests that although certain characteristics of the complex networks may differ when probed in a static environment, the system has been optimized for a robust response to a dynamically changing environment. [ABSTRACT FROM AUTHOR]

Published

2008

6. Origins of extrinsic variability in eukaryotic gene expression.

Author

Volfson, Dmitri, Marciniak, Jennifer, Blake, William J., Ostroff, Natalie, Tsimring, Lev S., and Hasty, Jeff

Subjects

*GENE expression, *GENETIC disorders, *GENETIC regulation, *GENES, *SACCHAROMYCES cerevisiae, *TRANSCRIPTION factors

Abstract

Variable gene expression within a clonal population of cells has been implicated in a number of important processes including mutation and evolution, determination of cell fates and the development of genetic disease. Recent studies have demonstrated that a significant component of expression variability arises from extrinsic factors thought to influence multiple genes simultaneously, yet the biological origins of this extrinsic variability have received little attention. Here we combine computational modelling with fluorescence data generated from multiple promoter–gene inserts in Saccharomyces cerevisiae to identify two major sources of extrinsic variability. One unavoidable source arising from the coupling of gene expression with population dynamics leads to a ubiquitous lower limit for expression variability. A second source, which is modelled as originating from a common upstream transcription factor, exemplifies how regulatory networks can convert noise in upstream regulator expression into extrinsic noise at the output of a target gene. Our results highlight the importance of the interplay of gene regulatory networks with population heterogeneity for understanding the origins of cellular diversity. [ABSTRACT FROM AUTHOR]

Published

2006