Içvara Barbier scite author profile

Synthetic biologists increasingly rely on directed evolution to optimize engineered biological systems. Applying an appropriate screening or selection method for identifying the potentially rare library members with the desired properties is a crucial step for success in these experiments. Special challenges include substantial cell-to-cell variability and the requirement to check multiple states (e.g., being ON or OFF depending on the input). Here, we present a high-throughput screening method that addresses these challenges. First, we encapsulate single bacteria into microfluidic agarose gel beads. After incubation, they harbor monoclonal bacterial microcolonies (e.g., expressing a synthetic construct) and can be sorted according their fluorescence by fluorescence activated cell sorting (FACS). We determine enrichment rates and demonstrate that we can measure the average fluorescent signals of microcolonies containing phenotypically heterogeneous cells, obviating the problem of cell-to-cell variability. Finally, we apply this method to sort a pBAD promoter library at ON and OFF states.

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Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Barbier

Pérez-Carrasco

Schaerli

2020

Molecular Systems Biology

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The formation of spatiotemporal patterns of gene expression is frequently guided by gradients of diffusible signaling molecules. The toggle switch subnetwork, composed of two cross-repressing transcription factors, is a common component of gene regulatory networks in charge of patterning, converting the continuous information provided by the gradient into discrete abutting stripes of gene expression. We present a synthetic biology framework to understand and characterize the spatiotemporal patterning properties of the toggle switch. To this end, we built a synthetic toggle switch controllable by diffusible molecules in Escherichia coli. We analyzed the patterning capabilities of the circuit by combining quantitative measurements with a mathematical reconstruction of the underlying dynamical system. The toggle switch can produce robust patterns with sharp boundaries, governed by bistability and hysteresis. We further demonstrate how the hysteresis, position, timing, and precision of the boundary can be controlled, highlighting the dynamical flexibility of the circuit.

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Engineering synthetic spatial patterns in microbial populations and communities

Barbier

Kusumawardhani

Schaerli

2022

Current Opinion in Microbiology

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Engineering synthetic spatial patterns in microbial populations and communities

Barbier¹,

Kusumawardhani²,

Schaerli³

2022

Preprint

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Spatial pattern formation is an important feature of almost all biological systems, including microbial communities. Thanks to the advances in synthetic biology, we can engineer microbial populations and communities to display sophisticated spatial patterns. This bottom-up approach can be used to elucidate general principles underlying pattern formation. Moreover, it is of interest for a plethora of applications, from the production of novel living materials to medical diagnostics. In this short review, we comment the recent experimental advances in engineering spatial patterns formed by microbes. We classify the synthetic patterns based on the input signals provided and the biological processes deployed. We highlight some applications of microbial pattern formation and discuss the challenges and potential future directions.

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Synthetic gene circuits combining CRISPR interference and CRISPR activation inE. coli: importance of equal guide RNA binding affinities to avoid context-dependent effects

Barbier

Kusumawardhani

Chauhan

et al. 2023

Preprint

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Gene expression control based on CRISPR has emerged as a powerful approach for constructing synthetic gene circuits. While the use of CRISPR interference (CRISPRi) is already well-established in prokaryotic circuits, CRISPR activation (CRISPRa) is less mature and combination of the two in the same circuits is only just emerging. Here, we report that combining CRISPRi with SoxS-based CRISPRa inEscherichia colican lead to context-dependent effects due to different affinities in the formation of CRISPRa and CRISPRi complexes, resulting in loss of predictable behaviour. We show that this effect can be avoided by using the same scaffold guide RNA structure for both complexes.

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Içvara Barbier

Bacterial Microcolonies in Gel Beads for High-Throughput Screening of Libraries in Synthetic Biology

Controlling spatiotemporal pattern formation in a concentration gradient with a synthetic toggle switch

Engineering synthetic spatial patterns in microbial populations and communities

Engineering synthetic spatial patterns in microbial populations and communities

Synthetic gene circuits combining CRISPR interference and CRISPR activation inE. coli: importance of equal guide RNA binding affinities to avoid context-dependent effects

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