Macromolecular Crowding Induces Spatial Correlations That Control Gene Expression Bursting Patterns

Norred, S. Elizabeth; Caveney, Patrick M.; Chauhan, Gaurav; Collier, Lauren K.; Collier, C. Patrick; Abel, Steven M.; Simpson, Michael L.

doi:10.1021/acssynbio.8b00139

Cited by 41 publications

(61 citation statements)

References 50 publications

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“…The extent of the third, highly mobile fraction, which dominated in the quiescent state, decreased dramatically when cells were serum stimulated. This switch in chromatin mobility is suggestive of dramatically altered molecular crowding, as a result accrued concentration of players of all types in a highly transcribing nucleus, in particular ribosome biogenesis [20,[45][46][47].…”

Section: Discussionmentioning

confidence: 99%

Hi-D: Nanoscale mapping of nuclear dynamics in single living cells

Shaban

Barth

Bystricky

2018

Preprint

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ABSTRACTBulk chromatin motion has not been analysed at high resolution. We present Hi-D, a method to quantitatively map dynamics of chromatin and abundant nuclear proteins for every pixel simultaneously over the entire nucleus from fluorescence image series. Hi-D combines reconstruction of chromatin motion, and classification of local diffusion processes by Bayesian inference. We show that DNA dynamics in the nuclear interior are spatially partitioned into 0.3 – 3 μm domains in a mosaic-like pattern, uncoupled from chromatin compaction. This pattern was remodelled in response to transcriptional activity. Hi-D can be applied to any dense and bulk structures opening new perspectives towards understanding motion of nuclear molecules.

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Section: Discussionmentioning

confidence: 99%

Hi-D: Nanoscale mapping of nuclear dynamics in single living cells

Shaban

Barth

Bystricky

2018

Preprint

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“…Synthetic biology approaches to controlling gene expression level and variability have focused on genetic circuits. However, the central feature of cell-free synthetic biology is the ability to define the environment by manipulating confinement volume (Caveney et al, 2016), degree of macromolecular crowding (Norred et al, 2018), and the composition of cell extract (Garcia et al, 2018). Likewise, the results reported here show that membrane engineering is a viable approach to control expression behavior and demonstrate a simple optical treatment that greatly diminishes the variability in the permeability of POPC vesicle membranes.…”

Section: Resultsmentioning

confidence: 99%

“…A broader goal is the realization of more complex cell-free systems (Perez et al, 2016) that may approach cell-like capabilities (Scott et al, 2016). However, these aspirations are stymied by highly variable behavior from identical cell-free expression reactors, especially at cell-relevant reactor volumes (Boreyko et al, 2017;Caveney et al, 2016;Hansen et al, 2015;Norred et al, 2018). Even in simple, single-gene, expression experiments, protein concentrations may vary by more than an order of magnitude across a population of identically constructed reaction chambers (Nourian and Danelon, 2013;Saito et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Controlling Cell-Free Gene Expression Behavior by Tuning Membrane Transport Properties

Caveney

Dabbs

McClintic

et al. 2019

Preprint

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Controlled transport of molecules across boundaries for energy exchange, sensing, and communication is an essential step toward cell-like synthetic systems. This communication between the gene expression compartment and the external environment requires reaction chambers that are permeable to molecular species that influence expression. In lipid vesicle reaction chambers, species that support expression -from small ions to amino acids -may diffuse across membranes and amplify protein production. However, vesicle-to-vesicle variation in membrane permeability may lead to low total expression and high variability in this expression. We demonstrate a simple optical treatment method that greatly reduces the variability in membrane permeability. When transport across the membrane was essential for expression, this optical treatment increased mean expression level by ~6-fold and reduced expression variability by nearly two orders of magnitude. These results demonstrate membrane engineering may enable essential steps toward cell-like synthetic systems. The experimental platform described here provides a means of understanding controlled transport motifs in individual cells and groups of cells working cooperatively through cell-to-cell molecular signaling.

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“…Perhaps cell and cell-free synthetic biology differ most in the emphasis each place either on gene circuits or on the environment in which gene circuits reside. Cell-free synthetic biology is placing ever greater emphasis on controlling the gene circuit environment by manipulating confinement volume (Caveney et al, 2016), degree of macromolecular crowding (Norred et al, 2018), and the composition of cell extract (Garcia et al, 2018). A defining feature of the gene circuit environment in cells is the controlled transport of molecules across membranes.…”

Section: Resultsmentioning

confidence: 99%

Molecular Transport across Lipid Membranes Controls Cell-Free Expression Level and Dynamics

Caveney

Dabbs

McClintic

et al. 2019

Preprint

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Essential steps toward synthetic cell-like systems require controlled transport of molecular species across the boundary between encapsulated expression and the external environment. When molecular species (e.g. small ions, amino acids) required for expression (i.e. expression resources) may cross this boundary, this transport process plays an important role in gene expression dynamics and expression variability. Here we show how the location (encapsulated or external) of the expression resources controls the level and the dynamics of cell-free protein expression confined in permeable lipid vesicles. Regardless of the concentration of encapsulated resources, external resources were essential for protein production. Compared to resource poor external environments, plentiful external resources increased expression by ~7fold, and rescued expression when internal resources were lacking. Intriguingly, the location of resources and the membrane transport properties dictated expression dynamics in a manner well predicted by a simple transport-expression model. These results suggest membrane engineering as a means for spatio-temporal control of gene expression in cell-free synthetic biology applications and demonstrate a flexible experimental platform to understand the interplay between membrane transport and expression in cellular systems.

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Macromolecular Crowding Induces Spatial Correlations That Control Gene Expression Bursting Patterns

Cited by 41 publications

References 50 publications

Hi-D: Nanoscale mapping of nuclear dynamics in single living cells

Hi-D: Nanoscale mapping of nuclear dynamics in single living cells

Controlling Cell-Free Gene Expression Behavior by Tuning Membrane Transport Properties

Molecular Transport across Lipid Membranes Controls Cell-Free Expression Level and Dynamics

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