Synchronization of gene expression across eukaryotic communities through chemical rhythms

Pérez-García, Sara; García-Navarrete, Mario; Ruiz-Sanchis, Diego; Prieto-Navarro, Cristina; Avdovic, Merisa; Pucciariello, Ornella; Wabnik, Krzysztof

doi:10.1038/s41467-021-24325-z

Cited by 14 publications

(21 citation statements)

References 49 publications

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“…1A). We chose Mar receptors (consecutively named MarR and IacR)(16, 17) to facilitate dual-chemical perception of phytohormones salicylate acid (SA) and indole acetic acid/auxin (IAA) in the environment (Fig. 1B).…”

Section: Resultsmentioning

confidence: 99%

“…Molds for the production of microfluidic device (16) were designed in Inkscape and printed on plastic sheets with the monochrome laser printer at 1200dpi resolution as described in (16). A density of Ink deposition was used to control the feature height.…”

Section: Microfluidic Mold Fabricationmentioning

confidence: 99%

“…To address this challenge, we build a synthetic gene regulatory system that is capable of effectively buffering cellular noise, coordinating ion channel expression in the cell populations of the model eukaryote S. cerevisiae. This synthetic system builds upon gene circuits that respond to chemical stimuli (16) through coupled Mar-family receptors (MarR and IacR) (17). These circuits can synchronize cell responses by using a rate-dependent hysteresis mechanism (16).…”

Section: Introductionmentioning

confidence: 99%

“…This synthetic system builds upon gene circuits that respond to chemical stimuli (16) through coupled Mar-family receptors (MarR and IacR) (17). These circuits can synchronize cell responses by using a rate-dependent hysteresis mechanism (16). Here, we modified these circuits to encode intrinsic excitability (Fig.…”

Section: Introductionmentioning

confidence: 99%

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Macroscopic control of synchronous electrical signaling with chemically-excited gene expression

Wabnik¹,

Navarrete²,

Avdovic³

et al. 2022

Preprint

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Excitable nerve cells convert electrical signals into chemical outputs to facilitate the active transport of information across the nervous system. We engineered unicellular microbe S. cerevisiae to directly read and convert local chemical concentrations into a dynamic electrical field that is uniformly distributed across fungi populations. The chemically-excitable dual-feedback gene circuit precisely tunes the expression of active potassium channels, coordinating cyclic firing of the plasma membrane potential (PMP). Our findings provide mechanistic insights into how cells transform local chemical environments into electrical signals to guide coordinated behavior at the macroscopic scale.

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Section: Resultsmentioning

confidence: 99%

Section: Microfluidic Mold Fabricationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Macroscopic control of synchronous electrical signaling with chemically-excited gene expression

Wabnik¹,

Navarrete²,

Avdovic³

et al. 2022

Preprint

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“…These studies are motivated by their potential to provide unique insights into the mechanisms that drive ecological dynamics across a range of spatial scales (Bjørnstad et al, 1999;Koenig, 1999;Walter et al, 2017). The study of spatial population synchrony is one of the fields within ecology that is, both conceptually and methodologically, most tightly linked to other sciences that also deal with spatio-temporal dynamics (Nareddy et al, 2020;Pérez-García et al, 2021). P.A.P.…”

Section: Introductionmentioning

confidence: 99%

Seasonality, density dependence and spatial population synchrony

Nicolau¹,

Sørbye²,

Yoccoz³

et al. 2022

Preprint

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Spatial population synchrony has been the focus of theoretical and empirical studies for decades, in the hopes of understanding mechanisms and interactions driving ecological dynamics. In many systems, it is well-known that seasonality plays a critical role in the density-dependence structure of the populations, yet this has hardly received any attention in synchrony studies. Here, we propose a protocol that allows to elucidate deterministic and stochastic sources of spatial synchrony, while accounting for geographic-and season-specific density dependence. We apply our protocol to seasonally-sampled time series of sub-arctic gray-sided voles, known for marked spatial synchrony. Dissociating seasonal density-dependence contributions to the total observed synchrony reveals differential strength and shape of synchrony patterns by season. Mild winter weather reveals to be an important driver of vole spatial synchrony, with lagged effects in the fall. This has direct implications to the future population dynamics of such species when facing climate change.

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Orthogonal Light‐Dependent Membrane Adhesion Induces Social Self‐Sorting and Member‐Specific DNA Communication in Synthetic Cell Communities

Heidari

Şentürk

Yang

et al. 2023

Small

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Intercellular communication is essential to coordinate the collective operation of individual cells and to establish multicellular structures with specialized cells. [ , ] For this, sender cells secrete signals in the form of diffusible chemicals which can be recognized by receiver cells within the signaling range and with appropriate receptors. Building similar capabilities into synthetic cells allows community-based functions and interactions among synthetic cells [ , ] and living cells. [ ] Remarkable achievements of communication in synthetic cells include communities that process DNA-coded information through reaction networks, [ ] mimic quorum sensing, [ , ] differentiate into different patterns, [ ] exhibit prey-predatory relationships, [ ] synchronization, [ ] and oscillations, [ , ] and regulate cellular behavior in response to physiological conditions. [ ] These studies illustrated how communication in synthetic cells helps to understand underlying organizational Developing orthogonal chemical communication pathways in diverse synthetic cell communities is a considerable challenge due to the increased crosstalk and interference associated with large numbers of different types of sender-receiver pairs. Herein, the authors control which sender-receiver pairs communicate in a three-membered community of synthetic cells through red and blue light illumination. Semipermeable protein-polymer-based synthetic cells (proteinosomes) with complementary membrane-attached protein adhesion communicate through single-stranded DNA oligomers and synergistically process biochemical information within a community consisting of one sender and two different receiver populations. Different pairs of red and blue light-responsive protein-protein interactions act as membrane adhesion mediators between the sender and receivers such that they self-assemble and socially self-sort into different multicellular structures under red and blue light. Consequently, distinct sender-receiver pairs come into the signaling range depending on the light illumination and are able to communicate specifically without activation of the other receiver population. Overall, this work shows how photoswitchable membrane adhesion gives rise to different self-sorting protocell patterns that mediate member-specific DNA-based communication in ternary populations of synthetic cells and provides a step towards the design of orthogonal chemical communication networks in diverse communities of synthetic cells.

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Synchronization of gene expression across eukaryotic communities through chemical rhythms

Cited by 14 publications

References 49 publications

Macroscopic control of synchronous electrical signaling with chemically-excited gene expression

Macroscopic control of synchronous electrical signaling with chemically-excited gene expression

Seasonality, density dependence and spatial population synchrony

Orthogonal Light‐Dependent Membrane Adhesion Induces Social Self‐Sorting and Member‐Specific DNA Communication in Synthetic Cell Communities

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