Temperature-induced variation in gene expression burst size in metazoan cells

Arnaud, Ophélie; Meyer, Sam; Vallin, Elodie; Beslon, Guillaume; Gandrillon, Olivier

doi:10.1186/s12867-015-0048-2

Cited by 8 publications

(8 citation statements)

References 38 publications

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“…(Importantly, Padovan-Merhar et al followed up by experiments to explicitly demonstrate that this results from a global volume-dependent transcriptional control mechanism to maintain transcript concentration rather than just count.) Additional factors influencing variability in expression include cell cycle (Buettner et al, 2015; Zopf et al, 2013), mitochondrial variability (Guantes et al, 2015; Johnston et al, 2012), heterogeneity in cell culture medium (Guo et al, 2016), temperature (Arnaud et al, 2015) and a plethora of other factors (Battich et al, 2015). …”

Section: Why Are Cells Different From Each Other?mentioning

confidence: 99%

What’s Luck Got to Do with It: Single Cells, Multiple Fates, and Biological Nondeterminism

2016

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The field of single cell biology has morphed from a philosophical digression at its inception to a playground for quantitative biologists, to a major area of biomedical research. The last several years have witnessed an explosion of new technologies, allowing us to apply ever more of the modern molecular biology toolkit to single cells. Conceptual progress, however, has been comparatively slow. Here, we provide a framework for classifying both the origins of the differences between individual cells and the consequences of those differences. We discuss how the concept of “random” differences is context dependent, and propose that rigorous definitions of inputs and outputs may bring clarity to the discussion. We also categorize ways in which probabilistic behavior may influence cellular function, highlighting studies that point to exciting future directions in the field.

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Section: Why Are Cells Different From Each Other?mentioning

confidence: 99%

What’s Luck Got to Do with It: Single Cells, Multiple Fates, and Biological Nondeterminism

2016

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“…In particular, the molecular mechanisms affected or influenced by temperature choice and the translation into potentiated immune response remain unknown. In ectotherms, the influence of thermoregulation upon gene expression has been supported by correlations between temperature, regulatory response, and variation in gene expression ( 32 , 33 ). However, the contribution of epigenetic regulation including DNA methylation and histone modification remains unexplored [e.g., Streelman et al ( 34 ); Baalsrud et al ( 35 ); and Mallard et al ( 36 )].…”

Section: Introductionmentioning

confidence: 99%

Behavioral Fever Drives Epigenetic Modulation of the Immune Response in Fish

et al. 2018

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Ectotherms choose the best thermal conditions to mount a successful immune response, a phenomenon known as behavioral fever. The cumulative evidence suggests that behavioral fever impacts positively upon lymphocyte proliferation, inflammatory cytokine expression, and other immune functions. In this study, we have explored how thermal choice during infection impacts upon underpinning molecular processes and how temperature increase is coupled to the immune response. Our results show that behavioral fever results in a widespread, plastic imprint on gene regulation, and lymphocyte proliferation. We further explored the possible contribution of histone modification and identified global associations between temperature and histone changes that suggest epigenetic remodeling as a result of behavioral fever. Together, these results highlight the critical importance of thermal choice in mobile ectotherms, particularly in response to an infection, and demonstrate the key role of epigenetic modification to orchestrate the thermocoupling of the immune response during behavioral fever.

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“…Additional complexity stems from nontrivial effects of temperature on transcription ( 10 ), translation ( 11 ), and their regulation ( 12 , 13 ). Previous transcriptome expression measurements in heat and cold shock revealed broad responses ( 14 ), but it is hard to discern the degree to which these changes are individual gene-level ( 15 ) or network-level effects, or cellular attempts to restore homeostasis. Adding to these difficulties are the complexity of biochemical interaction networks and the incomplete knowledge of their connectivity ( 16 , 17 ).…”

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confidence: 99%

Multiscale effects of heating and cooling on genes and gene networks

Charlebois

Hauser

Marshall

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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SignificanceFluctuating environments such as changes in ambient temperature represent a fundamental challenge to life. Cells must protect gene networks that protect them from such stresses, making it difficult to understand how temperature affects gene network function in general. Here, we focus on single genes and small synthetic network modules to reveal four key effects of nonoptimal temperatures at different biological scales: (i) a cell fate choice between arrest and resistance, (ii) slower growth rates, (iii) Arrhenius reaction rates, and (iv) protein structure changes. We develop a multiscale computational modeling framework that captures and predicts all of these effects. These findings promote our understanding of how temperature affects living systems and enables more robust cellular engineering for real-world applications.

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Temperature-induced variation in gene expression burst size in metazoan cells

Cited by 8 publications

References 38 publications

What’s Luck Got to Do with It: Single Cells, Multiple Fates, and Biological Nondeterminism

What’s Luck Got to Do with It: Single Cells, Multiple Fates, and Biological Nondeterminism

Behavioral Fever Drives Epigenetic Modulation of the Immune Response in Fish

Multiscale effects of heating and cooling on genes and gene networks

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