Fundamental trade-offs between information flow in single cells and cellular populations

Suderman, Ryan; Bachman, John A.; Smith, A. R.; Sorger, Peter K.; Deeds, Eric J.

doi:10.1073/pnas.1615660114

Cited by 112 publications

(169 citation statements)

References 43 publications

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“…Analysis of 45 a single-cell channel from the Ca 2+ response in HEK293 cells stimulated with acetylcholine repetitively at various concentrations enabled the calculation of the channel capacity, which is the maximal amount of information that the channel can transfer, at 2 bits (21). This 2-bit channel capacity is higher than the 1-bit capacity calculated for cell-population channels in other studies (4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20). With organs, such as skeletal muscle, functioning not as a single cell, but as the sum of single cells, a multiple-cell channel should correspond to the physiological 5 communication channel.…”

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confidence: 65%

“…For a cell-population channel, the mutual information relating stimulation intensity and cellular response contains only 1 bit information (Fig. 1C, left, table S1) (4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20), indicating that the cellular response can distinguish only the two conditions of 20 stimulation: the presence or absence of stimulation. Physiologically, cellular responses are often gradually controlled by the intensity of stimulation, meaning that a cellular response can encode more than 1 bit information.…”

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confidence: 99%

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Single-cell information analysis reveals small intra- and large intercellular variations increase cellular information capacity

Wada

Wataya

Fujii

et al. 2019

Preprint

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Cells transmit information about extracellular stimulation through signaling pathways to control cellular function. A signaling pathway can be regarded as a communication channel. In the analysis of channels of cell populations, intercellular variation is considered noise. However, intercellular variation enables individual cells to encode different information. Therefore, at the single-cell level, each cell can be regarded as an independent channel. Thus, we propose that responses of cells of the same type in tissues, such as the fibers in a skeletal muscle, should be regarded as a multiple-cell channel composed of single-cell channels, in which intercellular variation contains information. Here, we applied electrical pulses to individual myotubes from cultured C2C12 cells or dissociated skeletal muscle fibers and measured Ca2+ responses or contraction, respectively, to estimate information capacity in a biological system. For each muscle cell system, we found that a single-cell channel transmitted more information than did a cell-population channel, indicating that the cellular response is consistent with each cell (low intracellular variation) but different among individual cells (high intercellular variation). As cell number and thus the number of single-cell channels increased, a multiple-cell channel transmitted more information by incorporating the differences among individual cells. Thus, a tissue with small intracellular and large intercellular variations has the capacity to distinguish differences in stimulation intensity to precisely control physiological function.One Sentence SummarySmall intracellular and large intercellular variations increase information transmission for precise control of tissue function.

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confidence: 65%

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confidence: 99%

Single-cell information analysis reveals small intra- and large intercellular variations increase cellular information capacity

Wada

Wataya

Fujii

et al. 2019

Preprint

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“…We point out that the EM essentially belongs to the frequency modulation (FM) strategy since it regulates the gene expression (refer to (Eqn 1)) by modulating the off-state dwell time, whereas the IM to the amplitude modulation (AM) strategy since it regulates the gene expression by changing the on-state dwell time [44][45][46][47][48]. The combination of the results in Fig.…”

Section: Signal Pathways' Cross-talk In the Enhancement Model Can Incmentioning

confidence: 92%

Entangled signal pathways can both control expression stability and induce stochastic focusing

Wang

Liu

2018

FEBS Letters

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Gene transcription is often controlled by multiple interacting signal pathways, but how these pathways impact gene expression is not fully understood. Here, we refine a mechanic model based on experiments in murine embryonic stem cells and analyze the influence of pathway-pathway cross-talk strength (CTS) on mRNA expression stability. We find that the CTS can tune this stability, depending on the manner of regulation. Furthermore, there is an optimal CTS such that the expression pattern is most stable but free energy consumption is at its highest; the CTS can induce stochastic focusing of the mRNA level but this is at the cost of energy. In both cases, there is a cross-talk-mediated trade-off, implying that entangled signal pathways can control both expression stability and energy dissipation.

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“…For example, analysis of the signalling pathway activated by TRAIL suggests that limits on the fidelity of information transmission through the pathway are not imposed by biological or physical limitations, but rather may be necessary to allow graded cell death responses in a population (Suderman et al 2017). …”

Section: Cellular Manifestations Of Molecular Heterogeneity Impactingmentioning

confidence: 99%

The impact of non-genetic heterogeneity on cancer cell death

Inde

Dixon

2017

Critical Reviews in Biochemistry and Molecular Biology

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The goal of chemotherapy is to induce homogeneous cell death within the population of targeted cancer cells. However, no two cells are exactly alike at the molecular level, and sensitivity to drug-induced cell death therefore varies within a population. Genetic alterations can contribute to this variability and lead to selection for drug resistant clones. However, there is a growing appreciation for the role of non-genetic variation in producing drug tolerant cellular states that exhibit reduced sensitivity to cell death for extended periods of time, from hours to weeks. These cellular states may result from individual variation in epigenetics, gene expression, metabolism and other processes that impact drug mechanism of action or the execution of cell death. Such population-level non-genetic heterogeneity may contribute to treatment failure and provide a cellular ‘substrate’ for the emergence of genetic alterations that confer frank drug resistance.

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Fundamental trade-offs between information flow in single cells and cellular populations

Cited by 112 publications

References 43 publications

Single-cell information analysis reveals small intra- and large intercellular variations increase cellular information capacity

Single-cell information analysis reveals small intra- and large intercellular variations increase cellular information capacity

Entangled signal pathways can both control expression stability and induce stochastic focusing

The impact of non-genetic heterogeneity on cancer cell death

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