Abstract
BackgroundCell-to-cell variability in protein expression can be large, and its propagation through signaling networks affects biological outcomes. Here, we apply deterministic and probabilistic models and biochemical measurements to study how network topologies and cell-to-cell protein abundance variations interact to shape signaling responses.ResultsWe observe bimodal distributions of extracellular signal-regulated kinase (ERK) responses to epidermal growth factor (EGF) stimulation, which are generally thought to indicate bistable or ultrasensitive signaling behavior in single cells. Surprisingly, we find that a simple MAPK/ERK-cascade model with negative feedback that displays graded, analog ERK responses at a single cell level can explain the experimentally observed bimodality at the cell population level. Model analysis suggests that a conversion of graded input–output responses in single cells to digital responses at the population level is caused by a broad distribution of ERK pathway activation thresholds brought about by cell-to-cell variability in protein expression.ConclusionsOur results show that bimodal signaling response distributions do not necessarily imply digital (ultrasensitive or bistable) single cell signaling, and the interplay between protein expression noise and network topologies can bring about digital population responses from analog single cell dose responses. Thus, cells can retain the benefits of robustness arising from negative feedback, while simultaneously generating population-level on/off responses that are thought to be critical for regulating cell fate decisions.
Highlights
Cell-to-cell variability in protein expression can be large, and its propagation through signaling networks affects biological outcomes
We show that population averages obtained from flow cytometry-based phosphorylation assay (FCPA) results correspond well to traditional Western blot measurements of activated ppERK levels in cell populations (Additional file 1: Figure S1)
A fraction of cells contain ppERK levels similar to those of the basal state. We refer to this feature of the distribution as a shoulder. The height of this shoulder decreases with increasing epidermal growth factor (EGF) dose, its position remains unchanged, indicating a dose-dependent fraction of cells failing to activate extracellular signal-regulated kinase (ERK)
Summary
Cell-to-cell variability in protein expression can be large, and its propagation through signaling networks affects biological outcomes. It is becoming clear that the fundamental processes of transcription and translation are inherently stochastic, and give rise to significant cell-to-cell variability in protein levels [13,14,15,16,17,18,19,20]. Even genetically identical cells show substantial variations in protein and mRNA abundance, and as a result, may show differences in their signaling responses [25]. Because of such heterogeneity in protein abundance, population average measurements are not sufficient for investigating “all-or-nothing” responses; single-cell measurement techniques capable of capturing the dynamics of digital signal transduction are needed [12]
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