Abstract
Cancer cells within tumors display a high degree of phenotypic variability. This variability is thought to allow some of the cells to survive and persist after seemingly effective drug treatments. Studies on vemurafenib, a signaling inhibitor that targets an oncogenic BRAF mutation common in melanoma, suggested that cell-to-cell variation in drug resistance, measured by long-term proliferation, originates from epigenetic differences in gene expression that pre-exist treatment. However, it is still unknown whether reactivation of signaling downstream to the inhibited BRAF, thought to be a key step for resistance, is heterogeneous across cells. While previous studies established that signaling reactivation takes place many hours to days after treatment, they monitored reactivation with bulk-population assays unsuitable for detecting cell-to-cell heterogeneity. We hypothesized that signaling reactivation is heterogeneous and is almost instantaneous for a small subpopulation of resistant cells. We tested this hypothesis by monitoring signaling dynamics at a single-cell resolution and observed that despite highly uniform initial inhibition, roughly 15% of cells reactivated signaling within an hour of treatment. Moreover, by tracking cell lineages over multiple days, we established that these cells indeed proliferated more than neighboring cells, thus establishing that rapid signaling reactivation predicts long-term vemurafenib resistance.
Highlights
Cancer cells within tumors display a high degree of phenotypic variability
A recent pioneering study that investigated vemurafenib resistance in-vitro in isogenic populations of melanoma cells revealed that drug resistance can arise from a reversible epigenetic state that characterizes a rare subpopulation of c ells[5] (Fig. 1A)
In this study we examined how changes in extracellular signal-regulated kinase (ERK) signaling transpire upon treatment at the single-cell resolution and tested how signaling dynamics in individual cells correlate with their ultimate proliferation capacity
Summary
Cancer cells within tumors display a high degree of phenotypic variability. This variability is thought to allow some of the cells to survive and persist after seemingly effective drug treatments. A signaling inhibitor that targets an oncogenic BRAF mutation common in melanoma, suggested that cell-to-cell variation in drug resistance, measured by long-term proliferation, originates from epigenetic differences in gene expression that pre-exist treatment. It is still unknown whether reactivation of signaling downstream to the inhibited BRAF, thought to be a key step for resistance, is heterogeneous across cells. The study leveraged on cell cultures that were plated sparsely for monitoring the long-term fate of individual cells and revealed that resistance is extremely heterogeneous and is correlated with high expression of multiple resistance marker genes, many of which belong to the gene network responding to extra-cellular growth factors (e.g., the growth factor receptors NGFR and EGFR)
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