Melanoma subpopulations that rapidly escape MAPK pathway inhibition incur DNA damage and rely on stress signalling

Yang, Chen; Tian, Chengzhe; Hoffman, Timothy E.; Jacobsen, Nicole K; Spencer, Sabrina L.

doi:10.1038/s41467-021-21549-x

Cited by 46 publications

(48 citation statements)

References 70 publications

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“…Initially, melanoma cells expressed higher levels of MITF when exposed to BRAFi and MEKi, which was in line with a previous report of Smith et al [72], followed by dedifferentiation and a slow-cycling phenotype marked by a decrease of MITF and an increase in nerve growth factor receptor (NGFR) expression [118]. However, single-cell RNA sequencing revealed that a MITF low AXL high subpopulation was already present during this first phase of acquiring drug resistance [118]. Knockdown experiments showed that the cells were dependent on ATF4 expression to escape MAPK pathway inhibition [118].…”

Section: Targeted Therapysupporting

confidence: 89%

“…Furthermore, ATF4 that suppresses MITF expression as described above plays also a role in acquired resistance to BRAFi and MEKi. Recently, Yang et al discovered that ATF4 stress signaling mediates to a rapid escape already within the first days after initiating MAPK pathway inhibition [118]. Initially, melanoma cells expressed higher levels of MITF when exposed to BRAFi and MEKi, which was in line with a previous report of Smith et al [72], followed by dedifferentiation and a slow-cycling phenotype marked by a decrease of MITF and an increase in nerve growth factor receptor (NGFR) expression [118].…”

Section: Targeted Therapymentioning

confidence: 57%

“…Recently, Yang et al discovered that ATF4 stress signaling mediates to a rapid escape already within the first days after initiating MAPK pathway inhibition [118]. Initially, melanoma cells expressed higher levels of MITF when exposed to BRAFi and MEKi, which was in line with a previous report of Smith et al [72], followed by dedifferentiation and a slow-cycling phenotype marked by a decrease of MITF and an increase in nerve growth factor receptor (NGFR) expression [118]. However, single-cell RNA sequencing revealed that a MITF low AXL high subpopulation was already present during this first phase of acquiring drug resistance [118].…”

Section: Targeted Therapymentioning

confidence: 99%

“…However, single-cell RNA sequencing revealed that a MITF low AXL high subpopulation was already present during this first phase of acquiring drug resistance [118]. Knockdown experiments showed that the cells were dependent on ATF4 expression to escape MAPK pathway inhibition [118].…”

Section: Targeted Therapymentioning

confidence: 99%

See 3 more Smart Citations

How Neural Crest Transcription Factors Contribute to Melanoma Heterogeneity, Cellular Plasticity, and Treatment Resistance

Wessely

Steeb

Berking

et al. 2021

IJMS

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Cutaneous melanoma represents one of the deadliest types of skin cancer. The prognosis strongly depends on the disease stage, thus early detection is crucial. New therapies, including BRAF and MEK inhibitors and immunotherapies, have significantly improved the survival of patients in the last decade. However, intrinsic and acquired resistance is still a challenge. In this review, we discuss two major aspects that contribute to the aggressiveness of melanoma, namely, the embryonic origin of melanocytes and melanoma cells and cellular plasticity. First, we summarize the physiological function of epidermal melanocytes and their development from precursor cells that originate from the neural crest (NC). Next, we discuss the concepts of intratumoral heterogeneity, cellular plasticity, and phenotype switching that enable melanoma to adapt to changes in the tumor microenvironment and promote disease progression and drug resistance. Finally, we further dissect the connection of these two aspects by focusing on the transcriptional regulators MSX1, MITF, SOX10, PAX3, and FOXD3. These factors play a key role in NC initiation, NC cell migration, and melanocyte formation, and we discuss how they contribute to cellular plasticity and drug resistance in melanoma.

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Section: Targeted Therapysupporting

confidence: 89%

Section: Targeted Therapymentioning

confidence: 57%

Section: Targeted Therapymentioning

confidence: 99%

Section: Targeted Therapymentioning

confidence: 99%

See 2 more Smart Citations

How Neural Crest Transcription Factors Contribute to Melanoma Heterogeneity, Cellular Plasticity, and Treatment Resistance

Wessely

Steeb

Berking

et al. 2021

IJMS

View full text Add to dashboard Cite

show abstract

“…We can briefly mention two recent ones from cancer biology. Early (in the first three days) adaptation of melanoma cell population was investigated after application of a potent targeted anticancer drug dabrafenib, belonging to the family of so-called BRAF inhibitors [2]. Most of the cells adapt to such treatment by entering quiescence but some "escapees" manage to maintain their cell cycle and eventually outproliferate other cells.…”

mentioning

confidence: 99%

Adaptation through the lens of single-cell multi-omics data

Zinovyev

2021

Physics of Life Reviews

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Focal adhesion alterations in G0‐positive melanoma cells

et al. 2022

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Background Melanoma is a highly heterogeneous malignant tumor that exhibits various forms of drug resistance. Recently, reversal transition of cancer cells to the G 0 phase of the cell cycle under the influence of therapeutic drugs has been identified as an event associated with tumor dissemination. In the present study, we investigated the ability of chemotherapeutic agent dacarbazine to induce a transition of melanoma cells to the G 0 phase as a mechanism of chemoresistance. Methods We used the flow cytometry to analyze cell distribution within cell cycle phases after dacarbazine treatment as well as to identifyG 0 ‐positive cells population. Transcriptome profiling was provided to determine genes associated with dacarbazine resistance . We evaluated the activity of β‐galactosidase in cells treated with dacarbazine by substrate hydrolysis. Cell adhesion strength was measured by centrifugal assay application with subsequent staining of adhesive cells with Ki‐67 monoclonal antibodies. Ability of melanoma cells to metabolize dacarbazine was determined by expressional analysis of CYP1A1, CYP1A2, CYP2E1 followed by CYP1A1 protein level evaluation by the ELISA method. Results The present study determined that dacarbazine treatment of melanoma cells could induce an increase in the percentage of cells in G 0 phase without alterations of β‐galactosidase positive cells which corresponded to the fraction of the senescent cells. Transcriptomic profiling of cells under dacarbazine induction of G 0 ‐positive cells percentage revealed that ‘VEGFA‐VEGFR2 signaling pathway’ and ‘Cell cycle’ signaling were mostly enriched by dysregulated genes. ‘Focal adhesion’ signaling was also found to be triggered by dacarbazine. In melanoma cells treated with dacarbazine, an increase in G 0 ‐positive cells among adherent cells was found. Conclusions Dacarbazine induces the alteration in a percentage of melanoma cells residing in G 0 phase of a cell cycle. The altered adhesive phenotype of cancer cells under transition in the G 0 phase may refer to a specific intercellular communication pattern of quiescent/senescent cancer cells.

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Melanoma subpopulations that rapidly escape MAPK pathway inhibition incur DNA damage and rely on stress signalling

Cited by 46 publications

References 70 publications

How Neural Crest Transcription Factors Contribute to Melanoma Heterogeneity, Cellular Plasticity, and Treatment Resistance

How Neural Crest Transcription Factors Contribute to Melanoma Heterogeneity, Cellular Plasticity, and Treatment Resistance

Adaptation through the lens of single-cell multi-omics data

Focal adhesion alterations in G0‐positive melanoma cells

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