Multi-omic Single-cell Snapshots Reveal Multiple Independent Trajectories to Drug Tolerance in a Melanoma Cell Line

Overview

Journal Nat Commun

Specialty Biology

Date 2020 May 13

PMID 32393797

Citations 51

Authors

Yapeng Su

Melissa E Ko

Hanjun Cheng

Ronghui Zhu

Min Xue

Jessica Wang

Jihoon W Lee

Luke Frankiw

Alexander Xu

Stephanie Wong

Lidia Robert

Kaitlyn Takata

Dan Yuan

Yue Lu

Sui Huang

Antoni Ribas

Raphael Levine

Garry P Nolan

Wei Wei

Sylvia K Plevritis

Guideng Li

David Baltimore

James R Heath

Affiliations

Soon will be listed here.

Abstract

The determination of individual cell trajectories through a high-dimensional cell-state space is an outstanding challenge for understanding biological changes ranging from cellular differentiation to epigenetic responses of diseased cells upon drugging. We integrate experiments and theory to determine the trajectories that single BRAF mutant melanoma cancer cells take between drug-naive and drug-tolerant states. Although single-cell omics tools can yield snapshots of the cell-state landscape, the determination of individual cell trajectories through that space can be confounded by stochastic cell-state switching. We assayed for a panel of signaling, phenotypic, and metabolic regulators at points across 5 days of drug treatment to uncover a cell-state landscape with two paths connecting drug-naive and drug-tolerant states. The trajectory a given cell takes depends upon the drug-naive level of a lineage-restricted transcription factor. Each trajectory exhibits unique druggable susceptibilities, thus updating the paradigm of adaptive resistance development in an isogenic cell population.

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