Multiplex single-cell chemical genomics reveals the kinase dependence of the response to targeted therapy

McFaline-Figueroa, José L.; Srivatsan, Sanjay; Hill, Andrew J.; Gasperini, Molly; Jackson, Dana L.; Saunders, Lauren; Domcke, Silvia; Regalado, Samuel G.; Lazarchuck, Paul; Alvarez, Sarai; Monnat, Raymond J.; Shendure, Jay; Trapnell, Cole

doi:10.1101/2023.03.10.531983

Cited by 3 publications

(6 citation statements)

References 90 publications

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“…However, we show that an inhibitor’s impact on viability is not always correlated with global transcriptional response, indicating that inhibitor responses extend beyond viability, consistent with previous chemical genomic profiling efforts ( 5 , 16 ). Moreover, we show that EGFRi differentially induce an adaptive resistance molecular response recently associated with MEK inhibition ( 31 ). The presence of an adaptive resistance may explain the disparity between promising preclinical results and broad clinical nonsuccess.…”

Section: Discussionmentioning

confidence: 91%

“…Relationship between the total number of differentially expressed genes as a function of EGFR inhibitor dose (quasi-poisson regression, Wald test FDR < 1%) for the specified EGFR inhibitor (top annotations) with the expression of the proliferation marker MKI67 across BT112 ( A ), BT228 ( B ) and BT333 ( C ) PDCLs. The scatter plots ( right of each heatmap) represent the Pearson correlation within a cell line of inhibitor impact on MKI67 (normalized beta coefficient from fitting a GLM of MKI67 as a function of dose) versus overall transcriptional changes (as total number of DEGs) D ) Heatmap of z-scored mean aggregate expression of genes previously associated with adaptation ( 31 ) to inhibition of the RTK pathway.…”

Section: Resultsmentioning

confidence: 99%

“…Given the minimal efficacy of EGFR inhibitors to treat GBM in the clinic, we next examined the expression of programs associated with acquired resistance to therapy. Recently, we identified an adaptive resistance signature across established GBM cell lines and glioma stem cell models in response to the inhibition of RTK signaling, most prominently by inhibition of MEK via trametinib ( 31 ). Across the EGFRi signatures from our pilot screen, we found that the shared EGFR signature ( Fig.…”

Section: Resultsmentioning

confidence: 99%

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A heterogeneous pharmaco-transcriptomic landscape induced by targeting a single oncogenic kinase

Giglio,

Hou,

Wyatt

et al. 2024

Preprint

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Over-activation of the epidermal growth factor receptor (EGFR) is a hallmark of glioblastoma. However, EGFR-targeted therapies have led to minimal clinical response. While delivery of EGFR inhibitors (EGFRis) to the brain constitutes a major challenge, how additional drug-specific features alter efficacy remains poorly understood. We apply highly multiplex single-cell chemical genomics to define the molecular response of glioblastoma to EGFRis. Using a deep generative framework, we identify shared and drug-specific transcriptional programs that group EGFRis into distinct molecular classes. We identify programs that differ by the chemical properties of EGFRis, including induction of adaptive transcription and modulation of immunogenic gene expression. Finally, we demonstrate that pro-immunogenic expression changes associated with a subset of tyrphostin family EGFRis increase the ability of T-cells to target glioblastoma cells.One Sentence SummaryDeep chemical genomic profiling reveals heterogeneity in response to the targeting of EGFR via myriad chemical means.

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Section: Discussionmentioning

confidence: 91%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

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A heterogeneous pharmaco-transcriptomic landscape induced by targeting a single oncogenic kinase

Giglio,

Hou,

Wyatt

et al. 2024

Preprint

Self Cite

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“…As single-cell sequencing becomes more affordable and widely used, both the number and the size of single-cell genomics datasets are growing exponentially 1,2 with no signs of slowing down. Current single-cell sequencing studies from tissues, organs and whole organisms can profile millions of cells [3][4][5][6][7][8][9] . Along with the development of integration algorithms, even larger atlases have been built, reaching tens of millions of cells 10…”

Section: Introductionmentioning

confidence: 99%

Building and analyzing metacells in single-cell genomics data

Bilous,

Hérault,

Gabriel

et al. 2024

Preprint

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The advent of high-throughput single-cell genomics technologies has fundamentally transformed biological sciences. Currently, millions of cells from complex biological tissues can be phenotypically profiled across multiple modalities. The scaling of computational methods to analyze such data is a constant challenge and tools need to be regularly updated, if not redesigned, to cope with ever-growing numbers of cells. Over the last few years, metacells have been introduced to reduce the size and complexity of single-cell genomics data while preserving biologically relevant information. Here, we review recent studies that capitalize on the concept of metacells – and the many variants in nomenclature that have been used. We further outline how and when metacells should (or should not) be used to study single-cell genomics data and what should be considered when analyzing such data at the metacell level. To facilitate the exploration of metacells, we provide a comprehensive tutorial on construction and analysis of metacells from single-cell RNA-seq data (https://github.com/GfellerLab/MetacellAnalysisTutorial) as well as a fully integrated pipeline to rapidly build, visualize and evaluate metacells with different methods (https://github.com/GfellerLab/MetacellAnalysisToolkit).

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“…Several mechanisms underpinning this plasticity have been proposed and more continue to be reported. These mechanisms-operational at multiple levels of biological organization-include protein feedback loops, adaptive mutations, and single-cell molecular variabilities [10][11][12][13][14][15][16] . One recently reported robustness mechanism is a type of transcriptional adaptation, wherein nonsense mutations, i.e., mutations that result in premature termination of protein synthesis, can remarkably trigger the transcription of related genes, including paralogs 14,15,[17][18][19] .…”

Section: Introductionmentioning

confidence: 99%

Prevalence of and gene regulatory constraints on transcriptional adaptation in single cells

Mellis

Bodkin²,

Goyal³

2023

Preprint

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Cells and tissues have a remarkable ability to adapt to genetic perturbations via a variety of molecular mechanisms. Nonsense-induced transcriptional compensation, a form of transcriptional adaptation, has recently emerged as one such mechanism, in which nonsense mutations in a gene can trigger upregulation of related genes, possibly conferring robustness at cellular and organismal levels. However, beyond a handful of developmental contexts and curated sets of genes, to date, no comprehensive genome-wide investigation of this behavior has been undertaken for mammalian cell types and contexts. Moreover, how the regulatory-level effects of inherently stochastic compensatory gene networks contribute to phenotypic penetrance in single cells remains unclear. Here we combine computational analysis of existing datasets with stochastic mathematical modeling and machine learning to uncover the widespread prevalence of transcriptional adaptation in mammalian systems and the diverse single-cell manifestations of minimal compensatory gene networks. Regulon gene expression analysis of a pooled single-cell genetic perturbation dataset recapitulates our model predictions. Our integrative approach uncovers several putative hits-genes demonstrating possible transcriptional adaptation-to follow up on experimentally, and provides a formal quantitative framework to test and refine models of transcriptional adaptation.

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Multiplex single-cell chemical genomics reveals the kinase dependence of the response to targeted therapy

Cited by 3 publications

References 90 publications

A heterogeneous pharmaco-transcriptomic landscape induced by targeting a single oncogenic kinase

A heterogeneous pharmaco-transcriptomic landscape induced by targeting a single oncogenic kinase

Building and analyzing metacells in single-cell genomics data

Prevalence of and gene regulatory constraints on transcriptional adaptation in single cells

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