Genetic program activity delineates risk, relapse, and therapy responsiveness in Multiple Myeloma

Wall, Matthew A.; Turkarslan, Serdar; Wu, Wei-Ju; Danziger, Samuel A.; Reiss, David J; Mason, Mike J.; Dervan, Andrew; Trotter, Matthew; Bassett, Douglas E.; Hershberg, Robert M.; Lomana, Adrián López García de; Ratushny, Alexander V.; Baliga, Nitin S.

doi:10.1101/2020.04.01.012351

Cited by 3 publications

(5 citation statements)

References 77 publications

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“…Regulons are identified, in part, by performing PCA on the normalized scRNA-seq data profiles to identify principal components in which decreasing amounts of variation across genes are captured along each principal component – defined as a linear combination of gene expression values. This linear combination of weighted gene expression values defines the eigengene value per sample ( 41 , 42 , 86 , 87 ). Alternatively, the eigengene is defined as the first principal component of the module expression matrix composed of expression values of regulon genes across samples.…”

Section: Methodsmentioning

confidence: 99%

“…To infer regulons within single cells, we applied the MINER ( 86 ) workflow to the SN520 and SN503 scRNA-seq data sets independently. As part of the scSYGNAL framework, the MINER algorithm involves a suite of functions that enables the inference of causal mechanistic relationships linking genetic mutations to transcriptional regulation.…”

Section: Methodsmentioning

confidence: 99%

“…We applied single-cell SYstems Genetics Network AnaLysis (scSYGNAL) framework to uncover the transcriptional regulatory networks (TRNs, (43,44)) responsible for driving the distinct transcriptome responses of the two PD-GSCs. Briefly, Mechanistic Inference of Node Edge Relationships (MINER), an algorithm within the scSYGNAL framework, was used to identify modules of genes (regulons) that were co-regulated differentially in response to treatment across sub-populations of cells (45,46). Further, using the transcription factor binding site database (47) and the Framework for Inference of Regulation by miRNAs (FIRM, (48)), scSYGNAL implicated specific TFs and miRNAs in mechanistically co-regulating genes of all regulons.…”

Section: Inference and Simulation Of The Dynamics Of Transcriptional ...mentioning

confidence: 99%

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Gene regulatory network topology governs resistance and treatment escape in glioma stem-like cells

Park,

Hothi,

Garcia de Lomana

et al. 2024

Preprint

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Poor prognosis and drug resistance in glioblastoma (GBM) can result from cellular heterogeneity and treatment-induced shifts in phenotypic states of tumor cells, including dedifferentiation into glioma stem-like cells (GSCs). This rare tumorigenic cell subpopulation resists temozolomide, undergoes proneural-to-mesenchymal transition (PMT) to evade therapy, and drives recurrence. Through inference of transcriptional regulatory networks (TRNs) of patient-derived GSCs (PD-GSCs) at single-cell resolution, we demonstrate how the topology of transcription factor interaction networks drives distinct trajectories of cell state transitions in PD-GSCs resistant or susceptible to cytotoxic drug treatment. By experimentally testing predictions based on TRN simulations, we show that drug treatment drives surviving PD-GSCs along a trajectory of intermediate states, exposing vulnerability to potentiated killing by siRNA or a second drug targeting treatment-induced transcriptional programs governing non-genetic cell plasticity. Our findings demonstrate an approach to uncover TRN topology and use it to rationally predict combinatorial treatments that disrupts acquired resistance in GBM.TeaserGene regulatory networks drive glioma stem-like cell drug response and drug-induced cell-state transitions leading to resistance.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Inference and Simulation Of The Dynamics Of Transcriptional ...mentioning

confidence: 99%

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Gene regulatory network topology governs resistance and treatment escape in glioma stem-like cells

Park,

Hothi,

Garcia de Lomana

et al. 2024

Preprint

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“…Our analysis revealed the mechanistic co-regulation of 809 genes across 160 regulons by at least 65 TFs and 141 miRNAs (Supplementary Tables 3, 4). Subsequent analysis via Mining for Node Edge Relationships (MINER) algorithm 13 revealed a subset of 93 significant regulons that included 52 nonredundant TFs regulating 454 target genes (Methods, Supplementary Tables 3, 4). Of the 52 TFs identified, 33 TFs (63.4%, p value = 0.009) have been reported to play biologically meaningful roles in GBM 12,14 , indicating that the single-cell-level network analysis had identified GBM-relevant regulatory mechanisms (Supplementary Table 5).…”

Section: Modeling Frameworkmentioning

confidence: 99%

“…To infer regulons within single cells, we applied the SYGNAL 12 and MINER 13 workflow to the snRNA-seq dataset resulting from the Batch Integration procedure described above. The MINER algorithm involves a suite of functions that enables the inference of causal mechanistic relationships linking genetic mutations to transcriptional regulation.…”

Section: Regulatory Network Analysismentioning

confidence: 99%

A single-cell based precision medicine approach using glioblastoma patient-specific models

et al. 2022

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Glioblastoma (GBM) is a heterogeneous tumor made up of cell states that evolve over time. Here, we modeled tumor evolutionary trajectories during standard-of-care treatment using multi-omic single-cell analysis of a primary tumor sample, corresponding mouse xenografts subjected to standard of care therapy, and recurrent tumor at autopsy. We mined the multi-omic data with single-cell SYstems Genetics Network AnaLysis (scSYGNAL) to identify a network of 52 regulators that mediate treatment-induced shifts in xenograft tumor-cell states that were also reflected in recurrence. By integrating scSYGNAL-derived regulatory network information with transcription factor accessibility deviations derived from single-cell ATAC-seq data, we developed consensus networks that modulate cell state transitions across subpopulations of primary and recurrent tumor cells. Finally, by matching targeted therapies to active regulatory networks underlying tumor evolutionary trajectories, we provide a framework for applying single-cell-based precision medicine approaches to an individual patient in a concurrent, adjuvant, or recurrent setting.

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A single-cell based precision medicine approach using glioblastoma patient-specific models

Park

Feroze

Emerson

et al. 2021

Preprint

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Glioblastoma (GBM) is a heterogeneous tumor made up of cell states that evolve over time. Here, we modeled tumor evolutionary trajectories during standard-of-care treatment using multimodal single-cell analysis of a primary tumor sample, corresponding mouse xenografts subjected to standard of care therapy, and recurrent tumor at autopsy. We mined the multimodal data with single cell SYstems Genetics Network AnaLysis (scSYGNAL) to identify a network of 52 regulators that mediate treatment-induced shifts in xenograft tumor-cell states that were also reflected in recurrence. By integrating scSYGNAL-derived regulatory network information with transcription factor accessibility deviations derived from single-cell ATAC-seq data, we developed consensus networks that regulate subpopulations of primary and recurrent tumor cells. Finally, by matching targeted therapies to active regulatory networks underlying tumor evolutionary trajectories, we provide a framework for applying single-cell-based precision medicine approaches in a concurrent, neo-adjuvant, or recurrent setting.SummaryInference of mechanistic drivers of therapy-induced evolution of glioblastoma at single cell resolution using RNA-seq and ATAC-seq from patient samples and model systems undergoing standard-of-care treatment informs strategy for identification of tumor evolutionary trajectories and possible cell state-directed therapeutics.

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Genetic program activity delineates risk, relapse, and therapy responsiveness in Multiple Myeloma

Cited by 3 publications

References 77 publications

Gene regulatory network topology governs resistance and treatment escape in glioma stem-like cells

Gene regulatory network topology governs resistance and treatment escape in glioma stem-like cells

A single-cell based precision medicine approach using glioblastoma patient-specific models

A single-cell based precision medicine approach using glioblastoma patient-specific models

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