A Next Generation Connectivity Map: L1000 Platform and the First 1,000,000 Profiles

Subramanian, Aravind; Narayan, Rajiv; Corsello, Steven M.; Peck, Donald J.; Natoli, Ted; Lü, Xiaodong; Gould, Joshua; Davis, John F.; Tubelli, Andrew A.; Asiedu, Jacob K.; Lahr, David L.; Hirschman, Jodi E.; Liu, Zihan; Donahue, Melanie; Julian, Bina; Khan, Mariya; Wadden, David; Smith, Ian C. P.; Lam, Daniel D.; Liberzon, Arthur; Toder, Courtney; Bagul, Mukta; Orzechowski, Marek; Enache, Oana; Piccioni, Federica; Johnson, Sarah A.; Lyons, Nicholas; Berger, Alice H.; Shamji, Alykhan F.; Brooks, Angela N.; Vrcic, Anita; Flynn, Corey; Rosains, Jacqueline; Takeda, David Y.; Hu, Roger; Davison, Desiree; Lamb, Justin; Ardlie, Kristin; Hogstrom, Larson; Greenside, Peyton G.; Gray, Nathanael S.; Clemons, Paul A.; Silver, Serena J.; Wu, Xiaoyun; Zhao, Wen-Ning; Read-Button, Willis; Wu, Xiaohua; Haggarty, Stephen J.; Ronco, Lucienne; Boehm, Jesse S.; Schreiber, Stuart L.; Doench, John G.; Bittker, Joshua A.; Root, David E.; Wong, Bang; Golub, Todd R.

doi:10.1016/j.cell.2017.10.049

Cited by 2,478 publications

(2,500 citation statements)

References 53 publications

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“…A simple alternative to performing random composite measurements is using the training phase to select a set of individual “signature genes” for measurements (Biswas et al, 2016; Donner et al, 2012; Peck et al, 2006; Subramanian et al, 2017), along with learning a model to predict the remaining genes from this measured set.…”

Section: Resultsmentioning

confidence: 99%

“…In some cases, a limited subset (“signature”) of genes can be identified, which, when measured in new samples, can be used together with the earlier profiling data to estimate the abundance of the remaining unmeasured (unobserved) genes in these new samples (Biswas et al, 2016; Donner et al, 2012; Peck et al, 2006; Subramanian et al, 2017). With the recent advent of massively parallel single-cell RNA-Seq, shallow RNA-Seq data is often used for each cell to draw inferences about the full expression profile and to recover meaningful biological distinctions on cell type (Jaitin et al, 2014; Shekhar et al, 2016) and state (Paul et al, 2015; Shalek et al, 2013, 2014).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Efficient Generation of Transcriptomic Profiles by Random Composite Measurements

Cleary

Cong

Cheung

et al. 2017

Cell

111

100

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Summary RNA profiles are an informative phenotype of cellular and tissue states, but can be costly to generate at massive scale. Here, we describe how gene expression levels can be efficiently acquired with random composite measurements – in which abundances are combined in a random weighted sum. We show that the similarity between pairs of expression profiles can be approximated with very few composite measurements; that by leveraging sparse, modular representations of gene expression we can use random composite measurements to recover high-dimensional gene expression levels (with 100 times fewer measurements than genes); and that it is possible to blindly recover gene expression from composite measurements, even without access to training data. Our results suggest new compressive modalities as a foundation for massive scaling in high-throughput measurements, and new insights into the interpretation of high-dimensional data.

show abstract

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Efficient Generation of Transcriptomic Profiles by Random Composite Measurements

Cleary

Cong

Cheung

et al. 2017

Cell

111

100

View full text Add to dashboard Cite

show abstract

“…Fortunately, many of these challenges have been overcome largely by the pioneering work by a collaborative effort of the Broad Institute and funding from a National Institutes of Health Common Fund (https://commonfund.nih.gov/lincs). They have compiled the Library of Integrated Network-based Cellular Signatures (LINCS-L1000) database which contains gene expression responses to genetic and pharmacologic manipulation across a diverse set of human cell lines (Subramanian et al 2017). They also maintain a repurposing hub that contains over 5,000 manually-curated drugs that are either FDA approved or in clinical trials (Corsello et al 2017).…”

Section: Computational Approachesmentioning

confidence: 99%

“…However, for larger datasets, such as LINCS-L1000, implementation of permutations tests becomes computationally expensive and less straightforward. Currently, the web app for querying the LINCS-L1000 data (https://clue.io/l1000-query) uses the “sig_gutc” tool (Subramanian et al 2017) to summarize the connectivity scores and provide a measure of reliability. Each compound has been profiled under multiple experimental conditions (different cell lines, drug doses, and exposure time points).…”

Section: Computational Approachesmentioning

confidence: 99%

“…To compare the disease and drug signatures the KS-like statistic (as described by (Lamb et al 2006; Subramanian et al 2017) is the most frequently used similarity metric, although several studies also use Spearman or Pearson correlation coefficients (Azim et al 2017; Siavelis et al 2016; So et al 2017) or Fischer’s Exact Test (Delahaye-Duriez et al 2016). Most studies operate under the transcriptional “reversal hypothesis”, which assumes that drugs with negative connectivity scores (i.e., with gene expression signatures that revert the disease’s effects on gene expression to the control state) would ameliorate disease phenotype.…”

Section: Application To Brain Diseasesmentioning

confidence: 99%

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From gene networks to drugs: systems pharmacology approaches for AUD

2018

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The alcohol research field has amassed an impressive number of gene expression datasets spanning key brain areas for addiction, species (humans as well as multiple animal models), and stages in the addiction cycle (binge/intoxication, withdrawal/negative effect, and preoccupation/anticipation). These data have improved our understanding of the molecular adaptations that eventually lead to dysregulation of brain function and the chronic, relapsing disorder of addiction. Identification of new medications to treat alcohol use disorder (AUD) will likely benefit from the integration of genetic, genomic, and behavioral information included in these important datasets. Systems pharmacology considers drug effects as the outcome of the complex network of interactions a drug has rather than a single drug-molecule interaction. Computational strategies based on this principle that integrate gene expression signatures of pharmaceuticals and disease states have shown promise for identifying treatments that ameliorate disease symptoms (called in silico gene mapping or connectivity mapping). In this review, we suggest that gene expression profiling for in silico mapping is critical to improve drug repurposing and discovery for AUD and other psychiatric illnesses. We highlight studies that successfully apply gene mapping computational approaches to identify or repurpose pharmaceutical treatments for psychiatric illnesses. Furthermore, we address important challenges that must be overcome to maximize the potential of these strategies to translate to the clinic and improve healthcare outcomes.

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Experiences in Academic and Industry Partnerships – Forging a Path to Translational Drug Discovery

Dolle

Barrault²,

Carragher³

et al. 2021

Burger's Medicinal Chemistry and Drug Discovery

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A Next Generation Connectivity Map: L1000 Platform and the First 1,000,000 Profiles

Cited by 2,478 publications

References 53 publications

Efficient Generation of Transcriptomic Profiles by Random Composite Measurements

Efficient Generation of Transcriptomic Profiles by Random Composite Measurements

From gene networks to drugs: systems pharmacology approaches for AUD

Experiences in Academic and Industry Partnerships – Forging a Path to Translational Drug Discovery

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