Drug mechanism-of-action discovery through the integration of pharmacological and CRISPR screens

Gonçalvès, Emanuel; Segura‐Cabrera, Aldo; Pacini, Clare; Picco, Gabriele; Behan, Fiona M.; Jaaks, Patricia; Coker, Elizabeth A.; Meer, Dieudonne van der; Barthorpe, Andrew; Lightfoot, Howard; Team, Gdsc Screening; Leach, Andrew R.; Lynch, James T.; Sidders, Ben; Crafter, Claire; Iorio, Francesco; Garnett, Mathew J.

doi:10.1101/2020.01.14.905729

Cited by 31 publications

(52 citation statements)

References 61 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Future versions of CEN‐tools, and as more data becomes available, will integrate an analysis for confounding factors more directly. An option for this could be identifying associations between gene essentialities and a given context using a mixed effect linear model while considering defined set of contexts as covariates, an approach that has been used very recently for the identification of drug‐gene associations from essentiality screens (Gonçalves et al , 2020). Currently, to aid the users in interpreting the statistical associations we have included a number of confidence annotations.…”

Section: Discussionmentioning

confidence: 99%

CEN‐tools: an integrative platform to identify the contexts of essential genes

Sharma

Dinçer

Weidemüller

et al. 2020

Molecular Systems Biology

View full text Add to dashboard Cite

An emerging theme from large‐scale genetic screens that identify genes essential for cell fitness is that essentiality of a given gene is highly context‐specific. Identification of such contexts could be the key to defining gene function and also to develop novel therapeutic interventions. Here, we present Context‐specific Essentiality Network‐tools (CEN‐tools), a website and python package, in which users can interrogate the essentiality of a gene from large‐scale genome‐scale CRISPR screens in a number of biological contexts including tissue of origin, mutation profiles, expression levels and drug responses. We show that CEN‐tools is suitable for the systematic identification of genetic dependencies and for more targeted queries. The associations between genes and a given context are represented as dependency networks (CENs), and we demonstrate the utility of these networks in elucidating novel gene functions. In addition, we integrate the dependency networks with existing protein–protein interaction networks to reveal context‐dependent essential cellular pathways in cancer cells. Together, we demonstrate the applicability of CEN‐tools in aiding the current efforts to define the human cellular dependency map.

show abstract

Section: Discussionmentioning

confidence: 99%

CEN‐tools: an integrative platform to identify the contexts of essential genes

Sharma

Dinçer

Weidemüller

et al. 2020

Molecular Systems Biology

View full text Add to dashboard Cite

show abstract

“…Future versions of CEN-tools, and as more data becomes available, will integrate an analysis for confounding factors more directly. An option for this could be identifying associations between gene essentialities and a given context using a mixed effect linear model while considering defined set of contexts as covariates, an approach that has been used very recently for the identification of drug-gene associations from essentiality screens (Gonçalves et al, 2020). Currently, to aid the users in interpreting the statistical associations we have included a number of confidence annotations.…”

Section: Discussionmentioning

confidence: 99%

CEN-tools: An integrative platform to identify the ‘contexts’ of essential genes

Sharma

Dinçer

Weidemeueller

et al. 2020

Preprint

View full text Add to dashboard Cite

An emerging theme from large-scale genetic screens that identify genes essential for fitness of a cell, is that essentiality of a given gene is highly context-specific and depends on a number of genetic and environmental factors. Identification of such contexts could be the key to defining the function of the gene and also to develop novel therapeutic interventions. Here we present CEN-tools (Context-specific Essentiality Network-tools), a website and an accompanying python package, in which users can interrogate the essentiality of a gene from large-scale genome-scale CRISPR screens in a number of biological contexts including tissue of origin, mutation profiles, expression levels, and drug response levels. We show that CEN-tools is suitable for both the systematic identification of genetic dependencies as well as for targeted queries into the dependencies of specific user-selected genes. The associations between genes and a given context within CEN-tools are represented as dependency networks (CENs) and we demonstrate the utility of these networks in elucidating novel gene functions. In addition, we integrate the dependency networks with existing protein-protein interaction networks to reveal context-dependent essential cellular pathways in cancer cells. Together, we demonstrate the applicability of CEN-tools in aiding the current efforts to define the human cellular dependency map.

show abstract

“…Pharmacological and CRISPR screens are being increasingly integrated as a means to elucidate drug mechanism-of-action 28 . Here we used drug sensitivity analysis to compare the Recall of significant associations between a drug sensitivity profile and its nominal targets' CRISPR dependency profile, across cell lines.…”

Section: Comparisons Of Binary Dependency Matrices (Methods) From Thementioning

confidence: 99%

“…Thus, we systematically calculated Spearman's correlation between the dependency profile of a drug target across different pre-processing methods with the profile of cell line sensitivity to that drug. As indicators of drug sensitivity, we used viability reduction indicators (IC50 values) from two studies 29,30 for 307 unique compounds mapped to their targets 28 , across 486 cell lines included in our integrated datasets. Next we compared the resulting drug-response/target-dependency correlation patterns across pre-processing methods.…”

Section: Comparisons Of Binary Dependency Matrices (Methods) From Thementioning

confidence: 99%

Integrated cross-study datasets of genetic dependencies in cancer

Pacini

Dempster

Boyle

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

CRISPR-Cas9 viability screens are being increasingly performed at a genome-wide scale across large panels of cell lines to identify new therapeutic targets for precision cancer therapy. Integrating the datasets resulting from these studies is necessary to adequately represent the heterogeneity of human cancers, and to assemble a comprehensive map of cancer genetic vulnerabilities that might be exploited therapeutically. Here, we integrated the two largest independent CRISPR-Cas9 screens performed to date (at Broad and Sanger institutes), by assessing and selecting methods for correcting technology-specific biases and batch effects arising from differences in the underlying experimental protocols. Our integrated datasets recapitulate findings from the individual ones, provide larger statistical power allowing novel cancer-and subtype-specific analyses, unveil additional biomarkers of gene dependency, and improve the detection of common essential genes. Finally, we provide the largest integrated resources of CRISPR-Cas9 screens to date and the basis for harmonizing existing and future functional genetics datasets and assembling large cross-study cancer dependency maps.Cancer is a complex disease that can arise from multiple different genetic alterations.The alternative mechanisms by which cancer can evolve result in a large amount of heterogeneity between patients, with the vast majority of them still not benefiting from approved targeted therapies 1 . In order to identify and prioritize new potential therapeutic targets for precision cancer therapy, analyses of cancer vulnerabilities at a genome-wide scale and across large panels of in vitro cancer models are being increasingly performed 2-11 . This has been facilitated by recent advances in genome editing technologies allowing unprecedented precision and scale via CRISPR-Cas9 screens. To date, two large pan-cancer CRISPR-Cas9 screens have been independently performed by the Broad and Sanger institutes 2,12 . The two institutes have also joined forces in a collaborative endeavor with the aim of assembling a joint comprehensive map of all the intracellular genetic dependencies and vulnerabilities of cancer: the Cancer Dependency Map (DepMap) 13,14 .Despite the two generated datasets containing so far data from over 300 cell lines each, detecting all cancer dependencies has been estimated to require the analysis of thousands of cancer models 3 . Consequently, the integration of these two datasets will be key for the DepMap and other projects aiming at systematically probing cancer dependencies.This will provide a more comprehensive representation of heterogeneous cancer types as well as an increased sample size to support the use of statistical/machine-learning methods to identify molecular features associated with differential gene dependencies. This will form the basis for the development of effective new therapies with associated biomarkers for patient stratification 15 . Furthermore, designing robust standards and computational protocols for the integration of t...

show abstract

Drug mechanism-of-action discovery through the integration of pharmacological and CRISPR screens

Cited by 31 publications

References 61 publications

CEN‐tools: an integrative platform to identify the contexts of essential genes

CEN‐tools: an integrative platform to identify the contexts of essential genes

CEN-tools: An integrative platform to identify the ‘contexts’ of essential genes

Integrated cross-study datasets of genetic dependencies in cancer

Contact Info

Product

Resources

About