The cornucopia of meaningful leads: Applying deep adversarial autoencoders for new molecule development in oncology

Kadurin, Artur; Aliper, Alexander; Kazennov, Andrey; Mamoshina, Polina; Vanhaelen, Quentin; Khrabrov, Kuzma; Zhavoronkov, Alex

doi:10.18632/oncotarget.14073

Cited by 285 publications

(225 citation statements)

References 30 publications

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“…10,11 For instance, a recent group trained adversarial autoencoders on chemical compound structures and their growth inhibiting effects in cancer cell lines to learn manifold spaces of effective small molecule drugs. 12,13 Additionally, Rampasek et al trained a VAE to learn a gene expression manifold of reactions of cancer cell lines to drug treatment perturbation. 14 The theoretical basis for modeling cancer using lower dimensional manifolds is established, as it has been previously hypothesized that cancer exists in "basins of attraction" defined by specific pathway aberrations that drive cells toward cancer states.…”

Section: Introductionmentioning

confidence: 99%

Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders

2017

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The Cancer Genome Atlas (TCGA) has profiled over 10,000 tumors across 33 different cancertypes for many genomic features, including gene expression levels. Gene expression measurements capture substantial information about the state of each tumor. Certain classes of deep neural network models are capable of learning a meaningful latent space. Such a latent space could be used to explore and generate hypothetical gene expression profiles under various types of molecular and genetic perturbation. For example, one might wish to use such a model to predict a tumor's response to specific therapies or to characterize complex gene expression activations existing in differential proportions in different tumors. Variational autoencoders (VAEs) are a deep neural network approach capable of generating meaningful latent spaces for image and text data. In this work, we sought to determine the extent to which a VAE can be trained to model cancer gene expression, and whether or not such a VAE would capture biologically-relevant features. In the following report, we introduce a VAE trained on TCGA pan-cancer RNA-seq data, identify specific patterns in the VAE encoded features, and discuss potential merits of the approach. We name our method "Tybalt" after an instigative, cat-like character who sets a cascading chain of events in motion in Shakespeare's "Romeo and Juliet". From a systems biology perspective, Tybalt could one day aid in cancer stratification or predict specific activated expression patterns that would result from genetic changes or treatment effects.

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Section: Introductionmentioning

confidence: 99%

Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders

2017

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“…The renaissance of deep learning that started in 2015 resulted in unprecedented machine learning performance in image, voice, and text recognition, as well as a range of biomedical applications 29 such as drug repurposing 30 and target identification 31 . One of the most impactful applications of DL in biomedicine was in the applications of generative models to de novo molecular design [32][33][34][35][36] . In the context of aging research, these new methods can be combined for geroprotector discovery [37][38][39][40][41] .…”

Section: Introductionmentioning

confidence: 99%

Human microbiome aging clocks based on deep learning and tandem of permutation feature importance and accumulated local effects

Galkin

Aliper

Putin

et al. 2018

Preprint

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The human gut microbiome is a complex ecosystem that both affects and is affected by its host status. Previous analyses of gut microflora revealed associations between specific microbes and host health and disease status, genotype and diet. Here, we developed a method of predicting biological age of the host based on the microbiological profiles of gut microbiota using a curated dataset of 1,165 healthy individuals (3,663 microbiome samples). Our predictive model, a human microbiome clock, has an architecture of a deep neural network and achieves the accuracy of 3.94 years mean absolute error in cross-validation. The performance of the deep microbiome clock was also evaluated on several additional populations. We further introduce a platform for biological interpretation of individual microbial features used in age models, which relies on permutation feature importance and accumulated local effects. This approach has allowed us to define two lists of 95 intestinal biomarkers of human aging. We further show that this list can be reduced to 39 taxa that convey the most information on their host's aging. Overall, we show that (a) microbiological profiles can be used to predict human age; and (b) microbial features selected by models are age-related.

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“…This in turn provides an opportunity to study genome-wide interactions in ways that may be computationally intractable using traditional statistical modeling approaches. Indeed, to date, deep learning have been used to generate photo-realistic cell images [3], learn functional representations of neural in-situ hybridization images [4], to predict novel drug targets [5,6,7,8], and to model the hierarchical structure and function of the cell [9]. Recently, VAE methods have also been shown to learn biologically-relevant latent representations of tumors using genome-scale gene expression [10] and DNA methylation data11.…”

Section: Introductionmentioning

confidence: 99%

Unsupervised deep learning with variational autoencoders applied to breast tumor genome-wide DNA methylation data with biologic feature extraction

Titus

Wilkins

Bobak

et al. 2018

Preprint

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Recent advances in deep learning, particularly unsupervised approaches, have shown promise for furthering our biological knowledge through their application to gene expression datasets, though applications to epigenomic data are lacking. Here, we employ an unsupervised deep learning framework with variational autoencoders (VAEs) to learn latent representations of the DNA methylation landscape from three independent breast tumor datasets. Through interrogation of methylation-based learned latent dimension activation values, we demonstrate the feasibility of VAEs to track representative differential methylation patterns among clinical subtypes of tumors. CpGs whose methylation was most correlated VAE latent dimension activation values were significantly enriched for CpG sparse regulatory regions of the genome including enhancer regions. In addition, through comparison with LASSO, we show the utility of the VAE approach for revealing novel information about CpG DNA methylation patterns in breast cancer.

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The cornucopia of meaningful leads: Applying deep adversarial autoencoders for new molecule development in oncology

Cited by 285 publications

References 30 publications

Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders

Extracting a biologically relevant latent space from cancer transcriptomes with variational autoencoders

Human microbiome aging clocks based on deep learning and tandem of permutation feature importance and accumulated local effects

Unsupervised deep learning with variational autoencoders applied to breast tumor genome-wide DNA methylation data with biologic feature extraction

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