GEESE: Metabolically driven latent space learning for gene expression data

Barsacchi, Marco; Andrés-Terré, Helena; Lió, Píetro

doi:10.1101/365643

Cited by 5 publications

(2 citation statements)

References 26 publications

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“…Moreover, metabolism and GSMMs can be used as a basis to understand underlying genomic variation. The Gene Expression Latent Space Encoder (GEESE) is a recently proposed approach [92] in which transcriptomic information is fed into a deep generative model (specifically, a variational autoencoder) combined with a GSMM. Initially, gene expression data is provided as an input to the autoencoder, returning reconstructed gene expression vectors that are then used to train an FBA approximator.…”

Section: Unsupervised Multiomic Analysismentioning

confidence: 99%

Machine and deep learning meet genome-scale metabolic modeling

et al. 2019

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Omic data analysis is steadily growing as a driver of basic and applied molecular biology research. Core to the interpretation of complex and heterogeneous biological phenotypes are computational approaches in the fields of statistics and machine learning. In parallel, constraint-based metabolic modeling has established itself as the main tool to investigate large-scale relationships between genotype, phenotype, and environment. The development and application of these methodological frameworks have occurred independently for the most part, whereas the potential of their integration for biological, biomedical, and biotechnological research is less known. Here, we describe how machine learning and constraint-based modeling can be combined, reviewing recent works at the intersection of both domains and discussing the mathematical and practical aspects involved. We overlap systematic classifications from both frameworks, making them accessible to nonexperts. Finally, we delineate potential future scenarios, propose new joint theoretical frameworks, and suggest concrete points of investigation for this joint subfield. A multiview approach merging experimental and knowledge-driven omic data through machine learning methods can incorporate key mechanistic information in an otherwise biologically-agnostic learning process.

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Section: Unsupervised Multiomic Analysismentioning

confidence: 99%

Machine and deep learning meet genome-scale metabolic modeling

et al. 2019

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“…Several strategies have been developed to characterize the geometry of the flux cone, many of which involve random sampling or computation of geometric properties such as extreme pathways or elementary flux modes 1 . Recent years have witnessed a growing interest in the use of machine learning in tandem with GEMs 11,16 , particularly for improving phenotype predictions 20,21 , enrich the quality of metabolic models 22,23 , or interpreting gene expression data 24 .…”

Section: Discussionmentioning

confidence: 99%

Low-dimensional representations of genome-scale metabolism

Cain,

Merzbacher,

Oyarzún

2024

Preprint

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Cellular metabolism is a highly interconnected network with thousands of reactions that convert nutrients into the molecular building blocks of life. Metabolic connectivity varies greatly with cellular context and environmental conditions, and it remains a challenge to compare genome-scale metabolism across cell types because of the high dimensionality of the reaction flux space. Here, we employ self-supervised learning and genome-scale metabolic models to compress the flux space into low-dimensional representations that preserve structure across cell types. We trained variational autoencoders (VAEs) on large fluxomic data (N= 800, 000) sampled from patient-derived models for various cancer cell types. The VAE embeddings have an improved ability to distinguish cell types than the uncompressed fluxomic data, and sufficient predictive power to classify cell types with high accuracy. We tested the ability of these classifiers to assign cell type identities to unlabelled patient-derived metabolic models not employed during VAE training. We further employed the pre-trained VAE to embed another 38 cell types and trained multilabel classifiers that display promising generalization performance. Our approach distils the metabolic space into a semantically rich vector that can be used as a foundation for predictive modelling, clustering or comparing metabolic capabilities across organisms.

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