Learning the rules of collective cell migration using deep attention networks

LaChance, Julienne; Suh, Kevin; Clausen, J. V.; Cohen, Daniel

doi:10.1371/journal.pcbi.1009293

Cited by 18 publications

(6 citation statements)

References 54 publications

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“…Training was done with the same hyperparameters as Lachance et al(2022). Training was performed on the Oxford Advanced Research Computing cluster using five 48-core Cascade Lake (Intel Xeon Platinum 8268 CPU @ 2.90GHz) nodes.…”

Section: Methodsmentioning

confidence: 99%

Identification of Neural Crest and Neural Crest-Derived Cancer Cell Invasion and Migration Genes Using High-throughput Screening and Deep Attention Networks

Kasemeier-Kulesa,

Martina Perez,

Baker

et al. 2024

Preprint

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Background: Cell migration and invasion are well-coordinated processes in development and disease but remain poorly understood. We previously showed that highly migratory neural crest (NC) cells share a 45-gene panel with other cell invasion phenomena, including cancer. To identify critical genes of the 45-gene panel, we performed a high-throughput siRNA screen and used statistical and deep learning methods to compare NC- versus non-NC-derived human cell lines. Results: We find 14 out of 45 genes significantly reduces c8161 melanoma cell migration; only 4 are shared with HT1080 fibrosarcoma cells (BMP4, ITGB1, KCNE3, RASGRP1). Deep learning attention network analysis identified distinct cell-cell interaction patterns and significant alterations after BMP4 or RASGRP1 knockdown in c8161 cells. Addition of recombinant proteins to the culture media identified 5 out of the 10 known secreted molecules stimulate c8161 cell migration, including BMP4. BMP4 siRNA knockdown inhibited c8161 cell invasion in vivo and in vitro; however, its addition to the culture media rescued c8161 cell invasion. Conclusion: A high-throughput screen and deep learning rapidly distilled a 45-gene panel to a small subset of genes that appear critical to melanoma cell invasion and warrant deeper in vivo functional analysis for their role in driving the neural crest.

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Section: Methodsmentioning

confidence: 99%

Identification of Neural Crest and Neural Crest-Derived Cancer Cell Invasion and Migration Genes Using High-throughput Screening and Deep Attention Networks

Kasemeier-Kulesa,

Martina Perez,

Baker

et al. 2024

Preprint

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“…To test the potential symmetries of cell-cell interactions, a data-driven approach for cells in 2D monolayers using attention neural networks was recently proposed [329] (figures 9(M) and (N)). This approach detects how predictive the behaviour of neighbouring cells is for the behaviour of a given cell.…”

Section: From Cell Pairs To Collective Migrationmentioning

confidence: 99%

Learning dynamical models of single and collective cell migration: a review

Brückner,

Broedersz

2024

Rep. Prog. Phys.

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Single and collective cell migration are fundamental processes critical for physiological phenomena ranging from embryonic development and immune response to wound healing and cancer metastasis. To understand cell migration from a physical perspective, a broad variety of models for the underlying physical mechanisms that govern cell motility have been developed. A key challenge in the development of such models is how to connect them to experimental observations, which often exhibit complex stochastic behaviours. In this review, we discuss recent advances in data-driven theoretical approaches that directly connect with experimental data to infer dynamical models of stochastic cell migration. Leveraging advances in nanofabrication, image analysis, and tracking technology, experimental studies now provide unprecedented large datasets on cellular dynamics. In parallel, theoretical efforts have been directed towards integrating such datasets into physical models from the single cell to the tissue scale with the aim of conceptualizing the emergent behaviour of cells. We first review how this inference problem has been addressed in both freely migrating and confined cells. Next, we discuss why these dynamics typically take the form of underdamped stochastic equations of motion, and how such equations can be inferred from data. We then review applications of data-driven inference and machine learning approaches to heterogeneity in cell behaviour, subcellular degrees of freedom, and to the collective dynamics of multicellular systems. Across these applications, we emphasize how data-driven methods can be integrated with physical active matter models of migrating cells, and help reveal how underlying molecular mechanisms control cell behaviour. Together, these data-driven approaches are a promising avenue for building physical models of cell migration directly from experimental data, and for providing conceptual links between different length-scales of description.

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“…There is no Navier–Stokes equation rushing to the rescue and one can therefore naturally wonder whether hand-crafted models ( 33 , 34 ) could perhaps be usefully replaced by purely data-driven ones. This question is being actively investigated for a number of experimental cell motility systems ( 35 , 36 ) and of course is under intense study in many biomedical contexts, see e.g. work on digital pathology ( 37 ).…”

Section: The Spreading Of MLmentioning

confidence: 99%

Machine learning meets physics: A two-way street

Levine,

2024

Proc. Natl. Acad. Sci. U.S.A.

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Learning the rules of collective cell migration using deep attention networks

Cited by 18 publications

References 54 publications

Identification of Neural Crest and Neural Crest-Derived Cancer Cell Invasion and Migration Genes Using High-throughput Screening and Deep Attention Networks

Identification of Neural Crest and Neural Crest-Derived Cancer Cell Invasion and Migration Genes Using High-throughput Screening and Deep Attention Networks

Learning dynamical models of single and collective cell migration: a review

Machine learning meets physics: A two-way street

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