Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Zaritsky, Assaf; Jamieson, Andrew; Welf, Erik S.; Nevarez, Andres; Cillay, Justin; Eskiocak, Uğur; Cantarel, Brandi L.; Danuser, Gaudenz

doi:10.1101/2020.05.15.096628

Cited by 18 publications

(31 citation statements)

References 93 publications

(112 reference statements)

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“…Meanwhile, it has been shown that DL techniques can holistically capture complex structural features for classification. This has found broad applications in detecting cell types (12)(13)(14), cell states (15)(16)(17)(18)22), drug response (19), and stem cell lineage (20). By fully leveraging the label-free and high multiplexing nature of our technique, it can potentially generate significant impacts in imaging cytometry by offering unprecedented information content and discovering new compound morphological features necessitating multiplexed fluorescence readout.…”

Section: Discussionmentioning

confidence: 99%

“…By doing so, multiple subcellular structures and cell states can be revealed simultaneously without physical labeling. While previous work has shown that DL models can disentangle the complex structures captured in the label-free data and make in-silico fluorescence labeling with high accuracy (10)(11)(12) or holistically capture "hidden" structural features that are not easily perceived or described (13)(14)(15)(16)(17)(18)(19)(20)(21)(22), these results are fundamentally limited by the weak structural contrast from the transmission modes that contain only forward scattering information. By exploiting the enhanced resolution and sensitivity in the backscattering data, we demonstrate a dramatic increase in the fluorescence prediction accuracy with up to 3× improvement as compared to the current state-of-the-art.…”

Section: Introductionmentioning

confidence: 99%

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Single-cell cytometry via multiplexed fluorescence prediction by label-free reflectance microscopy

Cheng

Kim

et al. 2020

Preprint

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Traditional imaging cytometry uses fluorescence markers to identify specific structures, but is limited in throughput by the labeling process. Here we develop a label-free technique that alleviates the physical staining and provides highly multiplexed readout via a deep learning-augmented digital labeling method. We leverage the rich structural information and superior sensitivity in reflectance microscopy and show that digital labeling predicts highly accurate subcellular features after training on immunofluorescence images. We demonstrate up to 3× improvement in the prediction accuracy over the state-of-the-art. Beyond fluorescence prediction, we demonstrate that single-cell level structural phenotypes of cell cycles are correctly reproduced by the digital multiplexed images, including Golgi twins, Golgi haze during mitosis and DNA synthesis. We further show that the multiplexed readout enables accurate multi-parametric single-cell profiling across a large cell population. Our method can dramatically improve the throughput for imaging cytometry towards applications for phenotyping, pathology, and high-content screening.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Single-cell cytometry via multiplexed fluorescence prediction by label-free reflectance microscopy

Cheng

Kim

et al. 2020

Preprint

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“…We used self-supervised deep learning ( Figure 1E) to build an unbiased model of microglia morphology. Recent work has demonstrated that self-supervised learning with autoencoders (5,6) can provide a quantitative model of cell morphology informed by all of data.…”

Section: Learning a Latent Representation Of Morphology Thatmentioning

confidence: 99%

“…Recent work on analysis of morphological states of cells has relied on images of fixed cells labeled with a panel of fluorescent markers (1), live three-dimensional imaging of the membrane labeled with genetic markers (2), and phase contrast imaging of live cells (3)(4)(5)(6). The morphological states have been analyzed with low dimensional representations computed with geometric or biophysical models (3,(7)(8)(9)(10)(11), supervised learning of morphological labels (4,(12)(13)(14)(15)(16)(17), and, recently, self-supervised learning of latent representations of morphology (5,6). These analytical approaches have been inspired by the need for quantitative descriptions of specific, complex biological functions, such as motility of single cells (2,3,7,8,18), collective cell migration (9,11), cell cycle (4,12,13), spatial gene expression (17), and spatial protein expression (14,16).In addition, data-driven integration of the morphology and gene expression (13,17,(19)(20)(21)(22) is now enabling rapid analysis of functional roles of genes.…”

Section: Introductionmentioning

confidence: 99%

“…Microglia survey brain parenchyma with their highly motile processes and respond to changes in brain homeostasis by altering cell morphology and motility (26,27), but large-scale features of their dynamic behavior are not well characterized partly due to the lack of tractable molecular labeling tools. For other types of motile cells, either learned features or the manually curated features (3,5,6,18) have been used to describe complex cell dynamics, including random search, persistent migration towards target, changes in cell shape due to interaction with other cells and targets, and endocytosis, among others. However, changes in the expression of a small number of genes or morphological features of relevance to the other cell types may not reflect the full spectrum of microglia phenotypes and functions.…”

Section: Introductionmentioning

confidence: 99%

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DynaMorph: self-supervised learning of morphodynamic states of live cells

Chhun

Попова³

et al. 2020

Preprint

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Morphological states of human cells are widely imaged and analyzed to diagnose diseases and to discover biological mechanisms. Morphodynamics of cells capture their functions more fully than their morphology. Discovery of morphodynamic states of human cells is challenging, because genetic labeling or manual annotation may not be feasible. We propose a computational framework, DynaMorph, that combines quantitative label-free imaging and deep learning for automated discovery of morphodynamic states. As a case study, we apply DynaMorph to study the morphodynamic states of live primary human microglia, which are mobile immune cells of the brain that exhibit complex functional states. DynaMorph identifies two distinct morphodynamic states of microglia under perturbation by cytokines and glioblastoma supernatant. We find that microglia actively transition between the two states. Moreover, single-cell RNA-sequencing of the perturbed microglia shows that the morphodynamic states correspond to distinct transcriptomic clusters of the cells, revealing how perturbations alter gene expression and phenotype. DynaMorph can broadly enable automated discovery of functional states of cellular systems.

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Orientation-invariant autoencoders learn robust representations for shape profiling of cells and organelles

Burgess,

Nirschl,

Zanellati

et al. 2024

Nat Commun

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Cell and organelle shape are driven by diverse genetic and environmental factors and thus accurate quantification of cellular morphology is essential to experimental cell biology. Autoencoders are a popular tool for unsupervised biological image analysis because they learn a low-dimensional representation that maps images to feature vectors to generate a semantically meaningful embedding space of morphological variation. The learned feature vectors can also be used for clustering, dimensionality reduction, outlier detection, and supervised learning problems. Shape properties do not change with orientation, and thus we argue that representation learning methods should encode this orientation invariance. We show that conventional autoencoders are sensitive to orientation, which can lead to suboptimal performance on downstream tasks. To address this, we develop O2-variational autoencoder (O2-VAE), an unsupervised method that learns robust, orientation-invariant representations. We use O2-VAE to discover morphology subgroups in segmented cells and mitochondria, detect outlier cells, and rapidly characterise cellular shape and texture in large datasets, including in a newly generated synthetic benchmark.

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Interpretable deep learning of label-free live cell images uncovers functional hallmarks of highly-metastatic melanoma

Cited by 18 publications

References 93 publications

Single-cell cytometry via multiplexed fluorescence prediction by label-free reflectance microscopy

Single-cell cytometry via multiplexed fluorescence prediction by label-free reflectance microscopy

DynaMorph: self-supervised learning of morphodynamic states of live cells

Orientation-invariant autoencoders learn robust representations for shape profiling of cells and organelles

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