SCODE: an efficient regulatory network inference algorithm from single-cell RNA-Seq during differentiation

Matsumoto, Hirotaka; Kiryu, Hisanori; Furusawa, Chikara; Ko, Minoru S.H.; Ko, Shigeru B. H.; Gouda, Norio; Hayashi, Tetsutaro; Nikaido, Itoshi

doi:10.1093/bioinformatics/btx194

Cited by 335 publications

(352 citation statements)

References 44 publications

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“…Inferring gene regulatory relationships is related to the detection of trajectory-associated regulatory genes. Indeed, several single-cell GRN inference methods use trajectories with mechanistic differential equation models (Ocone et al, 2015;Matsumoto et al, 2017).…”

Section: Gene Regulatory Networkmentioning

confidence: 99%

“…While there exist GRN inference methods that were specifically developed for scRNA-seq data (SCONE: Matsumoto et al, 2017;PIDC: Chan et al, 2017;SCENIC: Aibar et al, 2017), a recent comparison has shown both bulk and single-cell methods to perform poorly on these data (Chen & Mar, 2018). GRN inference methods may still offer valuable insights to identify causal regulators of biological processes, yet we recommend that these methods be used with care.…”

Section: Gene Regulatory Networkmentioning

confidence: 99%

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Current best practices in single‐cell RNA‐seq analysis: a tutorial

Luecken

Theis

2019

Molecular Systems Biology

1,443

1,386

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Single‐cell RNA ‐seq has enabled gene expression to be studied at an unprecedented resolution. The promise of this technology is attracting a growing user base for single‐cell analysis methods. As more analysis tools are becoming available, it is becoming increasingly difficult to navigate this landscape and produce an up‐to‐date workflow to analyse one's data. Here, we detail the steps of a typical single‐cell RNA ‐seq analysis, including pre‐processing (quality control, normalization, data correction, feature selection, and dimensionality reduction) and cell‐ and gene‐level downstream analysis. We formulate current best‐practice recommendations for these steps based on independent comparison studies. We have integrated these best‐practice recommendations into a workflow, which we apply to a public dataset to further illustrate how these steps work in practice. Our documented case study can be found at https://www.github.com/theislab/single-cell-tutorial . This review will serve as a workflow tutorial for new entrants into the field, and help established users update their analysis pipelines.

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Section: Gene Regulatory Networkmentioning

confidence: 99%

Section: Gene Regulatory Networkmentioning

confidence: 99%

Current best practices in single‐cell RNA‐seq analysis: a tutorial

Luecken

Theis

2019

Molecular Systems Biology

1,443

1,386

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“…For this reason, most algorithms require the user to provide a starting position, for example, if the dynamic process involves differentiation, a cell at a pluripotent stage would be chosen as a starting point. Other approaches used for finding such curve are Gaussian Processes and Differential Equations (21)(22)(23).…”

Section: Ti Frameworkmentioning

confidence: 99%

Learning Pathway Dynamics from Single‐Cell Proteomic Data: A Comparative Study

2020

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Single‐cell platforms provide statistically large samples of snapshot observations capable of resolving intrercellular heterogeneity. Currently, there is a growing literature on algorithms that exploit this attribute in order to infer the trajectory of biological mechanisms, such as cell proliferation and differentiation. Despite the efforts, the trajectory inference methodology has not yet been used for addressing the challenging problem of learning the dynamics of protein signaling systems. In this work, we assess this prospect by testing the performance of this class of algorithms on four proteomic temporal datasets. To evaluate the learning quality, we design new general‐purpose evaluation metrics that are able to quantify performance on (i) the biological meaning of the output, (ii) the consistency of the inferred trajectory, (iii) the algorithm robustness, (iv) the correlation of the learning output with the initial dataset, and (v) the roughness of the cell parameter levels though the inferred trajectory. We show that experimental time alone is insufficient to provide knowledge about the order of proteins during signal transduction. Accordingly, we show that the inferred trajectories provide richer information about the underlying dynamics. We learn that established methods tested on high‐dimensional data with small sample size, slow dynamics, and complex structures (e.g. bifurcations) cannot always work in the signaling setting. Among the methods we evaluate, Scorpius and a newly introduced approach that combines Diffusion Maps and Principal Curves were found to perform adequately in recovering the progression of signal transduction although their performance on some metrics varies from one dataset to another. The novel metrics we devise highlight that it is difficult to conclude, which one method is universally applicable for the task. Arguably, there are still many challenges and open problems to resolve. © 2020 The Authors. Cytometry Part A published by Wiley Periodicals, Inc. on behalf of International Society for Advancement of Cytometry.

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“…As was discussed in the section 'Approaches modelling gradual transitions', cells can be ordered along developmental trajectories. Some network inference methods can include the information from these inferred trajectories to reconstruct dynamic regulatory networks (AR1MA1 [117], SCODE [118]). Another source of external information could come from perturbational studies, in which genes are knocked out and the consequences on the transcriptome can be observed [21].…”

Section: Network Inferencementioning

confidence: 99%

Computational approaches for high‐throughput single‐cell data analysis

Todorov

Saeys

2018

The FEBS Journal

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During the past decade, the number of novel technologies to interrogate biological systems at the single-cell level has skyrocketed. Numerous approaches for measuring the proteome, genome, transcriptome and epigenome at the single-cell level have been pioneered, using a variety of technologies. All these methods have one thing in common: they generate large and high-dimensional datasets that require advanced computational modelling tools to highlight and interpret interesting patterns in these data, potentially leading to novel biological insights and hypotheses. In this work, we provide an overview of the computational approaches used to interpret various types of single-cell data in an automated and unbiased way.

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SCODE: an efficient regulatory network inference algorithm from single-cell RNA-Seq during differentiation

Cited by 335 publications

References 44 publications

Current best practices in single‐cell RNA‐seq analysis: a tutorial

Current best practices in single‐cell RNA‐seq analysis: a tutorial

Learning Pathway Dynamics from Single‐Cell Proteomic Data: A Comparative Study

Computational approaches for high‐throughput single‐cell data analysis

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