scGraph: a graph neural network-based approach to automatically identify cell types

Yin, Qijin; Li, Qiao; Fu, Zhuoran; Zeng, Wanwen; Zhang, Boheng; Zhang, Xuegong; Jiang, Rui; Lv, Hairong

doi:10.1093/bioinformatics/btac199

Cited by 16 publications

(4 citation statements)

References 40 publications

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“…In recent years, deep learning frameworks based on various of graph neural networks such as graph convolutional network (GCNs) [33], graph attention networks (GATs) [34], gated graph neural networks (GGNNs) [35] and residual gated graph convolutional network [36] have demonstrated ground-breaking performance on social science, natural science, knowledge graphs and many other research areas [37][38][39]. In particular, GCNs have been applied to various biochemical problems such as molecular properties prediction [40], molecular generation, protein function prediction [41].…”

Section: Introductionmentioning

confidence: 99%

DeepDrug: A general graph‐based deep learning framework for drug‐drug interactions and drug‐target interactions prediction

Yin,

Fan,

Cao

et al. 2023

Quant. Biol.

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Background: Computational approaches for accurate prediction of drug interactions, such as drugdrug interactions (DDIs) and drug-target interactions (DTIs), are highly demanded for biochemical researchers. Despite the fact that many methods have been proposed and developed to predict DDIs and DTIs respectively, their success is still limited due to a lack of systematic evaluation of the intrinsic properties embedded in the corresponding chemical structure. Methods: In this paper, we develop DeepDrug, a deep learning framework for overcoming the above limitation by using residual graph convolutional networks (Res-GCNs) and convolutional networks (CNNs) to learn the comprehensive structure-and sequence-based representations of drugs and proteins. Results: DeepDrug outperforms state-of-the-art methods in a series of systematic experiments, including binary-class DDIs, multi-class/multi-label DDIs, binary-class DTIs classification and DTIs regression tasks. Furthermore, we visualize the structural features learned by DeepDrug Res-GCN module, which displays compatible and accordant patterns in chemical properties and drug categories, providing additional evidence to support the strong predictive power of DeepDrug. Ultimately, we apply DeepDrug to perform drug repositioning on the whole DrugBank database to discover the potential drug candidates against SARS-CoV-2, where 7 out of 10 top-ranked drugs are reported to be repurposed to potentially treat coronavirus disease 2019 (COVID-19). Conclusions:To sum up, we believe that DeepDrug is an efficient tool in accurate prediction of DDIs and DTIs and provides a promising insight in understanding the underlying mechanism of these biochemical relations.

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Section: Introductionmentioning

confidence: 99%

DeepDrug: A general graph‐based deep learning framework for drug‐drug interactions and drug‐target interactions prediction

Yin,

Fan,

Cao

et al. 2023

Quant. Biol.

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“…Once the cell types were detected, temporal gene patterns were used to enhance the understandings of cell signatures. Compared with statistical approaches, deep learning models including graph learning and transformer have exhibited superior capability in analyzing high-dimensional single-cell transcriptomics data [6][7][8].…”

Section: Introductionmentioning

confidence: 99%

scCompressSA: Dual-channel self-attention based deep autoencoder model for single-cell clustering by compressing static gene-gene interactions

Zhang,

Yu,

et al. 2023

Preprint

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Background: Deep neural networks including auto-encoders have been widely employed to mime cell type specific patterns from single-cell RNA sequencing (scRNA-seq) data. Single cell clustering has played an important role to explore the molecular mechanisms about cell differentiation and human diseases. Due to highly stochastic and noisy data, accurate detection of cell types is still challenged, especially for RNA-sequencing data from human beings. Results: Using cross-correlation to capture gene-gene interactions, this study proposes the scCompressSA method to integrate static gene-gene interactions and gene expression dynamics with self-attention(SA) based coefficient compression(CC). This dual-channel self-attention CC block has been designed to automatically integrating topological features of scRNA-seq data. Furthermore, computational efficiency has been dramatically enhanced. The proposed scCompressSA method has boosted clustering accuracy in multiple benchmark scRNA-seq datasets by reconstructing input matrices. Conclusion: Static gene-gene interactions have been used as topological features to boost detection performance in cell clustering tasks. For scCompressSA method, self-attention based CC block was effective to integrate topological features with existing temporal patterns underlying transcriptomic data.

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“…One fundamental question regarding the abundant single cell data is how to distinguish different cell types in a heterogeneous cell population based on the measured molecular signatures. A variety of computational approaches have been developed to decipher the heterogeneity across cell types based on transcriptome, methylome, and chromatin accessibility [5][6][7][8][9][10][11].…”

Section: Introductionmentioning

confidence: 99%

Deep generative modeling and clustering of single cell Hi-C data

Liu

Zeng

Zhang

et al. 2022

Briefings in Bioinformatics

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Deciphering 3D genome conformation is important for understanding gene regulation and cellular function at a spatial level. The recent advances of single cell Hi-C technologies have enabled the profiling of the 3D architecture of DNA within individual cell, which allows us to study the cell-to-cell variability of 3D chromatin organization. Computational approaches are in urgent need to comprehensively analyze the sparse and heterogeneous single cell Hi-C data. Here, we proposed scDEC-Hi-C, a new framework for single cell Hi-C analysis with deep generative neural networks. scDEC-Hi-C outperforms existing methods in terms of single cell Hi-C data clustering and imputation. Moreover, the generative power of scDEC-Hi-C could help unveil the differences of chromatin architecture across cell types. We expect that scDEC-Hi-C could shed light on deepening our understanding of the complex mechanism underlying the formation of chromatin contacts.

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scGraph: a graph neural network-based approach to automatically identify cell types

Cited by 16 publications

References 40 publications

DeepDrug: A general graph‐based deep learning framework for drug‐drug interactions and drug‐target interactions prediction

DeepDrug: A general graph‐based deep learning framework for drug‐drug interactions and drug‐target interactions prediction

scCompressSA: Dual-channel self-attention based deep autoencoder model for single-cell clustering by compressing static gene-gene interactions

Deep generative modeling and clustering of single cell Hi-C data

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