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Abstract

Molecular heterogeneity exists in many biological systems, such as major malignancies or diverse cell populations. Clustering of gene expression profiles has been widely used to dissect molecular heterogeneity. One drawback common to most clustering methods is that they often suffer from high dimensionality and noise, as well as feature redundancy. To address these challenges, we propose Extreme learning machine self-diffusion (ELMSD), an auto-encoder extreme learning machine feature representation method that incorporates a self-diffusion graph denoising framework to effectively dissect molecular heterogeneity. Our method, ELMSD, first learns a compressed representation of gene expression profiles from the hidden layer of the autoencoder extreme learning machine, followed by an iterative graph diffusion process to enhance the sample-to-sample similarity. The enhanced graph can largely facilitate the downstream clustering analysis, making it more efficient to analyze molecular properties. To demonstrate the utility of ELMSD, we applied it on one simulation dataset, five single-cell datasets, and 20 cancer datasets. Experiment results show that the ELMSD approach outperforms several state-of-the-art clustering methods and cancer subtypes, cell types identified by ELMSD reveal strong clinical relevance and biological interpretation. The ELMSD code is available at: https://github.com/DXCODEE/ELMSD.

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References

Budinska

, Popovici

, Tejpar

, et al. Gene expression patterns unveil a new level of molecular heterogeneity in colorectal cancer. J Pathol, 2013; 231(1):63–76.

Coifman

, Lafon

. Diffusion maps. Applied and Computational Harmonic Analysis, 2006; 21(1):5–30.

D’Arrigo

, Leonardis

, Abd ElHafeez

, et al. Methods to analyse time-to-event data: The Kaplan-Meier survival curve. Oxid Med Cell Longev, 2021; 2021:2290120.

Dalmaijer

, Nord

, Astle

. Statistical power for cluster analysis. BMC Bioinformatics, 2022; 23(1):205–228.

Deng

, Ramsköld

, Reinius

, et al. Single-cell RNA-seq reveals dynamic, random monoallelic gene expression in mammalian cells. Science, 2014; 343(6167):193–196.

Dijk

, Veenstra

, Soer

, et al. Unsupervised class discovery in pancreatic ductal adenocarcinoma reveals cell-intrinsic mesenchymal features and high concordance between existing classification systems. Sci Rep, 2020; 10(1):337.

Duan

, Wang

, Tang

, et al. Dissecting cellular heterogeneity based on network denoising of scRNA-seq using local scaling self-diffusion. Front Genet, 2021; 12:811043.

Grabski

, Street

, Irizarry

. Significance analysis for clustering with single-cell RNA-sequencing data. Nat Methods, 2023; 20(8):1196–1202.

Guinney

, Dienstmann

, Wang

, et al. The consensus molecular subtypes of colorectal cancer. Nat Med, 2015; 21(11):1350–1356.

10.

Hao

, Stuart

, Kowalski

, et al. Dictionary learning for integrative, multimodal and scalable single-cell analysis. Nat Biotechnol, 2023:1–12.

11.

Huang

G-B

, Zhu

Q-Y

, Siew

C-K

. Extreme learning machine: Theory and applications. Neurocomputing, 2006; 70(1–3):489–501.

12.

Huh

, Yang

, Jiang

, et al. Same-clustering: Single-cell aggregated clustering via mixture model ensemble. Nucleic Acids Res, 2020; 48(1):86–95.

13.

Kempa

, Hollywood

, Smith

, et al. High throughput screening of complex biological samples with mass spectrometry–from bulk measurements to single cell analysis. Analyst, 2019; 144(3):872–891.

14.

Kiselev

, Kirschner

, Schaub

, et al. SC3: Consensus clustering of single-cell RNA-seq data. Nat Methods, 2017; 14(5):483–486.

15.

Kolodziejczyk

, Kim

, Tsang

, et al. Single cell RNA-sequencing of pluripotent states unlocks modular transcriptional variation. Cell Stem Cell, 2015; 17(4):471–485.

16.

Lengyel

, Botta‐Dukát

. Silhouette width using generalized mean—A flexible method for assessing clustering efficiency. Ecol Evol, 2019; 9(23):13231–13243.

17.

, Courtois

, Sengupta

, et al. Reference component analysis of single-cell transcriptomes elucidates cellular heterogeneity in human colorectal tumors. Nat Genet, 2017; 49(5):708–718.

18.

Lin

, Troup

, Ho

. CIDR: Ultrafast and accurate clustering through imputation for single-cell RNA-seq data. Genome Biol, 2017; 18(1):59.

19.

Marisa

, de Reyniès

, Duval

, et al. Gene expression classification of colon cancer into molecular subtypes: Characterization, validation, and prognostic value. PLoS Med, 2013; 10(5):e1001453.

20.

McInnes

, Healy

, Melville

. Umap: Uniform manifold approximation and projection for dimension reduction. arXiv Preprint arXiv, 2018:180203426.

21.

Melo

FDSE

, Vermeulen

, Fessler

, et al. Cancer heterogeneity—a multifaceted view. EMBO Rep, 2013; 14(8):686–695.

22.

Ming

, Xie

, Hu

, et al. Two distinct subtypes revealed in blood transcriptome of breast cancer patients with an unsupervised analysis. Front Oncol, 2019; 9:985.

23.

Nguyen

, Shrestha

, Nguyen

. Pinsplus: Clustering algorithm for data integration and disease subtyping. CRAN R Package, 2018.

24.

Pang

, Cao

, Chen

, et al. Unsupervised clustering reveals distinct subtypes of biliary atresia based on immune cell types and gene expression. Front Immunol, 2021; 12:720841.

25.

Pollen

, Nowakowski

, Shuga

, et al. Low-coverage single-cell mRNA sequencing reveals cellular heterogeneity and activated signaling pathways in developing cerebral cortex. Nat Biotechnol, 2014; 32(10):1053–1058.

26.

Ritchie

, Phipson

, Wu

, et al. limma powers differential expression analyses for RNA-sequencing and microarray studies. Nucleic Acids Res, 2015; 43(7):e47–e47.

27.

Santos

, Embrechts

. On the use of the adjusted rand index as a metric for evaluating supervised classification. In: International conference on artificial neural networks. Springer: 2009; pp. 175–184.

28.

Therneau

, Lumley

. Package ‘survival’. R Top Doc, 2015; 128(10):28–33.

29.

Thysell

, Vidman

, Ylitalo

, et al. Gene expression profiles define molecular subtypes of prostate cancer bone metastases with different outcomes and morphology traceable back to the primary tumor. Mol Oncol, 2019; 13(8):1763–1777.

30.

Traag

, Waltman

, Van Eck

. From Louvain to Leiden: Guaranteeing well-connected communities. Sci Rep, 2019; 9(1):5233–5212.

31.

Wang

, Terfve

, Rose

, et al. HTSanalyzeR: An R/Bioconductor package for integrated network analysis of high-throughput screens. Bioinformatics, 2011; 27(6):879–880.

32.

Wang

, Zhu

, Pierson

, et al. Visualization and analysis of single-cell RNA-seq data by kernel-based similarity learning. Nat Methods, 2017; 14(4):414–416.

33.

Wang

, Tu

. Affinity learning via self-diffusion for image segmentation and clustering. In: 2012 IEEE conference on computer vision and pattern recognition. IEEE: 2012; pp. 2312–2319.

34.

, Xu

. Global colorectal cancer burden in 2020 and projections to 2040. Transl Oncol, 2021; 14(10):101174.

35.

Zappia

, Phipson

, Oshlack

. Splatter: Simulation of single-cell RNA sequencing data. Genome Biol, 2017; 18(1):174–115.

36.

Zelnik-Manor

, Perona

. Self-tuning spectral clustering. Advances in Neural Information Processing Systems, 2004; 17:1601–1608.

37.

Zhang

. Evaluating accuracy of community detection using the relative normalized mutual information. J Stat Mech, 2015; 2015(11):P11006.

38.

Zheng

, Terry

, Belgrader

, et al. Massively parallel digital transcriptional profiling of single cells. Nat Commun, 2017; 8(1):14049.

39.

Zhu

, Lei

, Klei

, et al. Semisoft clustering of single-cell data. Proc Natl Acad Sci U S A, 2019; 116(2):466–471.

40.

Zou

, Hua

, Zhang

. HGC: Fast hierarchical clustering for large-scale single-cell data. Bioinformatics, 2021; 37(21):3964–3965.

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Compressed Representation of Extreme Learning Machine with Self-Diffusion Graph Denoising Applied for Dissecting Molecular Heterogeneity

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