A subspace clustering method for satisfying stoimetric constraints in scRNA -seq

2021 IEEE 21st International Conference on Bioinformatics and Bioengineering (BIBE) Pub Date : 2021-10-25 DOI:10.1109/BIBE52308.2021.9635324

Angela Huang, Junhyong Kim

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Abstract

With the advent of single-cell RNA-sequencing, researchers now have the ability to define cell types from large amounts of transcriptome information. Over the years, various clustering algorithms have been designed. Currently, most clustering algorithms measure cell-to-cell similarities using distance metrics based on the assumption that each cluster is comprised of “nearby” neighbors. In effect, clusters are a collection of similar cells in the embedded metric. Here, we propose that biological clusters should be comprised of sets of cells that satisfy a set of stochiometric constraints, whose intersections define a cell type. We propose to model each cell population with a single affine subspace, where all cells of the same type share a common set of linear constraints. We present an algorithm that leverages this subspace structure and learns a cell-to-cell affinity matrix based on notions of subspace similarity. We simulate scRNA-seq data according to the subspace model and benchmark our algorithm against preexisting methods. We further test our algorithm on an in-house C. elegans dataset and show recovery of information on both cell type and developmental time.

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scRNA -seq中满足计量约束的子空间聚类方法

随着单细胞rna测序的出现，研究人员现在有能力从大量的转录组信息中定义细胞类型。多年来，人们设计了各种聚类算法。目前，大多数聚类算法基于假设每个聚类由“附近”邻居组成，使用距离度量来测量细胞间的相似性。实际上，簇是嵌入度量中相似单元的集合。在这里，我们提出生物集群应该由满足一组计量约束的细胞集合组成，它们的交集定义了细胞类型。我们建议用单个仿射子空间对每个细胞群进行建模，其中所有相同类型的细胞共享一组共同的线性约束。我们提出了一种算法，利用这种子空间结构，并学习基于子空间相似性概念的细胞间亲和矩阵。我们根据子空间模型模拟scRNA-seq数据，并将我们的算法与已有的方法进行比较。我们在线虫内部数据集上进一步测试了我们的算法，并显示了细胞类型和发育时间的信息恢复。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2021 IEEE 21st International Conference on Bioinformatics and Bioengineering (BIBE)

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