神经元表型遗传特征的因子化判别分析

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Mu Qiao
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引用次数: 0

摘要

导航单细胞转录组数据的复杂景观提出了重大挑战。这一挑战的核心是确定高维基因表达模式的有意义的表示,从而揭示细胞类型的结构和功能特性。为了追求模型的可解释性和计算的简单性,我们经常寻找原始数据的线性转换,使其与细胞的关键表型特征保持一致。针对这一需求,我们引入了一种新的线性降维方法——因式线性判别分析(FLDA)。FLDA的关键在于确定与一种表型特征高度相关的基因表达水平的线性函数,同时将其他表型特征的影响降到最低。为了增强该方法,我们将其与基于稀疏性的正则化算法相结合。这种整合是至关重要的,因为它选择了对特定表型特征或其组合至关重要的基因子集。为了说明FLDA的有效性,我们将其应用于果蝇视叶神经元的转录组数据集。我们证明,FLDA不仅捕获了与表型特征一致的固有结构模式,而且揭示了与每种表型相关的关键基因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Factorized discriminant analysis for genetic signatures of neuronal phenotypes

Navigating the complex landscape of single-cell transcriptomic data presents significant challenges. Central to this challenge is the identification of a meaningful representation of high-dimensional gene expression patterns that sheds light on the structural and functional properties of cell types. Pursuing model interpretability and computational simplicity, we often look for a linear transformation of the original data that aligns with key phenotypic features of cells. In response to this need, we introduce factorized linear discriminant analysis (FLDA), a novel method for linear dimensionality reduction. The crux of FLDA lies in identifying a linear function of gene expression levels that is highly correlated with one phenotypic feature while minimizing the influence of others. To augment this method, we integrate it with a sparsity-based regularization algorithm. This integration is crucial as it selects a subset of genes pivotal to a specific phenotypic feature or a combination thereof. To illustrate the effectiveness of FLDA, we apply it to transcriptomic datasets from neurons in the Drosophila optic lobe. We demonstrate that FLDA not only captures the inherent structural patterns aligned with phenotypic features but also uncovers key genes associated with each phenotype.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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