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Nonnegative spatial factorization applied to spatial genomics

F. William Townes, Barbara E. Engelhardt

2022Nature Methods114 citationsDOIOpen Access PDF

Abstract

Nonnegative matrix factorization (NMF) is widely used to analyze high-dimensional count data because, in contrast to real-valued alternatives such as factor analysis, it produces an interpretable parts-based representation. However, in applications such as spatial transcriptomics, NMF fails to incorporate known structure between observations. Here, we present nonnegative spatial factorization (NSF), a spatially-aware probabilistic dimension reduction model based on transformed Gaussian processes that naturally encourages sparsity and scales to tens of thousands of observations. NSF recovers ground truth factors more accurately than real-valued alternatives such as MEFISTO in simulations, and has lower out-of-sample prediction error than probabilistic NMF on three spatial transcriptomics datasets from mouse brain and liver. Since not all patterns of gene expression have spatial correlations, we also propose a hybrid extension of NSF that combines spatial and nonspatial components, enabling quantification of spatial importance for both observations and features. A TensorFlow implementation of NSF is available from https://github.com/willtownes/nsf-paper .

Topics & Concepts

Non-negative matrix factorizationComputer scienceProbabilistic logicDimension (graph theory)Matrix decompositionPattern recognition (psychology)Artificial intelligenceFactorizationRepresentation (politics)Spatial analysisGaussianDimensionality reductionData miningMachine learningMathematicsAlgorithmEigenvalues and eigenvectorsStatisticsPolitical sciencePure mathematicsQuantum mechanicsLawPoliticsPhysicsSingle-cell and spatial transcriptomicsGene expression and cancer classificationGenetic and phenotypic traits in livestock
Nonnegative spatial factorization applied to spatial genomics | Litcius