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Literature DB >> 31237565

Unified single-cell analysis of testis gene regulation and pathology in five mouse strains.

Min Jung¹, Daniel Wells^2,3, Jannette Rusch¹, Suhaira Ahmad¹, Jonathan Marchini^2,3, Simon R Myers^2,3, Donald F Conrad^1,4.

Abstract

To fully exploit the potential of single-cell functional genomics in the study of development and disease, robust methods are needed to simplify the analysis of data across samples, time-points and individuals. Here we introduce a model-based factor analysis method, SDA, to analyze a novel 57,600 cell dataset from the testes of wild-type mice and mice with gonadal defects due to disruption of the genes Mlh3, Hormad1, Cul4a or Cnp. By jointly analyzing mutant and wild-type cells we decomposed our data into 46 components that identify novel meiotic gene-regulatory programs, mutant-specific pathological processes, and technical effects, and provide a framework for imputation. We identify, de novo, DNA sequence motifs associated with individual components that define temporally varying modes of gene expression control. Analysis of SDA components also led us to identify a rare population of macrophages within the seminiferous tubules of Mlh3-/- and Hormad1-/- mice, an area typically associated with immune privilege.

Entities: Chemical

Keywords: computational biology; factor analysis; gene regulation; genetics; genomics; infertility; meiosis; mouse; single-cell; systems biology; testis

Mesh：

Substances：

Year: 2019 PMID： 31237565 PMCID： PMC6615865 DOI： 10.7554/eLife.43966

Source DB: PubMed Journal: Elife ISSN： 2050-084X Impact factor: 8.140

139 in total

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