Expression analysis of Baz1a-deficient spermatocytes and spermatids
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ABSTRACT: Acf1 was isolated almost 15 years ago from Drosophila embryo extracts as a subunit of several complexes that possess chromatin assembly activity. Acf1 binds to the ATPase ISWI (SNF2H in mammals) to form the ACF/CHRAC chromatin remodeling complexes. Studies in Drosophila and in human and mouse cell culture implicate Acf1 in many cellular processes including transcriptional repression, heterochromatin formation and replication, and DNA damage checkpoints and repair. However, the in vivo function of Acf1 in mammals is unknown. We generated mice deficient for Baz1a, the mammalian homolog of Drosophila Acf1. In contrast to partially penetrant lethality of the mutation in flies, Baz1a-deficient mice are viable. The mutant mice show no obvious defects in B or T cell lineages, class switch recombination in cultured B cells, or meiotic recombination. Thus, BAZ1A is dispensable in vivo for the survival and differentiation of cells that require the repair of developmentally programmed DNA double-strand breaks (DSBs). However, Baz1a-/- male mice are sterile because of a severe defect in spermiogenesis that results in fewer and non-motile sperm with morphological defects. Baz1a-deficient round spermatids display widespread perturbation of gene expression. The mutant cells faithfully execute the widespread reprogramming of gene expression that normally accompanies the developmental transition from meiosis to postmeiotic differentiation, but overlaid on this normal developmental program is mis-regulation of a large number of additional genes. The inappropriate expression of this eclectic group of genes is likely the cause of the pleiotropic spermiogenesis defects in the mutant. We propose that the dramatic changes in chromatin composition that occur in late meiotic prophase and early spermiogenesis create a window of vulnerability during which BAZ1A-targeted chromatin assembly functions are needed to prevent inappropriate transcription changes. This appears to be the sole essential function of the ACF and CHRAC complexes in mouse.
ORGANISM(S): Mus musculus
PROVIDER: GSE41303 | GEO | 2013/11/12
SECONDARY ACCESSION(S): PRJNA176483
REPOSITORIES: GEO
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