RNA-binding protein Ptbp1 regulates alternative splicing and transcriptome in spermatogonia and maintains spermatogenesis in concert with Nanos3

RNA-binding protein Ptbp1 regulates alternative splicing and transcriptome in spermatogonia and maintains spermatogenesis in concert with Nanos3

PTBP1, a well-conserved RNA-binding protein, regulates cellular development by tuning posttranscriptional mRNA modification such as alternative splicing (AS) or mRNA stabilization. We previously revealed that the loss of Ptbp1 in spermatogonia causes the dysregulation of spermatogenesis, but the mol...

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Bibliographic Details
Published in:Journal of Reproduction and Development Vol. 66; no. 5; pp. 459 - 467
Main Authors: SENOO, Manami, HOZOJI, Hiroshi, ISHIKAWA-YAMAUCHI, Yu, TAKIJIRI, Takashi, OHTA, Sho, UKAI, Tomoyo, KABATA, Mio, YAMAMOTO, Takuya, YAMADA, Yasuhiro, IKAWA, Masahito, OZAWA, Manabu
Format: Journal Article
Language:English
Published: Tokyo The Society for Reproduction and Development 2020
Japan Science and Technology Agency
Subjects:
Alternative splicing
Gene expression
Genes
Homeostasis
Molecular modelling
Next-generation sequencing
Original
Post-transcription
Proteins
PTBP1
RNA modification
RNA-binding protein
Spermatogenesis
Spermatogonia
Stem cell transplantation
Stem cells
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Summary:PTBP1, a well-conserved RNA-binding protein, regulates cellular development by tuning posttranscriptional mRNA modification such as alternative splicing (AS) or mRNA stabilization. We previously revealed that the loss of Ptbp1 in spermatogonia causes the dysregulation of spermatogenesis, but the molecular mechanisms by which PTBP1 regulates spermatogonium homeostasis are unclear. In this study, changes of AS or transcriptome in Ptbp1-knockout (KO) germline stem cells (GSC), an in vitro model of proliferating spermatogonia, was determined by next generation sequencing. We identified more than 200 differentially expressed genes, as well as 85 genes with altered AS due to the loss of PTBP1. Surprisingly, no differentially expressed genes overlapped with different AS genes in Ptbp1-KO GSC. In addition, we observed that the mRNA expression of Nanos3, an essential gene for normal spermatogenesis, was significantly decreased in Ptbp1-KO spermatogonia. We also revealed that PTBP1 protein binds to Nanos3 mRNA in spermatogonia. Furthermore, Nanos3+/−;Ptbp1+/− mice exhibited abnormal spermatogenesis, which resembled the effects of germ cell-specific Ptbp1 KO, whereas no significant abnormality was observed in mice heterozygous for either gene alone. These data implied that PTBP1 regulates alternative splicing and transcriptome in spermatogonia under different molecular pathways, and contributes spermatogenesis, at least in part, in concert with NANOS3.
ISSN:0916-8818
1348-4400
DOI:10.1262/jrd.2020-060