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Keywords
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spermatogonial stem cells, KIT gene, spermatogenesis, stem cell differentiation,
microarray, pluripotency pathways
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Abstract
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Spermatogonial stem cells (SSCs) are essential for the continuous production
of sperm and the maintenance of male fertility. Their selection, culture,
and molecular characterization provide critical insights into spermatogenesis
and potential therapeutic applications for male infertility. This study utilized
CD49f-MACS and matrix selection techniques to isolate SSCs from mouse
testicular samples. The molecular profile of the selected SSCs was analyzed
through immunocytochemistry, gene ontology enrichment, weighted gene
co-expression network analysis (WGCNA), and single-cell RNA sequencing
(scRNA-seq). Additionally, protein-protein interaction (PPI) networks were
constructed to identify key regulatory factors in SSC maintenance and
differentiation. The selected SSCs exhibited a distinct molecular signature, with
high expression of Dazl, Pou5f1 (Oct4), Gfra1, Nanog, and Kit. The Kit gene (ckit)
emerged as a crucial regulator of SSC differentiation, strongly associated with
retinoic acid (RA)-mediated signaling pathways. Co-expression analysis revealed
significant interactions between Kit, Nmyc, and other pluripotency-associated
genes, highlighting its role in SSC development. Furthermore, single-cell RNA
sequencing confirmed the dynamic expression of Kit during SSC differentiation
and early meiosis initiation. Our findings underscore the pivotal role of Kit in
spermatogenesis, reinforcing its potential as a therapeutic target for treating
male infertility. The study also provides a comprehensive molecular framework
for understanding SSC biology, with implications for regenerative medicine,
fertility preservation, and in vitro gametogenesis. Further research integrating
gene-editing technologies and in vivo models will be essential to explore the
full therapeutic potential of SSC-based treatments.
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