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چکیده
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Background: Oxidative stress is a critical factor contributing to male infertility, impairing
spermatogonial stem cells (SSCs) and disrupting normal spermatogenesis. This study
aimed to isolate and characterize human SSCs and to investigate oxidative stress-related
gene expression, protein interaction networks, and developmental trajectories involved
in SSC function. Methods: SSCs were enriched from human orchiectomy samples using
CD49f-based magnetic-activated cell sorting (MACS) and laminin-binding matrix
selection. Enriched cultures were assessed through morphological criteria and immunocytochemistry
using VASA and SSEA4. Transcriptomic profiling was performed using
microarray and single-cell RNA sequencing (scRNA-seq) to identify oxidative stress-related
genes. Bioinformatic analyses included STRING-based protein–protein interaction (PPI)
networks, FunRich enrichment, weighted gene co-expression network analysis (WGCNA),
and predictive modeling using machine learning algorithms. Results: The enriched SSC
populations displayed characteristic morphology, positive germline marker expression,
and minimal fibroblast contamination. Microarray analysis revealed six significantly upregulated
oxidative stress-related genes in SSCs—including CYB5R3 and NDUFA10—and
three downregulated genes, such as TXN and SQLE, compared to fibroblasts. PPI and
functional enrichment analyses highlighted tightly clustered gene networks involved in
mitochondrial function, redox balance, and spermatogenesis. scRNA-seq data further confirmed
stage-specific expression of antioxidant genes during spermatogenic differentiation,
particularly in late germ cell stages. Among the machine learning models tested, logistic
regression demonstrated the highest predictive accuracy for antioxidant gene expression,
with an area under the curve (AUC) of 0.741. Protein oxidation was implicated as a major
mechanism of oxidative damage, affecting sperm motility, metabolism, and acrosome
integrity. Conclusion: T
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