Expression of Protein Markers in Spermatogenic and Supporting Sertoli Cells Affected by High Abdominal Temperature in Cryptorchidism Model Mice.

Cryptorchidism is a congenital abnormality resulting in increased rates of infertility and testicular cancer. We used cryptorchidism model mice that presented with the translocation of the left testis from the scrotum to the abdominal cavity. Mice underwent the surgical procedure of the left testis at day 0 and were sacrificed at days 3, 5, 7, 14, 21, and 28 post-operatively. The weight of the left cryptorchid testis decreased significantly at days 21 and 28. The morphological changes were observed after 5 days and showed detached spermatogenic cells and abnormal formation of acrosome at day 5, multinucleated giant cells at day 7, and atrophy of seminiferous tubules at days 21 and 28. The high abdominal temperature disrupted the normal expression of cell adhesion molecule-1, Nectin-2, and Nectin-3 which are essential for spermatogenesis. In addition, the pattern and alignment of acetylated tubulin in cryptorchid testes were also changed at days 5, 7, 14, 21, and 28. Ultrastructure of cryptorchid testes revealed giant cells that had been formed by spermatogonia, spermatocytes, and round and elongating spermatids. The study's findings reveal that cryptorchidism's duration is linked to abnormal changes in the testis, impacting protein marker expression in spermatogenic and Sertoli cells. These changes stem from the induction of high abdominal temperature.

Quantitative evaluation of spermatogenesis by fluorescent histochemistry.

Identifying the types of spermatogenic cells that compose seminiferous tubules, as well as qualitative confirmation of the presence or absence of disorders, has been regarded as crucial in spermatogenesis. Sperm count and fertilizing capacity, both of which depend on the quality as well as quantity of spermatogenesis, are factors critical to fertilization. However, the quantitative assessment of spermatogenesis is not commonly practiced. Spermatogenesis has species-specific stages; when the specific stage in the seminiferous tubules is precisely determined, the types of spermatogenic cells in each stage can be spontaneously identified. Thereafter, a unique marker is used to classify the cells observed in each stage. Quantitative assessment of spermatogenesis has the potential to detect inapparent spermatogenesis disorders or numerically indicate the degree of the disorder. To this end, a histochemical approach using unique markers is indispensable for the quantitative assessment of spermatogenesis. Future developments in techniques to measure cell populations using computer software will further facilitate the establishment of quantitative assessment of spermatogenesis as a standard analysis method that can contribute significantly to advance our understanding of spermatogenesis.