Three-Dimensional Analysis of Busulfan-Induced Spermatogenesis Disorder in Mice

Three-dimensional analysis of partial restoration of spermatogenesis in vitamin A-deficient mice

BACKGROUND

An animal model of the partial restoration of spermatogenesis may be useful in the field of reproductive biology and medicine. Vitamin A deficiency (VAD) induces the restorable arrest of spermatogenesis at the level of spermatogonia and is used as a mouse model of spermatogenesis disorder.

OBJECTIVE

We aimed to establish an animal model in which spermatogenesis is partially restored by switching a vitamin A deficiency diet to a normal vitamin A-containing diet and conduct a comprehensive analysis to identify vulnerable sites in the seminiferous tubules that affect the efficient restoration of spermatogenesis in this model.

MATERIALS AND METHODS

Mice fed a vitamin A deficiency diet until 12 weeks old and then reared with a normal diet for 15 weeks served as the restoration model. We performed three-dimensional reconstructions of the seminiferous tubules and analyzed the three-dimensional distribution of restored spermatogenesis throughout the testis.

RESULTS

Fifteen weeks after the switch to the normal diet, spermatogenesis was restored in 78% of the length of seminiferous tubules. The percentage of restored spermatogenesis was lower in longer seminiferous tubules. An analysis of the distribution of spermatogenesis throughout the testis in this model revealed that it was restored less in portions of seminiferous tubules near the rete testis and hairpin curves and also in those located in the caudal region of the testis. These sites tended to correspond to sites with fewer spermatogonia in the vitamin A deficiency testis.

DISCUSSION AND CONCLUSIONS

We established an animal model of the partial restoration of spermatogenesis and examined the three-dimensional distribution of restored spermatogenesis in seminiferous tubules. The results obtained provide insights into the mechanisms underlying spermatogenesis disorders and may contribute to better clinical practices, such as the screening of drugs or therapeutic interventions for human male infertility and improvements in fertility preservation techniques for individuals undergoing chemotherapy.

Three-dimensional analysis of junctions between efferent and epididymal ducts in the human caput epididymis

BACKGROUND

Due to the scarcity of studies using human tissues, the limited information is currently available on the gross structure of the caput epididymis in humans, at which efferent ducts connect to the epididymal duct.

OBJECTIVE

The present study investigated the three-dimensional structures of efferent and caput epididymal ducts in humans, with a focus on junctions between the former and the latter.

MATERIALS AND METHODS

We examined three sets of human efferent and caput epididymal ducts in specimens obtained from prostatic carcinoma patients. They were reconstructed from serial paraffin sections using a segmentation model created by a deep learning protocol and high-performance three-dimensional reconstruction software.

RESULTS

Serial sections and three-dimensional images of human efferent and caput epididymal ducts were combined to obtain the detailed anatomical information. When a single efferent duct was defined as a duct connecting to both the extra-testicular rete testis and epididymal duct, there were 14.7 efferent ducts with a total length of 3.0 m per specimen on average. The cranial portion of the efferent ducts joined to a single duct and terminated at the end of the epididymal duct, whereas other efferent ducts terminated independently on the side of the epididymal duct. These two types of junctions between the efferent and epididymal ducts differed in the patterns of the epithelial-type switch. The epididymal duct consisted of multiple segments, which were separated by a minimal amount of connective tissue septa or even without them. Efferent ducts occupied most of the volume of the caput epididymis.

DISCUSSION AND CONCLUSIONS

By utilizing deep learning, we reconstructed human efferent and caput epididymal ducts and revealed their precise three-dimensional structures, which differed from those of rodents in several aspects. The present results may be useful for analyzing anatomical abnormalities related to some types of male infertility.

Three-dimensional morphological analysis of spermatogenesis in aged mouse testes

Spermatogenesis, which is a continuous process from undifferentiated spermatogonia to spermatozoa in the seminiferous tubules, declines with age. To investigate changes in spermatogenesis with aging, we reconstructed the seminiferous tubules of 12 mice aged 12 to 30 months from serial sections and examined age-related and region-specific alterations in the seminiferous epithelium and spermatogenic waves in three dimensions. The basic structure of the seminiferous tubules, including the numbers of tubules, terminating points, branching points, and total tubule length, did not change with age. Age-related alterations in spermatogenesis, primarily assessed by the formation of vacuoles in Sertoli cells, were detected in the seminiferous tubules at 12 months. The proportion of altered tubule segments with impaired spermatogenesis further increased by 24 months, but remained unchanged thereafter. Altered tubule segments were preferentially distributed in tubule areas close to the rete testis and those in the center of the testis. Spermatogenic waves became shorter in length with age. These results provide a basis for examining the decline of spermatogenesis not only with aging, but also in male infertility.

Three-dimensional reconstruction of testis cords/seminiferous tubules

BACKGROUND

Due to the development of novel equipment for the acquisition of two-dimensional serial images and software capable of displaying three-dimensional (3D) images from serial images, the accurate 3D reconstruction of organs and tissues has become possible.

METHODS

Based on published studies, this review summarizes techniques for the 3D reconstruction of the testis cords/seminiferous tubules, with special reference to our method using serial paraffin sections and 3D visualization software.

MAIN FINDINGS

The testes of mice, rats, and hamsters of various ages were 3D reconstructed and species and age differences in the structures of the testis cords/seminiferous tubules were analyzed. Our method is advantageous because conventional paraffin-embedded normal and pathological specimens may be utilized for the 3D analysis without the need for complicated and expensive equipment.

CONCLUSION

By further decreasing the time and labor required for the procedure and adding information on molecular localization, the technique for 3D reconstruction will contribute to the elucidation of not only the structures, but also the functions of various organs, including the testis.

Three-dimensional structure of testis cords in mice and rats

BACKGROUND

Testis cord elongation and coiling, which occur in the final stage of testis formation, have been attributed to Sertoli cell proliferation; however, the underlying mechanisms remain unclear.

OBJECTIVE

The aim of the present study was to clarify the precise three-dimensional structure of testis cords in the final stage of testis formation in mice and rats.

MATERIALS AND METHODS

We reconstructed whole testis cords in the final stage of testis formation in mice (on embryonic days 15.5 and 18.5) and rats (on embryonic days 16.5 and 19.5) using serial paraffin sections and high-performance three-dimensional reconstruction software.

RESULTS

Detailed morphometric parameters were calculated for three-dimensionally reconstructed testis cords in six mouse and rat testes each. The mean numbers of testis cords in mice and rats were 12.7 and 27.8, respectively. The mean number of branching points per testis cord was 1.52 in mice, whereas it was only 0.30 in rats. In contrast, the mean ratio of the inner cords, that is, cords not in contact with the tunica albuginea, was 23.0% in rats, whereas it was only 6.5% in mice. In both species, the cords on the cranial side coiled more strongly than those on the caudal side, consistent with the greater expansion of the testis volume on the caudal side. All cords formed right-handed helices from the rete testis side.

DISCUSSION AND CONCLUSIONS

The present results suggest that testis cords undergo anastomosis at a higher frequency in mice than in rats and that the coiling of testis cords proceeds from the cranial to caudal side of the testis in both species.