A new approach for optimal morphological identification and immunolabeling of spermatogonial cells.

High quality fixation often inactivates epitopes and gentler fixation can fail to preserve biological structure at the required resolution. For studies of male reproduction, immunofluorescence techniques using paraformaldehyde fixation associated with paraffin as an embedding medium gives good epitope preservation, although the cell becomes morphologically compromised. On the other hand, glutaraldehyde associated with a plastic resin has been used with success to recognize and distinguish each spermatogonial cell subtype, but the antigenic sites become inaccessible to antibodies. Here we describe a new method that provides excellent morphological details of testicular cells while preserving the binding capacity of epitopes. Using a combination of glutaraldehyde and paraformaldehyde as a fixative and LR White resin for embedding, we show that it is possible to clearly recognize spermatogonial subtypes (Aund, A-A4, In and B spermatogonia) on 1-µm thick-sections and to label epitopes such as bromodeoxyuridine, a marker used for cellular cycle studies in the testis. The information gained from this procedure can be critical for understanding spermatogonial process of self-renewal and differentiation.

Spermatogonial behavior in rats during radiation-induced arrest and recovery after hormone suppression.

Ionizing radiation has been shown to arrest spermatogenesis despite the presence of surviving stem spermatogonia, by blocking their differentiation. This block is a result of damage to the somatic environment and is reversed when gonadotropins and testosterone are suppressed, but the mechanisms are still unknown. We examined spermatogonial differentiation and Sertoli cell factors that regulate spermatogonia after irradiation, during hormone suppression, and after hormone suppression combined with Leydig cell elimination with ethane dimethane sulfonate. These results showed that the numbers and cytoplasmic structure of Sertoli cells are unaffected by irradiation, only a few type A undifferentiated (Aund) spermatogonia and even fewer type A1 spermatogonia remained, and immunohistochemical analysis showed that Sertoli cells still produced KIT ligand (KITLG) and glial cell line-derived neurotrophic factor (GDNF). Some of these cells expressed KIT receptor, demonstrating that the failure of differentiation was not a result of the absence of the KIT system. Hormone suppression resulted in an increase in Aund spermatogonia within 3 days, a gradual increase in KIT-positive spermatogonia, and differentiation mainly to A3 spermatogonia after 2 weeks. KITL (KITLG) protein expression did not change after hormone suppression, indicating that it is not a factor in the stimulation. However, GDNF increased steadily after hormone suppression, which was unexpected since GDNF is supposed to promote stem spermatogonial self-renewal and not differentiation. We conclude that the primary cause of the block in spermatogonial development is not due to Sertoli cell factors such (KITL\GDNF) or the KIT receptor. As elimination of Leydig cells in addition to hormone suppression resulted in differentiation to the A3 stage within 1 week, Leydig cell factors were not necessary for spermatogonial differentiation.

Spermatogonial morphology and kinetics during testis development in mice: a high-resolution light microscopy approach.

Despite the knowledge of spermatogonial biology in adult mice, spermatogonial development in immature animals has not been fully characterized. Thus, the aim of this study was to evaluate the ontogeny of the morphological development of the spermatogonial lineage in C57BL/6 mouse testis, using high-resolution light microscopy. Spermatogonial morphology, chronology, and absolute number were determined for different ages postpartum (pp). The morphology of spermatogonia in immature mice was similar to that of adult spermatogonia, although their nuclear diameter was slightly smaller. The A(1) spermatogonia were first observed on day 2 pp, and only 24 h later, differentiating type A(3) and A(4) spermatogonia were observed in the seminiferous cords. This result indicated a shortening of the spermatogonial phase for immature mice of about ∼2.5 days when compared with adult mice and suggests that gonocytes and/or A(1) spermatogonia could directly become A(4) spermatogonia, skipping the developmental sequence of type A spermatogonia. These A(4) spermatogonia are functional as they develop into type B spermatogonia by day 5 pp. At day 8 pp, while differentiation to spermatocytes begins, the A(und) spermatogonia reach their maximal numbers, which are maintained through adulthood. The various details of the spermatogonial behavior in immature normal mice described in this study can be used as a baseline for further studies under experimental or pathological conditions.

High-resolution light microscopic characterization of spermatogonia.

It is possible to distinguish the morphological features of the spermatogonial nuclei and nucleoli and to further identify their distinct generations using an appropriate method to fix whole testes via vascular perfusion with glutaraldehyde, postfixation by immersion in reduced osmium, embedding in araldite, and staining of semithin tissue sections. A well-trained individual can distinguish each of the spermatogonial types in rodents (A(undiferentiated), A(1), A(2), A(3), A(4), In, and B) using this tissue preparation technique based on their morphological details and without correlation with the stages of the epithelium cycle or other parameters. The possibility of distinguishing each spermatogonial type by their morphological characteristics allows a more accurate evaluation of their kinetics during the spermatogenic cycle. Moreover, the understanding of spermatogonial behavior is a means to elucidate the functional control of the spermatogenesis, which consequently allows the determination of their effects on the fertility of humans and other animals.