Sertoli cells, proximal convoluted tubules in the kidney, and neurons in the brain contain cyclic protein-2

We analyze by immunocytochemistry the in vivo distribution in rat Sertoli cells of Cyclic Protein-2 (CP-2), which is maximally synthesized and secreted in vitro at stages VI and VII of the cycle of the seminiferous epithelium. This analysis demonstrates that CP-2 staining is strongest in Sertoli cells in stage VI and VII tubules. Additionally, we demonstrate that the staining for CP-2 within a stage VII tubule differs from the staining of another Sertoli cell secretory product, androgen-binding protein. CP-2 is not detected by immunocytochemistry in any other tissues of the reproductive tract, though immunoblot analysis demonstrates the presence of CP-2 in rete testis and epididymal fluids. CP-2 was immunocytochemically detected in only three other organs: the kidney, the brain (with greatest concentration in the supraoptic and paraventricular nuclei), and the posterior pituitary. The presence of CP-2 in the kidney was confirmed by metabolic radiolabeling, immunoprecipitation, and peptide analysis. The presence of CP-2 in the brain was confirmed by immunoblot analysis of radioinert protein immunoprecipitated from the anterior hypothalamus.     

Germ cell-Sertoli cell interactions: analysis of the biosynthesis and secretion of cyclic protein-2

Cyclic protein-2 (CP-2) is secreted in vitro in substantial amounts by mature rat Sertoli cells in intact Stage VI and Stage VII seminiferous tubules. This stage-dependent secretion has led us to postulate that the biosynthesis of this molecule is stimulated by germ cells at a specific state of development. In order to explore this hypothesis and to examine the steps in CP-2's biosynthesis, we generated a polyclonal antisera against this protein and used it to analyze the biosynthesis and secretion of CP-2. Analysis of the steps in the biosynthesis of CP-2 indicated that its polypeptide core represented most if not all of the translation product of the CP-2 mRNA and that a single aspargine-linked oligosaccharide became attached to this core. Analysis of the rate of biosynthesis of CP-2 at specific stages of the cycle of the seminiferous epithelium was also conducted. Two-millimeter segments of tubules at Stage II, VI, VIIa, b, VIII, and XII were cultured for 1 hr in the presence of [35S]methionine and radiolabeled CP-2 immunoprecipitated from the tubules. Data (35S-CP-2 synthesized per hour) demonstrated that the rate of CP-2's biosynthesis increased 9-fold from Stage II to Stages VI and VIIa, b and then decreased 13-fold by Stage XII. To determine whether these rates of biosynthesis were identical to the rates of secretion, tubules were cultured for 17 hr with [35S]methionine, CP-2 was immunoprecipitated from the culture medium and data were expressed as 35S-CP-2 secreted per hour. This analysis demonstrated that the rate of secretion of CP-2 varied in the same stage-specific manner as its rate of synthesis. However, at each stage, the apparent rate of biosynthesis of the molecule exceeded its apparent rate of secretion. In order to explain this observation, we analyzed the rate of export of newly synthesized CP-2 out of the tubules. This demonstrated that quantitative export of the protein into culture medium required at least 17 hr. This period of time was most likely due to the retention of the protein within the tubular lumen, since primary cultures of Sertoli cells were shown to rapidly secrete newly synthesized CP-2. We, therefore, concluded that CP-2 was biosynthesized in a stage-dependent manner and that all CP-2 was secreted.     

Isolation of cyclic protein-2 from rat seminiferous tubule fluid and Sertoli cell culture medium

Cyclic Protein-2 (CP-2), a stage-specific secretory product of the rat seminiferous epithelium, has been isolated from seminiferous tubule fluid (STF) and Sertoli cell culture medium. Isolation from STF was accomplished by mixing STF with radiolabeled proteins secreted by Stage VI-VII seminiferous tubules and sequential fractionation of these proteins by hydroxylapatite, DEAE-agarose, and quaternary amine ion-exchange chromatography. Radiolabeled proteins were used to identify the chromatographic fractions that contained CP-2. Through use of these procedures, a highly purified preparation of radioinert CP-2 was obtained from seminiferous tubule fluid. Cyclic Protein-2 was also isolated from Sertoli cell culture medium, indicating that the Sertoli cell is its most likely source. Preliminary characterization of CP-2 was conducted. First, CP-2 appeared to be highly enriched in methionine. Second, the molecular weight of CP-2 was found to be 20,000. Third, analysis by reverse-phase hydrophobic chromatography indicated that CP-2 was relatively hydrophobic. We conclude that CP-2 is a small hydrophobic glycoprotein secreted in vivo and in vitro in a stage-specific manner by Sertoli cells.     

Stage-specific effects of the fungicide carbendazim on Sertoli cell microtubules in rat testis

The aim of the present study is to provide a morphological explanation of carbendazim (CBZ)-induced sloughing of germ cells that occurs in a stage-specific manner. Therefore, very early alterations in the seminiferous tubule epithelium were examined histologically in the rat testis after oral administration of CBZ (400mg/kg). Gaps between the elongated and round spermatids, the first indication of germ cell sloughing (pre-sloughing), were observed in stage late VI-early VII seminiferous tubules at 90-min post-treatment. Tubulin immunoreaction in the Sertoli cells was reduced in intensity in tubules with pre-sloughing. However, electron microscopy demonstrated that there were some intact microtubules in these cells. At 120 min, sloughing was seen in stage late VI-early VII and XIII-XIV. Tubulin immunoreaction in the Sertoli cells was greatly decreased in intensity in tubules where cell sloughing was observed. Electron microscopy showed that there were few microtubules in the body region of these cells. Stages II-V and mid-VII-VIII were exempt from the sloughing effect at 180 min. These changes in microtubules were not observed in Sertoli cells that did not exhibit sloughing characteristics, regardless of the post-treatment intervals. The present results suggest that stage specificity of sloughing is due to the stage-specific susceptibility of Sertoli cell microtubules to CBZ.     

Regulation of the synthesis and secretion of transferrin and cyclic protein-2/cathepsin L by mature rat Sertoli cells in culture.

While numerous studies have examined the response of immature rat Sertoli cells to specific hormones and growth factors, the regulation of mature cells in vitro has not been well examined because highly purified cells have been difficult to isolate. We now describe a detailed method for isolating Sertoli cells from mature (> 60 days of age) rats and generating primary cultures of these cells greater than 90% in purity. We demonstrate that cell density, hormones, and growth factors regulate the synthesis or secretion of two Sertoli cell products, transferrin and Cyclic Protein-2 (CP-2)/cathepsin L. Cell density modulated the response of mature Sertoli cells to some hormones; insulin (at 10 micrograms/ml) and epidermal growth factor (EGF) acted synergistically to stimulate transferrin synthesis by 80% when cells were cultured at a density of 1.65 x 10(5) cells/cm2 but had no effect on transferrin synthesis by cells cultured at 1.46 x 10(5) cells/cm2. A mixture of FSH, retinol, and testosterone increased transferrin synthesis by 30% at both cell densities, and this stimulation was independent of the effect of EGF and insulin. CP-2/cathepsin L synthesis was significantly stimulated by increased cell density. FSH, retinol, and testosterone also stimulated CP-2/cathepsin L synthesis by 30%; however, this stimulation just missed being statistically significant. Finally, we demonstrated that secretion of transferrin and CP-2 was reduced when cells were cultured in the presence of interleukin-1 alpha, a cytokine synthesized by Sertoli cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of stage-specific proteins synthesized by rat seminiferous tubules

Experiments were conducted to determine how the cycle of the seminiferous epithelium influenced synthesis and secretion of proteins by seminiferous tubules. Tubular segments were treated with collagenase and then cultured with [35S]methionine. These myoid cell-depleted tubules isolated from different stages of the epithelial cycle exhibited, at Stages VI and XII, two distinct peaks of secretion of total radiolabeled proteins. Two-dimensional gel electrophoresis indicated that the patterns of secreted proteins from these two stages were remarkably different, while those from other stages were intermediate between those at the peaks. At least 15 proteins were secreted cyclically, many of them previously unrecognized products of the seminiferous epithelium. One product, designated Cyclic Protein-2 (CP-2), exhibited a pronounced cycle of secretion, its peak at Stage VI being 30-fold greater than at its nadir at Stages XII-XIV. Further investigation indicated that CP-2 did not appear to originate from myoid cells or dispersed germ cells but could be recovered from Sertoli cell-enriched cultures prepared from Stage VI tubules. Protein secretion by tubular segments was also characterized by immunoprecipitation with two polyspecific antisera directed against Sertoli cell products. Five secretory proteins were identified which had cycles different from one another and from CP-2. In contrast to secreted products, the synthesis of most cellular proteins by tubular segments remained relatively constant throughout the cycle. It is concluded: 1) segments of the seminiferous epithelium secrete proteins into the culture medium which are distinct from cellular proteins; 2) the synthesis of many of these proteins varies with the epithelial cycle; and 3) several of the secreted proteins are of Sertoli cell origin, including a newly identified protein, CP-2. This indicates that the morphology and the protein synthetic capacity of the seminiferous epithelium are coordinated over space and time.     

Localization of sulfated glycoprotein-2 (clusterin) on spermatozoa and in the reproductive tract of the male rat

Sulfated glycoprotein-2 (SGP-2) is one of the major proteins secreted by rat Sertoli cells and epididymal cells in culture. The disulfide-linked dimeric protein secreted by Sertoli cells and found in seminiferous tubule fluid is composed of monomers of Mr 47 000 and 34 000 whereas the epididymal protein exhibits monomers of Mr 40 000 and 29 000. When both forms were chemically or enzymatically deglycosylated, they yielded proteins of similar molecular weight. No modification of the higher molecular weight testicular form by epididymal cells or fluids could be detected in incubation media. SGP-2 mRNA was localized in epididymal epithelium by in situ hybridization. Northern blot analysis indicated the testicular and epididymal mRNAs were of similar size. These findings suggest that the two forms of the protein occur because of tissue-specific post-translational modifications. The detergent-extracted protein from washed testicular spermatozoa is of the higher molecular weight form while epididymal sperm carry the lower molecular weight form. Immunohistochemical evidence suggests that the testicular form is removed prior to the initial segment of the epididymis and the epididymal form is applied in the proximal caput epididymidis. SGP-2 was immunolocalized to the sperm membrane at the ultrastructural level and was distinctly different from the immunolocalization of outer dense fiber proteins and fibrous sheath proteins.     

DNA synthesis during larval development and compensatory growth in the mesonephros of Xenopus laevis.

Autoradiography following tritiated thymidine administration to Xenopus laevis tadpoles of stages 45–48 of larval development has revealed that, as the cells of the mesonephric kidney differentiate during organogenesis, there is a marked decrease in the percentage of cells synthesizing DNA (from 100% at stage 45 to less than 9% at stage 48). In the adult this figure is of the order of 0.1%. This reduced DNA synthetic activity was found to take place in the cells of both the proximal and distal tubules of the nephrons. Special mucous cells which serve as markers of distal tubules were not observed to synthesize DNA after the onset of their differentiation at stage 48 of larval development.Through the partial extirpation of tissue in one kidney of adult Xenopus laevis males, DNA synthesis was reactivated in differentiated cells. The increased DNA synthetic activity following partial unilateral nephrectomy was found to be maximal after 6 days of recovery when 19% of cells synthesize DNA. This increased DNA synthetic activity was found to occur only in the cells of the distal tubules, both mucous and nonmucous cells, while the cells of the proximal tubules did not respond to this reactivation.The apparent inability of proximal tubule cells to synthesize DNA following partial unilateral nephrectomy is discussed.     

Spontaneous degeneration of germ cells in normal rat testis: assessment of cell types and frequency during the spermatogenic cycle.

The occurrence of degenerating germ cells in the cycle of the seminiferous epithelium was measured in testicular tissues from eight normal adult rats. Testes were perfusion fixed, embedded in epoxy resin and, after sectioning a total of 180 randomly selected blocks at 1 microns, stained sections were examined by light microscopy; all cross-sectioned seminiferous tubules were categorized into one of 14 stages of the spermatogenic cycle. The number of degenerating cells per tubule was recorded in 2103 tubules. Degenerating germ cells were not detected at stages II-VI, and only rarely at stage VII (n = 366 tubules) in which one primary spermatocyte and one step 19 spermatid degenerated. All other stages exhibited a greater incidence of degenerative germ cells, particularly at stage XIV where, on average, the frequency of degenerating cells per round seminiferous tubule was about 40 times greater than at stage VII. The results indicated that, in the normal adult rat testis, the germ cells are least at risk of degeneration as they pass through stage VII.     

Disruption of seminiferous epithelial function in the rat by ovarian protein

The granulosa cell produces an inhibitor of aromatase activity, which recently was purified to homogeneity (follicle-regulatory protein: FRP). Since extracts of testicular homogenates also contain factor(s) with biological properties similar to FRP, including inhibition of granulosa cell aromatase, we examined the effects of ovarian FRP on testicular function. Forty-five-day-old rats received daily FRP injections (100 micrograms or 300 micrograms). After 15, 30, 45, and 70 days of therapy, (n = 5 each group), trunk serum was measured for testosterone, androstenedione, estradiol, and FSH levels by established radioimmunoassays (RIA). One testis from each rat was homogenized, centrifuged, and evaluated for sperm head counts; the other testis was dissected by transillumination, and the length of seminiferous epithelial stages determined. After 15 (control: 4.8 +/- 0.2 mm; 100 micrograms: 6.0 +/- 0.3 mm; 300 micrograms: 6.6 +/- 0.3 mm) and 30 days (control: 4.6 +/- 0.2 mm; 100 micrograms: 6.3 +/- 0.2 mm; 300 micrograms: 5.9 +/- 0.2 mm) of treatment the length of the "strong" seminiferous tubule segment in FRP-treated rats was greater than in control rats (p less than 0.05). Serum levels of steroids and FSH were similar in all groups. After 30, 45, and 70 days of treatment, the sperm head counts for the 100-micrograms and 300-micrograms dosages were 26%, 29%, 30% and 20%, 34%, and 24% of control values, respectively. By 70 days of treatment, cycle Stage VII was markedly reduced or absent in FRP-treated rats, and their round spermatids contained ring chromatin; both conditions indicate degeneration. FRP (50 micrograms/ml) was added to rat Sertoli cell cultures for 4 days after which transferrin and androgen-binding protein (ABP) were measured. FRP enhanced Sertoli cell secretion of ABP (58 vs. 138 +/- 7 microliters eq/culture) and transferrin (2.1 vs. 4.7 +/- 0.6 microgram/culture). In conclusion, systemic injection of FRP alters seminiferous epithelial function by reducing maturation of mature sperm forms. Adding FRP to Sertoli cells in culture enhances secretion of transferrin and ABP; this suggests that maturation of the germinal elements may be linked to the secretory function of seminiferous tubules.