Germ cell control of testin production is inverse to that of other Sertoli cell products

Recent studies have shown that germ cells can regulate testins, two newly identified Sertoli cell proteins that are associated with junctional complexes. To investigate this possibility, several parameters of Sertoli cell function were investigated over 2-120 days post exposure of the rat testes to x-rays (3 Grays). The irradiation-induced loss of spermatogonia resulted in a maturation-depletion process progressively affecting all germ cell classes. Testis weight began to decrease when the most numerous germ cell type (spermatids) began to decline. A complete or near complete recovery of spermatogenesis and of the testis weight had occurred by day 120 post irradiation. There was no significant change in FSH, epididymal androgen-binding protein, and tubule fluid levels during the first weeks after irradiation, when the seminiferious epithelium was depleted of spermatogonia and germ cells up to early spermatids. In contrast, when the number of the more mature forms of spermatids declined (between day 21 and 54), FSH rose and androgen-binding protein as well as fluid production declined. The subsequent recovery of these parameters was also highly correlated with the number of late spermatids. By contrast, testicular testin contents reacted to the depletion of germ cells with a biphasic increase; a doubling occurred when spermatogonia, spermatocytes, and early spermatids were absent (days 4-28), and a 7-fold rise occurred by day 37 when the number of late spermatids had decreased by 50%. By day 54, when the sperm counts had reached a nadir, testin contents had returned to levels corresponding to about four times the control levels; they progressively recovered thereafter. These observations support the postulate that germ cells negatively regulate testins. This possibility was investigated with in vitro experiments showing that addition of germ cell-conditioned medium to Sertoli cell monolayers inhibited testin secretion in a dose-dependent manner. In conclusion this study; 1) highlights the complex interplay between the various germ cell classes in the control of the Sertoli cell function in the adult testis; 2) establishes that germ cell effects may be opposite on different Sertoli cell products; 3) demonstrates that several classes of germ cells negatively control testicular testin contents; and 4) emphasizes the particular role of late spermatids in Sertoli cell regulation.     

Morphology and function of rooster efferent ductule epithelial cells in culture

Regulation of the excurrent ducts of the testis is not well understood, particularly in avian species. To investigate the role of steroid hormones in the male reproductive tract, we developed a primary cell culture of epithelia isolated from rooster ductuli efferentes (efferent ductules). Efferent ductules of the avian testis comprise 77% of the epididymal region and form a mass of tubules containing a heavily folded epithelium enmeshed in connective tissue. The epididymal region was separated by microdissection and small epithelial plaques isolated by serial digestion with collagenase, elastase and repeated pipetting. Isolated cell plaques were cultured in a bicameral chamber on Millicell-CM inserts coated with two layers of basement membrane matrix, consisting primarily of laminin and Types I and IV collagen. Active ciliary beat was observed before plating and this activity was maintained for 14 days in culture. Cell plaques attached within 24 h and outgrowths formed a confluent monolayer by 5-6 days. The epithelial nature of cultured cells was demonstrated by immunocytochemical staining for cytokeratin. Light and electron microscopy confirmed that morphology and polarity of the original epithelial cells were maintained in culture. Cultured efferent ductal epithelium was cuboidal in shape and maintained many of the cytoplasmic organelles typical of these cells in vivo. The uptake of cationic ferritin indicated the endocytotic activity of these cultured cells was maintained. Estrogen receptor mRNA expression was maintained in cultured cells. These data demonstrate avian efferent ductal epithelium can be isolated and grown in defined culture medium for the purpose of determining the role of hormones and other factors in regulating the function of the epididymal region in the bird.     

Rat sperm surface mannosidase is first expressed on the plasma membrane of testicular germ cells

In previous publications (Tulsiani et al., Biochem J 1993; 290:427-436 and Tulsiani et al., Dev Biol 1995; 167:584-595), we reported that sperm surface mannosidase is present in rat testis and is modified during spermatogenesis and sperm maturation. The present studies were directed towards examining the origin of alpha-D-mannosidase activity present on fertile spermatozoa. Mixed germ cells prepared after sequential enzymatic digestions of rat testis were separated by unit gravity sedimentation using 2-4% linear bovine serum albumin gradient. Fractions enriched in spermatocytes, round spermatids, and condensed/elongated spermatids (> 95% pure cells) were separately pooled and assayed for [3H]Man9-mannosidase activity before (intact) and after lysis with Triton X-100. Interestingly, the cells contained a significant level of alpha-D-mannosidase activity. Approximately 70% of the total [3H]Man9-mannosidase activity present in the detergent-solubilized germ cell extract cross-reacted with anti-rat sperm mannosidase, and 25% of the activity cross-reacted with anti-Golgi mannosidase I. This result indicates that most of the mannosidase activity present in the germ cell extract is antigenically similar to the enzyme present on the cauda spermatozoa. Using cell fractionation techniques, we obtained evidence suggesting that the germ cell-associated mannosidase activity is an integral component of the plasma membranes. Taken together, these results indicate that sperm surface mannosidase is first expressed on the testicular germ cells.     

Lamin-binding fragment of LAP2 inhibits increase in nuclear volume during the cell cycle and progression into S phase

It is hypothesized that the two-cell model for estrogen production by the ovarian follicle is preserved in the primate corpus luteum, but there is little direct evidence to support this theory. To determine the sites of androgen and estrogen synthesis within the primate corpus luteum and to ascertain whether changes in steroid hormone levels are related to steroidogenic enzyme expression, the enzymes converting progesterone to androgen (cytochrome P450 17alpha-hydroxylase/17,20 lyase; P450(c17)) and then to estrogen (aromatase; P450(arom)), as well as P450 side-chain cleavage (P450(scc)) and 3beta-hydroxysteroid dehydrogenase (3beta HSD), were detected by immunohistochemistry in macaque luteal tissue throughout the menstrual cycle and simulated early pregnancy. Corpora lutea were collected from rhesus monkeys in the early (Days 2-4 post-LH surge), mid (Days 6-8), mid-late (Days 10-12), and late (Days 14-15) luteal phase and after 1, 3, 6, or 9 days of hCG treatment that began on Day 9 of the luteal phase. Specific cytoplasmic staining for P450(c17), P450(arom), P450(scc), and 3beta HSD was present in luteal cells, but not in the microvasculature, within all luteal tissues examined. P450(c17)-stained luteal cells were located along the vascular tracts and around the periphery of the corpus luteum. Intensely stained luteal cells were associated with blood vessels entering from the outer surface of the corpus luteum, but not with blood vessels returning from the connective tissue centrum. In contrast, P450(arom)-stained luteal cells were distributed throughout the luteal parenchyma. P450(c17) staining intensity was similar at all stages of the luteal phase; however, the number and intensity of P450(arom)-stained cells decreased by late luteal phase. In simulated early pregnancy, cells stained for P450(c17) were present near blood vessels, with some positive cells scattered throughout the corpus luteum. P450(arom) immunostaining was heterogeneous within the corpus luteum; many intensely stained cells were interspersed among others that were only lightly stained. Overall, cellular staining for P450(c17) and P450(arom) remained intense through 9 days of simulated early pregnancy. In contrast, P450(scc) and 3beta HSD immunoreactivity were not located in distinct luteal compartments. These results are consistent with a two-cell model for steroid hormone production in the primate corpus luteum, whereby paraluteal (theca-luteal) cells produce androgen substrate that is converted to estrogens by true (granulosa-) luteal cells. The divergence in enzyme detection as the luteal phase progresses, with P450(c17) labeling high and P450(arom) staining having decreased, suggests a shift in the function of the corpus luteum as it ages. Enzyme localization during chorionic gonadotropin exposure simulating early pregnancy demonstrates the continued capacity of the primate corpus luteum to produce steroid hormones.     

Expression and possible role of muscle-type carnitine palmitoyltransferase I during sperm development in the rat

Because we had found whole testis from adult rats to be much richer in the messenger RNA for the muscle (M) than for the liver (L) form of mitochondrial carnitine palmitoyltransferase I (CPT I), we sought to determine which cell type(s) accounts for this expression pattern and how it might relate to reproductive function. Studies with immature (14-day-old) and adult animals included 1) Northern blot analysis of testis mRNA; 2) in situ hybridization with slices of testis; 3) enzyme assays for CPT I, CPT II, and carnitine acetyltransferase (CAT) in testicular germ cells and nongerm cells, together with measurement of the malonyl-coenzyme A (CoA) sensitivity and affinity for carnitine of CPT I; 4) labeling of testicular CPT I with [3H]etomoxir, a covalent inhibitor of the enzyme; and 5) the response of testicular and nontesticular CPT I to dietary etomoxir. The data established the following: 1) L-CPT I was the sole isoform detected in immature testis. 2) Expression of the M-CPT I gene was associated only with meiotic and postmeiotic germ cells. 3) Adult testis contains a mixture of the L- and M-CPT I enzymes, the L and M form dominating in extratubular cells and spermatids, respectively. Mature epididymal spermatozoa appear to be devoid of CPT I activity while possessing abundant levels of CPT II and CAT. 4) Five days of dietary etomoxir treatment at a dose that resulted in essentially complete inhibition of CPT I in liver, heart, skeletal muscle, and kidney was totally without effect on either the L- or M-type enzyme in the testis of mature rats. The data point to an important role for transient expression of M-CPT I, coupled with sustained activity of CAT, in the maturation and/or function of rat sperm. They also suggest that, at least in the case of one CPT I inhibitor (etomoxir), the testis is unusually resistant to the agent when given orally.     

Controlled comparison of percutaneous and microsurgical sperm retrieval in men with obstructive azoospermia

A controlled comparison of the efficacy and reliability of sperm retrieval by testicular fine needle aspiration (TFNA), percutaneous testicular needle biopsy (PercBiopsy) and microsurgical epididymal sperm aspiration (MESA) was performed in nine patients with obstructive azoospermia. During a planned MESA procedure, sperm retrieval was attempted on the same testis with TFNA and PercBiopsy. Spermatozoa were obtained from all patients using MESA and PercBiopsy. Spermatozoa were retrieved using TFNA from 6/9 (67%) men. The mean number of epididymal spermatozoa retrieved with MESA (15 x 106) was significantly higher (P = 0.003) than that retrieved percutaneously from the testis. The mean number of spermatozoa obtained by PercBiopsy was 0.116 x 10(6) while TFNA recovered 0.014 x 106 spermatozoa (P = 0.025). MESA is the optimal choice to retrieve the greatest number of spermatozoa with highest motility for assisted reproduction and subsequent cryopreservation. However, percutaneous testicular retrieval does not require microsurgical expertise and is less invasive. Our results suggest that the optimal percutaneous procedure for sperm retrieval from the testis involves percutaneous testicular needle biopsy with an automatic biopsy gun.     

A randomized, controlled trial of intravenous clodronate in patients with metastatic bone disease and pain

The present study analyses cell loss and proliferation which account for the decrease in the number of germ cell populations in the senile male Octodon degus. This is a good model to study ageing in wild animals, since it has recently been incorporated as a laboratory animal but still has a high degree of genetic heterogeneity, thus representing a situation found in natural systems. The cell loss from pachytene spermatocytes to round spermatids is estimated by cell counts in the cross section of seminiferous tubules. DNA testicular synthesis is measured by scintillation counting and the index of labelling of spermatogonia by radioautography of testes comparing sexually mature young animals and senile animals. Other determinations in both groups are testis weight, thickness of the albuginea and tubular wall, daily sperm production, percentage of depleted seminiferous tubules and nuclear cell diameters of germ cells. The results suggest a decrease in the number of cell population in the senile animals resulting from an increase in physiological cell loss coupled with a decreased proliferative spermatogonial activity. There is also a decreased yield of meiosis in terms of round spermatid production. Lowered testosterone levels both in plasma and testicular parenchymal fluid are found in senile animals. All these senescent changes reflect an altered remodelling activity of the seminiferous epithelium and presumably also of Leydig cells.     

Differential responses of the heart and vasculature to chronic blood pressure reduction in essential hypertension

In the current study, localization of D-aspartic acid (D-Asp) in rat testis was studied by immunohistochemical and biochemical techniques. Immunohistochemical staining of this tissue using specific polyclonal antibody to D-Asp revealed D-Asp immunoreactivity (IR) in the cytoplasm of germ cells, especially around the region rich in elongate spermatids, the most mature of the germ cells. Weak IR was also noted in cytoplasm of spermatocytes and round spermatids; however, it was negligible in interstitial cells and Sertoli cells. The intensity of immunostaining in each seminiferous tubule differed according to its distinct germ cell composition. In testis of young rats, seminiferous tubules lack elongated spermatids, and D-Asp was found to be localized in spermatocytes, the most mature population of germ cells at that age. We used various toxicants to destroy specific testicular cell populations and to confirm the localization of D-Asp in rat testis. Administration of ethane dimethane sulfonate induced a selective destruction of all Leydig cells in this tissue. This resulted in a significant decrease in the D-Asp level, which was probably due to a drop in testosterone brought about by this treatment, and this was followed by a modulation of spermatogenesis. Three days after treatment with methoxyacetic acid (MAA), many seminiferous tubules were found to lack or to have severe depletions of pachytene spermatocytes, but not of elongate spermatids. This caused reductions in protein content and in the total amount of L-Asp, but not that of D-Asp. Twenty days after treatment with MAA, the depleted population of germ cells progressed through the spermatogenic cycle from pachytene spermatocytes to elongate spermatids. At this time, the level of D-Asp decreased significantly, as did that of L-Asp and protein, consistent with D-Asp localization in elongate spermatids. This decrease in the D-Asp level was also seen with immunostaining.     

Expression of alpha-fetoprotein and stem cell factor/c-kit system in bile duct ligated young rats

We report the synthesis by mouse testicular cells of antibiotic peptides related to the defensins secreted by the Paneth cells of the intestinal epithelium. A Sertoli cell-derived line (15P-1), Sertoli cells in primary cultures, and explanted testicular tissue in culture medium were observed to release protease-sensitive material with a broad-spectrum antibacterial activity. The activity of 15P-1 culture medium was increased 10- to 50-fold in the presence of fractions enriched in round spermatids and of nerve growth factor. Two series of results suggest that this activity may correspond to the release by testicular cells of defensin peptides, and specifically, of peptides of the cryptdin family first identified in the Paneth cells of intestinal crypts. First, a characteristic nucleotide sequence corresponding to the conserved first exon of the mouse cryptdin and cryptdin-related (CRS) genes was evidenced in the RNA of 15P-1 cells and of the testis. Second, immunohistochemical analysis demonstrated the presence of cryptdins of the cryp-1, -2, -3, -6 group in 15P-1 cells, and identified two distinct localizations in the testis. Inside the seminiferous tubule, these cryptdins were found accumulated in Sertoli cells at stages corresponding to the maturation of spermatids. In the interstitial space, Leydig cells also contained immunoreactive cryptdins.     

Aromatase-immunoreactive neurons in the adult female chicken brain detected using a specific antibody

Estrogen formation in the brain catalysed by the cytochrome P450arom is required for the control of estrogen-dependent neural mechanisms regulating reproductive behaviour. A polyclonal antibody was raised against a 15-amino acid fragment of the chicken ovarian P450arom protein, to localise aromatase-immunoreactive (AR-IR) cells in the adult female chicken brain. Specificity of antibody reaction was established by Western blot and by inhibition of aromatase activity in homogenates of chicken ovarian follicles determined by a radiometric assay. The AR-IR material in the brain was localised in the perikarya and some of their adjacent cytoplasmatic processes. Intense immunoreactivity was observed in the preoptic region as well as in other hypothalamic nuclei. AR-IR cells were also found in extrahypothalamic areas; in particular, in the area entorhinalis and hippocampus. These results confirm histologically that aromatization of testosterone in the adult female chicken brain occurs in preoptic nuclei closely associated with the regulation of reproductive behaviour. The mapping of AR-IR cells in the female chicken brain now allows study of its regulation under different physiological and environmental conditions, and its relation to classic target areas expressing estrogen receptors.     

Distribution of spermatogenesis in the testicles of azoospermic men: the presence or absence of spermatids in the testes of men with germinal failure

The aim of the study was to determine whether a prior diagnostic testicle biopsy can predict success or failure of testicular sperm extraction (TESE) with intracytoplasmic sperm injection (ICSI) in patients with non-obstructive azoospermia caused by testicular failure, and what is the minimum threshold of sperm production in the testis which must be surpassed for spermatozoa to reach the ejaculate. Forty-five patients with non-obstructive azoospermia caused by testicular failure underwent diagnostic testicle biopsy prior to a planned future TESE-ICSI procedure. The diagnostic testicle biopsy was analysed quantitatively, and correlated with the quantitative findings of spermatogenesis in patients with normal spermatogenesis, as well as with the results of subsequent attempts at TESE-ICSI. Men with non-obstructive azoospermia caused by germinal failure had a mean of 0-6 mature spermatids/seminiferous tubule seen on a diagnostic testicle biopsy, compared to 17-35 mature spermatids/tubule in men with normal spermatogenesis and obstructive azoospermia. These findings were the same for all types of testicular failure whether Sertoli cell only, maturation arrest, cryptorchidism, or post-chemotherapy azoospermia. Twenty-two of 26 men with mature spermatids found in the prior testis biopsy had successful retrieval of spermatozoa for ICSI, 12 of their partners became pregnant, and are either ongoing or delivered. The study suggests that 4-6 mature spermatids/tubule must be present in the testis biopsy for any spermatozoa to reach the ejaculate. More than half of azoospermic patients with germinal failure have minute foci of spermatogenesis which are insufficient to produce spermatozoa in the ejaculate. Prior diagnostic testicle biopsy analysed quantitatively (for the presence of mature spermatids) can predict subsequent success or failure with TESE-ICSI. Incomplete testicular failure may involve a sparse multi-focal distribution of spermatogenesis throughout the entire testicle, rather than a regional distribution. Therefore, it is possible that massive testicular sampling from many different regions of the testes may not be necessary for successful TESE-ICSI.     

Differential localization of fibroblast growth factor receptor-1, -2, -3, and -4 in fetal, immature, and adult rat testes

Fibroblast growth factors (FGFs) are essential for embryonic development and have been implicated in testis development and function. The effects of FGFs are mediated through four high-affinity receptors (FGFRs), which have different binding affinities for each of the ligands. We have used indirect avidin-biotin-horseradish peroxidase-enhanced immunohistochemistry to localize FGFR-1, -2, -3, and -4 in fetal, immature, and adult rat testes. In the fetal testis, immunoreactivity for FGFR-1 was seen in gonocytes, Sertoli cells, Leydig cells, and mesenchyme, and FGFR-3 was localized in gonocytes. In the immature testis, FGFR-1 was localized to spermatogonia, and all four FGFRs were localized in pachytene spermatocytes, immature adultlike Leydig cells, and peritubular cells. In the adult testis epithelium, Sertoli cells were immunoreactive for FGFR-4, and germ cells were immunoreactive for all four FGFRs, with specific receptors localized to specific stages of germ cell development. In the adult testis interstitium, FGFR-1, -2, and -4 were localized in Leydig cells, and FGFR-1 and -4 were also localized in peritubular cells. The discrete cell- and stage-specific localization of FGFRs in the fetal, immature, and adult rat testis suggests that FGFs exert specific roles through these receptors in spermatogenesis, Leydig cell function, and testicular development.     

Use of immature germ cells for the treatment of male infertility

Both animal experimentation data and preliminary clinical experience converge to suggest that normal progeny can be obtained by fertilizing oocytes with spermatids, the youngest male germ cells to have a set of haploid chromosomes. Spermatids can be obtained from the ejaculate of many patients with non-obstructive azoospermia. The use of ejaculated spermatids in the treatment of non-obstructive azoospermia is thus to be considered as an alternative to that of testicular spermatozoa. Fertilization with ejaculated spermatids makes it possible to avoid the potential adverse consequences of extensive testicular biopsy and may thus become the treatment of first choice. The recourse to testicular spermatids represents a treatment of last chance if no spermatids can be recovered either from the ejaculate and no spermatozoa from the testis.