Aspects on the formation and detection of tissue levels of anabolic steroids in domestic animals

Anabolic agents used in animal production can be classified according to their biological activity into compounds with oestrogenic, androgenic and gestagenic activity and according to the structure into endogeneous steroids, extraneous steroids and non-steroidal compounds. Metabolism of endogenous steroids is well established, a major principle being the formation of biologically less active metabolites, whilst the metabolism is not yet fully understood for non-endogenous steroids. Differences between compounds exist and it can be assumed that those with a high oral activity are only to a small extent biodegraded. Tissue residues of anabolic steroids can be expected in the ng/g to pg/g range. By using radioimmunoassay techniques, these low level residues and the naturally occurring tissue-concentration of endogenous steroids can be quantitated. Depending on the. animal and the tissue, endogenous steroids exhibit large variations. Oestrone was > 2 ng/g in muscle from a pregnant cow and, like oestradiol-17β, generally < 0.1 ng/g in all tissues in veal-calves, heifers and steers. Testosterone was highest in the bull (0.5 ng/g–11 ng/g), then the heifer (0.1 ng/g–0.6 ng/g) and veal-calf (0.02 ng/g–0.3 ng/g). Progesterone in fat was > 300 ng/g in pregnant cows and 17 and 6 ng/g in non-pregnant heifers and calves respectively. After implantation of 20 mg oestradiol-17β combined with 200 mg testosterone or progesterone into veal-calves 70–77 days before slaughter the oestrogen-tissue concentrations were <0.1 ng/g and the testosterone and progesterone concentrations were slightly elevated but still lower or in the same range as in heifers. Implantation of 140 mg trienbolone acetate (TBA) into veal-calves 70–77 days before slaughter yielded residues of free trienbolone between 0.13 and 0.5 ng/g. It is concluded that endogenous hormones are natural constitutents of edible animal tissue and that the amount of residues present in treated or untreated animal will not measurably contribute to the levels already seen in the human. In the case of extraneous compounds residues should be graded according to normal toxicological criteria.     

Seasonal changes in testicular contents and plasma concentrations of androgens in the desert gerbil (Gerbillus gerbillus)

Gerbils were caught in the Béni-Abbès area (Algeria). Testicular endocrine activity was highest in spring (testicular wt 298 +/- 10 mg; seminal vesicle wt 603 +/- 62 mg; testicular testosterone and androstenedione content 9.2 +/- 1.7 and 0.5 +/- 0.1 ng/testis; plasma testosterone 832 +/- 200 pg/ml). Values decreased in summer, were lowest in late summer and in autumn (84 +/- 17 mg; 40 +/- 14 mg; 0.20 +/- 0.06 and 0.02 +/- 0.01 ng/testis; 228 +/- 54 pg/ml, respectively) and increased again in winter (December-January). The onset of testicular endocrine activity was concomitant with the lowest temperatures and the shortest photoperiod; it increased when temperatures and daylength were increasing and began to decline when temperatures and photoperiod were still maximal. These seasonal changes in the endocrine activity of the testis of the gerbil differ from those of the sand rat inhabiting the same area.     

Morphometric analysis of Leydig cells in the normal rat testis

Leydig cells are thought to be the source of most, if not all, the testosterone produced by the testis. The goal of this study was to obtain quantitative information about rat Leydig cells and their organelles that might be correlated with pertinent physiological and biochemical data available either now or in the future. Morphometric analysis of Leydig cells in mature normal rats was carried out on tissue fixed by perfusion with buffered glutaraldehyde, and embedded in glycol methacrylate for light microscopy and in Epon for electron microscopy. In a whole testis, 82.4% of the volume was occupied by seminiferous tubules, 15.7% by the interstitial tissue, and 1.9% by the capsule. Leydig cells constituted 2.7% of testicular volume. Each cubic centimeter (contained approximatelyy 1 g) of rat testis contained about 22 million Leydig cells. An average Leydig cell had a volume of 1,210 micron3 and its plasma membrane had a surface area of 1,520 micron2. The smooth endoplasmic reticulum (SER), the most prominent organelle in Leydig cells and a major site of steroidogenic enzymes, had a surface area of approximately 10,500 micron2/cell, which is 6.9 times that of the plasma membrane and is 60% of the total membrane area of the cell. The total surface area of Leydig SER per cubic centimeter of testis tissue is approximately 2,300 cm2 or 0.23 m2. There were 3.0 mg of Leydig mitochondria in 1 g of testis tissue. The average Leydig cell contained approximately 622 mitochondria, measuring on the average 0.35 micron in diameter and 2.40 micron in length. The mitochondrial inner membrane (including cristae), another important site of steroidogenic enzymes, had a surface area of 2,920 micron2/cell, which is 1.9 times that of the plasma membrane. There were 644 cm2 of inner mitochondrial membrane/cm3 of testis tissue. These morphometric results can be correlated with published data on the rate of testosterone secretion to show that an average Leydig cell secretes approximately 0.44 pg of testosterone/d or 10,600 molecules of testosterone/s. The rate of testosterone production by each square centimeter of SER is 4.2 ng/d or 101 million molecules/s: the corresponding rate for each square centimeter of mitochondrial inner membrane is 15 ng testosterone/d or 362 million molecules/s.     

Cholesterol substrate pools and steroid hormone levels are normal in the face of mutational inactivation of NPC1 protein

Mutational inactivation of NPC1 largely blocks the movement of LDL-derived cholesterol from the lysosome to the metabolically active, cytosolic pool of sterol that is the substrate for steroid hormone production. Such a block might, in theory, lead to deficiencies in circulating levels of testosterone, progesterone, and corticosterone. However, there are at least two other sources for cellular cholesterol, de novo synthesis and scavenger receptor class B type I-mediated uptake of HDL cholesteryl ester (CE). In this study, we measured the rates of net cholesterol acquisition by these three pathways in the adrenal, ovary, and testis. In all three organs, the majority (81-98%) of cholesterol acquisition came from the selective uptake of CE from HDL and de novo synthesis. Furthermore, in the npc1(-/-)mouse, the cytosolic storage pool of CE in a tissue such as the adrenal remained constant (approximately 25 mg/g). As a result of these alternative pathways, the plasma concentrations of testosterone (3.5 vs. 2.5 ng/ml), progesterone (8.5 vs. 6.7 ng/ml), and corticosterone (391 vs. 134 ng/ml) were either the same or elevated in the npc1(-/-)mouse, compared with the control animal. Thus, impairment of cholesterol acquisition through the NPC1-dependent, clathrin-coated pit pathway did not limit the availability of cholesterol substrate for steroid hormone synthesis in the steroidogenic cells.     

Radioimmunoassay of testosterone in late fetal and newborn rabbit plasma, gonads and adrenal glands]

A radioimmunoassay was used for measuring testosterone in the plasma, gonads and adrenals of 28, 29, 30 and 31-day-old rabbit fetuses of both sexes and newborns. A marked sex difference was shown in the concentrations of testosterone in plasma and in gonads whereas in adrenals the levels of testosterone were low in both sexes (34 to 147 pg/10 mg). In male fetuses, plasma testosterone levels increased from the 28th (133 +/- 20 pg/ml) to the 31st day (361 +/- 119 pg/ml) of intrauterine life, reaching then the values observed in the newborns (387 +/- 73 pg/ml). Plasma from males, on the other hand contained, at all stages studied, significantly more testosterone than plasma from female fetuses (21 +/- 6 to 41 +/- 11 pg/ml) and female newborns (42 +/- 6 pg/ml). In the same way, fetal testicular testosterone concentrations varying from 1 382 +/- 218 to 2 317 +/- 333 pg/10 mg were similar to those measured in the newborns (1 940 +/- 304 pg/10 mg) and significantly higher than fetal (13 to 34 pg/10 mg) or neonatal (44 pg/10 mg) ovarian concentrations. These results showed at evidence the endocrine activity of the fetal testis during this period.     

Basal and HCG-stimulated testosterone production by interstitial cells of the Mongolian gerbil (Meriones unguiculatus)--I. Influence of preincubation length, medium composition and temperature

In the absence of HCG, production of testosterone by whole testes superfused in vitro was quite constant during the 5-hr superfusion period. Addition of 23-184 mIU/ml HCG caused a significant increase of testosterone production which was apparent from 30 min after start of superfusion. Basal and HCG-stimulated testosterone production by whole testes was significantly higher (400, 1950 ng/testis/5 hr, without and with 100 mIU HCG) than by isolated cells (200, 1350 ng/testis/5 hr). Incubation of isolated interstitial cells in medium 199 supplemented with fetal calf serum (FCS), (N-2-hydroxyethylpiperazine-N-2-ethanesulphonic acid, HEPES) and 3-isobutyl-methylxanthine (MIX), and in medium 199 without FCS, HEPES or MIX, gave similar testosterone responses. While centrifugation at 8000 g for 2 min drastically diminished testosterone formation by isolated interstitial cells, production was similar by cells incubated in either 0.5, 1.0 or 1.5 ml medium. A significant decrease of testosterone synthesis by isolated interstitial cells was found when cells were stored at 4 degrees C for 2 days and then were incubated at 35 degrees C for 6 hr without or with 1-1000 microIU HCG. While isolated interstitial cells incubated at 5 degrees C did not produce testosterone at all, testosterone production increased to 49.5 +/- 3.9 ng/10(5) cells (30 degrees C) and 24.1 +/- 1.1 ng/10(5) cells (40 degrees C), respectively. HCG-stimulated testosterone production was maximal when interstitial cells were incubated at 34 degrees C.     

An enzyme-linked immunoassay of testosterone

An enzyme-linked immunoassay of testosterone is described. The conjugation of testosterone with high specific activity horseradish peroxidase and a highly sensitive assay for this enzyme having previously been studied, here we describe the immobilization of the anti-testosterone antibody and the development of assay conditions permitting the determination of 50 pg to 1.5 ng testosterone in one working day. In this work attention has been paid to keeping the assay method as simple as possible. The method is discussed in terms of other enzyme-linked immunoassays for steroids.     

Involvement of D-Asp in P450 aromatase activity and estrogen receptors in boar testis

Summary. Mammalian testis contains D-aspartic acid (D-Asp), which enhances testosterone production. D-Asp, on other hand, also stimulates 17β-estradiol synthesis in the ovary of some lower vertebrates. We studied boar testis in order to determine if D-Asp intervenes in 17β-estradiol synthesis in the testis of those mammals which produce significant amounts of estrogens as well as testosterone. The boar testis contains D-Asp (40 ± 3.6 nmol/g tissue) which, according to immunohistological techniques, is localized mainly in Leydig cells, and, to a lesser extent, in sustentacular (Sertoli), peritubular and some germ cells. The enzyme P450aromatase is present in Leydig cells and few germ cells. In vitro experiments showed that the addition of D-Asp to testicular tissue extracts induced a significant increase of aromatase activity, as evaluated by testosterone conversion into 17β-estradiol. The enzyme’s K_m was not affected by D-Asp (about 25 nM in both control and D-Asp added tests). On the basis of these results we suggest that, as in the ovary, D-Asp is involved in the local control of aromatase activity of boar testis and, therefore, it intervenes in the 17β-estradiol production. In the testis, the D-Asp targets are presumably the Leydig cells, which having also a nuclear estrogen receptor are, in turn, one of the putative targets of the 17β-estradiol that they produce (autocrine effect).     

The roles of prolactin and testosterone in the development and function of granulosa lutein tissue in the rat

The luteotropic roles of prolactin and testosterone (or estradiol formed in luteal tissue) were investigated in hypophysectomized rats with homografts of granulosa lutein tissue. Using this approach, we could determine the effects of prolactin independently of estrogen, since granulosa lutein tissue does not produce estrogen de novo under these conditions. Luteinizing granulosa cells were expressed from the ovaries of immature pregnant mare's serum gonadotropin-primed Fischer 344 rats 6 h after injection of human chorionic gonadotropin. The cells were transplanted beneath the kidney capsule of adult, hypophysectomized, ovariectomized Fischer 344 recipients, which were treated with hormones daily for 12 or 14 days. In rats without treatment (no hormones, n = 3) and in rats treated with only testosterone (Silastic capsule, n = 6), only small amounts of luteal tissue (less than 5 mg/rat) were found and serum progesterone remained at low concentrations (10 ng or less) throughout the experiment. In contrast, in rats treated either with ovine prolactin (300 micrograms/day, n = 10) or with the combination of prolactin and testosterone (n = 12), serum progesterone increased to 43 ng/ml by Day 8. Beyond Day 8, serum progesterone continued to rise in rats treated with the combination of prolactin and testosterone to reach a mean value of 87 ng/ml by Day 14, and mean homograft wet weight was 49 mg/rat; in rats treated with only prolactin, serum progesterone decreased to 25 ng/ml by Day 14 and homograft wet weight was lower (24 mg/rat). Prolactin and testosterone together stimulated more homograft aromatase activity in vivo than did prolactin alone, but the in vitro production of progesterone was not different.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes of basal and steroidal precursor-stimulated testosterone secretion in isolated Mongolian gerbil and guinea pig testes after a single episode of heating

1. In the absence of steroidal precursors, testosterone secretion by Mongolian gerbil testes incubated at 37 degrees C was 340 ng/g tissue/4 hr. Addition of 1 microgram progesterone or DHEA drastically stimulated testosterone secretion by testes incubated at 37 degrees C (progesterone: 3281 ng/g tissue/4 hr, DHEA: 4654 ng/g tissue/4 hr). 2. While neither basal nor DHEA-stimulated production of testosterone was significantly affected by a single episode of heating (43-44 C for 30 min), progesterone-stimulated testosterone secretion markedly decreased during the 4-hr incubation period. 3. In contrast, in isolated testes of adult guinea pigs, a single episode of heating (44 degrees C for 30 min) resulted in a drastic reduction of basal and precursor-stimulated testosterone production during the 4-hr incubation period. 4. From these data it appears that enzymatic activities in the testes of the two species do not have their maxima at the same temperature, but rather in each case at, or close to, the temperature prevailing in the scrotal testis.     

Acute and sub-acute effects of 2-butenoic acid-3-(diethoxy phosphinothioyl) methyl ester (RPR-II) on testis of albino rat

Acute and sub-acute toxic effects of a novel phosphorothionate coded as RPR-II on testis of albino rats were studied. In acute study rats received a single dose of 12.3 mg/kg of RPR-II and sacrificed after 24 hr. For sub-acute study 0.58 mg/kg/day was administered orally to rats for 10 and 21 days. Acute exposure of rats to RPR-II brought no change either in the gonadosomatic index (GSI) or in the structure of testis or in the serum levels of testosterone. Testis glutathione (GSH) level and glutathione S-transferase (GST) activity was significantly decreased whereas, acid phosphatase (AcP) levels increased significantly at 24 hr post-treatment. On 7th day (withdrawal period) after the cessation of the treatment the GSH, GST, AcP, and AkP levels reached to near control. The sub-acute study revealed a significant decrease in GSI on 10th and 21st day of the treatment. In contrast, a time-dependent and significant increased in GSH level and GST activity was observed on 100th and 21st day of post-treatment, except GSH level on 10th day, which was declined. Due to RPR-II treatment the testis AcP and alkaline phosphatase (AkP) levels were significant at both 10th and 21st day of medication but AcP levels were increased whereas AkP levels decreased. The histopathological studies on day 10th showed considerable loss of spermatozoids in testis and at 21st day complete derangement of cellular organization was observed. Testosterone levels decreased significantly on 10th day and remained significantly low at 21st day. However, withdrawal studies showed a recovery in testis of rat treated with RPR-II. GST, GSH, GSI, AcP and AkP values recovered, testosterone levels were also well recovered but recovery in testis structure remained at a low profile. The present study suggests that RPR-II may cause testicular toxicity in rats affecting the normal functioning of testis and it also gave some new information in withdrawal studies.     

Effect of protein-synthesis inhibitors on testosterone production in rat testis interstitial tissue and Leydig-cell preparations.

Luteinizing-hormone-stimulated testosterone biosynthesis was inhibited by cycloheximide during incubation of rat testis intersitial tissue in vitro and also by puromycin and cycloheximide during incubation of Leydig-cell preparations, but not by chloramphenicol. These results suggest that a protein regualtor(s) formed by cytoplasmic protein synthesis is involved in steroidogenesis in the rat testis. The specific effect of cycloheximide and puromycin on protein synthesis rather than on other non-specific processes is suggested by the inhibition of protein synthesis and steroidogenesis with different doses of the inhibitors and the lack of effect of cycloheximide on luteinizing-hormone-induced adenosine 3':5'-cyclic monophosphate production. Stimulation of testosterone production by luteinizing hormone during superfusion of interstitial tissue was detectable within 10-20 min and reached a maximum of 120 min, and thereafter slowly decreased. Cycloheximide added at maximum steroid production caused a rapid decrease in testosterone synthesis which followed first-order kinetics (half-life 13 min), thus indicating that the protein regulator(s) has a short half-life. No effect of cycloheximide, puromycin or chloramphenicol on testosterone production in the absence of added luteinizing hormone was found, suggesting that the basal production of testosterone is independent of protein synthesis.     

Gas chromatographic–tandem mass spectrometric determination of anabolic steroids and their esters in hair: Application in doping control and meat quality control

We have developed a powerful and simple sensitive method for testing hair for anabolic steroids and their esters. A 100-mg amount of powdered hair was treated with methanol in an ultrasonic bath for extraction of esters, then alkaline digested with 1 M NaOH for an optimum recovery of other drugs. The two liquid preparations were subsequently extracted with ethyl acetate, pooled, then finally highly purified using a twin solid-phase extraction on amino and silica cartridges. The residue was derivatized with N-methyl-N(trimethylsilyl)-trifluoracetamide (MSTFA) prior to injection. Analysis was conducted by gas chromatography coupled to a triple quadrupole mass spectrometer. The generally chosen parent ion was the molecular ion while two daughter ions were selected for each compound with collision energies ranging from −16 to −21 eV. Internal standards were nandrolone d₃ for non-esterified drugs and testosterone phenyl propionate for esters. The limits of detection calculated from an analysis of the blanks (n=30) were 0.08 pg/mg for nandrolone, 6.20 pg/mg for boldenone, 0.07 pg/mg for methyl testosterone, 0.15 pg/mg for ethinyl estradiol, 2.10 pg/mg for metandienone, 0.86 pg/mg for testosterone propionate, 0.95 pg/mg for testosterone cypionate, 1.90 pg/mg for nandrolone decanoate, 3.10 pg/mg for testosterone decanoate and 4.80 pg/mg for testosterone undecanoate. Application to doping control has been demonstrated. In a series of 18 sportsmen, two tested positive for anabolic steroids in hair whereas urinalysis was negative for both of them. The first positive case was nandrolone and the second case concerned the identification of testosterone undecanoate. Measured in 10 white males aged between 22 and 31 years, the testosterone concentration was in the range 1.7–9.2 pg/mg (mean=5.0 pg/mg). The method was also applied in meat quality control. Of the 187 analyses realized based upon hair and urine sampling in slaughter houses, 23 were positive for anabolic steroids in hair: one case for boldenone, one case for metandienone, two cases for testosterone propionate, three cases for nandrolone, five cases for testosterone decanoate and 11 cases for methyl testosterone. In the meantime, urinalysis was always negative for these drugs or their metabolites.     

Effects of various doses of testosterone propionate on intratesticular and plasma testosterone levels and maintenance of spermatogenesis in adult hypophysectomized rats.

Adult hypophysectomized rats were maintained on different regimens of testosterone propionate (TP) treatment for 27 days (0.2, 0.4, 0.6 and 1 mg/day) and autopsied 16 hours after the last injection. Blood samples were taken, sex organs were weighed and one testis from each animal was fixed in Bouins fluid for histologic analysis. The other testis and blood were used for testosterone (T) determinations. Both testicular and plasma T were below detectable levels in hypophysectomized control rats. The plasma T level showed a dose response relationship with increasing dose of TP but such was not the case for intratesticular T concentrations. Qualitative and quantitative evaluation of testis sections showed that spermatogenesis was incomplete in rats receiving 0.2 mg TP/day characterized by the absence of step 15 to 19 spermatids, degeneration of some pachytene spermatocytes and a significantly lower yield of B type spermatogonia. Analysis of testis sections from animals treated with 0.4 to 1 mg TP/day showed complete maintenance and maturation of pachytene spermatocytes, meiosis and spermiogenesis. However, even with the highest dose of TP (1 mg/day) the total yield of B type spermatogonia was only about 58% of the intact controls. It is concluded that at least 0.4 mg/day of exogenous TP is essential for qualitative maintenance of spermatogenesis in hypophysectomized rats with an intratesticular T concentration of 17 to 18 ng/gm testis.     

Effect of taurine on arterial, uterine and cardiac PGI2 and TXA2 synthesis in the rat

The influence of taurine (in drinking water for 6 weeks) on PGI2 and TXA2 synthesis by some female rat organs was investigated using radioimmunoassay and platelet antiaggregatory bioassay. Taurine 100 and 200 mg/kg/day increased aortic PGI2 release from 0.59 +/- 0.04 (control) to 0.85 +/- 0.05 and 1.01 +/- 0.06 ng/mg, respectively and that by the myometrium from 0.24 +/- 0.02 (control) to 0.38 +/- 0.01 and 0.50 +/- 0.04 ng/mg wet tissue, respectively (P less than 0.05, n = 6). It did not affect PGI2 and TXA2 production in the heart or TXA2 in the aorta. Taurine 200 mg/kg depressed uterine TXA2 synthesis from 148.6 +/- 9.8 (control) to 85.4 +/- 6.8 pg/mg (P less than 0.05, n = 6). Furthermore taurine 0.4 and 0.8 mM in vitro stimulated PGI2 release by the myometrial and aortic tissues from pregnant rats. The stimulant effect of taurine on PGI2 may be related to its antioxidant effect whereas its inhibitory effect on uterine TXA2 may result from direction of synthesis towards PGI2. It is concluded that endogenous taurine may participate in regulation of PGs synthesis and that prostanoids may contribute to its known actions. On broad basis, taurine-induced release of PGI2 may prove of potential value in those ailments characterised by deficiency in PGI2 release.     

Assessment of Testicular Corticosterone Biosynthesis in Adult Male Rats

Corticosterone is synthesized in the adrenal glands and is circulated throughout the body to perform regulatory functions in various tissues. The testis is known to synthesize and secrete testosterone and other androgens. We developed an accurate method to measure steroid content using liquid chromatography-mass spectrometry analysis. In the present study, significant levels of the precursor compounds of testosterone and corticosterone synthesis could be detected in rat testis using this method. After adrenalectomy, corticosterone remained in the blood and testicular tissue at approximately 1% of the amount present in the control testis. When the excised testicular tissue was washed and incubated with NADH, NADPH and progesterone, not only testosterone and its precursors but also 11-deoxycorticosterone and corticosterone were produced; the levels of 11-deoxycorticosterone and corticosterone increased with incubation time. The production rate of 11-deoxycorticosterone from progesterone was estimated to be approximately 1/20 that of 17-hydroxyprogesterone, and the corticosterone level was approximately 1/10 that of testosterone. These ratios coincided with those in the testicular tissue of the adrenalectomized rats, indicating that corticosterone was synthesized in the testis and not in the blood. A primary finding of this study was that corticosterone and testosterone were synthesized in a 1/10-20 ratio in the testis. It is concluded that corticosterone, which has various functions, such as the regulation of glycolysis and mediating spermatogenesis, is produced locally in the testis and that this the local production is convenient and functional to respond to local needs.     

Detection of platelet-derived growth factor-alpha (PDGF-A) protein in cells of Leydig lineage in the postnatal rat testis

Platelet-derived growth factor-A (PDGF-A) is a locally produced growth factor in the rat testis secreted by both Sertoli cells and Leydig cells. It has been suggested that PDGF-A may be involved in modulation of testosterone production and may be essential to Leydig cell differentiation, however it is not known at what stage of differentiation PDGF-A begins to be expressed in the cells of Leydig lineage in the postnatal rat testis. Therefore, the objectives of this research were to determine at what postnatal age and in which cell type is PDGF-A first expressed in cells of the adult Leydig cell lineage, and does PDGF-A expression coincide with expression of 3beta-hydroxysteroid dehydrogenase (3beta-HSD), an indicator of steroid hormone synthesis. Male Sprague Dawley rats of postnatal day 1, 7, 9-14, 21, 28, 40, 60, and 90 were used (n=6). Animals were euthanized and their testicles removed, fixed in Bouin's solution, embedded in paraffin, and 5 micrometers sections were prepared. Immunolocalization of PDGF-A and 3beta-HSD was carried out using a peroxidase-streptavidin-biotin method. PDGF-A was first detected in cells of the Leydig cell lineage at postnatal day 10 in progenitor cells, which were surrounding the seminiferous tubules (peritubular). These cells were confirmed to be the progenitor cells and not the mesenchymal or any other spindle-shaped cells in the testis interstitium by immunolocalization of 3beta-HSD and PDGF-A in the cells in adjacent sections of testis tissue from rats of postnatal days 10-14. After postnatal day 10, PDGF-A was continued to be expressed in subsequent cells of the Leydig lineage through day 90 (adult), however, was not present in peritubular mesenchymal precursor cells of the Leydig cell lineage or any other spindle-shaped cells in the testis interstitium at any tested age. These results revealed that PDGF-A first appears in Leydig progenitor cells in the postnatal rat testis at the onset of mesenchymal cell differentiation into progenitor cells at postnatal day 10 and suggest that a functional role(s) of PDGF-A in postnatally differentiated Leydig cells in the rat testis is established at the time of the onset of postnatal Leydig stem cell differentiation. It is suggested that the significance of the first expression of PDGF-A in the Leydig progenitor cells may be associated with inducing cell proliferation and migration of this cell away from the peritubular region during Leydig cell differentiation.     

Synthesis and degradation of cyclic nucleotides in the pituitary gland, ovary and testis of rats treated with D-Trp6-luteinizing hormone-releasing hormone

The effect of administration of D-Trp6-Luteinizing Hormone-Releasing Hormone (LH-RH) on synthesis and degradation of cyclic nucleotides was studied in the rat. There were no significant changes in the rate of synthesis and degradation of cyclic AMP in the ovary, testis and pituitary gland of D-Trp6-LH-RH-treated rats as compared to controls. On the other hand, the levels of cyclic GMP and activity of guanylate cyclase were significantly higher in the ovary and testis as well as in the pituitary gland of animals which received the analog. The rate of hydrolysis of cyclic GMP was unchanged by the administration of D-Trp6-LH-RH. Interestingly, the cyclic CMP phosphodiesterase seemed to be activated in animals treated with D-Trp6-LH-RH.     

Stimulation of the synthesis of steroids and steroid sulphates in human testicular tissue in vitro by hCG and by 8-bromo-cyclic AMP

Small pieces (10-20 mg) of human testis tissue were incubated for 4 h in the presence or absence of hCG and 8-bromo-cAMP and the concentrations of testosterone, some of its steroidal precursors, and their sulphates were measured by radioimmunoassays. The results showed, we believe for the first time, that the production of steroid sulphates as well as of unconjugated steroids can be stimulated in human testis tissue in vitro and they confirm earlier observations in vivo which suggested that testicular production of steroid sulphates can be stimulated by hCG.     

Ligandin concentrations in the steroidogenic tissues of the rat during development

Ligandin, a ubiquitous multifunctional cytoplasmic protein which exhibits glutathione S-transferase, glutathione peroxidase and Δ⁵-3-ketosteroid isomerase activities and binds to cortisol metabolites, is present in relatively high concentrations in gonadal and adrenal tissue. In contrast to hepatic ligandin, little is known about the ontogeny of ligandin in steroid-synthesising tissues. We report here the intracellular concentrations of ligandin as well as the serum concentrations of testosterone and progesterone measured by radioimmunoassay at different stages of development in the rat. Ligandin levels in testis, ovary and adrenal tissue were relatively high soon after birth, decreased by day 9 and increased rapidly during puberty to reach adult levels. These changes appeared to be paralleled by changes in the circulating levels of testosterone and progesterone. In contrast, ligandin levels in non-steroidogenically active tissues, such as liver and kidney, were low at birth and rose progressively to reach adult levels. Whereas hepatic ligandin concentration could be increased at all stages of development by phenobarbital induction, no induction occurred in the endocrine tissues.