The influence of dehydroepiandrosterone on basal and gonadotrophin-stimulated testosterone secretion by Mongolian gerbil interstitial cells incubated or superfused in vitro

1. Testosterone secretion by Mongolian gerbil interstitial cells incubated in the absence of HCG linearly increased with cell concentration (1 x 10(5) cells: 0.6 ng/4 hr, 10 x 10(5) cells: 8.0 ng/4 hr). Addition of 100 mIU HCG resulted in a drastic increase of testosterone secretion which was linear between concentrations of 1 x 10(5) and 4 x 10(5) cells. 2. Compared to HCG-stimulated testosterone release, secretion was significantly higher by cells incubated with 60-100 ng DHEA. 3. During the 4-hr incubation period, 53-69% of added progesterone and 72-88% of added dehydroepiandrosterone (DHEA) were converted to testosterone by cells freshly prepared or stored for 1-3 days at 4 degrees C. On the other hand, prolonged storage at 4 degrees C resulted in a marked decrease of HCG-stimulated testosterone secretion. 4. Testosterone secretion by interstitial cells superfused in vitro increased with the length of HCG (100 mIU/ml) application from 0.08 to 0.22 ng/10(6) cells/min (10 and 60 min, respectively). A much faster and pronounced elevation was found when cells were stimulated with DHEA (200 ng/ml: 0.06-0.80 ng/10(6) cells/min, 0 and 20 min, respectively). 5. After interstitial cells have been stimulated with a DHEA (200 ng/ml) pulse for 30 min and then superfused with medium only for an additional 30 min, testosterone secretion remained significantly elevated and could not be further stimulated by superfusing medium which contained as much as 100 mIU/ml HCG.     

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.     

Basal and HCG-stimulated testosterone production by interstitial cells of the Mongolian gerbil (Meriones unguiculatus)--II. Influence of glucocorticosteroids and steroidal precursors

Compared to testosterone production by Mongolian gerbil interstitial cells in the absence of HCG or precursors, testosterone formation was significantly elevated by the addition of 100 ng pregnenolone, progesterone, 17-hydroxyprogesterone or DHEA. Production increased linearly with the amounts of precursors added (pregnenolone: r = 0.99; progesterone: r = 0.98; 17-OH-progesterone: r = 0.96; DHEA: r = 0.92, N = 40, all P less than 0.001). Approximately 50% of DHEA were converted to testosterone during the 6-hr incubation period. Neither the addition of 100 ng 11-deoxycortisol, 11-deoxycorticosterone, cortisol, corticosterone, cortisone, 18-OH-corticosterone, 21-deoxycortisone or 11-dehydrocorticosterone, nor of 100 ng estradiol had a significant effect on testosterone production by isolated interstitial cells incubated without or with 1 mIU HCG. Testosterone production by isolated interstitial cells was significantly increased within 2 min after the addition of 100 ng DHEA; production then linearly increased with the length of incubation (r = 0.98, N = 40, P less than 0.001). After addition of as little as 2 ng DHEA, testosterone formation was higher than by cells incubated without DHEA. While testosterone production could not be stimulated by the addition of 1-500 microIU HCG during a 30-min incubation period, it was drastically elevated by the addition of 10, 20 or 100 ng DHEA. Steroidal precursor concentrations secreted by the Mongolian gerbil adrenal gland incubated in vitro for 120 min were too low to stimulate testosterone production by interstitial cells. On the other hand, testosterone synthesis could be increased by the addition of 10-100-microliter aliquots of adrenal extracts.     

Effect of time and temperature on bovine serum and plasma progesterone concentration

Whole blood, with and without anticoagulant, from 5 pregnant cows was incubated at 40°C for 0 (30 minutes after collection), 6 and 24 hours (hr) before the blood was centrifuged and the plasma or serum was frozen for later progesterone assay. Mean plasma progesterone concentration decreased from 6.6 ng/ml at 0 hr to 1.7 ng/ml at 6 hr (P < 0.01) and to 2.8 ng/ml at 24 hr (P < 0.01). Mean serum progesterone concentration decreased from 6.1 ng/ml at 0 hr to 3.9 ng/ml at 6 hr (P < 0.01) and to 4.4 ng/ml at 24 hr (P < 0.01). Whole blood samples with and without EDTA were also incubated at 4°C for 24 hr. Mean plasma progesterone concentration decreased from 6.6 ng/ml at 0 hr to 4.2 ng/ml at 24 hr (P < 0.01). Mean serum progesterone concentration decreased from 6.1 ng/ml at 0 hr to 4.7 ng/ml at 24 hr (P < 0.01). The incubation time and temperature of whole blood, from collection of blood to the separation of serum or plasma, significantly affects assayable concentration of progesterone.     

Apolipoprotein C-II synthesis as studied in explants of rat liver in culture

Adult male Sprague-Dawley rats (200-250 g) were used to study apolipoprotein C-II synthesis and secretion. Liver slices were prepared and incubated in RPMI 1629-medium (tissue amount and incubation time studies) and in Minimum Essential Medium (Eagle) with Earle's salts (hormone experiments). Incubation was performed in scintillation vials in a 95% O2-5% CO2 atmosphere, at 37 degrees C from 1 to 21 hr (2 and 4 hr with hormones). The hormones used and their amounts per millilitre medium were: oestradiol-17 beta 0.1 microgram, progesterone 3.0 micrograms and dexamethasone 1.5 micrograms. Apolipoprotein C-II was determined by specific double immunoprecipitation technique and TCA-insoluble protein fraction represented total protein. Optimal tissue amount was 100 mg/vial and the results show that liver slices quickly secrete the newly synthesized apo C-II (also total protein) into the surrounding medium. There were only minor differences between apo C-II values with the hormones used. The portion of apo C-II synthesis from total protein synthesis was 0.47-1.50%. After 4 hr incubation the [3H]leucine incorporation was almost equal for controls and hormone treated slices.     

Biosynthesis and metabolism of testosterone by sertoli cell-enriched seminiferous tubules

Sertoli cell-enriched tubules isolated from rats which had been treated with 1,4-dimethyl sulfonyloxybutane were incubated with either [¹⁴C] progesterone or [¹⁴C] testosterone for 2 hours. Tubules of normal rats and fragments of Sertoli cell-enriched testes were incubated under the same conditions. Sertoli cell-enriched tubules converted progesterone to 20α-dihydroprogesterone, 17α-hydroxyprogesterone, androstenedione and testosterone. The major metabolite was 20α-dihydroprogesterone. The percentage conversion of progesterone into testosterone corresponded to a production of 10–20 ng testosterone. Sertoli cell-enriched tubules converted testosterone to dihydrotestosterone, androstenedione, 3α-androstanediol and 3β-androstanediol. Under our experimental conditions, dihydrotestosterone was the major 5α-reduced metabolite. Normal tubules converted progesterone and testosterone to the same metabolites as Sertoli cell-enriched tubules. Fragments of Sertoli cell-enriched testes were much more active than isolated tubules in metabolizing progesterone. They produced the same amounts of 5α-reduced metabolites of testosterone.     

Ontogeny of steroid metabolizing enzymes in rat oligodendrocytes

Rat oligodendroglial cells were isolated from newborn and developing brains and used immediately after, for quantification of steroid metabolizing activities. Oligodendrocytes (Ol) and their progenitor cells were incubated with [(14)C] testosterone, [(14)C] progesterone, [(14)C] pregnenolone or [(14)C] dehydroepiandrosterone (DHEA). Oligodendrocytes and their progenitor cells expressed different steroid metabolizing enzymes. The main activities were 5 alpha reduction of testosterone and progesterone and 3 beta hydroxy steroid dehydrogenase-isomerase which transformed pregnenolone into progesterone and DHEA into Delta 4 androstenedione. 5 alpha reductase activity increased in male and female rats in parallel with testosterone or progesterone. Contrary to this, 3 beta hydroxysteroid dehydrogenase-isomerase activity was found to be high in the young rat and to decrease when testosterone and progesterone plasma concentration increased.     

High activity of 17 alpha-oxidoreductase in neonatally grafted mouse testes in adult female mice

Male and female (WB-C57BL/6)F1 hybrid mice were used. Two testes from neonatal mice were grafted into the spleen of adult male and female mice, and the grafted testes were removed 30 and 60 days after grafting. Normal testes from 30- and 60-day old mice were also used. Testicular homogenates were incubated with [14C]4-androstene-3,17-dione or [3H]progesterone, and enzyme activities per g wet tissue and progesterone metabolism were examined. Activity of 17 alpha-oxidoreductase in the grafted testes in females (20 nmol/g/h) was approx. 10 times the activity in the grafted testes in males or in the normal testes, whereas 17 beta-oxidoreductase activity in the grafted testes in females was the lowest among these testes. The bilateral ovariectomy performed 1 month before the grafting of neonatal testes, artificial cryptorchidism performed at 20 days of age, and estrogen treatment for 10 days by diethylstilbestrol pellets resulted in no significant changes in 17 alpha-oxidoreductase activities in 30- and 60-day old grafted, cryptorchid or normal testes. The major 17-hydroxy-C19-steroids formed in vitro from progesterone by the grafted testes in female mice were testosterone and 17 alpha-hydroxy-4-androsten-3-one (epitestosterone), but the formation of epitestosterone was insignificant in the normal testes. The present results demonstrate for the first time that epitestosterone is formed as one of major C19-steroids in neonatally grafted mouse testes in females but not in those in males or in normal mouse testes. However, the mechanisms remain unexplained.     

Role of arachidonic acid and its metabolites in the regulation of progesterone and oxytocin release from the bovine corpus luteum.

We have examined the effects of arachidonic acid (AA) and some of its metabolites on progesterone (P4) and oxytocin (OT) release by corpora lutea obtained from Holstein heifers at day 8 of the estrous cycle (Day 0 = estrus). The luteal cells were dispersed with collagenase and small and large cells were separated by unit gravity sedimentation and flow cytometry. After an 18-hr preincubation period, the cells were incubated in the presence of various treatments for 1 hr, followed by a 23-hr incubation period with no treatment. OT was secreted by the large, but not by the small, luteal cells into the incubation medium. AA elicited a significant (P less than 0.05) release of OT from the large cells and P4 from both the large and small cells within 1 hr of incubation, having a specific effect at a concentration of 10 microM. Larger doses (25 and 100 microM) of AA adversely affected the cell viability. Phospholipases A2 (0.5 unit/ml) and C (0.05 unit/ml) and calcium ionophore A23187 (0.1 microM) stimulated OT release from the large cells to the same extent as AA (10 microM). Inhibition of the AA cyclooxygenase metabolic pathway by indomethacin did not affect AA-induced release of OT and P4, although exogenous prostaglandins F2 alpha and I2 (5-25 ng/ml) stimulated the release of OT. Lipoxygenase products of AA (hydroxyeicosatetraenoic acid and leukotrienes; 25 ng/ml) also stimulated OT release. Inhibition of the lipoxygenase metabolic pathway by nordihydroguaiaretic acid abolished AA-induced release of both OT and P4. These results suggest that intracellular accumulation of free AA may modulate secretory functions in the bovine corpora lutea, including OT and P4 release.     

Stress- and (1-24)ACTH-induced alterations in adrenal and testicular steroidogenesis in Mongolian gerbils (Meriones unguiculatus): comparison of plasma levels, tissue content and in vitro secretion

Plasma glucocorticosteroid levels were significantly elevated 1 hr after confinement stress or (1-24)ACTH administration. Both adrenal content and in vitro secretion of glucocorticosteroids and progesterone from adrenals of stressed or (1-24)ACTH-injected animals were higher than values measured in controls. Neither adrenal testosterone content nor output of testosterone or progesterone from superfused testes were changed. Significant correlations were obtained between glucocorticosteroid plasma levels and corresponding adrenal content/in vitro secretion, adrenal progesterone content and output, and between adrenal glucocorticosteroid and progesterone content.     

Steroid metabolism in gonads of turtle embryos as a function of the incubation temperature of eggs

In embryos of many reptiles, the sexual differentiation of gonads is temperature-dependent. In the turtle Emys orbicularis, all individuals become phenotypic males at 25 degrees C, whereas 100% phenotypic females are obtained at 30 degrees C. Steroid metabolism in embryonic gonads was studied at both temperatures, during and after the thermosensitive period for sexual differentiation. Pools of gonads were incubated for various times, with 3 beta-hydroxy-5-pregnen-20-one (pregnenolone), progesterone, dehydroepiandrosterone or 4-androstene-3,17- dione as substrates. The analysis of metabolites combined two successive chromatographies (HPLC and TLC) and autoradiography. Conversion of pregnenolone to progesterone and of dehydroepiandrosterone to 4-androstene-3,17-dione was more important in testes at 25 degrees C than in ovaries at 30 degrees C. In ovaries, a large amount of 5-pregnene- 3 beta,20 beta-diol was formed from pregnenolone, and 5-androstene-3 beta,17 beta-diol was produced from dehydroepiandrosterone. In both testes and ovaries, 5 alpha-pregnane and 5 alpha-androstane derivatives were the main metabolites obtained from progesterone and 4-androstene-3,17-dione, respectively. Progesterone was also converted to 20 beta-hydroxy-4-pregnen-3-one. Dehydroepiandrosterone and 4-androstene-3,17-dione were also metabolized into 11 beta-hydroxy-4-androstene-3,17-dione (only in testes), testosterone, 11 beta,17 beta-dihydroxy-4-androstene-3-one, 17 beta-hydroxy-4-androstene-3,11-dione (low amounts in testes, traces in ovaries), 17 alpha-hydroxy-4-androstene-3-one, estrone and estradiol-17 beta (traces).     

Exposure to pretreatment hypothermia as a determinant of heat killing

When Chinese hamster ovary (CHO) cells were exposed to 22 degrees C for 2 hr prior to 42.4 degrees C hyperthermia, neither the shoulder region of the survival curve nor the characteristic development of thermotolerance after 3-4 hr of heating were observed. Absolute cell survival after 4 hr at 42.4 degrees C was decreased by a factor of between 10 and 100 (depending on the rate of heating of nonprecooled controls). Conditioning at 30 degrees C for 2 hr, 26 degrees C for 2 hr, or 22 degrees C for 20 min followed by heating to 42.4 degrees C over 30 min did not result in sensitization. Prolonged (16 hr) conditioning at 30 degrees C, however, increased the cytotoxicity of immediate exposure to 41.4 or 45 degrees C with maximum sensitization to 45 degrees C occurring after 6 hr at 30 degrees C. Both 3- and 18-hr pretreatments at 30 degrees C similarly increased the cytotoxicity of 45-41.5 degrees C step-down heating (D0 = 28 min in precooled versus 40 min in nonprecooled cells).     

Luteal progesterone and prostaglandin F2α production invitro during fluprostenol-induced luteolysis in the mare

Prostaglandin F₂α (PGF₂α) release $\text{in}$$\text{vitro}$ by luteal tissue from mares was quantified to determine if exogenous prostaglandin analog increased endogenous luteal PGF₂α production during induced luteolysis. On day 8 after ovulation, luteal tissue was collected by flank laparotomy and endometrium was collected by uterine biopsy. Mares were assigned to one of four treatments: (1) no intramuscular injection at 0-hr (n = 5), (2) 250 μg Fluprostenol (ICI 81008 PGF₂α analog) at 4-hr (n = 4), (3) 250 μg Fluprostenol at 12-hr (n = 5), or (4) 250 μg Fluprostenol at 28-hr (n = 5) prior to tissue collection at laparotomy. Blood was collected from a jugular vein at laparotomy. Luteal and endometrial tissues (100-mg minces) were incubated in duplicate in 5 ml of Krebs-Ringer bicarbonate buffer (pH 7.4) in an ice bath in an air atmosphere or at 37°C in an atmosphere of 95% O₂:5% CO₂. The incubation treatments consisted of: no treatment, indomethacin 1.3 × 10^?4M, 1 μg/ml of arachidonic acid, 10 μg/ml of Fluprostenol, and 100 μM dbc-AMP (Fluprostenol was not added to endometrial tissue incubations). The injection of Fluprostenol induced luteolysis in these mares as indicated by decreased plasma progesterone and luteal tissue progesterone production (P<0.01). Luteal PGF₂α production was only detectable in tissue from mares that had been injected with Fluprostenol; production reached a maximum by 12 hr post-injection and had returned to pre-treatment levels by 28 hr (P<0.01). Endometrial tissue produced PGF₂α, but this activity was not significantly affected by injection of mares with Fluprostenol. Increased production of PGF₂α by luteal tissue of mares during PGF₂α analog induced luteolysis was similar to that observed in the pig and ewe.     

Comparisons of gonadotropin binding sites and progesterone concentrations among the corpora lutea of individual pigs

In polyovular species, it is unclear whether the characteristics of each individual corpus luteum (CL), such as mass, progesterone concentration and receptors for luteinizing hormone (LH), are representative of those of its cohorts during the ovarian cycle. The current study was performed 1) to characterize the conditions for estimation of binding parameters for LH receptors in porcine CL, and 2) to compare LH binding sites, luteal progesterone concentrations and luteal masses among CL of ovaries within individual pigs. Gonadotropin binding sites in porcine CL were characterized via specific binding of 125I-human (h) LH to 20,000 X g particulate fractions of luteal tissue. Specific binding was directly proportional to tissue content and was detectable at the lowest content tested (0.5 mg tissue equivalents/tube). Specific uptake of 0.25 ng LH by 5.0 mg tissue equivalents was time- and temperature-dependent; steady-state binding was achieved within 20 h at 37 and 25 degrees C. Binding of LH after 20 h incubation at 37 degrees C (4718 +/- 192 cpm, means +/- SEM) and 25 degrees C (4112 +/- 340 cpm) was greater than that at 4 degrees C (1930 +/- 5 cpm, P less than 0.01). Luteal particulates from individual CL of ovaries collected from four mature nonpregnant pigs (13-23 CL/pig) were incubated with eight concentrations of 125I-hLH. Steady-state binding depended upon hormone concentration until reaching saturation at 2.5 ng 125I-hLH/tube. Scatchard analyses yielded linear plots. Binding capacities for LH ranged among pigs from 0.71 +/- 0.03 to 3.69 +/- 0.13 fmol/mg CL equivalents and receptor affinities (Kd) ranged from 0.92 +/- 0.05 to 4.89 +/- 0.41 X 10(-11) M.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of follicle regulatory protein on thecal aromatase and 3 beta-hydroxysteroid dehydrogenase activity in medium- and large-sized pig follicles

Theca was excised from large (greater than 8 mm) and medium-sized (3-6 mm) pig follicles and prepared as monolayer cultures in serum-free media. After 24 h cells were treated with (1) M199 (control), (2) 5 i.u. hCG, (3) 100 micrograms or 100 ng FRP or (4) hCG (5 i.u.) + FRP (100 micrograms or 100 ng). At 3, 6, 12, 24 and 48 h after treatment, progesterone, oestradiol, androstenedione and testosterone were measured in media. Formation of progesterone by microsomal fractions incubated (37 degrees C) with 1 microM-pregnenolone + 5-microM-NAD+ for 1 h was used as a measure of 3 beta-HSD activity. Aromatase activity was determined by incubating cells with [3H]testosterone for 3 h (37 degrees C) and measuring 3H2O release. In theca from large follicles, hCG enhanced 3 beta-HSD activity after 48 h (P less than 0.05) and secretion of progesterone after 36 h. FRP alone inhibited 3 beta-HSD activity at 36 and 72 h, but had little effect on progesterone secretion. FRP inhibited (P less than 0.05) the hCG-induced increase in 3 beta-HSD activity at 36, 48 and 72 h. HCG enhanced aromatase activity after 48 h while FRP prevented (P less than 0.05) the hCG-induced increase in aromatase activity at 48 and 72 h. Secretion of oestradiol was enhanced (P less than 0.05) at 48 h but inhibited at 72 h by hCG. FRP alone had little effect on secretion of oestradiol but hCG + FRP was inhibitory at 72 h.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ovarian steroidogenesis during follicular maturation in the domestic fowl (Gallus domesticus)

The steroidogenic potential of various physiological compartments within the ovary of the hen were examined using in vitro systems. Three-hour incubations of individual whole small follicles (less than 1 mm-1 cm) or 100,000 collagenase-dispersed theca cells of the five largest ovarian follicles (F1-F5) were conducted in 1 ml of Medium 199 at 37 degrees C in the presence and absence of luteinizing hormone (LH) (0.39, 0.78, 1.56, 3.13 and 6.25 ng), progesterone (5 ng), and dehydroepiandrosterone (DHEA, 5 ng). Steroid output was measured by radioimmunoassay of incubation media. Progesterone was not produced by small follicles although they are a major source of DHEA and estradiol and a significant source of androstenedione. Output of DHEA, androstenedione and estradiol was highly stimulated by LH. The substrate for androstenedione and estradiol in small follicles is probably DHEA. Output of DHEA and androstenedione in theca cells of F2-F5 was stimulated by LH in a dose-related manner. A dose-response relationship between estradiol output and the concentration of LH in media was not apparent in theca cells from F2-F5. Steroidogenesis in theca tissue of large follicles occurs predominantly via the delta 4 pathway. The ability of these theca cells to metabolize progesterone to androstenedione is lost between 36 and 12 h before ovulation. Their ability to metabolize DHEA to androstenedione is still present 12 h before ovulation. Aromatase activity is significantly reduced between 36 and 12 h before ovulation. These data indicate that both large and small follicles can be stimulated by LH. The small follicles are the major source of estrogen. As the large yolky follicles mature, steroidogenesis shifts from the delta 5 to the delta 4 pathway. By 12 h before ovulation, the F1 follicle has lost the ability to convert progesterone to androstenedione. The inability of the largest ovarian follicle to convert progesterone to androstenedione contributes at least in part to the preovulatory increase in the plasma concentration of progesterone that generates the preovulatory LH surge by positive feedback.     

Comparison of cold storage and perfusion of dog livers on function of tissue slices

We compared how two methods of hypothermic preservation affect physiological functions of tissue slices of dog liver. Livers were preserved by either (i) cold storage (CS) in Collins' solution or (ii) continuous perfusion (P) with a perfusate, containing hydroxyethyl starch, sodium gluconate, adenosine, and potassium phosphate, recently developed in our laboratory. Livers were cold stored for 6 to 8, 24, or 48 hr, and perfused for 24 or 72 hr. Tissue slices of preserved livers were incubated at 30 degrees C and analyzed for volume control, electrolyte-pump activity (K and Na), and adenine nucleotide concentration. Also, mitochondria were isolated after preservation to quantify respiratory activity. Slice functions of livers preserved for short periods (6 to 8 hr by CS and 24 hr by P) were similar to those for control livers. After normothermic incubation, the mean (+/- SD) water content of tissue (expressed per unit dry mass of tissue) was 2.3 +/- 0.3 kg/kg for control, 2.6 +/- 0.4 kg/kg for 6- to 8-hr CS, and 2.5 +/- 0.5 kg/kg for 24-hr P. Longer periods of preservation resulted in cell swelling, and water content was 3.3 +/- 0.4 kg/kg for 24- to 48-hr CS and 2.8 +/- 0.3 kg/kg for 72-hr P. The mean (+/- SD) K/Na ratio was nearly normal for livers preserved for short periods: 3.7 +/- 0.5 for control, 4.1 +/- 0.2 for 6- to 8-hr CS, and 3.3 +/- 0.4 for 24-hr P.(ABSTRACT TRUNCATED AT 250 WORDS)     

Progesterone metabolism during storage of blood samples from Gyr cattle: effects of anticoagulant, time and temperature of incubation

Ten Gyr cows with a functional corpus luteum were used to evaluate the effects of time and temperature of incubation of blood samples on progesterone (P4) concentrations detected in plasma or serum. From each cow, a blood sample was collected into a flask containing no anticoagulant, another into an heparinized flask and a third into a flask containing sodium fluoride. The blood from each flask was divided into 46 aliquots. One of them was centrifuged within 5 min of collection. The remaining 45 aliquots were divided into three groups and kept at three different temperatures: 4 degrees C, 17 degrees C, or 37 degrees C. For each anticoagulant, aliquots from every cow and incubation temperature were centrifuged every 30 min for 6 h, and then at 8, 12 and 24 h. Plasma or serum were separated immediately after centrifugation and were kept frozen at -20 degrees C until assayed for progesterone. The mean initial concentration of P4 in serum (8.3 ng/ml) significantly diminished (P<0.05) to 6.7 ng/ml after 5 h of incubation at 4 degrees C, 3 h at 17 degrees C, or 2 h at 37 degrees C. In plasma from heparinized blood the initial concentration (7.8 ng/ml) declined significantly after 6 h of incubation at 4 degrees C, 2 h at 17 degrees C, or 1 h at 37 degrees C. Sodium fluoride used as anticoagulant prevented the degradation of P4 since the initial concentration of P4 (6.7 ng/ml) never declined during incubation at either 4 degrees C or 37 degrees C; the only significant reduction occurred after 24 h of incubation at 17 degrees C.     

Hormone secretion by euthyroid and hypothyroid rat ovaries during the early stages of hCG-induced ovarian cyst development

This study was undertaken to examine ovarian steroid production during the early stages of hCG-induced ovarian cyst formation in the hypothyroid rat. Rats were placed into two groups with one group made hypothyroid by adding thiouracil to their diet. After 10 days, each group was divided into two subgroups with one subgroup receiving daily injections of hCG for 2 days and the other subgroup receiving saline. On the morning of Day 13, ovaries were removed and incubated for 2 hr. No significant difference in progesterone secretion was observed. However, ovaries from hypothyroid, hCG-treated rats secreted significantly more testosterone and estradiol than ovaries from vehicle-treated, hypothyroid rats and euthyroid, hCG-treated rats. In a second experiment, ovaries from euthyroid and hypothyroid rats treated with hCG were incubated in medium supplemented with 100 nM androstenedione and 0 or 100 ng FSH/ml. FSH failed to affect progesterone, testosterone, and estradiol secretions by ovaries from euthyroid, hCG-treated rats. In contrast, FSH significantly enhanced testosterone and estradiol secretion by ovaries from hypothyroid, hCG-treated rats. These results support the hypothesis that increased levels of testosterone and estradiol secretion have a central role in the induction of polycystic ovaries by hCG in the hypothyroid rat.     

Multiple effects of seminal plasma on the acrosome reaction of human sperm

Mammalian sperm do not respond to inducers of the acrosome reaction immediately after ejaculation. They become responsive after they are removed from seminal plasma and incubated in an appropriate medium. We tested the effects of seminal plasma on the development of acrosomal responsiveness. Washed human sperm incubated 24 hr in vitro with 10% (v/v) seminal plasma did not complete an acrosome reaction when exposed to human follicular fluid, progesterone, or ionomycin. Seminal plasma did not reduce sperm viability or motility. Electron microscopy of sperm incubated 24 hr with 5% seminal plasma and then treated with progesterone revealed no sign of membrane fusion or other changes that are associated with the acrosome reaction. During a 12-hr incubation, seminal plasma was 50% effective at inhibiting the acrosomal response to progesterone when diluted 821 ± 112 foid (mean ±SD, n = 3). Sperm that were incubated with seminal plasma for 24 hr and then washed free of the seminal plasma became acrosomally responsive over the following 24 hr, at a rate similar to that of sperm not incubated with seminal plasma in vitro. When sperm were incubated 6 hr without seminal plasma and then seminal plasma was added, the sperm population transiently became more responsive to progesterone, and then became unresponsive. During incubation in vitro, the ability of sperm to have an augmented response to a mixture of seminal plasma plus progesterone developed slightly earlier and more rapidly than ability to respond to progesterone alone. When sperm were incubated 24 hr without seminal plasma, a few acrosome reacted in response to the addition of seminal plasma alone. Therefore, depending on how it is applied, seminal plasma can prevent or reverse the development of acrosomal responsiveness, and it can enhance or induce the acrosome reaction. © 1993 Wiley-Liss, Inc.