Effect of glucose availability on pulsatile luteinizing hormone release in rams before and after castration

The hypothesis tested was that availability of glucose modulates the control of luteinizing hormone (LH) release. A second objective was to determine the role of testicular hormones in the control of pulsatile LH secretion during depressed blood glucose. Serial blood samples were collected at 15 min intervals for 8 h from intact pubertal Suffolk rams (n = 8; 7 months old) on consecutive days (Days 1, 2 and 3). Rams were castrated after sampling on Day 3 and samples were collected 3 weeks later on consecutive days (Days 4, 5 and 6). Insulin (120 units, iv) was given at Hour 4 of each of the six days to lower blood glucose. On Days 1 and 4, no other treatments were given (Control). On Days 2 and 5, LH releasing hormone (LHRH; 5 ng/kg, iv) was given at Hours 5, 6 and 7 to assess the ability of the pituitary to release LH. On Days 3 and 6, N-methyl-D,L-aspartate (NMA; 5 mg/kg, iv) was given at Hours 5, 6 and 7 to assess the ability of the hypothalamus to release LHRH. Insulin reduced plasma glucose by 52% for at least 3 h (P < 0.001). Insulin reduced the mean LH concentration (P < 0.05) and tended to reduce the LH response area (P < 0.10) in castrated animals during the control period. LHRH increased LH pulse number (P < 0.001) in intact rams and increased mean LH concentration (P < 0.01), LH pulse amplitude (P < 0.05) and LH response area (P < 0.01) in castrated animals compared to respective control periods. NMA increased mean LH concentration in intact rams (P < 0.0001) but did not affect mean LH in castrates. NMA increased LH pulse number in rams (P < 0.0001) but decreased number of pulses in castrates (P < 0.0001) compared to control periods. NMA increased LH pulse amplitude in both intact (P < 0.001) and castrated animals (P < 0.05). In conclusion, these results support the hypothesis that blood glucose concentrations influence the control of LH release in sheep. In addition, LH release in response to the LHRH secretagogue, NMA, is positively influenced by testicular hormones.     

Estrogen - Induced release of luteinizing hormone in prepubertal and postpubertal heifers

This experiment was designed to determine the age at which estradiol-17beta (E(2)) first induces a preovulatory-like surge of luteinizing hormone (LH) in prepubertal heifers. Responses of prepubertal animals 3 to 4 and 5 to 6 months of age were compared with those of postpubertal heifers that received 25 mg prostaglandin F(2)alpha at 0800 hr on day 15 of the estrous cycle. E(2) (500mug) induced surges of LH in 1 5 heifers 3 to 4 months of age, 3 3 heifers 5 to 6 months of age and 5 5 postpubertal heifers. Duration of response and interval between E(2) injection and peak of the response were longer in postpubertal heifers than in those 5 to 6 months old (P<0.10). Peak response and total amount of LH released were greater in animals 5 to 6 months old (P<0.10). Only one prepubertal heifer had elevated concentrations of progesterone following an LH surge. Four of 5 postpubertal heifers receiving E(2) and 3 of 4 postpubertal heifers receiving corn oil had corpora lutea and similar patterns of progesterone concentrations. We conclude that ability to release an LH surge in response to E(2) develops in heifers between 3 and 5 months of age, but that this induced surge does not cause ovulation.     

Relationship between serum luteinizing hormone and estradiol in prepubertal boars

Effects of estradiol on serum luteinizing hormone (LH) were studied in prepubertal boars. In Exp. 1, 15-wk-old boars were given (iv) 50 mug estradiol, 1 mg testosterone or 1.5 ml ethanol. Estradiol (P<0.05) decreased LH over a 2.5-hr period, but testosterone did not. In Exp. 2, an estradiol implant reduced LH sample variance (P<0.01) while LH (547 +/- 96 vs 655 +/- 43 pg/ml) and estradiol (14.2 +/- 3.3 vs 18.4 +/- 1.0 pg/ml; control vs implant) were unchanged in 12-wk-old boars. Pulsatile LH releases (4.3 +/- 1.1 vs 3.0 +/- 0.4 pulses/pig/8 hr; control vs treated) and pulse amplitude (272 +/- 34 vs 305 +/- 40 pg/ml) were not affected. The implant tended to decrease serum testosterone (4.86 +/- 0.75 vs 7.66 +/- 1.51 ng/ml; P<0.10). In Exp. 3, LH was higher after zero implants than after four implants (279 +/- 7 vs 227 +/- 9 pg/ml; P<0.01), and LH after two implants was also higher than after four implants (263 +/- 7 pg/ml; P<0.01) in 14-wk-old boars in a Latin square design. Peak LH after 40 mug gonadotropin releasing hormone (GnRH) was less after two and four implants (1,100 +/- 126 and 960 +/- 167 pg/ml, respectively; P<0.01) than after zero implants (1,742 +/- 126 pg/ml). Slope of the first 20 min of LH response to GnRH was greater after zero implants (45.3 pg/min; P<0.05) than after either two or four implants (20.6 and 16.9 pg/min, respectively). Implant treatment decreased serum testosterone (P<0.025) but increased estradiol (P<0.10). Small changes in serum estradiol resulted in changes in LH. These changes in sample variance and mean LH were recognized by boars as different from normal because serum testosterone decreased. Changes in LH may result from estradiol's negative effect on pituitary responsiveness to endogenous GnRH because response to exogenous GnRH was depressed by estradiol.     

Pituitary responsiveness to luteinizing hormone-releasing hormone in prepubertal and postpubertal male ferrets

The pituitary response to three different doses of exogenously administered LHRH was examined in prepubertal (9-wk-old) and postpubertal (32-wk-old) male ferrets. The doses of 5, 10, and 15 ng LHRH/kg body weight tested in this study produced dose-related increases in circulating LH concentrations in both pre- and postpubertal groups. In addition, a significant effect of age on LH response was observed, with the prepubertal animals demonstrating significantly greater serum LH values in response to the two higher doses than the postpubertal males. Prepubertal ferrets also exhibited a significant increase in endogenous LH pulse amplitude in sampling periods following exogenous administration of LHRH compared to baseline pulse amplitudes in periods prior to the LHRH infusions. These results suggest that the low frequency of endogenous LH pulses previously observed in prepubertal ferrets is not due to unresponsiveness of the pituitary gland to LHRH. Thus, suppression of the hypothalamo-hypophyseal axis observed in the prepubertal ferret is probably mediated at the level of the hypothalamus.     

Effect of castration on plasma concentrations of luteinizing hormone and follicle-stimulating hormone in adult Merino rams which were homozygous carriers or non-carriers of the Booroola fecundity gene

Before castration, the mean plasma concentrations of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) did not differ between FF and ++ Booroola rams. After castration, mean LH and FSH concentrations increased after 8 h, and for the next 14 days the rate of increase in FSH, but not LH, secretion was significantly faster in FF than in ++ rams (P less than 0.05). Mean FSH concentrations over this period were significantly higher in FF than in ++ rams (P less than 0.05). In both genotypes, the ranked FSH values did not significantly change their order over time, i.e. a significant within-ram effect was noted (P less than 0.05). Repeated-measures analysis of variance indicated a significant effect of genotype on mean FSH secretion (P less than 0.05) and a significant effect of sire in the FF (P less than 0.05), but not the ++ (P = 0.76), genotype. From Day 28 to Day 58 after castration, FSH and LH concentrations were variable and no overall increases in concentrations were observed. The mean concentrations of both hormones over this period were not related to genotype. There were no gene-specific differences in pulsatile LH secretion 14 weeks after castration. However, the mean LH, but not FSH, response to a bolus injection of 25 micrograms of gonadotrophin-releasing hormone (GnRH) was significantly higher in FF than in ++ rams (P less than 0.05) and this was not significantly affected by sire. These studies support the hypothesis that the F gene is expressed in adult rams, in terms of pituitary responsiveness to an injection of GnRH and to the removal of the testes, but it is not clear from this study whether the influence of sire is related to or independent of the apparent gene-specific differences.     

阉割和睾丸酮替代对雄性老年大鼠下丘脑和血浆促黄体生成...

Hypothalamic and plasma luteinizing hormone-releasing hormone (LHRH) levels following orchidectomy (ORDX) and testosterone (T)-replacement were compared between young (2-3 months old) and aged (24-26 months old) male rats by radioimmunoassay. Plasma T level and hypothalamic LHRH content are markedly decreased in the aged rat as compared to those of the young rat, whereas plasma LHRH levels are similar in the two groups. Following ORDX and ORDX plus T-replacement, plasma T levels in both groups are about the same, whereas the rates of variation of hypothalamic and plasma LHRH levels in the aged rat are significantly lower than those in the young rat. These results suggest that the negative feedback mechanism of the hypothalamic LHRHergic system is impaired in the aged rat, which may be one of the important reasons causing age-dependent deterioration of the functional control of hypothalamic-pituitary-testicular axis.     

Ovine luteinizing hormone. I. Effects of castration and steroid administration on the charge heterogeneity of pituitary luteinizing hormone

Chromatofocusing was used to separate and characterize the isohormones of ovine luteinizing hormone (oLH) in the pituitaries of rams, wethers, and wethers receiving Silastic implants containing 5 alpha-dihydrotestosterone (DHT), 17 beta-estradiol (E2), or DHT plus E2. Extracts of anterior pituitaries were prepared by homogenization and centrifugation at 100,000 X g. Castration reduced the amount of oLH in the pituitary, even though peripheral levels were elevated. Pituitary oLH concentrations in wethers were further reduced by all three steroid treatments. When subjected to chromatofocusing on pH 10.5 to 7.0 gradients, pituitary extracts yielded eight peaks of immunoreactive oLH, which eluted with apparent isoelectric points of greater than 9.8, 9.26, 9.14, 9.07, 8.98, 8.91, and less than or equal to 7.0. These isohormones were designated A-G and Z, respectively. In rams, isohormones F and G were the predominant species, representing approximately equal to 57% of the immunoreactive oLH recovered from the column. Castration resulted in a subtle shift toward more basic isohormones. DHT administration caused an increase in the relative amount of isohormone A, whereas E2 treatment resulted in an increase in isohormone Z. DHT and E2 in combination produced increases in the relative amounts of both isohormones A and Z. All eight oLH isohormones were active in an in vitro LH bioassay and exhibited biological-to-immunological-assay (B/I) ratios in the ram ranging from 0.4 to 2.8. Isohormone F exhibited the highest B/I ratio in all the treatment groups. Similarly, isohormone F was clearly the predominant biologically active form of oLH in all groups. These results demonstrate that at least eight immunoreactive and biologically active forms of pituitary oLH can be separated by using chromatofocusing; the pattern of oLH isohormones is markedly different from that in the rat; castration has a minimal effect on the pattern of oLH isohormones in pituitary extracts; and exogenous gonadal steroid administration reduces the amount of oLH in the pituitary and changes the pattern of oLH isohormones, resulting in a higher percentage of less biologically active forms.     

Modulation of growth hormone, luteinizing hormone, and testosterone secretion by excitatory amino acids in boars

Ketamine hydrochloride, an n-methyl-d-aspartate (NMDA) receptor antagonist was used in an experiment that tested the hypothesis that fasting-induced increases in growth hormone (GH) secretion is mediated by excitatory amino acid (EAA) neurotransmission in boars. The effects of the drug on circulating concentrations of luteinizing hormone (LH) and testosterone were also evaluated. Blood was sampled at 15-min intervals for 8 h from 12 boars fitted with jugular vein catheters. At Hours 4 and 6, fasted boars (feed was withdrawn 48 h before the start of blood sampling) received i.m. injections of ketamine (19.9 mg/kg body weight; n=4) or .9% saline (n=4). Boars allowed feed on an ad libitum basis (n=4) received i.v. injections of n-methyl-d,l-aspartate (NMA; 2.5 mg/kg body weight), an NMDA receptor agonist, at Hours 4 and 6. Secretion of GH increased after NMA injections but was unaffected by treatment with ketamine or saline. Circulating concentrations of LH and testosterone were increased by injections of ketamine but were unaffected by injections of NMA or saline. Our results suggest that NMA is a potent GH secretagogue, but do not support the hypothesis that EAA neurotransmission drives the increased GH secretion displayed in fasted boars. Our finding that ketamine increased LH and testosterone release supports the notion that EAA have inhibitory effects on gonadotropin secretion in acutely fasted swine.     

Effect of heat stress on plasma concentrations of prolactin and luteinizing hormone in ewes.

Basal concentrations of prolactin but not luteinizing hormone were elevated in ewes by 8--10 h of heat stress given daily during the first 11 days of their oestrous cycle. However, the prolactin and luteinizing hormone responses to thyrotrophin releasing hormone and gonadotrophin releasing hormone were unaffected.     

Circulating concentrations of luteinizing hormone, testosterone, and growth hormone after naloxone treatment in sexually mature boars

The effects of naloxone, an antagonist of opioid peptides, on circulating concentrations of luteinizing hormone (LH), testosterone, and growth hormone (GH) were determined in sexually mature boars. Blood samples were collected at 15-min intervals for three hr from five crossbred boars. Two hr after initiation of blood sampling, boars received an i.v. challenge of naloxone (1 mg/kg body weight; n=2) or 0.9% saline (n=3). Twenty-four hr later the experiment was repeated, but boars that previously received naloxone received saline and vice versa. A time by treatment interaction (p=0.09) was detected for concentrations of LH in serum, and levels of LH were greater (p<0.03) after treatment with naloxone compared to saline. Concentrations of testosterone in serum were affected by time (p<0.01), but not treatment (p= 0.59) or treatment by time (p=0.74). A treatment by time interaction (p=0.02) was detected for serum GH concentrations. Levels of GH increased in saline-treated boars (p<0.01), but not in boars receiving naloxone (p>0.1). Our results are consistent with the theory that opioid peptides suppress LH secretion and stimulate GH release in sexually mature boars.     

Follicle stimulating hormone and luteinizing hormone levels in buffalo seminal plasma

The levels of follicle stimulating hormone (FSH) and luteinizing hormone (LH) were determined in the buffalo bull seminal plasma by double-antibody radioimmunoassay. The mean levels of FSH and LH ranged from 8.98 ± 3.08 to 18.40 ± 2.19 ng/ml and from 0.598 ± 0.200 to 1.22 ± 0.334 ng/ml, respectively. FSH and LH concentration was positively correlated with mass motility and sperm concentration of buffalo semen samples. Concentration of hormones did not differ significantly among bulls.     

Phenotypic variation in testosterone and luteinizing hormone production among boars: differential response to gonadotropin releasing hormone and adrenocorticotropic hormone

Variation in ability of boars to produce testosterone and luteinizing hormone (LH) in response to both gonadotropin releasing hormone (GnRH) and adrenocorticotropic hormone (ACTH) stimulation, as well as quantitative relationships between pretreatment and posttreatment responses, were assessed in a population of 38 boars of similar age and breeding. Peripheral testosterone concentrations following either GnRH or ACTH increased (P less than 0.01) to peak circulating levels of 7.16 +/- 0.62 and 8.42 +/- 0.81 ng/ml by 120 and 45 min, respectively. Post-GnRH testosterone area varied from 7.44 to 50.84 ng/ml X h (CV = 47.44%) and post-ACTH testosterone area ranged from 3.05 to 28.78 ng/ml X h (CV = 46.09%). GnRH-induced increases in testosterone were preceded by elevations (P less than 0.01) in peripheral LH concentrations but ACTH had no effect upon LH levels. Post-GnRH area varied from 7.07 to 125.45 ng/ml X h (CV = 76.61%). Significant (P less than 0.01) correlations were obtained between pre-GnRH and post-GnRH testosterone areas (r = 0.58) and between pre-ACTH and post-ACTH testosterone areas (r = 0.67). Nonsignificant (P greater than 0.10) correlations were obtained between post-GnRH and post-ACTH testosterone areas (r = 0.006) and between post-GnRH testosterone and LH areas (r = 0.09). The testosterone producing ability of boars was highly variable and their innate ability to produce testosterone influenced their response to GnRH and ACTH. Additionally, the mechanisms by which GnRH and ACTH influence testosterone production in boars appear to differ. Variation in the ability of boars to produce testosterone could not be explained on the basis of differences in circulating levels of LH.     

Semen quality of postpubertal boars during increasing and decreasing natural photoperiods

The present study analyses the effects of increasing and decreasing photoperiods on the semen quality of 20 selected postpubertal Landrace boars. The boars were exposed, throughout 75 days, to increasing and decreasing photoperiods of natural light, a constant temperature of 21 +/- 1 degrees C and 60-70% of humidity, fed with a nutritious diet and, submitted to a rhythm of semen collection of twice a week. During the last 2 weeks of each treatment, semen samples were analysed and the parameters measured were: ejaculate volume and pH, sperm concentration, sperm production and the number of semen doses per ejaculate, sperm vitality, sperm motility, osmotic resistance of spermatozoa and sperm morphology. The comparative analysis between increasing and decreasing photoperiods indicated that the semen quality of boars exposed to a decreasing photoperiod was reduced as a consequence of decreases in sperm concentration, sperm production and the number of semen doses. There was no difference between increasing and decreasing photoperiods in terms of sperm vitality and sperm motility, nor in the osmotic resistance of spermatozoa to isotonic and hypotonic media. The analysis of sperm morphology showed significantly lower frequencies of mature and immature spermatozoa with a distal cytoplasmic droplet, and significantly higher frequencies of immature spermatozoa with a proximal droplet in boars exposed to the decreasing photoperiod. These results indicate that the sperm quality of the selected boars decreased during decreasing photoperiods, in comparison with increasing photoperiods, mainly due to impaired testicular function.     

Testosterone, luteinizing hormone, follicle stimulating hormone, and prolactin response to unilateral castration in prepubertal Holstein bulls

Hemicastration of Holstein bulls at 3 months of age resulted in increased (P<0.005) testicular weitht and testis sperm cell content at 330 days after treatment, but did not alter sperm cell concentration in the remaining hypertrophied testis. Radioimmuroassay of blood hormones at 1, 6, 12, and 24 weeks after treatment revealed that unilateral castration did not alter (P>0.1) basal levels or GnRH response profiles of either LH or testosterone compared to intact bulls. Hemicastration caused FSH to be elevated (P<0.01) compared to intact bulls at all sampling periods in both unstimulated and GnRH stimulated bulls. Prolactin varied with season and was greater (P<0.001) in hemicastrated bulls than in intact bulls at 1 and 6 weeks after treatment. Results indicate that unilateral castration at 3 months of age caused testicular hypertrophy of both steroidogenic and gametogenic function and this phenomena may be triggered by increased FSH or prolactin secretion, or both. Further, results indicate different testicular regulation mechanisms exist for pituitary LH and FSH release in bulls.     

Interrelationship of plasma and urinary luteinizing hormone preovulatory surge

The only reliable method of predicting spontaneous ovulation relies on the detection of the preovulatory luteinizing hormone (LH) surge in urine or plasma. The efficiency of the detection by means of plasma LH radioimmunoassay, urine LH radioimmunoassay or urine LH agglutination inhibition immunoassay were compared in 33 patients. The detection of the onset of LH surge was simultaneous in plasma and urine in only 11 cases. In two thirds of the patients, the urine LH surge onset is delayed by 3 to 21 h as compared with plasma LH surge onset. In some of these cases the oocyte would probably be missed if the laparoscopy had been scheduled according to urine data.