Testosterone metabolic clearance rate and production rate in the male infant rhesus monkey

The male infant rhesus monkey (Macaca mulatta) undergoes a period of testicular activation similar to that seen in the human infant. Plasma testosterone (T) concentrations rise after birth, reaching levels of about 500 ng/dl at 1-3 mo of age and then fall to approximately 50 ng/dl at 60 mo. The plasma T metabolic clearance rates (MCRT) and production rates (PRT) were measured in two rhesus infants at 1 and 6 mo of age to determine the mechanism of the observed increase in plasma T. While there was little change in the MCRT between 1 and 6 mo, PRT was much higher at 1 mo than at 60 mo of age. These observations are consistent with the hypothesis that the increased plasma testosterone levels in infant rhesus monkeys reflect an increased production of testosterone rather than an altered metabolic disposition of the hormone.     

The relationship between circulating testosterone levels and male sexual behavior in rats

The relationships between plasma testosterone (T) and various parameters of male sexual behavior were examined in intact and castrated T-treated male rats. Repeated blood sampling and behavioral testing revealed no correlation between any measure of sexual behavior and plasma T in normal untreated sexually active males. T-Filled Silastic capsules, implanted subcutaneously at the time of castration, were found to produce plasma T levels proportional to capsule size. Plasma T titers less than 10% of normal (0.2 ng/ml) maintained ejaculatory behavior near normal levels for the 58 days of the experiment. Measures of sexual behavior which showed androgen dependence were intromission latency, postejaculatory interval, and intromission frequency. The plasma T concentration required to maintain these parameters within the intact range was 0.7 ng/ml, which is less than one-third of the mean intact level (2.6 ng/ml). No significant improvement in the sex behavior measures was seen with plasma T levels between 0.7 and 3.1 ng/ml. It was concluded that the absence of relationships between circulating T and sexual behavior in the normal rat population is due to the androgen requirement for this behavior being less than the amount normally present. Findings on T levels and T treatment in noncopulator males are also presented.     

A theoretically sound and practicable equilibrium dialysis method for measuring percentage of free testosterone

Free testosterone measured in serum equilibrated in vitro is considered a good index of biologically available testosterone even though a large part of free testosterone in vivo is derived locally from rapid dissociation of testosterone bound to albumin. The most accurate method for measuring free testosterone, however, is unsettled. The classical method--equilibrium dialysis--has been questioned because of the dilution of serum that it entails and the previous inability to achieve identical results with diluted and undiluted serum. Essentially identical measurements of free testosterone were achieved in diluted and undiluted charcoal-stripped serum by using the dialysis method and calculation reported here. The measured free testosterone in undiluted whole serum from women was only 4-6% lower than the estimated physiological values. These results were obtained using a validated calculation, controlling pH, using physiological bicarbonate buffer at 37 degrees C, maintaining a constant free ligand concentration for dilutions, measuring the water gain by the dialysis bag, and using highly purified labeled testosterone. The mean free testosterone for normal women was 0.17 ng/dl (0.11-0.23) and for hirsute women was 0.49 ng/dl (0.27-0.71). The testosterone not bound to testosterone-estradiol binding globulin, calculated from free testosterone and albumin concentrations, was close to the production rate/min of testosterone. The method should be adaptable to other ligands.     

Plasma insulin-like growth factor-I,testosterone and morphological changes in the growth of captive agile gibbons ( Hylobates agilis) from birth to adolescence

We examined growth changes in concentrations of plasma insulin-like growth factor-1 (IGF-1) and testosterone, and somatometric parameters in two captive male agile gibbons from birth to about 4 years of age, to examine the evolution of growth patterns in primates. Plasma IGF-1 concentrations in agile gibbons generally increased with age with values ranging from 200 to 1,100 ng/ml. The growth profiles in plasma IGF-1 in the gibbons were similar to those reported for chimpanzees. The highest concentrations of plasma testosterone (230 and 296 ng/dl) were observed within the first 0.3 years from birth, then the concentrations rapidly decreased and fluctuated below 100 ng/dl. Continuously higher IGF-1 concentrations were observed after 2.6 and 3.5 years of age. The profiles of plasma testosterone in these gibbons also resembled those of other primates including humans. However, their plasma testosterone levels in both neonate and adult stages (60 ng/dl) were lower than those reported for macaques and chimpanzees of respective stages. The obtained growth profiles of plasma IGF-1 and testosterone suggest that the adolescent phase starts around 2.6 or 3.5 years of age in male agile gibbons. The growth trend in many morphological parameters including body weight showed a linear increase without a significant growth spurt at approximately the onset of puberty. Head length and first digit length had reached a plateau during the study period. Brachial index, which indicates the relative length of forearm to upper arm, significantly increased gradually through the growth period. This result indicates that forearm becomes relatively longer than the upper arm with growth, which may be an evolutionary adaptation for brachiation.     

Estimation by gas chromatography-mass spectrometry with selected ion monitoring of urinary excretion rates of 3 alpha-androstanediol during/after i.v. administration of 13C-labelled testosterone in man

To study in vivo the conversion of testosterone (T) into its metabolites, dihydro-testosterone (DHT) and 5 alpha-androstane-3 alpha, 17 beta diol (3 alpha-Diol) the urinary excretion rates of these steroids were determined by mass spectrometry in 6 healthy men during/after the i.v. infusion (t = 4 h) of 20 mg [13C]testosterone. In addition, plasma concentrations of T, DHT and 3 alpha-Diol were determined by radioimmunoassay. During steady state conditions at the end of the 4-h infusion of [13C]T the increase in the plasma concentrations of T from, basal, 405 +/- 140 ng/dl to 4205 +/- 804 ng/dl was paralleled by an increase in the plasma concentrations of DHT to 106.4 +/- 62.5 ng/dl) (basal: 30.8 +/- 21.8 ng/dl), and of 3 alpha-Diol to 32.2 +/- 12.5 ng/dl (basal: 12.5 +/- 13.9 ng/dl). Plasma concentrations of T, DHT and 3 alpha-Diol then returned to basal concentrations within 24 hours. Using mass-spectrometry we found a cumulative renal excretion of 13C-labelled T of 15.6 +/- 9.6 micrograms/24 h, equivalent to 0.08 +/- 0.05% of the infused amount (20 mg) of [13C]T. Whereas urinary excretion of [13C]DHT was below the level of detection by mass-spectrometry the cumulative excretion of [13C]3 alpha-Diol was 67.7 +/- 19.9 micrograms/24 hours which is equivalent to 0.3 +/- 0.1% of the infused dose of 13C-labelled testosterone. These data suggest that the determination of urinary 3 alpha-Diol by mass-spectrometry during/after the infusion of stable-labelled testosterone represents an alternative to the use of radioactive label for turnover studies.     

Developmental patterns of serum luteinizing hormone, gonadal and adrenal steroids in the sooty mangabey (Cercocebus atys)

Serum levels of luteinizing hormone (LH), testosterone, dehydroepiandrosterone sulfate (DHAS), androstenedione and cortisol were determined in multiple samples from 86 sooty mangabeys of varying ages (0-17 years). Testosterone, androstenedione, DHAS and cortisol were measured by radioimmunoassay; LH was determined by in vitro bioassay. Serum LH concentrations were elevated in neonates (less than 6 months) and in animals older than 72 months of age. The higher LH levels were associated with increased circulating concentrations of testosterone in males but not females. The pubertal rise in serum testosterone at approximately 55-60 months of age in males was coincident with rapid body growth. No pubertal growth spurt was observed in females. Serum levels of androstenedione and DHAS were highest during early postnatal life (less than 6 months) with androstenedione exceeding 600 ng/dl in males and 250 micrograms/dl in females, but declined rapidly in both sexes to a baseline of 150 ng/dl by 19 months of age. Serum androstenedione did not fluctuate significantly in adult animals. The pattern of age-related changes in serum DHAS paralleled those of serum androstenedione, whereas serum cortisol values did not change significantly with age. Developmental changes in serum LH, testosterone and body weight suggest that the sooty mangabey matures substantially later than the rhesus monkey. The pattern of serum gonadal and adrenal steroids during sexual maturation is similar to that seen in the baboon with no evidence of an adrenarche.     

Plasma leptin levels of elite endurance runners after heavy endurance training

A decrease in testosterone levels and an increase in cortisol levels are observed in male athletes with the overtraining syndrome (OTS). Cortisol causes blood leptin levels to rise and testosterone has an inverse relationship with blood leptin levels. Therefore, we hypothesized that the hormonal changes as a result of OTS induce an increase in leptin. To test this hypothesis, we examined the relationship among changes in leptin, testosterone and cortisol in thirteen male collegiate distance runners (aged 20.3+/-1.1 years) before and after an 8-day strenuous training camp. Runners ran 284.1+/-48.2 km during the training camp. Body fat percentages and plasma glucose concentrations decreased significantly after the training. Non-ester fatty acids and total cholesterol concentrations in blood were unchanged. Serum cortisol concentrations showed a significant increase after the training camp (from 11.82+/-2.00 microg/dl to 16.78+/-3.99 microg/dl), and serum testosterone decreased significantly (from 408.0+/-127.6 ng/dl to 265.2+/-97.6 ng/dl). The ratio of testosterone to cortisol (TCR) dropped by 50% after training (from 35.62+/-13.69 to 16.94+/-8.47). These results suggest that the subjects reached a state of the OTS. Contrary to our hypothesis, plasma leptin was not significantly changed (from 1.34+/-0.29 ng/ml to 1.49+/-0.18 ng/ml). Delta Plasma leptin was not significantly correlated with delta serum cortisol, delta TCR or delta fat percentage. However, delta serum testosterone was positively correlated with delta plasma leptin (r=596, p<0.05). Plasma leptin concentrations might modulate the secretion of testosterone in overtraining conditions. In conclusion, the change in blood leptin level is independent of the changes in cortisol, TCR and fat percentage in highly trained male athletes in the state of the OTS.     

Assessment of the relationship between serum thyroid hormone levels and peripheral metabolism in patients with anorexia nervosa

It has been observed that basal and/or TRH-stimulated serum TSH levels occasionally conflict with the actual values of circulating thyroid hormones in patients with anorexia nervosa. In the present study sixteen female patients with anorexia nervosa during self-induced starvation displayed clinical findings suggesting hypothyroidism, e.g., cold intolerance, constipation, bradycardia, hypothermia and hypercholesterolemia in association with decreased serum total T3 (62.8 +/- 5.2 ng/dl) and T4 (6.6 +/- 0.3 micrograms/dl). Markedly decreased T3 correlated positively with average heart rate (r = 0.5655, P less than 0.025) and negatively with total cholesterol (r = -0.7413, P less than 0.005). This result may suggest that peripheral metabolic state of the underweight anorexics depends considerably upon the serum T3 concentration. Despite decreased total thyroid hormones, free T4 assayed by radioimmunoassay was normal in all five cases examined (1.4 +/- 0.2 ng/dl) and the free T4 index in fifteen cases was normal except in one case. Basal TSH was not increased and TSH response to exogenous TRH was not exaggerated in any. These results may be compatible with a theory that free T4 has a dominant influence on pituitary TSH secretion. Furthermore, glucocorticoids may also have some influence on depressed TSH response, because an inverse correlation between increased plasma cortisol and the sum of net TSH increase after TRH was observed in twelve cases examined. In conclusion, it is suggested that normal sensitivity of peripheral tissues and pituitary thyrotroph to different circulating thyroid hormones is maintained in anorexia nervosa patients even during severe self-induced starvation, and that the metabolic state in these patients is considerably under the influence of circulating T3.     

Serum androstenedione and testosterone concentrations during pregnancy and nonpregnant cycles in dogs

Concentrations of testosterone and of androstenedione were determined by radioimmunoassay in serum samples collected every 2-5 days throughout the periovulatory and luteal phases of the ovarian cycles of pregnant and nonpregnant beagle bitches. Testosterone levels were consistently lower than those of androstenedione, reached peaks of 29 +/- 4 ng/dl near the time of the preovulatory luteinizing hormone peak, and were reduced to near the limits of detection (less than or equal to 5-10 ng/dl) throughout the luteal phase. Androstenedione levels reached preovulatory peaks of 73 +/- 13 ng/dl, were 54 +/- 7 ng/ml during early estrus, increased (P less than 0.05) to early luteal phase peaks of 76 +/- 8 ng/dl between Days 6 and 18, and then declined to 41 +/- 5 ng/dl by Day 35-40 in both pregnant (n = 8) and nonpregnant (n = 4) bitches. Subsequent protracted increases in androstenedione occurred in 4 of 8 pregnancies but in none of the nonpregnant bitches. From Days 42 to 64 the differences in mean levels between pregnant (45 +/- 2 ng/ml) and nonpregnant (32 +/- 3 ng/ml) bitches was not significant (P greater than 0.05). At parturition androstenedione levels fell (P less than 0.05) abruptly from 39 +/- 7 to 13 +/- 3 ng/dl. These results suggest that, in the bitch, androstenedione is the major circulating androgen during the follicular and luteal phases and that patterns of androstenedione levels during the luteal phase parallel those reported for progesterone in pregnant and nonpregnant bitches, including maintenance of elevated levels throughout gestation and an abrupt decline at parturition.     

Reversible inhibition of testicular androgen secretion by 3-, 5- and 6-month controlled-release microsphere formulations of the LH-RH agonist [D-Trp6, des-Gly-NH10(2)] LH-RH ethylamide in the dog

This study examines the effect of treatment with controlled-release poly(DL-lactide-coglycolide) microsphere formulations of the LH-RH agonist [D-Trp6, des-Gly-NH10(2)]-LH-RH ethylamide (LH-RH-A) designed to release about 100 or 200 micrograms of the peptide per day for 3, 5 or 6 months in male dogs. Plasma levels of testosterone and LH-RH-A were measured at 2-day intervals. After the first injection of the 100-micrograms/day formulation, plasma testosterone increased from 1.6 +/- 0.2 to 3.5 +/- 0.6 ng/ml for 5-7 days before decreasing and remaining at 0.05 +/- 0.008 ng/ml for approximately 150 days (5 months). After two months of recovery, microspheres designed to release 100 micrograms for 6 months of LH-RH agonist per day were then injected. Plasma testosterone levels showed an elevation from 1.5 +/- 0.5 to 4.7 +/- 2.0 ng/ml during the first few days before gradually decreasing to castration levels for 200 days (6 months). One month later, plasma testosterone had returned to normal levels. When microspheres designed to deliver an average of 200 micrograms per day of the peptide for 3 months were injected in another series of animals, castration levels of plasma testosterone were maintained for 95 days with a progressive increase to normal values at later time intervals. The animals of the first series of experiments were then sacrificed after 4 months of recovery following maintenance of plasma testosterone at castration levels for a total period of 11 months. The testes, prostate and pituitary gland were kept for histological examination which was completely normal in all tissues. The efficacy and excellent tolerance of the controlled-release form of LH-RH-A as inhibitor of the pituitary-gonadal axis strongly support the use of such long-term controlled-release formulations of LH-RH agonists for the treatment of sex steroid sensitive diseases.     

Partial deficiency in 17-ketosteroid reductase presenting as gynecomastia

We report a 14 year-old male with severe, long-lasting gynecomastia. Baseline serum androstenedione levels were elevated compared to testosterone levels (330 ng/dl vs 28 ng/dl). In order to evaluate testosterone biosynthesis by this patient in more detail, androstenedione, testosterone, dehydroepiandrosterone (DHEA) and estradiol responses to a single dose of hCG were measured. The responses observed were different from those reported in normal males in two respects: 1) there was no immediate rise in testosterone two to four hours after the injection of hCG, and 2) levels of androstenedione and estradiol at 24, 36 and 48 hours after injection were much higher than expected. We postulate that a partial defect in testicular 17-ketosteroid reductase activity was responsible for the abnormal androstenedione to testosterone ratio in our patient. This, in turn, lead to an increased peripheral synthesis of estrogens and marked gynecomastia.     

Plasma and salivary 6beta-hydroxycortisol measurements for assessing adrenocortical activity in patients with adrenocortical adenomas.

The aim of this study was to examine and compare the potential usefulness of plasma and salivary 6beta-hydroxycortisol measurements for assessing adrenocortical activity in patients with adrenocortical adenomas. Plasma and salivary cortisol as well as 6beta-hydroxycortisol determinations were performed by radioimmunoassay after extraction with ethyl acetate followed by chromatographic separation using a modified paper chromatographic system. Samples were obtained from 36 control subjects and 37 patients with non-hyperfunctioning adrenocortical adenomas in the morning at 8 a.m. after a low-dose of dexamethasone and after stimulation with synthetic depot ACTH. Basal and post-dexamethasone hormone levels were also measured in plasma and salivary samples of 4 patients with Cushing's syndrome from adrenal adenomas. In the baseline state, patients with non-hyperfunctioning adrenocortical adenomas had significantly higher plasma and salivary 6beta-hydroxycortisol levels (mean+/-SE, 79.0+/-7 and 17.1+/-2.2 ng/dl, respectively) compared to those measured in controls (62.0+/-4 and 7.7+/-0.6 ng/dl, respectively), whereas baseline plasma and salivary cortisol levels (9.6+/-0.5 microg/dl and 342+/-39 ng/dl, respectively) were similar to those measured in the control group (9.9+/-0.4 microg/dl and 366+/-24 ng/dl, respectively). In all groups, the changes in plasma and salivary 6beta-hydroxycortisol concentrations after dexamethasone suppression and ACTH stimulation were similar to the changes in plasma and salivary cortisol levels, although the differing ratios of 6betaOHF to cortisol indicated potentially important variations in the induction of 6beta-hydroxylase activity between the three groups. In patients with Cushing's syndrome, baseline plasma and salivary 6beta-hydroxycortisol concentrations (754+/-444 and 104+/-88 ng/dl, respectively) were more markedly increased than plasma and salivary cortisol levels (24.8+/-6.7 microg/dl and 1100+/-184 ng/dl, respectively), and all remained non-suppressible after dexamethasone administration. These results suggests that plasma and salivary 6beta-hydroxycortisol determinations may precisely detect not only overt increases of cortisol secretion in patients with Cushing's syndrome but also mild glucocorticoid overproduction presumably present in patients with non-hyperfunctioning adrenocortical tumors.     

Total and free testosterone in plasma of hypo- and agonadal men.

Plasma total testosterone (T), apparently free T and testosterone binding globulin (TeBG) capacity determined in 14 normal men aged 30-40 years were 461 +/- 100 ng/100 ml, 9.4 +/- 3.0 ng/100 ml and 5.7 +/- 1.9 X 10(-8) M, respectively, whereas in 16 hypogonadal men the corresponding values were 38.6 +/- 27.2 ng/100 ml, 0.47 +/- 0.41 ng/100 ml and 10.4 +/- 3.4 X 10(-8) M showing the TeBG capacity significantly higher (p less than 0.001) in hypogonadal than in normal men. Treatment of 5 hypogonadal subjects with 250 mg testosterone enanthate plus 50 mg testosterone propionate decreased (p less than 0.001) the TeBG level from 14.7 +/- 2.5 X 10(-8YM to 8.3 +/- 1.4 X 10(-8) M on day 8 after a single injection. According to this difference in TeBG, the free T fraction in plasma rose from 0.94% to 1.9% of the total T concentration. These results suggest that alteration of total plasma T affected the TeBG capacity. Decreased T levels raised and increased T concentrations suppressed TeBG, but with a delayed response to the changed T concentrations. The initial mean values in 12 patients with prostatic cancer aged 60-74 years were 397 +/- 165 ng/100 ml, 4.05 +/- 1.8 ng/100 ml and 11.9 +/- 3.3 X 10(-8) M, respectively. The TeBG capacity in these patients was significantly higher and the free T concentration significantly lower (p less than 0.001) than those of the younger normal males. After treatment with 12 g diethylstilbestrol diphosphate and orchidectomy, the TeBG increased to 33.3 +/- 13.1 X 10(-8) M and the plasma free T concentration decreased to the minimal value of 0.053 +/- 0.04 ng/100 ml.     

Diurnal variations of androgens in sexually mature male Bolivian squirrel monkeys (Saimiri sciureus) during the breeding season

To assess diurnal fluctuations of serum androgens and cortisol in adult male Bolivian squirrel monkeys, these steroids were measured at predetermined times (0300, 0900, and 2300 hours) during two separate 24-hour periods in the breeding season (January 1983 and late November 1983). A significant diurnal change in serum cortisol was noted, with a nadir of 99.9 ± 11.9 μg/dl (x? ± SEM) at 2300 hours and a peak of 168.9 ± 7.8 μg/dl at 0900 hours. Conversely, a nadir in serum testosterone was noted at 0900 hours (117 ± 26.5 ng/ml) increasing to a peak of 328.5 ± 57.9 ng/ml at 0300 hours. Serum androstenedione and dehydroepiandrosterone followed a pattern similar to testosterone, with a serum androstenedione (176.4 ± 34.9 ng/ml) and dehydroepiandrosterone (11.7 + 1.8 ng/ml) nadir at 0900 hours and a plasma androstenedione (494.5 ± 55.4 ng/ml) and dehydroepiandrosterone (32.5 ± 4.1 ng/ml) peak at 0300 hours. Parallel changes of testosterone, androstenedione, and dehydroepiandrosterone suggest a significant contribution of all three androgens from a common site, the testes. In contrast to old world primates and humans, serum androstenedione levels exceeded serum testosterone levels in this species.     

Determination of plasma testosterone using a simple liquid chromatographic method

A simple and sensitive high-performance liquid chromatographic (HPLC) method using ultraviolet detection was developed for the determination of testosterone in human plasma. Testosterone and the internal standard, griseofulvin, were extracted from 0.50 ml plasma sample using a mixture of dichloromethane-2,2,4-trimethylpentane (3:2, v/v). The mobile phase, consisted of 0.02 M sodium dihydrogenphosphate-acetonitrile-methanol (51:47:2, v/v) adjusted to pH 3.1 and delivered to a C(18) analytical column (150 x 4.6 mm I.D., 4 microm particles) at a flow-rate of 1 ml/min while the detection wavelength was set at 240 nm with a sensitivity range of 0.005 a.u.f.s. The method has a quantification limit of 1.6 ng/ml. Recoveries of testosterone were all greater than 92% over the linear concentration range of 1.6-400 ng/ml while that of griseofulvin was approximately 95%. The within- and between-day RSD values were all less than 8% while the accuracy values ranged from 96.0 to 106.0% over the concentration range studied. The method was applied to the analysis of early morning plasma testosterone levels of 12 healthy human male volunteers. The levels were found to range from 3.1 to 8.4 ng/ml, within the normal range reported in the literature.     

Testicular responsiveness to long-term administration of hCG and hMG in patients with hypogonadotrophic hypogonadism

Steroidogenic responsiveness and amelioration of sperm number and motility following long-term intramuscular hCG and hMG administration were evaluated in 18 males with hypogonadotrophic hypogonadism (HH). The patients consisted of 13 patients with isolated gonadotrophin deficiency (IGD) and 5 patients hypophysectomized at an early or middle pubertal period. Basal serum levels of testosterone and 17 beta-estradiol were within prepubertal range in all patients before the treatment. Serum testosterone levels reached the normal adult male levels within 12-24 months of the treatment in only 2 of 7 younger patients and 1 of 6 older patients with IGD, whereas in all hypophysectomized patients serum levels of both testosterone and 17 beta-estradiol increased to the levels found in normal adult males within 6 months of the treatment. The mean peak levels of serum testosterone and 17 beta-estradiol, respectively, during the treatment were 2.1 +/- 0.8 (SD) ng/ml and 10.8 +/- 4.9 (SD) pg/ml in younger patients with IGD, 1.4 +/- 0.9 ng/ml and 9.7 +/- 5.1 pg/ml in older patients with IGD and 6.0 +/- 1.2 ng/ml and 34.2 +/- 14.8 pg/ml in hypophysectomized patients. Quantitative improvement in both sperm density and sperm motility were found in 4 of 7 younger patients, 1 of 6 older patients with IGD and all hypophysectomized patients, but only 3 of hypophysectomized patients (3 of 18 patients) could become fertile.     

Individual rabbit cardiac myocytes have different thresholds for alpha myosin heavy chain regulation by thyroid hormone

Myocytes in adult rabbit ventricle express and alpha and a beta form of myosin heavy chain (MHC). The alpha-MHC distribution detected with indirect immunofluorescence has been found in different proportions in adjacent myocytes producing a mosaic staining pattern. The basis for cell-specific expression of the alpha-MHC isoform is not known. Since thyroid hormone is a major regulator of myosin gene expression, we varied the plasma thyroid level and followed the alpha-MHC content within a population of myocytes. Ventricular myocytes were induced to become 100% beta-MHC by placing the rabbits on a 0.15% propylthiouracil diet for 70 days. L-triiodothyronine (LT3) over a dose range of 1 to 10 micrograms/kg/day was delivered by an osmotic minipump for 5 days, with actual serum levels confirmed by LT3 radioimmunoassay to be in the range of from 115 to 1,230 ng/dl. The amount of alpha-MHC that returned was estimated in randomly selected cells by measuring the relative intensity of the fluorescence-tagged secondary antibody. The normal mosaic pattern of alpha-MHC expression in the left ventricle returned with an LT3 dose of 2-5 micrograms/kg/day. The first myocytes to express alpha-MHC were in the subepicardium and did so at a LT3 serum level of 115 of ng/dl. All myocytes of the ventricular wall expressed alpha-MHC at serum levels above 1,230 ng/dl. These data are interpreted to show that the variation of myosin isoform content seen in the adult heart is indicative of heterogeneity of thyroid sensitivity, with the threshold for serum LT3 being between 115 and 370 ng/dl.     

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.     

Peripheral plasma testosterone levels in two indian breeds of goats and their reciprocal crosses

Plasma testosterone levels were estimated in different male goat age groups. In Black Bengal at 15–30 days, 2–3 months, 3–5 months and in Black Bengal, Beetal, Beetal × Black Bengal and Black Bengal × Beetal at 6 months and > 12 months (n = 6 in each case). The plasma testosterone levels (mean ± s.e.m.) were high (7.1 ± 2.0 ng/ml) at 2–3 months and fell drastically to 2.6 ± 0.5 ng/ml before attaining sexually mature levels of 4.6 ± 0.9 ng/ml at 6 months and 4.1 ± 0.8 ng/ml at > 12 months. The mature bucks of all genetic groups had a plasma testosterone concentration of 4.6 ± 0.8 ng/ml. Genetic group differences were not significant.