Mating-associated peak in plasma testosterone concentration in wild male grey-headed flying foxes (Pteropus poliocephalus)

Plasma testosterone (T) concentrations, measured in wild bats of P. poliocephalus in Queensland in 1983-87, showed a peak during the mating season in March. Plasma androstenedione (A) concentrations changed less dramatically with season. Mean testicular concentration and total content of T and A was substantially greater in March than in regressed testes in July-October. Paired adrenal glands were heavier during February to April than during September to November. In the same wild population, throughout a single breeding season (1987), plasma T concentrations were significantly higher in mid-March than 3 weeks previously or 3 weeks later. Testicular T content rose as the breeding season progressed, being greatest during March, coinciding with the large rise in plasma T concentrations. Testicular T concentration and content were correlated significantly with plasma T concentrations. Adrenal glands contained T, but the absolute concentrations were much lower than in the testis. No significant changes in plasma, testicular or adrenal A concentrations were found as the breeding season progressed. The large increase in plasma T during the mating season appears to be due to increased testicular production.     

Changes in prolactin in peripheral plasma during lactation in the brushtail possum Trichosurus vulpecula

A heterologous double-antibody radioimmunoassay has been validated for prolactin in plasma and pituitary preparations of T. vulpecula. Serial dilutions of crude pituitary homogenates and plasmas from several marsupials and purified prolactin from the tammar, Macropus eugenii, showed parallel dose response curves. In both male and female possums plasma prolactin concentrations increased in response to a single intravenous injection of thyrotrophin releasing hormone. Plasma prolactin concentrations were measured in six lactating females (June-November) and in four non-lactating females (July-October). In the following year prolactin levels were also measured in 11 possums with young less than 50 days old and in 24 possums with young aged between 100 and 145 days. In early lactation prolactin concentrations were low (less than 8 ng/ml) but increased to high levels (greater than 30 ng/ml) by 120 days and remained high until about 160 days of lactation. Thereafter concentrations declined although the young continued to take milk from the mother for a further 30-50 days. The changes in plasma prolactin concentrations throughout lactation are very similar to those described for the tammar, and this unusual pattern appears to be common to marsupials. Non-lactating possums showed no consistent changes in plasma prolactin concentrations between July and October.     

Plasma profiles of the sex steroids and gonadotropins in maturing female spring chinook salmon (Oncorhynchus tshawytscha)

Plasma testosterone concentrations were low through the spring and early summer, concentrations began rising in late July and reached maximum levels by ovulation in September. Plasma concentrations of 11-ketotestosterone were low throughout sexual maturation until ovulation when a significant increase occurred. Plasma androstendione and 17β-estradiol concentrations were high throughout sexual maturation, and decreased significantly at ovulation. Plasma 17α,20β-dihydroxy-4-pregnen-3-one concentrations were low throughout maturation, and increased significantly at ovulation. Plasma gonadotropin I concentrations paralleled those of estradiol and exceeded gonadotropin II levels prior to ovulation. Plasma concentrations of gonadotropin II were low throughout the spring and summer, increasing dramatically at ovulation.     

Steroid concentrations in follicular fluid aspirated repeatedly from transitional and cyclic mares

The objectives of the present study were to determine follicular progesterone (P4) and estradiol-17beta (E2) in transitional mares and to compare follicular steroid concentrations between transitional and cyclic mares. Follicles > 8 mm were aspirated under transvaginal ultrasound-guidance 4 times at 3 to 4 day intervals (T1-T4) in Norwegian pony mares during vernal transition. During the breeding season, follicular aspirations were conducted in each mare on Day 6, Day 14 and Day 18 after ovulation of 3 separate estrous cycles (Day of ovulation = Day 0). Plasma and follicular fluids were analyzed for P4 and E2 with ELISA and RIA, respectively. Plasma P4 concentrations remained below 1 ng/mL throughout T1-T4, while the follicular P4 concentrations increased significantly to cyclic levels after the first transitional aspiration. Plasma E2 concentrations similarly remained at low levels during the course of the transitional aspirations, while the follicular E2 concentrations increased gradually over the 4 aspirations to cyclic concentrations. The mares ovulated on average 9.8 +/- 1.6 (mean +/- SEM) days after the last transitional aspiration, and 16.6 +/- 0.2, 11.3 +/- 1.5 and 23.2 +/- 4.4 days after aspirations conducted on Day 6, 14 and 18, respectively. The present study demonstrates that in the transitional mare newly developing follicles exhibit biosynthesis of P4 and E2. Furthermore, an increase in follicular steroid concentrations is not necessarily reflected in the peripheral steroid concentrations.     

Circadian variations in concentrations of plasma thyroxine and triiodothyronine in man.

The plasma concentrations of thyroxine (T4), triiodothyronine (T3), and total protein (Pr) were measured at 2-h intervals in 8 male subjects during two 24-h periods. Plasma T4 and T3 levels varied significantly during the day. T4 values were highest at 0900 hours and thereafter declined rapidly reaching lowest levels at 1500-1700 hours (mean decrement, 13.2% of 0.00-hour value). Plasma T3 was highest at 0900 hours and lowest at 1700-1900 hours (mean decrement, 16.7% of 0900-hour value). Fluctuations observed in Pr were not significant. Variations in plasma T4 and T3 appeared concordant with respect to time, since no significant variation was detected in T3:T4 plasma concentration ratios. In view of previous studies that have demonstrated circadian variations in the binding of thyroid hormones by plasma proteins, it is suggested that the observed temporal variations in plasma concentrations of T3 and T4 reflect parallel changes in the capacity or affinity of specific plasma binding proteins of these iodothyronines.     

Plasma triiodothyronines in fetal sheep: effects of illness and thyroidectomy.

Plasma 3,5,3'-triiodothyronine (T3) and 3,3',5'-triiodothyronine concentrations were measured in fetal sheep prior to death in utero and after thyroidectomy. In six fetal sheep who subsequently died in utero, plasma rT3 concentrations were elevated in all for 2 to 13 days prior to death. There were no consistent changes in plasma T4 concentrations. In two thyroidectomized fetal sheep, plasma T4 and rT3 concentrations fell to low levels. Plasma T3 concentrations remained low and there was no increase in plasma T3 in the last week prior to parturition like that which occurs in normal fetal sheep. Parturition was preceded by the normal increase in fetal plasma cortisol concentrations and occurred at the normal time. These data indicate that plasma rT3 concentrations are increased as a result of illness in fetal sheep and that such measurements may be useful as an indicator of fetal distress. The normal increase in plasma T3 late in gestation is not necessary for the late gestational cortisol surge or for normal parturition.     

Time course of changes in plasma concentrations of the growth related hormones during protein restriction in the domestic fowl (Gallus domesticus)

Experiments were conducted to evaluate the possible role of circulating growth hormones triiodothyronine (T3), thyroxine (T4), and insulin-like growth factor I (somatomedin-C; IGF-I) in the elevation of plasma growth hormone (GH) which occurs in protein-restricted chickens. Plasma hormone changes were determined over a 2-week period of protein depletion by feeding a 5% protein diet as well as a similar period of protein repletion with a 20% protein diet. The rise in plasma GH was observed in two separate studies. Plasma concentrations of T4, T3, and IGF-I were all depressed in protein-restricted chicks prior to or concurrent with the GH elevation. In the protein repletion time course study, T4 and T3 concentrations were normalized prior to or concurrent with plasma GH normalization. However, IGF-I concentrations in repleted chicks did not return to control levels until after normal levels of GH were observed. These data suggest that thyroid hormones may play a greater role in the regulation of GH secretion during periods of malnourishment than IGF-I; the latter being currently thought to be a peripherally circulating inhibitor of GH release in animals.     

Plasma and ovarian thyroxine levels in relation to sexual maturation and gestation in female Sebastes inermis

Plasma T₄ (L-thyroxine) concentrations in the viviparous rockfish Sebastes inermis showed a peak (119·3±27·8 ng ml⁻¹) during the development of embryos. Ovarian T₄ concentrations increased during vitellogenesis and final maturation and decreased during embryogenesis.However, total T₄ content within the ovary increased continuously up to the larval stages. Plasma oestradiol-17β, (E₂) concentrations peaked at the final maturation stage and then recovered to the level seen during the non-reproductive periods. Plasma testosterone (T) concentrations showed a peak (5·33±1·08 ng ml⁻¹) at the embryo stage and high levels were maintained throughout the gestation period. Plasma T₄ concentrations during the embryo stage and ovarian T₄ content during vitellogenesis were much higher than the levels reported in oviparous fishes. These data suggest that in viviparous rockfish, T₄ may be required for sustaining gestation or embryo development within the maternal body. In addition, the high content of total T₄ in the ovary implies that there probably does exist a maternal-embryo relationship during gestation as well as during vitellogenesis.     

Seasonal changes in circulating levels of thyroid hormones are not dependent on the age in Djungarian hamsters Phodopus sungorus

1. Plasma levels of total and free thyroxine (T4; FT4) and triiodothyronine (T3; FT3) were measured by radioimmunoassay in adult and senescent Djungarian hamsters at different times of the year. 2. Seasonal changes of both hormones were found in adult and senescent hamsters. 3. However, except for total thyroxine, the patterns were different in both groups of hamsters. 4. These results suggest, that in Djungarian hamsters age-related changes of thyroid function do not affect the secretory activity of the thyroid gland rather than the phase of the seasonal cycle.     

Plasma prolactin, thyroxine, triiodothyronine, testosterone, and luteinizing hormone during a photoinduced reproductive cycle in mallard drakes

The temporal relationships between plasma concentrations of prolactin, thyroxine (T4) and triiodothyronine (T3) were determined in a group of six wild mallard drakes during the development and maintenance of long-day refractoriness after transfer from 6 h light: 18 h darkness (6L:18D) to 20L:4D for 24 weeks. As shown by changes in the plasma concentrations of luteinizing hormone (LH) and testosterone, the birds came into breeding condition and then became long-day refractory within 5 weeks of photostimulation. Long-day refractoriness was maintained for the remainder of the study. Plasma prolactin began to increase immediately after photostimulation, although not as fast as the increases in plasma LH and testosterone. The concentration of plasma T4 also increased after photostimulation but, as shown by decreased plasma LH and testosterone levels, only after the birds had become long-day refractory. The development of long-day refractoriness was thus directly correlated with an increased plasma prolactin and not with a change in plasma concentration of T4. Plasma T3 decreased after photostimulation but returned to prestimulation values as the birds became long-day refractory and remained stable for the remainder of the study. Concentrations of plasma T4 and prolactin returned to baseline values after about 15 weeks photostimulation showing that the long-term maintenance of long-day refractoriness is not directly related to continuously high plasma concentrations of either hormone.     

Effect of the sex-linked dwarf gene on thyrotrophic and somatotrophic axes in the chick embryo

Plasma concentrations of thyroxine (T4), triiodothyronine (T3), reversed triiodothyronine (rT3), and insulin-like growth factors I and II (IGF-I, IGF-II) together with peripheral 5'-monodeiodination activity were measured in both normal and sex-linked dwarf embryos between day 14 of incubation and day 1 posthatch. Plasma T4 levels increased gradually during embryonic development while T3 concentrations remained low until day 20, when a sharp increase was observed. rT3 levels also increased from day 14 and dropped on day 20 when T3 levels started to increase. 5'-monodeiodination activity was high on day 14 of incubation, decreased thereafter, and showed an increase at the time of air sac penetration together with increased T3 levels. At this stage, differences between normal and dwarf embryos were observed; the latter had lower nonsignificant 5'-Monodeiodination activity and lower (P less than 0.01) plasma T3 levels. Plasma IGF-II levels were high during the whole embryonic period studied. Dwarf embryos had lower (P less than 0.05) IGF-II levels at the time of hatching. IGF-I levels were high on days 14 and 16, declined afterwards, and started to increase again around hatching. With the exception of T3 and IGF-II levels, introduction of the dwarf gene did not cause major changes in the hormonal parameters studied. This may explain the identical body weight at hatching.     

Changes in plasma iodohormone concentrations during the day before hatching in Gallus domesticus

Plasma concentrations of thyroxine (T4) and triiodothyronine (T3) were measured at the onset of breathing, clicking and hatching in unstimulated chick embryos. There was a progressive increase in plasma T3 concentration from the onset of breathing (482 hr of incubation) to hatching (496 hr). Plasma T4 concentration did not change significantly between the start of breathing and clicking (494 hr) but decreased between the onset of clicking and hatching. Embryos stimulated with artificial clicks hatched 19 hr before their unstimulated counterparts but their plasma concentrations of T3 and T4 did not differ at hatching from those of unstimulated embryos; however, the plasma T3 concentration, but not T4, at hatching was higher than in unstimulated embryos incubated for a similar length of time, i.e. to the onset of breathing.     

Plasma catecholamines in the aorta and the phrenicoabdominal vein in exercising dogs

Plasma epinephrine and norepinephrine concentrations were measured in the aorta and phrenicoabdominal vein in five dogs at rest and during short-duration mild- and moderate-intensity exercise and during prolonged mild-intensity exercise. Plasma epinephrine and norepinephrine concentrations increased with exercise in both the aorta and the phrenicoabdominal vein. Plasma epinephrine concentration was much higher in the phrenicoabdominal vein than in the aorta (24-43 times). Plasma epinephrine concentrations in the aorta and phrenicoabdominal vein were significantly correlated (r = 0.88). This confirms that peripheral epinephrine concentration is a reliable index of the activity of the adrenal medulla during exercise. The epinephrine-to-norepinephrine ratio in the phrenicoabdominal vein was stable (4:1) throughout the experimental protocol, suggesting that the proportion of the two amines released by the adrenal medulla did not vary through this range of adrenal activity in dogs.     

Seasonal changes in serum thyroid hormone levels of the feral brown bullhead, Ictalurus nebulosus Lesueur

Seasonal changes in serum L-thyroxine (T4) and triiodo-L-thyronine (T3) concentrations were measured in a feral population of brown bullheads, Ictalurus nebulosus . Serum T4 was elevated in mid April concomitant with the onset of gonadal recrudescence and the increase in ambient temperatures from the winter level. Thereafter, serum T4 levels were constant throughout the late spring and summer (except for a significant lowering in levels associated with the spawning and early postspawning period), declining to a low overwintering level by mid December. Serum T3 levels increased in April, and apart from a significant decrease in July associated with the postspawning period, rose progressively until August, after which levels declined progressively to reach overwintering levels again by mid December. Between mid April and mid May serum T4/T3 ratios fell from the high values found in fish during the winter months. Apart from variations associated with the fluctuations of T4 and T3 concentrations in the spawning and early postspawning periods, serum T4/T3 ratios remained at a low level throughout the summer and early autumn months, and rose again in October to the overwintering levels. The circannual cycles are discussed in relation to the possible role of the thyroid hormone in gonadal maturation and metabolism in this species.     

Seasonal variation in circulating testosterone and oestrogens of wild-caught California ground squirrels (Spermophilus beecheyi).

Blood samples were obtained each month for 18 months in 1984-85 from wild-caught California ground squirrels. Circulating testosterone and total oestrogens were extracted from the plasma, measured by radioimmunoassay and compared with concurrent changes in plasma progesterone and prolactin in the same individuals. Male plasma testosterone concentrations peaked in January, shortly before mating, whereas female testosterone concentrations were low throughout the year. Female plasma oestrogen concentrations peaked in February, during the mating period. Juvenile males exhibited a transient increase in circulating testosterone in September, followed by testis growth, preputial separation, and the appearance of epididymal spermatozoa. Juvenile females exhibited a transient increase in circulating oestrogens in November. By the start of the first mating season after their births, neither juvenile males nor females differed significantly from same-sex adults with respect to plasma concentrations of oestrogen or testosterone. Plasma concentrations of progesterone and prolactin in killed individuals were similar to those obtained in previous studies of free-living S. beecheyi. Mean plasma concentrations of all measured hormones varied significantly with reproductive condition in adults of both sexes.     

Seasonal variation in plasma thyroxine concentrations in juvenile alligators (Alligators mississippiensis) from three Florida Lakes

Circulating concentrations of thyroxine (T(4)) vary seasonally in many vertebrates. This study examined the seasonal variation in plasma concentrations of T(4) in juvenile American alligators (Alligator mississippiensis) from three populations in central Florida, USA. One site, Lake Woodruff National Wildlife Refuge, is considered a reference site whereas the other two lakes, Lake Apopka and Orange Lake, are significantly impacted by human activity. Juvenile American alligators ranging from 75-150 cm in total length were hand-captured at night from November 2000-April 2002. Plasma thyroxine concentrations were analyzed using a radioimmunoassay (RIA) previously validated for alligator plasma. Juvenile American alligators display seasonal variation in circulating T(4) concentrations. Plasma T(4) concentrations decrease from August/September to November and then begin a slow rise until April, at which point they plateau. Sex of juveniles influenced plasma concentrations of T(4) in some months but did not appear to alter the pattern in seasonal variation. The pattern we observed in plasma T(4) concentrations is not directly related to an environmental factor such as ambient temperature but is similar to that seen in plasma sex steroid concentrations during the reproductive cycle of adult alligators. Although the pattern and plasma concentration of T(4) exhibits significant variation among the three lakes studied, the pattern in seasonal variation appears similar. Comparing the seasonal pattern in plasma T(4) with plasma concentrations of sex steroids (testosterone and estradiol-17beta) or corticosterone could provide important information on the peripubescent life stage of the American alligator.     

Thyroid hormones in grey seal pups (Halichoerus grypus).

The aim of the present study was to describe the changes in thyroid hormone status in grey seal (Halichoerus grypus) pups from birth to weaning and moulting. Plasma concentrations of total thyroxine (tT4) were highest the first two days after birth, thereafter dropping to a lower, but stable level. This pattern may reflect a high transfer rate of maternal thyroxine prepartum, prior to parturition, or postpartum via colostrum, or it may be caused by active secretory thyrocytes in late foetal stage. Total triiodothyronine (tT3) concentrations were lowest in neonatal pups, and increased as a function of age, indicating that deiodination of T4 to T3 increases as a function of age. Plasma concentrations of free thyroxine (fT4) did not vary as a function of age. All hormone concentrations were higher than previously reported in adults, probably reflecting the important role of these hormones in regulating their high rates of metabolism and tissue synthesis and the growth of their juvenile pelage. Since polychlorinated biphenyls (PCBs) have been reported to affect plasma concentrations of thyroid hormones in seals, the information on thyroid hormone concentrations and dynamics reported in grey seal pups from a pristine Norwegian coastal environment provide valuable reference material for future studies on pups from more polluted areas.     

Changes in circulating iodothyronines in diabetics with various degrees of metabolic control

Plasma TSH, total and free T3 and T4, reverse T3, blood pH, HbAlc, ketonuria and glycosuria were evaluated in 8 subjects with diabetic ketoacidosis, in 54 diabetics of group 1 and group 2 without severe metabolic derangement and in 10 control women. The diabetics with ketoacidosis showed before intensive therapy low T3, total and free, and high reverse T3 concentrations as compared to controls (unpaired t-test, p less than 0.001). After one day of intensive therapy the decrease of hyperglycemia and pH increase (p less than 0.001, paired t-test), glycosuria and ketonuria are not related to significant variations of iodothyronines and TSH. The significant variations (paired t-test, p less than 0.001) in total and free T3 and in reverse T3 concentrations were found only six days after remission of ketoacidosis. In diabetics (type 1 and 2) without recent history of ketoacidosis no differences were found in mean total and free T3 and T4, in reverse T3 and in plasma concentrations although mean blood glucose and HbAlc were statistically different (t-test, p less than 0.001). The changes in serum T3 (total and free) and reverse T3 are useful indicators of total metabolic control during the management of diabetic ketoacidosis.     

Glucagon administration induces lowering of serum T3 and rise in reverse T3 in euthyroid healthy subjects

Euthyroid sick syndrome is characterized by low serum T3 and raised reverse T3 (rT3). Most of the states with this syndrome are also documented to manifest hyperglucagonemia. Furthermore, several recent studies have suggested that glucagon may play a role in T4 monodeiodination in some of these states such as starvation and uncontrolled diabetes mellitus. Therefore, hyperglucagonemia was induced by intravenous glucagon administration in euthyroid healthy volunteers and thyroid hormone levels were determined at frequent intervals up to six hours. Plasma glucose and insulin rose promptly on glucagon administration, thus establishing the physiologic effect of glucagon. Serum T4, free T4, T3 resin uptake, and TSH concentrations remained unaltered throughout the study period. Serum T3 declined to a significantly low level (P less than 0.05) between 60-90 minutes. Serum rT3 rose significantly (P less than 0.05) by four hours and the rise was progressive till the end of the study period. Therefore, these results suggest that hyperglucagonemia may be one of the factors responsible for lowering of T3 and a rise in rT3 in euthyroid sick syndrome.     

Influence of gestation on jugular plasma thyroxine levels in Murrah buffalo and Karan Swiss cows

Plasma samples from 106 pregnant Karan Swiss (Brown Swiss x Sahiwal) cows and 108 Murrah buffalo were tested for thyroxine (T(4)) levels to determine the relationship between the hormonal changes and advancing pregnancy in the two species. All samples were collected within 2 months (January and February) to avoid seasonal interference on T(4) levels. In pregnant cows, the concentration of T(4) increased sharply during the first trimester, reaching a peak at the third month of gestation followed by a gradual decline until the last month of pregnancy. In pregnant buffalo, peripheral plasma T(4) levels fluctuated slightly throughout pregnancy without exhibiting a specific trend. Statistical analysis revealed that the magnitude of T(4) levels was significantly lower in buffalo (P < 0.01) than in the cows throughout pregnancy and that the hormonal patterns of the two species were significantly different (P < 0.05) during gestation. It was hypothesized from this study that T(4) requirements for the fetal buffalo calf may be lower than that for the fetal cattle calf since the buffalo gestation period is a month longer and the metabolic rate lower vis-a-vis the cow.