Comparative urinary androstanes in the great apes.

Urinary androstanes from seven species of male great apes (human, bonobo, chimpanzee, lowland gorilla, mountain gorilla, Bornean orangutan, and Sumatran orangutan) were separated by HPLC and detected by RIA using two testosterone antibodies. All animals examined showed the presence of testosterone and six additional immunoreactive peaks. Although testosterone was the dominant peak (85%) in human urine, its proportion in urine was much less in the other apes, ranging from a high of 59% in the bonobo and chimpanzee to a low of 24% in the mountain gorilla. Urinary androstanes were also directly visualized using nano-spray mass spectrometry (nanoESI-MS). Although the RIA can qualitatively produce a strong signal for testosterone in unchromatographed urine, it is quantitatively present only as a trace metabolite, as demonstrated by nanoESI-MS. The combination of the two techniques showed large differences in androstane metabolism between the seven species. A previously undescribed testosterone metabolite (tentatively identified as either delta1- or delta6-testosterone sulfate) was present in significant proportions in all of the non-human apes examined. We conclude that in the great apes, testosterone is only a trace metabolite in urine, and as a consequence, its measurement may not produce results that parallel the levels of serum testosterone. The RIA measurement of urinary testosterone in part records additional androstane metabolites, which vary even between closely related genera, making the results neither equivalent with nor comparable to different species.

Fecal corticosterone reflects serum corticosterone in Florida sandhill cranes.

Florida sandhill cranes (Grus canadensis pratensis) were conditioned to confinement 6 hr/day for 7 days. On day 8, each bird's jugular vein was catheterized, blood samples were drawn, and each crane was confined for 6 hr. Using a randomized, restricted cross-over design, cranes were injected intravenously with either 0.9% NaCl solution or ACTH (cosyntropin; Cortrosyn; 0.25 mg). During the 6 hr of confinement, fecal samples (feces and urine) were collected from each of five cranes immediately after defecation. Individual fecal samples were collected approximately at hourly intervals and assayed for corticosterone. We showed previously that serum corticosterone did not vary significantly following saline injection, but peaked significantly 60 min after ACTH injection. Maximal fecal corticosterone concentrations (ng/g) were greater (P < 0.10; median 1087 ng/g) following ACTH stimulation compared to maximal fecal corticosterone concentrations at the end of acclimation (day 7; median 176) and following saline treatment (median 541). In cranes under controlled conditions, fecal corticosterone concentration reflects serum corticosterone levels, fecal corticosterone, Grus canadensis pratensis, sandhill cranes, serum corticosterone levels.

Ultrasonographic characterization of ovarian events and fetal gestational parameters in two southern black rhinoceros (Diceros bicornis minor) and correlation to fecal progesterone.

A tremendous potential exists for the application of transrectal ultrasonography as a tool to enhance the captive management of endangered species. Reproductive study of two southern black rhinoceros (Diceros bicornis minor) females was performed daily to every other day for a approximately 60 day period to document ovarian changes, and three times weekly in early pregnancy to once monthly in late pregnancy in order to characterize changes in fetal parameters throughout gestation. All ovarian and fetal anatomical structures were measured in millimeters. The mean (+/- SD) length of the estrous cycle or interovulatory period was 26 +/- 1.4 days (n=2 cycles). Follicular growth rate of a dominant follicle was approximately 3 mm/day once the follicle reached 35 mm in diameter. Ovulation was observed to occur at a mean (+/- SD) follicular diameter of 49.5 +/- 2.6 mm (n=4) and within 48 to 72 h after observed estrus (n=2). Large ovarian structures [mean (+/- SD) diameter of 71.7 +/- 2.9 mm; n=3], considered analogous to equine anovulatory hemorrhagic follicles, were observed to form in the winter months and suggest seasonal periods of reduced fertility. Fecal progesterone assays confirmed ultrasonographic events. Although preliminary, the results of fetal sexing are presented and compared to the horse. Our data indicate that fetal eye or fetal foot diameter measurements can be used to accurately predict gestational age from about 2 months to term, providing useful information to managers of both captive and wild rhino populations. The ability to identify and quickly release animals in late term pregnancy in the wild and thereby reduce-abortions and neonatal mortalities in holding bomas is one potential practical conservation benefit of the fetal age predictive models.

Monitoring hormones in urine and feces of captive bonobos (Pan paniscus).

Urinary and fecal hormones were analyzed on average every other day in 17 female bonobos kept at four US zoos (San Diego Zoo and Wild Animal Park, Milwaukee, Columbus, and Cincinnati). Ovarian cycle activity was monitored throughout the 15-month study period using estrogen and progesterone profiles and swelling charts. Behavioral data on sexual activity were also collected on a daily basis. Fecal and urinary samples were analyzed using high pressure liquid chromatography (HPLC), gas chromatography-mass spectrometry (CG-MS), and nanoelectrospray. Preliminary results indicate that in urine, both conjugated progestin and estrogen metabolites were abundant, while in fecal samples, free progestin metabolites from the 5a-pregnane series were found. Although traces of estrogen metabolites were detected in fecal samples, long-term monitoring of ovarian activity in our study yielded no meaningful estrogen profiles. In contrast, fecal progestin profiles, after adjusting for a one-day delay in excretion, closely matched the corresponding urinary progestin profiles. Using the identical antibody and tracer for both, fecal and urinary progestins, fecal samples yielded approximately ten times the relative amount of progestins compared to urinary progestins. Thus, when converted using a regression formula, fecal progestins may complete the picture obtained from urinary progestins, particularly in cases where the urine sample record is unavailable or incomplete. Evidence of the usefulness of urinary cortisol as a measure of stress is presented.

Growth hormone and thyroid stimulating hormone concentrations in captive male orangutans: implications for understanding developmental arrest.

There are two morphs of reproductive male in orangutans. Both morphs span the age range from adolescent to adult, but "subadult" males are smaller in size and lack secondary sexual features. In this study, urine samples were collected over a 2 year period from 23 captive male orangutans in order to define the endocrinology of this apparent arrest of secondary sexual development. Three males were juveniles, 3 to 5 years of age; seven males showed no secondary sexual trait development and were over 7 years of age; six males were in the process of developing secondary sexual features, with the youngest male being 6 years of age; and seven males were fully mature adults. Morning samples were analyzed by radioimmunoassay for levels of growth hormone (GH) and thyroid-stimulating hormone (TSH) and group hormone profiles were compared by analysis of variance. GH is the primary hormone of growth and development and its increase in teenage boys is associated with the adolescent growth spurt. TSH stimulates the thyroid to produce and secrete hormones that have metabolic effects and required for normal growth and development. Results show that arrested adolescent male orangutans have a GH level about 1/3 that of developing adolescents (P = .0006). TSH levels do not differ significantly between arrested and developing adolescents. These data complement other endocrine data showing significantly lower levels of sex steroids and luteinizing hormone (LH) in arrested males than developing males [Maggioncalda, 1995a,b; Maggioncalda et al., 1999]. Together with documented behavioral differences between reproductive males with and without secondary sexual features, these endocrine data support the hypothesis that in male orangutans there are alternative developmental pathways and corresponding alternative reproductive strategies.

Reproductive hormone profiles in captive male orangutans: implications for understanding developmental arrest.

For many years researchers have described some male orangutans as "subadult." These males are of adolescent to adult age and are reproductive, but have little to no secondary sexual trait development. Until now the only endocrine study of this arrest of secondary sexual trait development was performed by Kingsley (1982, 1988). She found that "subadult" or arrested males have lower testosterone levels than similar age developing adolescents or adult males. In this study, urine samples were collected over a two-year period from 23 captive male orangutans in order to more fully define male endocrine profiles. Three study males were juveniles, seven were arrested adolescents, six were developing adolescents, and seven were mature adults. Morning samples were analyzed by radioimmunoassay for levels of testicular steroids and gonadotropins and group hormone profiles were compared by analysis of variance. Results illustrate that arrested adolescent orangutans have significantly lower testosterone and dihydrotestosterone (DHT) levels than developing adolescents, but significantly higher levels than juveniles. Luteinizing hormone (LH) levels also differed between arrested and developing adolescents, with arrested males having lower levels. However, follicle stimulating hormone (FSH) levels were similar in both morphs of adolescent male. The overall hormone profiles for arrested and developing adolescent male orangutans suggest that arrested males lack levels of LH, testosterone, and DHT necessary for development of secondary sexual traits. However, they have sufficient testicular steroids, LH, and FSH to fully develop primary sexual function and fertility. These endocrine data help define alternative developmental pathways in male orangutans. The authors discuss the relationship between these developmental pathways and male orangutan reproductive strategies, and hypothesize about their prepubertal socioendocrine determination.

Serum corticosterone response to adrenocorticotropic hormone stimulation in Florida sandhill cranes.

Florida sandhill cranes (Grus canadensis pratensis) were conditioned to confinement in an enclosure for 7 days, 6 hr a day. On day 8, cranes were catheterized and then confined in an enclosure. Venous blood (2 ml) was collected through the catheter and an attached IV line immediately before (-60 min) and 60 min after (0 min) confinement. Using a randomization table and a restricted cross-over experimental design, cranes were injected intravenously with either saline (control) or adrenocorticotropic hormone (ACTH; cosyntropin, Cortrosyn; 0.25 mg). At 30, 60, 120, 180, 240 and 300 min after injection, blood samples were collected and assayed for corticosterone. The cranes receiving ACTH increased their serum corticosterone concentrations as much as fivefold above baseline concentrations. Serum corticosterone concentrations remained significantly elevated for approximately 60 min after ACTH stimulation. Physical restraint and catheterization caused an increase in serum corticosterone almost comparable to that induced by ACTH stimulation. In cranes injected with saline, serum corticosterone decreased within 1 hr after physical restraint and catheterization, and remained at lower levels throughout the remaining 5 hr of confinement.

Monitoring pregnancy in twinning pygmy loris (Nycticebus pygmaeus) using fecal estrogen metabolites.

Estrone and estrone conjugates were measured in the feces of three female pygmy lorises (Nycticebus pygmaeus) throughout estrus, pregnancy, and the postpartum period. Two females gave birth to twins, while the third had a single stillborn. A comparison between the hormonal profiles of these three pregnancies with each other and with previously reported pregnancies resulting in singletons or twins [Jurke et al., American Journal of Primatology 41:103-115, 1997] revealed a characteristic pattern of hormonal excretion. This report adds data to and confirms previous claims that monitoring estrone in this species provides a tool to assess gestation length (via determination of estrus period) and to predict the date of parturition and the number of offspring. However, there was an exceptional case of a pregnancy which had the hormonal appearance of a twin pregnancy but resulted in a single stillborn infant. This case prompted us to search for new insights into the characteristics and the origin of the estrogens that are excreted into the feces. Aromatase activity was evaluated in five partial placentae.

A preliminary investigation of urinary testosterone and cortisol levels in wild male mountain gorillas.

Urinary steroid hormone levels were measured in wild male mountain gorillas (Gorilla gorilla beringei) to determine how levels of testosterone and cortisol corresponded with age and social rank. Urine samples were collected noninvasively from 18 males, ranging in age from 3-26 years, in three groups of wild mountain gorillas at the Karisoke Research Center, Rwanda, Africa, and samples were analyzed using radioimmunoassay procedures. Males were classified as being immature (< 7 years), maturing (10-13 years), or adult (+13 years of age). Immature males had significantly lower levels of testosterone and higher levels of cortisol than both maturing and adult males. No differences in testosterone or cortisol levels were found between maturing and adult males. Dominant males exhibited a trend toward significantly higher levels of testosterone than subordinate males, but no difference was found between cortisol levels of dominant and subordinate males. These results suggest that the increase in testosterone associated with puberty occurs prior to any outward sign of development of secondary sexual characteristics. Within-group male-male competition may affect testosterone levels, but the lack of difference in cortisol levels between dominant and subordinate males suggests that subordinate males are not socially stressed, at least as measured by cortisol.

Non-invasive detection and monitoring of estrus, pregnancy and the postpartum period in pygmy loris (Nycticebus pygmaeus) using fecal estrogen metabolites.

Estrone-conjugates (E1C) were measured in the feces of six female pygmy lorises (Nycticebus pygmaeus) during estrus (n = 12), pregnancy (n = 4) and the postpartum period (n = 3). Noninvasive feces collection permitted frequent sampling throughout estrus and pregnancy, without disturbance of animals. The estrous period was defined as an increase in fecal E1C levels above an average of 70 ng/g feces with peaks above 100 ng/g feces obtained in consecutive fecal samples collected over a 6- to 11-day period between the end of July and the first third of October. Comparison of the periovulatory profile of E1C and the stage of labial opening of the vagina revealed a high agreement (P < 0.001). In all pregnant females, an E1C rise was found approximately 47 days postestrus, the source of which may be the growing fetal placental unit. Estimated gestation lengths ranged between 187 and 198 days (n = 4).

Diurnal urinary corticoid excretion in the human and gorilla.

Urinary corticoids were measured in humans (n = 9) in frequently collected urine samples taken during a 48 hr period, and in captive western lowland gorillas (n = 5) and free-ranging mountain gorillas (n = 3) from samples taken from 0700 to 1800 hr. In each study, the highest concentrations occurred in the morning hours, then declined gradually, reaching the lowest levels in the afternoon to evening. These data show that a similar diurnal pattern of corticoid excretion does occur in these species. We suggest that if single-sample urine collection for determination of hyperadrenal activity is to be used, urine is best collected during hours of low corticoid excretion. © 1994 Wiley-Liss, Inc.

Zebra chorionic gonadotropin: partial purification and characterization.

Six samples of pregnant zebra (z) serum from the first and second trimesters of pregnancy were analyzed by RIA and shown to have chorionic gonadotropin levels comparable to that of the mare (0.9-5.3 micrograms/ml); first trimester levels in most cases were higher than second trimester levels. A pool of the sera (10 ml) was fractionated by methods previously employed for the purification of equine (e) and donkey (d) chorionic gonadotropin to achieve a concentration of the zebra chorionic gonadotropin (zCG). A yield of 1.0 mg of glycoprotein was obtained. HPLC analysis of the material indicated the content of zCG to be about 7%. Its molecular size as judged by Ve/Vo values is smaller than eCG, greater than ovine LH, and about the same as equine LH. The zCG was tested in RIAs for LH and eCG, radioreceptor assays (RRA) for LH and FSH, and the rat testis Leydig cell assay for LH. Comparisons were made with equine and donkey chorionic gonadotropin, and equine and zebra LH. The results, preliminary because the preparation is not of high purity, showed that zCG is bioactive as an LH; immunologically similar to eCG, eLH, dCG, and zLH; and competes in RRAs for LH but not FSH receptors. It differs, therefore, from eCG and eLH--which have high levels of intrinsic FSH activity, and is more like dCG, dLH, and zLH--all of which have minimal if any FSH activity.

Reproductive cycle of the steppe polecat (Mustela eversmanni).

In laboratory conditions, in a natural photoperiod, testicular redevelopment began in late December. Maximal testis size was attained by the end of February. Testicular regression began in mid-May and was complete by the end of August. Oestrus was first observed in late March and continued throughout April. Females mated for the first time between 30 March and 8 April. Mating generally coincided with peak concentrations of urinary oestrone conjugates and when vaginal lavages contained greater than 90% cornified epithelial cells. Blastocyst implantation occurred by Day 13 and the post-implantation period was 29 days. Gestation ranged from 39 to 43 days and first parturition occurred in mid-May. Concentrations of urinary oestrone conjugates and free progesterone were elevated during the first half of pregnancy, reaching maximum values at mid-pregnancy, and then gradually declined as parturition neared. Litter size of primiparous females averaged 6.8 young/female. Females that were pseudopregnant or lost their litters shortly after birth, and several with weaned kits, exhibited a second oestrus.

Granulosa cell aromatase bioassay: changes of bioactive FSH levels in the female.

Some modified forms of follicle-stimulating hormone (FSH) may not cross react with the FSH antibody used in the radioimmunoassay (RIA), but still retain their biological activities. Therefore, estimates of immunoreactive FSH may not correspond with FSH bioactivity. The use of in vitro FSH bioassays may disclose possible roles of these heterogenous forms in vivo under various conditions. This review will focus on the history of FSH bioassays, and the widely used in vivo Steelman and Pohley bioassay, based on ovarian weight increase after injection into female rats, is discussed. Since 1971 different biological activities of FSH in various target tissues have been used for the in vitro estimates of FSH bioactivity. The aromatase bioassays involve the measurement of oestradiol in medium of FSH treated Sertoli cells or granulosa cells in culture. Estimates of FSH bioactivity, using the rat granulosa cell bioassay, in serum and urine or normally cycling women, during gonadotropin-releasing hormone-antagonist treatment in hypergonadotropic hypogonadal women and during different stages of female pubertal development will be discussed in more detail.

Monitoring ovarian function and pregnancy in the giant panda (Ailuropoda melanoleuca) by evaluating urinary bioactive FSH and steroid metabolites.

Urinary excretion of oestrone conjugates, pregnanediol-3 alpha-glucuronide (PdG) and 20 alpha-hydroxypregn-4-en-3-one were measured from 8 weeks before oestrus to 2 weeks post partum and bioactive FSH was monitored during the periovulatory interval in a female giant panda. A biphasic urinary bioactive FSH excretory profile appeared to indicate a broad (approximately 10 day) follicular phase followed by a sharp preovulatory bioactive FSH surge coincident with an acute increase in urinary oestrone conjugates and behavioural oestrus. Weekly concentrations of urinary oestrone conjugates and PdG increased (P less than 0.001) by Week 9 of gestation with 20 alpha-hydroxypregn-4-en-3-one levels increasing 10-30-fold (P less than 0.001) between Weeks 11 and 14. These observations indicate that the monoestrous giant panda does not appear to require a prolonged period of endogenous FSH release or multiple FSH peaks for ovarian priming and follicle selection to proceed normally. Furthermore, the delayed rise in urinary steroid excretion during the second half of gestation in the giant panda supports the concept of delayed implantation while the estimation of steroid conjugates in urine offers a non-invasive approach for monitoring pregnancy status in this endangered species.

Urinary concentrations of ovarian steroid hormone metabolites and bioactive follicle-stimulating hormone in killer whales (Orcinus orchus) during ovarian cycles and pregnancy.

Reproductive hormone profiles of six captive killer whales (Orcinu orcus) from three Sea World aquaria were studied for intervals up to 2 yr. Daily urine samples and bimonthly blood samples were collected and analyzed for hormone concentration. Immunoreactive estrone conjugates, pregnanediol-3-glucoruonide, 20-alpha-hydroxyprogesterone as well as bioactive follicle-stimulating hormone (FSH) were measured in urine samples and indexed by creatinine concentrations of the same sample. In selected cases, serum progesterone concentrations were also measured. Three of the animals in the study became pregnant during the study period and two of these animals were evaluated during the time of conception and throughout most of gestation. From the data of the three animals that conceived, hormone profiles of the complete ovarian cycle, early pregnancy, and mid- to late gestation are described. The remaining three animals did not conceive and only one of these demonstrated hormone changes that indicated regular ovarian activity. The female reproductive pattern of the killer whale is characterized by a gestation of 17 mo and an ovarian cycle of 6-7 wk in duration. The hormone changes associated with the ovarian cycle of the killer whale are similar to those of most other mammalian species. A bimodal pattern of bioactive FSH with a pronounced rise of estrogen predominates the preovulatory hormone profile. After ovulation, increased progesterone production is observed for approximately 4 wk in the nonconceptive ovarian cycle. During the luteal phase and early pregnancy, when progesterone metabolites are elevated, estrogen metabolite excretion remains low. These data extend the application of urine collections for longitudinal studies involving hormone changes, particularly those involving nondomesticated species.(ABSTRACT TRUNCATED AT 250 WORDS)

Urinary hormone analysis as a diagnostic tool to evaluate the ovarian function of female gorillas (Gorilla gorilla).

Daily urine samples were collected from 4 adult female gorillas over 7 menstrual cycles. Urinary oestrone conjugate and pregnanediol-3-glucuronide (PDG) were measured by radioimmunoassay; LH was measured by enzyme immunoassay and each hormone was indexed by creatinine. The quantity of urinary LH during the ovulatory surge was positively correlated with the quantity of PDG excreted during the luteal phase (r = 0.87, P = 0.0013). The observations indicate a relationship between the quality of the LH surge and the levels of PDG in the luteal phase and suggest that both the LH surge and subsequent luteal phase function may be predictable from the oestrogen excretion profile during the follicular phase.

Monitoring the menstrual cycle of humans and lowland gorillas based on urinary profiles of bioactive follicle-stimulating hormone and steroid metabolites.

A sensitive and specific in vitro granulosa cell aromatase bioassay was adapted to measure bioactive FSH (bio-FSH) levels in urine samples. Urinary levels of bio-FSH, immunoreactive LH, estrone conjugates, and pregnanediol-3-glucuronide (PdG) were measured in first morning urine samples during the menstrual cycle in six cycling women and four lowland gorillas. The cycle length of women was relatively constant [28 +/- 1 (+/- SD) days], but varied from 28-38 days for lowland gorillas; the length of the luteal phases was relatively constant for both. All subjects had a midcycle LH peak and a luteal phase elevation in PdG. In addition, urinary estrogen excretion displayed a midcycle elevation that preceded the LH peak and a luteal phase increase similar to that of PdG. The bio-FSH levels in urine of cycling women, although at almost 100-fold higher concentrations, exhibited a pattern that closely resembled that of serum bio-FSH levels reported earlier, with an early follicular phase rise and a midcycle peak. Statistical analysis indicated a highly significant correlation (r = 0.90) between serum and urinary bio-FSH levels during the human menstrual cycle and in women in several hypo- and hypergonadotropic states, including oral contraceptive pill users, hypothalamic amenorrhea, premature ovarian failure, and postmenopause. Although a midcycle bio-FSH surge was also detected in lowland gorillas, two peaks of bio-FSH levels were consistently found during the follicular phase. The late follicular phase increase in bio-FSH levels was presumably involved in follicle selection and preceded the midcycle FSH peak by about 6 days, whereas the timing of the early follicular phase peak was variable, suggesting the involvement of complex regulatory mechanisms. These findings suggest that measurement of urinary bio-FSH levels in humans reflects serum bio-FSH in subjects in several physiological and pathological states. Studies of urinary bio-FSH levels in humans and nonhuman primates are useful in monitoring menstrual cycles, and the gorillas may be a model for understanding human reproductive cycles. The urinary granulosa cell aromatase bioassay should be useful for future assessment of bio-FSH levels in situations where serum measurements are impractical or in animal species for which specific FSH RIAs are not available.

Níveis circulantes de estradiol, estrona e gonadotrofina, após a administraçåo de 17 beta-estradiol ativo por via oral, em mulheres após a menopausa / Circulating estradiol, estrone and gonadotropin levels following the administration of orally active 17 B-estradiol in postmenopausal women

A ingeståo de um único comprimido contendo 2mg de 17 beta-estradiol micronizado (E2) resultou em acentuado aumento das concentraçöes séricas de E2 e estrona (E1), em 9 mulheres após a menopausa. O aumento do E2 circulante se tornou significativo dentro de 2 horas, atingiu o pico (110 pg/ml; 437 por cento de aumento) em 5 horas, e permaneceu significativamente elevado em 8 horas após o tratamento. Em 24 horas, a concentraçåo sérica de E2 nåo diferiu significativamente da básica. Ao contrário, foi observado um aumento mais rápido (dentro de 1 hora) e pronunciado (4 vezes) na concentraçåo sérica de E1. O aumento continuou até ser atingido um pico (467 pg/ml; 2.000 por cento) em 6 horas após o tratamento. A seguir, a concentraçåo sérica de E1 decdlinou progressivamente, mas continuou significativamente elevada (140 pg/ml; P<0,01) em 24 horas após o tratamento. As concentraçöes séricas de FSH e LH se mostraram significativamente reduzidas em 6 e 3 horas, respectivamente, e ambas as gonadotrofinas permaneceram significativamente reduzidas em 24 horas após a ingeståo de E2. As relaçöes de E1:E2 em circulaçåo aqui relatadas (ca.3-6) foram muito superiores às observadas por outros investigadores após a administraçåo endovenosa de E2 (i.e. < 1). Assim, os resultados mostram que o E2 micronizado por via oral é rapidamente absorvido, e que, durante esse processo, uma porçåo significativa do hormômio se converte em E1 no trato gastrintestinal. Além disso, 2 mg de E2 oral exercem significativa atividade biológica, conforme demonstrado pela supressåo de gonadotrofina do soro. (J Clin Endocrinol Metab 40:518, 1975)