A quantitative study of serum testosterone,sex accessory organ growth,and the development of intermale aggression in the mouse

Radioimmunoassay of serum testosterone (T) was used to characterize circulating T levels in mice from birth to sexual maturity. Until 25 days of age, serum T levels ranged from 1 to 4 ng/ml. A significant increase in T concentrations was observed in 30-day-old males, followed by a secondary rise in serum T between Days 45 and 50 of life. The latter increment was associated with the appearance of extreme individual variation in circulating T levels which was also observed in adult (120 days) males. The most rapid growth of accessory sex organs occurred between 30 and 50 days of age, the period preceding attainment of peak serum-T levels. The first incidence of intermale aggression coincided with a prepubertal rise in circulating T, but adult levels of fighting were present prior to the secondary increase in T observed between 45 and 50 days of age. Although animals involved in a fight did not differ with respect to weight of the accessory sex organs or serum T concentrations, the male that weighed more than his opponent usually won an encounter. Compared to males in encounters in which no fighting occurred, animals that won or lost an aggressive encounter showed significantly greater accessory sex organ development. While circulating T is required for the initiation and maintenance of intermale aggression, it is apparent that additional factors are related to the onset of fighting and the establishment of dominance/ subordinance relationships in mice.     

The ovulatory and LH responses to the male effect in dominant and subordinate goats

The objective of this study was to evaluate the LH and ovulatory response of dominant and subordinate dairy does following the introduction of males. A behavioral study was carried out to determine the individual success index (SI) of 35 anestrous does according to their ability to dominate other females. The 8 highest-ranking (highest SI) and the 8 lowest-ranking does (lowest SI) in terms of dominance were separated from the rest of the herd and placed together in the same pen, where a male was later introduced. Blood samples for plasma LH determinations were obtained from the 16 females at 30 min intervals from 0 to 6, 12 to 18 and 33 to 39 h after the introduction of the male, using an intravenous catheter. After day 8, plasma progesterone was also measured daily in order to determine the occurrence of ovulation. None of the does showed LH pulses during the sampling period prior to the introduction of the male. The dominant does showed significantly (p < 0.05) more LH pulses (2.0 ± 0.18 ng/ml vs. 1.2 ± 0.25 ng/ml) and a higher mean plasma LH concentration (0.25 ± 0.03 ng/ml vs. 0.14 ± 0.03 ng/ml) than the subordinate goats during the first 6 h of exposure to the male. There were no differences in LH pulsatility or concentrations at other times. The frequency of goats that ovulated tended to be greater in high-ranked than low-ranked does (87% vs. 37%). It could be concluded that the immediate LH response to the presence of the male (number of LH pulses) is higher in the dominant, compared to the subordinate goats, and this is associated with a higher number of dominant goats ovulating in response to the male effect.     

Serum testosterone, agonistic behavior, and dominance in inbred strains of mice

Social situations in which male mice establish dominant/subordinate relationships were utilized in an attempt to correlate circulating testosterone (T) titer with agonistic behavior. Two long-term (several months) and two short-term (3- and 5-day) situations in which dominance was verified by severity of body scarring or individual aggression scores indicated no consistent correlation of dominance with serum T levels.     

Developmental patterns of plasma dehydroepiandrosterone sulfate and testosterone in male pigs

The relationship between plasma levels of dehydroepiandrosterone sulfate (DHAS) and testosterone (T) was determined by radioimmunoassays in growing and adult pigs. Seven young males were bled at 2-weekly intervals between 1 and 47 weeks of age and two adult boars were cannulated for short-term studies. Plasma samples were extracted with methylene chloride and T was isolated by Celite chromatography. DHAS was assayed directly in the aqueous phase.Dehydroepiandrosterone occurred predominantly (89.7 ± 10.6%) as the sulfoconjugate in boar plasma (n = 50). Plasma DHAS was undetectable in castrated males (n = 2). At 1 week of age, mean levels (± S.D.) of DHAS and T were 5.0 ± 3.0 ng/ml and 0.15 ± 0.10 ng/ml, respectively; and they rose to small peaks of 16.0 ± 2.0 ng/ml and 0.63 ± 0.10 ng/ml at 3 weeks. At 7 weeks, the levels of DHAS and T increased gradually from 10.0 ± 6.7 and 0.11 ± 0.10 ng/ml to 27.0 ± 6.6 and 1.84 ± 0.61 ng/ml at 19 weeks. There followed a marked increase to 4.90 ± 3.30 ng/ml at 21 weeks for T and a less abrupt rise to 44.0 ± 9.3 ng/ml at 23 weeks for DHAS. The mean levels remained high from then onwards, fluctuating between 24.0 ± 8.7 and 54.5 ± 5.0 ng/ml for DHAS and between 1.73 ± 0.86 and 4.43 ± 1.26 ng/ml for T. Episodic fluctuations were noted in two boars during hourly collection for 24 h, with mean levels of 9.0 ± 4.9 and 50.0 ± 10.4 ng/ml for DHAS, and 1.76 ± 0.83 and 3.26 ± 0.63 ng/ml for T, respectively.For all ages of males, plasma DHAS and T levels were highly correlated (r = 0.95) with greater concentrations of DHAS in all samples. Although individual differences in steroid profiles were noted, concentrations for DHAS and T showed almost parallel increases at puberty and corresponding fluctuations in adult boars. It is suggested that plasma DHAS determinations provide a simple, sensitive assessment of androgen production in the male pig.     

Mating Resets Male Cricket Aggression

An animal’s motivational state can significantly impact its behavior. We examined the effects of mating on the aggression of male Acheta domesticus crickets. Pairs of males were allowed to establish dominance and subordinance and were then physically separated. Subordinate males were then allowed to either copulate with a female or to have chemo-tactile contact with, but to not copulate with, a female. Less than 15 min after separation, all male pairs engaged in a second agonistic encounter. Subordinate males that copulated with females were significantly more aggressive toward their dominant partners than un-mated subordinate males. Many mated subordinates became dominant. Allowing a subordinate male to contact, but not copulate with, a female had a similar effect, suggesting that chemo-tactile cues from the female are sufficient to elicit this change in aggression.     

Circadian pattern of plasma melatonin concentrations in the marmoset monkey (Callithrix jacchus)

This study describes the concentrations of melatonin in plasma samples taken from marmoset monkeys (Callithrix jacchus) every 4 h over three 24-h periods. A circadian pattern of secretion was apparent, with higher levels recorded at night (20.00–08.00 h) than during the day (08.00–20.00 h) and a peak concentration at 20.00 h. There was a significant difference in the mean day and night concentrations (32.5 ± 4.5 pg/ml versus 49.0 ± 6.9 pg/ml, respectively) with individual concentrations ranging between<10–60 pg/ml in the day and 15–200 pg/ml at night. Circadian plasma melatonin concentrations were similar over the three 24-h periods, in male (n = 3) and female (n = 3) monkeys, and in dominant (cyclic, n = 5) and subordinate (acyclic, n = 4) females. The results show a less pronounced circadian profile in the marmoset than is seen in the human but a similar profile to that in the seasonally breeding rhesus monkey.     

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.     

Endocrine and ovarian responses associated with the first-wave dominant follicle in cattle.

To examine endocrine and biochemical differences between dominant and subordinate follicles and how the dominant follicle affects the hypothalamic-pituitary-ovarian axis in Holstein cows, the ovary bearing the dominant follicle was unilaterally removed on Day 5 (n = 8), 8 (n = 8), or 12 (n = 8) of synchronized estrous cycles. Follicular development was followed daily by ultrasonography from the day of detected estrus (Day 0) until 5 days after ovariectomy. Aromatase activity and steroid concentrations in first-wave dominant and subordinate follicles were measured. Intact dominant and subordinate follicles were cultured in 4 ml Minimum Essential Medium supplemented with 100 microCi 3H-leucine to evaluate de novo protein synthesis. Five days after unilateral ovariectomy, cows were resynchronized and the experiment was repeated. Follicular growth was characterized by the development of single large dominant follicles, which was associated with suppression of other follicles. Concentrations of estradiol-17 beta (E2) in follicular fluid and aromatase activity of follicular walls were higher in dominant follicles (438.9 +/- 45.5 ng/ml; 875.4 +/- 68.2 pg E2/follicle) compared to subordinate follicles (40.6 +/- 69.4 ng/ml; 99.4 +/- 104.2 pg E2/follicle). Aromatase activity in first-wave dominant follicles was higher at Days 5 (1147.1 +/- 118.1 pg E2/follicle) and 8 (1028.2 +/- 118.1 pg E2/follicle) compared to Day 12 (450.7 +/- 118.1 pg E2/follicle). Concentrations of E2 and androstenedione in first-wave dominant follicles were higher at Day 5 (983.2 +/- 78.2 and 89.5 +/- 15.7 ng/ml) compared to Days 8 (225.1 +/- 78.6 and 5.9 +/- 14.8 ng/ml) and 12 (108.5 +/- 78.6 and 13.0 +/- 14.8 ng/ml). Concentrations of progesterone in subordinate follicles increased linearly between Days 5 and 12 of the estrous cycle. Plasma concentrations of FSH increased from 17.9 +/- 1.4 to 32.5 +/- 1.4 ng/ml between 0 and 32 h following unilateral removal of the ovary with the first-wave dominant follicle. Increases in plasma FSH were associated with increased numbers of class 1 (3-4 mm) follicles in cows that were ovariectomized at Day 5 or 8 of the cycle. Unilateral ovariectomy had no effects on plasma concentrations of LH when a CL was present on the remaining ovary. First-wave dominant follicles incorporated more 3H-leucine into macromolecules and secreted high (90,000-120,000) and low (20,000-23,000) molecular weight proteins that were not as evident for subordinate follicles at Days 8 and 12.(ABSTRACT TRUNCATED AT 400 WORDS)     

Alpha melanocyte stimulating hormone inhibits prolactin secretion in fetal and infant lambs

The intravenous administration of αMSH (25 μg/kg) to 11 lambs (3 to 29 days of age) suppressed plasma PRL by 15 minutes. The mean basal concentration was 15.3 ± 2.9 ng/ml and the mean nadir was 4.9 ± 0.8 ng/ml (p<0.01). In chronically catheterized fetuses (128–140 days), intravenous administration of αMSH (25 μg/kg) decreased basal PRL levels (89.6 ± 12.4 ng/ml) significantly at 15–30 minutes to levels of 74.3 ± 11.4 ng/ml (p<.01). The degree of suppression of basal PRL levels was less in fetusus (76.9 ± 4.1%) than that induced in the neonates (40.5 ± 7.1%). In younger fetuses <120 days in whom basal PRL levels are low (3.0 ± 2.1 ng/ml), administration of αMSH was without effect. Plasma GH concentrations were not altered by administration of αMSH. The suppression of PRL secretion by αMSH administration could result from increased release of hypothalamic dopamine or be a direct effect on secretion of prolactin by the pituitary.     

Styles of male social behavior and their endocrine correlates among low-ranking baboons

We have previously studied the relationship between social subordinance (by approach-avoidance criteria) and physiology among male olive baboons (Papio anubis) living freely in a national park in Africa. In stable hierarchies, subordinate individuals have elevated basal glucocorticoid concentrations and a blunted glucocorticoid response to stress, as well as a prompt suppression of testosterone concentrations during stress. These facets have been interpreted as reflecting the chronic stress of social subordinance. In the present report, we find that these endocrine features do not mark all subordinate individuals. Instead, endocrine profiles differed among subordinate males as a function of particular stylistic traits of social behavior. A subset of subordinate males was identified who had significantly high rates of consortships, a behavior usually shown only by high-ranking males. Such behavior predicted the beginning transition to dominance, as these males were significantly more likely than other subordinates to have moved to the dominant half of the hierarchy over the subsequent 3 years. In keeping with this theme of emerging from subordinance, these individuals also had significantly larger glucocorticoid stress-responses, another feature typical of dominant males. However, these subordinate males also had significantly elevated basal glucocorticoid concentrations; it is suggested that this reflects that stressfulness of their overt and precocious strategy of reproductive competition. In support of this, subordinate males with high rates of covert “stolen copulations” did not show elevated basal glucocorticoid concentrations. A second subset of subordinate males were the most likely to initiate fights or to displace aggression onto a third party after losing a fight. These males had significantly or near-significantly elevated testosterone concentrations, compared to the remaining subordinate cohort. Moreover, these males had significantly lower basal glucocorticoid concentrations; this echoes an extensive literature showing that the availability of a displacement behavior (whether aggressive or otherwise) after a stressor decreases glucocorticoid secretion. In support of this interpretation suggesting that it was the initiation of these aggressive acts which attenuated glucocorticoid secretion, there was no association between glucocorticoid concentrations and participation (independent of initiation) in aggressive interactions. Thus, these findings suggest that variables other than rank alone may be associated with distinctive endocrine profiles, and that even in the face of a social stressor (such as subordinance), particular behavioral styles may attenuate the endocrine indices of stress. Am. J. Primatol. 42:25–39, 1997. © 1997 Wiley-Liss, Inc.     

Female Preferences Based on Male Quality in House Mice: Interaction between Male Dominance Rank and t-Complex Genotype

Considerable evidence indicates that female house mice (Mus domesticus) prefer dominant over subordinate males as mates. In addition, male genotype at the t-complex seems to be an important characteristic used by females in mate choice. Specifically, female mice that carry a t-haplotype at the t-complex prefer +/+ over +/t males as mates. The purpose of the present study was to examine the relative contributions of male dominance rank and male t-complex genotype to female mating preference when both factors were systematically varied. We tested females of three genotypes (+/+, +/t, and t/t) in a preference apparatus using pairs of stimulus males varying in relative dominance status and t-complex genotype. In general, when given the choice, females preferred dominant over subordinate males regardless of the male's t-complex genotype. The preference for dominant males was manifested when both stimulus males were of the same t-complex genotype but differed in dominance rank. In addition, when forced to choose between a dominant +/+ and subordinate +/t or between a dominant +/t and subordinate +/+, females continued to prefer the dominant male. Preference for dominant males was independent of female genotype. Only when both males were dominant but differed in t-complex genotype (i.e. one male was +/+ and the other +/t) or when males were unranked (i.e. had not been used in aggressive encounters to determine dominance rank) did females carrying t-haplotypes manifest preferences for +/+ males. Quite unexpectedly, when both males were subordinate but differed in t-complex genotype, preferences of all females shifted in the direction of the +/t male. It is not clear from present data whether the propensity of females to give greater weight to male dominance rank than to t-complex genotype in choosing mates results in greater fitness. However, if these trends are found in natural populations, it would indicate that the role of mating preference in regulating the frequency of t-haplotypes in wild populations is less straightforward than had been previously thought.     

A Trouble Shared Is a Trouble Halved: Social Context and Status Affect Pain in Mouse Dyads

In mice behavioral response to pain is modulated by social status. Recently, social context also has been shown to affect pain sensitivity. In our study, we aimed to investigate the effects of interaction between status and social context in dyads of outbred CD-1 male mice in which the dominance/submission relationship was stable. Mice were assessed for pain response in a formalin (1% concentration) test either alone (individually tested-IT), or in pairs of dominant and subordinate mice. In the latter condition, they could be either both injected (BI) or only one injected (OI) with formalin. We observed a remarkable influence of social context on behavioral response to painful stimuli regardless of the social status of the mice. In the absence of differences between OI and IT conditions, BI mice exhibited half as much Paw-licking behavior than OI group. As expected, subordinates were hypoalgesic in response to the early phase of the formalin effects compared to dominants. Clear cut-differences in coping strategies of dominants and subordinates appeared. The former were more active, whereas the latter were more passive. Finally, analysis of behavior of the non-injected subjects (the observers) in the OI dyads revealed that dominant observers were more often involved in Self-grooming behavior upon observation of their subordinate partner in pain. This was not the case for subordinate mice observing the pain response of their dominant partner. In contrast, subordinate observers Stared at the dominant significantly more frequently compared to observer dominants in other dyads. The observation of a cagemate in pain significantly affected the observer''s behavior. Additionally, the quality of observer''s response was also modulated by the dominance/submission relationship.     

Competitive protein binding assay of progesterone without chromatography

A competitive protein binding assay for the measurement of progesterone in human plasma without chromatographic separation of steroids and recovery evaluation in individual samples is described. It is based on the specificity of the progesterone binding plasma protein (PBP) of the pregnant guinea pig. A dried petroleum ether extract of plasma was incubated with ³H-progesterone and 1600 fold diluted pregnant guinea pig plasma. Bound radioactivity was measured with a dextran coated charcoal suspension technique. Plasma progesterone concentration was obtained by comparison with a standard curve and correction for extraction separately measured for each batch of petroleum ether. The sensitivity was 100 pg. Recovery experiments for progesterone and competing steroids added to plasma respectively showed the accuracy and the specificity of the method. However comparison of the results from assays with and without chromatographic separation of steroids, showed that in the latter-case the specificity was good only for plasmas containing more than 1ng/ml of progesterone. Concentration of progesterone in plasma from men was 0.46±0.14 ng/ml (mean ± S.D) and from post menopausal women 0.30± 0.13 ng/ml.Between days 1 and 13 and days 16 and 22 of the normal menstrualcycle the concentrations were respectively 0.81 ± 0.38 and 12.50 ± 2.96 ng/ml. The variations of the progesterone concentration during pregnancy are also shown.     

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.     

Circulating isoflavonoid levels in CD-1 mice: effect of oral versus subcutaneous delivery and frequency of administration

The CD-1 mouse is a commonly used animal model to understand the biological effects of early-life exposure to soy isoflavones in infants. Most studies using CD-1 mice have administered isoflavones by daily subcutaneous injection, while infants receive oral feeds every few hours. The study objectives were to compare the total serum levels of genistein (GEN), daidzein (DAI) and the DAI metabolites equol and O-desmethyl-angolensin (O-DMA), after subcutaneous injection and oral dosing and to determine if frequency of oral administration results in different circulating levels of isoflavones using the CD-1 mouse model. From postnatal days 1 to 5, pups randomly received corn oil or soy isoflavones (total daily dose, 0.010 mg DAI+0.025 mg GEN) by subcutaneous injection once a day, orally once a day or orally every 4 hours. On postnatal day 5, 1 h posttreatment, mice were killed and serum was collected. Mice treated with soy isoflavones had higher (P<.05) serum GEN (female: 1895–3391 ng/ml and male: 483–578 ng/ml) and DAI (female: 850–1580 ng/ml and male: 248–322 ng/ml) concentrations versus control (5–20 ng/ml) mice, regardless of route or frequency of administration, and were similar among dosing strategies. Total serum concentrations of GEN and DAI were higher (P<.05) among females (GEN: 2714 ± 393 ng/ml and DAI: 1205 ± 164 ng/ml) than males (GEN: 521 ± 439 ng/ml and DAI: 288 ± 184 ng/ml) across treatment groups. Serum equol and O-DMA concentrations were negligible (<3 ng/ml) across groups. In conclusion, different routes of delivery and frequency of administration resulted in similar total serum levels of GEN, DAI¸ equol or O-DMA.     

Effect of sexual stimulation on concentrations of 5α-androstenone and testosterone in the peripheral plasma of boars reared individually

Six Yorkshire boars were reared from 107 days of age in individual pens. No female pigs were housed in the same building. When the boars were 200 days old, sows in oestrus were introduced to the pens of five boars and remained with the boars for 2 days. No oestrous sow was introduced to the pen with the sixth boar. Plasma 5α-androstenone and testosterone concentrations were low between 107 and 200 days of age in all boars. The maximum mean concentrations of these two steroids during this period were 6.18 ± 0.72 and 3.04 ± 1.02 ng/ml, respectively. Plasma 5α-androstenone concentrations increased with advancing age (P < 0.01). A similar trend was not seen for plasma testosterone concentrations. Plasma concentrations of 5α-androstenone and testosterone increased by 247 ± 27% (P < 0.02) and 1212 ± 204% (P < 0.001), respectively, in the samples drawn 24 h after the introduction of the sexually receptive sows. The maximal mean concentrations recorded following sexual stimulation were 12.90 ± 1.80 and 17.51 ± 1.96 ng/ml for 5α-androstenone and testosterone, respectively. The control boar also showed increases in plasma 5α-androstenone (221%) and testosterone (751%) concentrations in the same period, probably in response to auditory and olfactory stimuli originating in the pens nearby with introduced oestrous sows.     

Plasma luteinizing hormone and prolactin in normothermic and hyperthermic ovariectomized ewes

The effect of bromocriptine on concentrations of luteinizing hormone (LH) and prolactin (PRL) as well as the rhythmicity of episodic profiles of plasma LH were investigated in twelve ovariectomized ewes exposed to 3-day trials during which ambient temperature/humidity conditions maintained either normothermia or induced an average of 1.4°C increase of rectal temperature (hyperthermia). In 24 of 48 trials, ewes received twice daily subcutaneous injections of 1 mg bromocriptine beginning at 1900 hr on day 1. Plasma PRL and LH were measured at 10-min intervals for 4 hr on days 2 and 3. Bromocriptine significantly decreased plasma PRL (65 ± 6 vs 5 ± 1 ng/ml), mean plasma LH (11.0 ± 0.2 vs 6.5 ± 0.2 ng/ml) and tended (P < 0.1) to decrease LH rhythmicity. In hyperthermic placebo-treated ewes, plasma PRL was increased (65 ± 6 vs 212 ± 20 ng/ml) and mean LH was decreased (11.0 ± 0.2 vs 8.2 ± 0.2 vg/ml) compared to normothermic, placebo-treated ewes, but there was no effect of hyperthermia on LH rhythmicity. Bromocriptine treatment of hyperthermic ewes decreased mean PRL (212 ± 20 vs 32 ± 9 ng/ml) on both days of sampling although mean levels were significantly higher on day 2 than on day 3(54 ± 14 vs 10 ± 6 ng/ml). Perhaps because mean LH was already inhibited in hyperthermic ewes, bromocriptine did not further decrease mean LH (8.2 ± 0.2 vs 6.6 ± 0.2 ng/ml), but LH rhythmicity was decreased (P < 0.01). There was no significant difference in mean LH between normothermic ewes receiving bromocriptine and hyperthermic ewes receiving bromocriptine (6.5 ± 0.2 vs 6.6 ± 0.2 ng/ml). These results indicate that bromocriptine inhibits PRL and LH secretion in normothermic ewes. In hyperthermic ewes, the inhibitory effect of bromoriptine on PRL was even more pronounced, but the effect on LH release was minimal perhaps because LH was already inhibited by hyperthermia.     

Changes in plasma,pituitary and brain α-MSH content in rats from birth to sexual maturity

Immunoreactive α-MSH was measured in plasma, pituitary and brain of male and female rats on the day of birth and at intervals afterwards up to 55–70 days of age. Plasma α-MSH concentrations on the day of birth were 528 ± 111 pg/ml and 406 ± 137 pg/ml in famel and male rats, respectively. Plasma α-MSH concentrations then fell and remained low until the onset of sexual maturity when they again rose reaching 406 ± 38 pg/ml in 70 day old females and 312 ± 46 pg/ml in 55 day old males. Pituitary α-MSH concentrations also changed with age and in male rats generally reflected the changes in plasma α-MSH concentrations. In females, on the other hand, pituitary α-MSH concentrations showed a gradual increase with age. Concentrations of α-MSH in the hypothalamus and brain increased with age and as with plasma and pituitary reached peak values in sexually mature animals. These findings are consistent with the idea that both piutiary and brain α-MSH have a role in sexually mature rats. Although α-MSH may have a role in sexual behaviour there was no evidence of any change in brain α-MSH throughout the estrous cycle.     

Manipulation of androgens causes different energetic responses to cold in 60- and 40-day-old male rats

Previous studies suggested that adults respond differently than pubertal male rats to cold stress. To test the role of androgens in this difference, we adrenalectomized and replaced with corticosterone either 60- or 40-day-old male rats, then sham gonadectomized (Intact), gonadectomized (GDX), or GDX and replaced with testosterone (T; GDX+T) or dihydrotestosterone (DHT). One-half remained at room temperature (RT), and one-half lived in cold for 5 days. Cold reduced T in adult but not in pubertal Intacts. In 60-day-old rats, GDX with or without T replacement had minor effects on body weight (BW) and food intake (FI) at RT and cold. In 40-day-old rats at RT, androgens had slight effects; however, androgens affected almost all variables in cold. Separation of 40-day-old T-treated rats into two groups (moderate T levels, 1.4 ng/ml; high T levels, 1.9 ng/ml) revealed major differences between the groups. Moderate T (and DHT) prevented cold-induced loss of BW and increased FI. No T and high T induced decreased BW and FI in cold. We conclude that at 40 days of age, partial resistance to stress-induced reduction of T and high sensitivity to small changes in T have markedly positive effects on threatened energy balance.     

Plasma prolactin in the periparturient sow

A homologous radioimmunoassay was used for measurement of porcine prolactin in blood plasma collected from sows during the periparturient period. The assay was able to detect prolactin over a range of 0.5 to 7.0 ng/assay tube. There was no significant cross reaction with growth hormone, luteinizing hormone, or follicle stimulating hormone at amounts up to 10⁵ ng/assay tube while porcine ACTH gave 30% binding at 10⁴ ng. Prolactin was not detected in plamsa from a hypophysectomized pig or 2 ergocryptine-treated sows when 100 μ l plasma were assayed. Prolactin concentration in plasma was then measured in 14 periparturient sows within a period extending from 7 days before farrowing to 7 days after farrowing. Samples were collected at 15 min intervals between 1330 and 1630 h each day. However, prolactin assays were done only on the even-numbered samples (30 min interval). Plasma prolactin concentrations (ng/ml, $\text{X}\text{± SEM}$) were 23.7 ± 2.0 on days ?7 to ?5 prepartum, began to rise by day ?3 prepartum (42.5 ± 5.9), and peaked at 127.5 ± 17.6 on day 1 prepartum. By day 3 postpartum, prolactin concentrations in plasma had decreased to 80.5 ± 12.6 and further declined to 51.6 ± 4.6 on day 7 postpartum. The mean prolactin concentration in plasma for all pigs on days ?1 to +2 was 116.8 ± 13.8. This mean concentration for days ?1 to +2 was different (P < 0.025) from the mean prolactin concentration for the period both prior and subsequent to these days (?8 to ?2 and +3 to +8 days).