Genetic regulation of hormone action: selective effects of progesterone and dihydroprogesterone (5alpha-pregnane-3,20-dione) on sexual receptivity in mice

Lordosis behavior was measured in estrogen-primed, castrated female mice of the CD-1 and Swiss-Webster strains. In CD-1 mice, repeated stimulation with progesterone or dihydro-progesterone for at least 5 weeks was required for maximal facilitation of the lordosis response. The data further indicated that progesterone and dihydroprogesterone were acting via independent systems. In Swiss-Webster mice, progesterone, but not dihydroprogesterone, was similarly capable of inducing a high probability of lordosis responses.     

Ovarian hormones and the duration of sexual receptivity in the female golden hamster

The induction of sexual receptivity and its maintenance after copulation in ovariectomized female golden hamsters (Mesocricetus auratus) was found to be a function of the levels of ovarian hormones administered. Various combinations of estradiol benzoate (between 0.6 and 666 μg) and progesterone (between 0.05 and 5.0 mg) were administered in two experiments. Although some animals responded at 0.6 μg, higher levels of estradiol benzoate (1–6 μg or more) were more effective in inducing levels of lordosis equivalent to those seen in intact females in natural estrus. After mating, a depression in lordosis was observed in both ovariectomized and intact females. However, in ovariectomized females (excluding animals that did not respond initially) the duration of postcopulatory receptivity was a function of the level of progesterone administered. High levels of progesterone tended to prolong slightly the duration of postcopulatory receptivity.     

Role played by the ovary and adrenals in early receptivity during 4-day cycle in the female rat

The mechanisms involved in the control of precocious sexual receptivity were studied in 4-day cyclic female Wistar rats injected with 10 μg estradiol benzoate (EB) and caged with a male during the night from diestrus II to proestrus. Early mating frequencies were compared in intact females, in animals ovariectomized on the morning of diestrus I, in adrenalectomized and in adrenalectomized-ovariectomized females. No change in early sexual receptivity occurred either in ovariectomized, or in adrenalectomized animals. On the contrary, a significant decrease of precocious mating frequencies was noted in adrenalectomized-ovariectomized females. The role played by the ovary in the control of precocious receptivity was supposed to be due to the secretion of progesterone which has been evidenced on the late afternoon of diestrus II in estrogen treated females.Concerning the mechanisms by which the adrenals may compensate for the ovaries in the control of early sexual receptivity in estrogen-primed females it was observed that notwithstanding an inhibitory action exerted by EB on the adrenal progesterone secretion, a low rate of progesterone was maintained in the peripheral plasma which was compatible with early mating in ovariectomized animals.     

Induction of lordosis behavior in female rats by intravenous administration of progestins

Progesterone is rapidly metabolized by neural cells in the rat. Progesterone could, therefore, act as a “prohormone,” stimulating lordosis behavior in estrogen-primed rats only after metabolic conversion. Were such the case, one might expect one or more of the naturally occurring metabolites of progesterone to be more potent than the parent compound. Estradiol benzoate-primed rats were therefore administered intravenously 200 μg of progesterone or one of five immediate metabolites of progesterone. The steroid 20α-dihydroprogesterone was found to be more potent than progesterone. Both 20α-hydroxy-5α-pregnan-3-one and 3α-hydroxy-5α-pregnan-20-one were less potent than progesterone, but more potent than the vehicle propylene glycol. Neither 5α-pregnane-3α, 20α-diol nor 5α-pregnane-3,20-dione (dihydroprogesterone, DHP) differed from the vehicle in potency. The data suggest that 20α-dihydroprogesterone, which is secreted at high levels during the estrous cycle, could play a role in the regulation of sexual receptivity. The data also suggest that 5α-reduction is probably not crucial for progesterone's action.     

Facilitation of sexual receptivity in female mice through blockade of adrenal 11 beta-hydroxylase

Ovariectomized mice were given replacement estrogen and progesterone, and tested for sexual receptivity in the presence of mounting males after various pharmacological manipulations of adrenocortical hormone activity. In Experiment I, females received a chronic regimen of varied dosages of metyrapone, which blocks adrenal conversion of desoxycorticosterone to corticosterone. In each of three repeated measures, females given an intermediate dosage (800 micrograms/animal/injection) showed substantially higher levels of receptivity than those given vehicle injections or other dosages. In Experiment 2, corticosterone administration reversed the facilitatory action of metyrapone on receptivity. In Experiment 3, chronic administration of either desoxycorticosterone or progesterone failed to elevate receptivity. These findings suggest that corticosterone titer may play a role in modulating female receptivity in sexually inexperienced mice.     

Cycles of mating behaviour, oestrogen and progesterone in the thick-tailed bushbaby (Galago crassicaudatus crassicaudatus) under laboratory conditions

Vaginal smears and blood samples were taken throughout the reproductive cycle of female Galago c. crassicaudatus. Blood plasma was assayed for oestradiol and progesterone, and vaginal smears were initially classified dioestrus or vaginal oestrus. During vaginal oestrus the females were tested daily for sexual receptivity by being placed with a male. Those days on which the male achieved intromission were reclassified as behavioural oestrus. During dioestrus the females were tested weekly with males. Female receptivity increased and then declined across a 6-day period of behavioural oestrus during the 44-day cycle. Fully cornified smears were characteristic of the period of maximal receptivity and oestradiol secretion. The luteal phase lasted 24 days with a plasma progesterone peak midway through dioestrus.     

Natural or hormone-induced sexual and social behaviors in the female brown lemming (Lemmus trimucronatus)

The behaviors of intact or ovariectomized, estradiol benzoate-treated or estradiol benzoate followed by progesterone-treated female brown lemmings were compared. Intact, diestrous females engaged in more social interactions with a male than did ovariectomized females (Experiment 1). In the first 5 min of a 1-hr mating exposure (Experiment 2, Test A) intact females in natural estrus engaged in more social and sexual behaviors than did ovariectomized females in estrogen-induced estrus. However, during the last 5 min of the 1-hr exposure (Test B) ovariectomized females receiving estrogen alone continued to show high levels of sexual activity with a male partner, while intact estrous females or females receiving estrogen followed by progesterone showed an apparent drop in sexual receptivity and an increase in aggressivity. Aggressive behaviors, as indexed by threat-leap behaviors on the part of the female may increase in the presence of progesterone. Declines in sexual activity, occurring within 1 hr of progesterone injection, were apparently dependent on the interaction of progesterone and copulatory events which may affect both the male and female.     

Long-term alteration of anxiolytic effects of ovarian hormones in female mice by a peripubertal immune challenge

Recent reports indicate that exposure to some stressors, such as shipping or immune challenge with the bacterial endotoxin, lipopolysaccharide (LPS), during the peripubertal period reduces sexual receptivity in response to ovarian hormones in adulthood. We hypothesized that a peripubertal immune challenge would also disrupt the response of a non-reproductive behavior, anxiety-like behavior, to ovarian hormones in adulthood. Female C57Bl/6 mice were injected with LPS during the peripubertal period and tested for anxiety-like behavior in adulthood, following ovariectomy and ovarian hormone treatment. Treatment with estradiol followed by progesterone reduced anxiety-like behavior in control, but not LPS-treated females. We next determined if the disruptive effect of LPS on adult behavior were limited to the peripubertal period by treating mice with LPS either during this period or in adulthood. LPS treatment during the peripubertal period disrupted the anxiolytic effect of ovarian hormones, whereas treatment in adulthood did not. We further tested if this model of peripubertal immune challenge was applicable to an outbred strain of mice (CD-1). Similar to C57Bl/6 mice, LPS treatment during the peripubertal period, but not later, disrupted the anxiolytic effect of estradiol and progesterone. These data suggest that a peripubertal immune challenge disrupts the regulation of anxiety-like behavior by ovarian hormones in a manner that persists at least for weeks after the termination of the immune challenge.     

Serum steroid hormones including 11-ketotestosterone, 11-ketoandrostenedione, and dihydroprogesterone in juvenile and adult bonnethead sharks, Sphyrna tiburo.

Previous studies in the placental viviparous bonnethead shark, Sphyrna tiburo, have correlated 17 beta-estradiol, progesterone, testosterone, and dihydrotestosterone with reproductive events in both males and females. However, several key reproductive events, including implantation, maintenance of pregnancy, and parturition, did not correlate with these four steroid hormones. Therefore, the present study investigated three steroid hormones, 11-ketotestosterone, 11-ketoandrostenedione, and dihydroprogesterone, which have demonstrably important roles in the reproductive cycles of teleosts. It was hypothesized that one or more of these three hormones would correlate with specific reproductive events in S. tiburo. Concurrently, developmental (growth and/or maturation) analyses of these three steroids plus 17 beta-estradiol, progesterone, testosterone, and dihydrotestosterone were investigated in juvenile bonnethead sharks. Serum dihydroprogesterone concentrations were highest in mature females and 11-ketotestosterone concentrations were highest in mature males. In mature females, 11-ketoandrostenedione levels were elevated from the time of mating, through six months of sperm storage and another four months of gestation. At parturition concentrations became significantly lower and remained lower until mating occurred again in another two to three months. Serum 11-ketotestosterone concentrations were the highest at implantation though not significant. In mature males, significantly elevated serum levels of dihydroprogesterone occurred in April and May, near the start of annual testicular development. During growth in males, testosterone and dihydrotestosterone increased progressively and in females, testosterone increased progressively. At maturity in males, significant increases occurred in testosterone and 11-ketotestosterone concentrations while, in females, dihydroprogesterone, 11-ketotestosterone, 17 beta-estradiol, progesterone, testosterone, and dihydrotestosterone concentrations increased. This study shows that although testosterone may be the primary androgen in the bonnethead shark, other derived androgens may have important functions in growth, maturation, and reproduction. J. Exp. Zool. 284:595-603, 1999.     

Progesterone facilitation of lordosis in male and female Sprague-Dawley rats following priming with estradiol pulses

Adult male Sprague-Dawley rats rarely exhibit progesterone-facilitated lordosis following steroid treatments which are effective in females. In contrast, progesterone-facilitated lordosis has been observed following priming with estradiol pulses in another strain. The aim of this study was to compare progesterone-facilitated feminine sexual behavior in adult male and female Sprague-Dawley rats following priming with estradiol benzoate (EB) or estradiol pulses. Female sexual behavior was measured in adult, gonadectomized males and females treated as follows: Two pulses of estradiol followed by progesterone or oil the next day; EB (two doses) for 3 days, and progesterone or oil the next day. These protocols were repeated at 4- or 6-day intervals, respectively. Progesterone-facilitated lordosis was observed consistently in both sexes treated with estradiol pulses. By the fifth test, lordosis quotients did not differ between the sexes, but the lordosis ratings in progesterone-treated males remained lower than those observed in females. Proceptivity (hop-darting) was facilitated by progesterone in females, but was never observed in males. Lordosis was induced in both sexes by 15 micrograms EB, but was not reliably facilitated by progesterone. Treatment with the lower dose of EB (1.5 micrograms) induced high levels of receptivity in females (occasionally facilitated by progesterone), but not in males regardless of subsequent treatment (i.e, progesterone or oil). These data suggest that progesterone-facilitated lordosis can be induced in male Sprague-Dawley rats, if a regimen of estradiol pulses is used. Thus, the brain of the adult male is not inflexibly differentiated with regard to progesterone facilitation of feminine receptive behavior.     

Sex steroid correlates of female-specific colouration,behaviour and reproductive state in Lake Eyre dragon lizards, <Emphasis Type="Italic">Ctenophorus maculosus</Emphasis>

In some species, females develop bright colouration to signal reproductive status and exhibit behavioural repertoires to incite male courtship and/or reduce male harassment and forced copulation. Sex steroids, including progesterone and testosterone, potentially mediate female reproductive colouration and reproductive behaviour. We measured associations among plasma profiles of testosterone and progesterone with variation in colour expression and reproductive behaviour, including unique courtship rejection behaviours, in female Lake Eyre dragon lizards, (Ctenophorus maculosus). At onset of breeding, progesterone and testosterone increased with vitellogenesis, coincident with colour intensification and sexual receptivity, indicated by acceptance of copulations. As steroid levels peaked around the inferred ovulation time, maximal colour development occurred and sexual receptivity declined. When females were gravid and exhibited maximal mate rejection behaviours, progesterone levels remained consistently high, while testosterone exhibited a discrete second peak. At oviposition, significant declines in plasma steroid levels, fading of colouration and a dramatic decrease in male rejection behaviours co-occurred. Our results indicate a generally concordant association among steroid levels, colouration, behaviour and reproductive events. However, the prolonged elevation in progesterone and a second peak of testosterone was unrelated to reproductive state or further colour change, possibly suggesting selection on females to retain high steroid levels for inducing rejection behaviours.     

Sustained influence of previous estradiol or testosterone treatments on sexual behaviors of female pigs

Two studies were conducted to determine the consequences of extended treatment with estradiol or testosterone on sexual behavior in postpubertal, female pigs. After ovariectomy, either steroid was administered for 6 weeks at dosages sufficient to maintain serum concentrations similar to those observed in mature male pigs. Behavioral evaluations were initiated 2 months after the last steroid treatment. These treatments reduced receptivity (immobile stance when placed with a mature male) and proceptivity (preference to remain near a mature male) in association with an increase in aggressive behavior. In females treated previously with both estradiol and progesterone, sexual behaviors 2 months later were similar to those of control females. When evaluations were repeated 5 months after extended estradiol treatment had ceased, receptivity and proceptivity had returned to that of control pigs and aggressive behavior had diminished greatly. Interpretation of these changes in behavior is that extended periods of estradiol or testosterone treatment sustain activational influences for a considerable amount of time after treatments cease and progesterone antagonizes estradiol's effect on these behaviors. In a companion study, pubertal and post-pubertal females were similar for receptivity but pubertal females spent less time near a mature male. This difference in proceptivity likely reflects a maturational change associated with sexual development in female pigs. Collectively, these observations in postpubertal, female pigs document that prolonged estrogen treatment will activate aggressive behaviors in association with reduced proceptivity and receptivity. Because these behavioral changes are reversible by 5 months after cessation of treatment, they are not the result of sexual differentiation.     

The effects of progestins,mineralocorticoids, glucocorticoids,and steroid solubility on the induction of sexual receptivity in rats

In the first experiment, progesterone and its 5α-reduced metabolite, 5α-dihydroprogesterone, dissolved in two different vehicles were compared for their effectiveness in facilitating lordosis behavior in ovariectomized estrogen-primed rats. When dissolved in oil vehicle, 5α-dihydroprogesterone was less effective than progesterone. However, when dissolved in Tween 80 solution, the two progestins were equally effective. In the second experiment, adrenal corticoids dissolved in Tween 80 solution were tested for their relative ability to facilitate sexual receptivity. Progesterone, desoxycorticosterone, and desoxycorticosterone acetate were equally effective in facilitating sexual receptivity. Aldosterone, corticosterone, and corticosterone acetate were no more effective than the vehicle in facilitating sexual receptivity.     

Relation between circulating sex steroid concentrations and sexual behaviour during pregnancy and post partum in the domestic rabbit

Sexual behaviour of 16 female and 12 male rabbits was studied during pregnancy and early post partum. The main behavioural events of the male (nuzzling and mounting) did not differ in the presence of receptive or non-receptive females. When introduced into the cage of the male, receptive and non-receptive females flattened to the floor or circled around. Sexual receptivity to males decreased in early pregnancy and increased to a maximum a few days around parturition; on Days 1 and 6 post partum, all experimental rabbits submitted to mating. Two groups of females were distinguished: one group submitting to mating whatever the stage of pregnancy, the second being receptive only during the few days before parturition or post partum. During pregnancy and early post partum there was no relation between the colour of the vulva and the female sexual behaviour. Does remained sexually receptive even when progesterone concentrations were high. Nevertheless, the number of receptive females was higher when progesterone concentrations decreased around parturition and the mean daily progesterone values were consistently higher in non-receptive than in receptive females. Oestrogen concentrations during pregnancy were very low and were not related to receptive behaviour.     

Ovarian hormones,copulatory stimuli,and female sexual behavior in the Mongolian gerbil

The effects of repeated estradiol benzoate (1.0 or 3.3 μg) and progesterone (0.5 mg) injections and mating experiences (10 min or 4 hr) were examined in ovariec-tomized female Mongolian gerbils (Meriones unguiculatus) paired with sexually vigorous but unfamiliar males. Estradiol benzoate alone for 2 days did not elicit female sexual responses. Estradiol benzoate for 2 days followed by progesterone facilitated lordosis in the female. In females injected daily with 1.0 μg estradiol benzoate, progesterone exposure for approximately 1 day produced a significant inhibition in subsequent lordosis, although these females continued to respond to the male with lordosis quotients of approximately 60. A 4-hr mating experience produced a nearly complete elimination of sexual activity in tests observed 24 hr later with a fresh male. Footstomping was positively associated with sexual activity in both sexes, although females footstomped more often in the 1.0 rather than the 3.3-μg estradiol benzoate condition. Fighting was most frequent in tests in which lordosis quotients were low. Interactions among copulatory experiences and inhibitory effects of progesterone summed to terminate female sexual receptivity and alter other social interactions in the gerbil.     

Activation and inhibition of isolation induced inter-male fighting behavior in castrate male CD-1 mice treated with steroidal hormones

Intermale fighting behavior between castrate male CD-1 mice living in isolation and castrate male CD-1 mice living in groups of 10 was activated by treating the isolated males with either testosterone or testosterone propionate. Fighting behavior was not activated by treating isolated males with androstenedione or dihydrotesterone even though these androgens were active in maintaining seminal vesicle weight at levels equal to, or greater than, those observed in gonadally intact males. Neither fighting behavior nor seminal vesicle weight was stimulated by treatment with progesterone, estradiol benzoate, or estradiol benzoate plus progesterone. Concurrent administration of progesterone inhibited fighting behavior activated by low, but not moderate to high doses of testosterone propionate. These results suggest that the hormone requirements for activation of fighting behavior in the male CD-1 mouse are more restrictive than those for maintenance of peripheral target tissues and that progesterone acts in the brain to competitively inhibit androgen-activated fighting.     

The reversible inhibition of steroid-induced sexual behavior by intracranial cycloheximide

Cycloheximide(Cyclo), an inhibitor of protein synthesis by a direct action on protein synthesis at the ribosomal level, was used to reversibly inhibit estrogen-induced sexual receptivity. Cyclo (100 μg per rat) was infused into the preoptic area(POA) of ovariectomized rats at varying times before, simultaneously with, and after 3 μg of subcutaneous estradiol benzoate (EB). All animals received 0.5 mg progesterone (P) 36 hr after EB, and were tested for sexual receptivity 4–6 hr after P. The females were placed with stud males and a lordosis quotient was computed for each female (lordosis quotient = number of lordosis responses/20 mounts by the male × 100). Females receiving Cyclo 6 hr before, simultaneously with, or 12 hr after EB showed significantly lower levels of sexual receptivity when compared to females receiving Cyclo 36 hr before and 18 and 24 hr after EB. When those animals that showed low levels of sexual behavior after Cyclo infusion were reprimed with EB and P 7 days later and presented with a male they showed high levels of sexual receptivity. Thus, the effect of Cyclo was reversible. Only Cyclo infusions into the POA (bilateral) and third ventricle were effective in suppressing sexual behavior. Caudate nucleus, lateral ventricle, and unilateral POA infusions were without effect.The data presented are in agreement with earlier work that utilized actinomycin D to inhibit steroid-induced sexual behavior. Cyclo was found to be less toxic than actinomycin D. All of the available evidence is consistent with the hypothesis that estrogen stimulates RNA and/or protein synthesis in its facilitation of sexual behavior in the female rat.     

The inhibitory actions of progesterone: effects on male and female sexual behavior of the hamster

A series of three experiments compared the inhibitory effects of progesterone on estrogen- or androgen-induced sexual behavior in male and female hamsters. In the first experiment chronic progesterone treatment was found to have no effect on male copulatory behavior maintained after castration with testosterone propionate or estradiol benzoate. However, testosterone propionate was more effective at maintaining male behavior than estradiol benzoate. In the second experiment progesterone was found to have a slight inhibitory effect on the rate of the restoration of the intromission response after androgen treatment in males which had been castrated for 8 weeks. In the final experiment, chronic progesterone treatment markedly inhibited sexual receptivity in male and female hamsters which had been given 4 weeks of androgen or estrogen treatment and a single pretest injection of progesterone. Thus, progesterone was shown to be a potent inhibitor of androgen- or estrogen-induced estrus in both male and female hamsters. Due to the large difference in effectiveness on these two behavioral systems, we suggest that progesterone affects steroid-induced male copulatory behavior and female receptivity by different mechanisms of action.     

Induction of lordosis in the female hamster utilizing metabolites of progesterone

Progesterone, 6α-methyl-17α-OHP, and several progesterone metabolites were administered to ovariectomized, estrogen-primed female hamsters. Progesterone was most effective in the facilitation of sexual receptivity. 5α-Pregnan-3,20-dione was significantly more effective than the other progestins, which were no more effective than oil.