Effects of naltrexone and CCK on estrous behavior and food intake in Syrian hamsters.

Food deprivation inhibits estrous behavior in several species of rodents, but little is known about the neurotransmitter systems mediating this phenomenon. We determined whether partial blockade of opioid receptors by continuous infusion of naltrexone and/or acute peripheral injection of cholecystokinin (CCK) administration would overcome the suppressive effects of food deprivation on estrous behavior in Syrian hamsters. Contrary to expectation, naltrexone produced a slight suppression of estrous behavior, and systemic CCK administration had no effect. This dose of naltrexone was sufficient to reduce in vivo binding of [(3)H]naloxone in the brain, and both compounds affected other parameters such as food intake and body weight gain. Thus, the doses of CCK and naltrexone that were used were physiologically effective. These findings suggest that neither peripheral CCK nor opioid systems are likely to play a major role in the suppression of hamster estrous behavior by food deprivation.

Neuropeptide Y inhibits estrous behavior and stimulates feeding via separate receptors in Syrian hamsters.

Central injections of neuropeptide Y (NPY) increase food intake in Syrian hamsters; however, the effect of NPY on sexual behavior in hamsters is not known nor are the receptor subtypes involved in feeding and sexual behaviors. We demonstrate that NPY inhibits lordosis duration in a dose-related fashion after lateral ventricular injection in ovariectomized, steroid-primed Syrian hamsters. Under the same conditions, we compared the effect of two receptor-differentiating agonists derived from peptide YY (PYY), PYY-(3-36) and [Leu(31),Pro(34)]PYY, on lordosis duration and food intake. PYY-(3-36) produced a 91% reduction in lordosis duration at 0.24 nmol. [Leu(31),Pro(34)]PYY was less potent, producing a reduction in lordosis duration (66%) only at 2.4 nmol. These results suggest NPY effects on estrous behavior are principally mediated by Y2 receptors. PYY-(3-36) and [Leu(31),Pro(34)]PYY stimulated comparable dose-related increases in total food intake (2 h), suggesting Y5 receptors are involved in feeding. The significance of different NPY receptor subtypes controlling estrous and feeding behavior is highlighted by results on expression of Fos immunoreactivity (Fos-IR) elicited by either PYY-(3-36) or [Leu(31),Pro(34)]PYY at a dose of each that differentiated between the two behaviors. Some differences were seen in the distribution of Fos-IR produced by the two peptides. Overall, however, the patterns of expression were similar. Our behavioral and anatomic results suggest that NPY-containing pathways controlling estrous and feeding behavior innervate similar nuclei, with the divergence in pathways controlling the separate behaviors characterized by linkage to different NPY receptor subtypes.

Metabolic control of food intake and estrous cycles in syrian hamsters. I. Plasma insulin and leptin.

The "adipostat hypothesis" refers to the idea that circulating hormone concentrations reflect levels of body adiposity and act as signals to control food intake and reproduction. Implicit in the adipostatic hypothesis are the following two assumptions: 1) plasma levels of adipostatic hormones accurately reflect body fat content and 2) decreased plasma concentrations of adipostatic hormones necessarily result in increased food intake and inhibited reproductive processes. The present experiments are designed to test these assumptions. Fat and lean Syrian hamsters were either fasted for 12, 24, 36, or 48 h or allowed ad libitum access to food. Contrary to the first assumption, plasma leptin and insulin levels in fat hamsters dropped dramatically by 12 h after the start of a fast, with no significant change in body fat content and no postfast hyperphagia. Lean hamsters showed anestrus after a 48-h fast but not after a 24-h fast. Contrary to the second assumption of the lipostatic hypothesis, lean hamsters fasted for 24 h and then refed for the next 24 h had leptin levels that were not significantly elevated compared with those of 48-h-fasted hamsters. Thus, in adult female Syrian hamsters, plasma leptin concentrations do not accurately reflect body fat content under all conditions; normal estrous cyclicity does not necessarily require plasma leptin concentrations higher than those of fasted hamsters; and decreased plasma leptin levels do not result in increased food intake.

Effects of cold exposure on estrous behavior and neural estrogen receptor in Syrian hamsters.

Two experiments examined the effects of 72-h exposure to reduced environmental temperature (5 degrees C) on steroid-induced estrous behavior and neural estrogen-receptor immunoreactivity (ERIR) in ovariectomized Syrian hamsters. Cold exposure significantly inhibited sexual receptivity induced by sequential injections of estradiol benzoate (2.5 microg) and progesterone (500 microg), but only if the animals were not permitted to overeat (limited to 110% of ad lib intake at 22 degrees C). The suppression of sexual receptivity was accompanied by decreases in the number of detectable ERIR cells in the ventromedial hypothalamus (VMH) and by increases in the number of ERIR cells in the medial preoptic area (mPOA). The cold-induced decreases in estrous behavior and in VMH ERIR cells were prevented by lesions of the area postrema (AP), but AP lesions did not prevent the increases in mPOA ERIR cells. Thus, cold exposure mimics the effects of treatment with metabolic inhibitors, experimental diabetes, food deprivation, and insulin-induced fattening on these endpoints. These findings are consistent with the hypothesis that dwelling in the cold affects reproduction indirectly via its actions on metabolic fuel availability, rather than by acting directly on neuroendocrine processes.

AP lesions block suppression of estrous behavior, but not estrous cyclicity, in food-deprived Syrian hamsters.

Food deprivation inhibits ovulatory cycles and estrous behavior in Syrian hamsters. Lesions of the area postrema (AP) prevented the suppression of estrous behavior in food-deprived hamsters, but they did not prevent the suppression of estrous cyclicity or the increase in running-wheel activity caused by food deprivation. Food deprivation or treatment with pharmacological inhibitors of glycolysis and fatty acid oxidation decreased estrogen-receptor immunoreactivity (ERIR) in the ventromedial hypothalamus (VMH), increased ERIR in the arcuate nucleus (Arc) and the posterior parvicellular paraventricular nucleus (PaPo), but had no effect on ERIR in the posterodorsal medial amygdala or the anterior parvicellular paraventricular nucleus. Lesions of the AP prevented the food deprivation-induced decrease in VMH ERIR and the increase in Arc ERIR, but they did not prevent the increase in ERIR in the PaPo. Thus, whatever physiological cues are produced by food deprivation, an intact AP is required for their transmission to the neural circuits controlling estrous behavior, VMH ERIR, and Arc ERIR. The AP is not essential for transmission of this information to the neural circuits controlling estrous cyclicity, running-wheel activity, or PaPo ERIR.

Insulin-induced repartitioning of metabolic fuels inhibits hamster estrous behavior: role of area postrema.

Excessive diversion of metabolic fuels away from oxidation and into adipose tissue storage depots, such as underfeeding or extraordinary levels of energy expenditure, can induce nutritional infertility. Treatment with pharmacological doses of insulin reduces metabolic fuel availability and suppresses both ovulatory cyclicity and pulsatile luteinizing hormone release in females of several mammalian species, but little attention has been paid to the effects of insulin treatments on reproductive behaviors. Ovariectomized Syrian hamsters were injected with long-acting insulin every 12 h for 72 h and were prevented from overeating by limiting their intake to approximately 110% of pretreatment levels. When given estradiol and progesterone, insulin-treated hamsters exhibited significantly reduced levels of sexual receptivity compared with saline-treated controls. This insulin-induced inhibition of estrous behavior was prevented by lesions of the area postrema. Insulin treatments also caused changes in the number of detectable estrogen receptor immunoreactive cells in the hypothalamus and preoptic area. Therefore, insulin-induced repartitioning of metabolic fuels induces changes in estrous behavior and neural estrogen receptors that are indistinguishable from those caused by food deprivation, cold exposure, or treatment with metabolic inhibitors.

Leptin facilitates and inhibits sexual behavior in female hamsters.

Food deprivation decreases fertility in female mammals in part by inhibiting sexual behaviors. Genetically obese ob/ob mice, like food-deprived wild-type animals, are also infertile; treatment of ob/ob mice with leptin, the adipocyte-derived protein that they lack, corrects some of their reproductive deficiencies. We tested the hypothesis that leptin treatment would prevent the suppression of sexual receptivity that is caused by food deprivation in female Syrian hamsters. Instead, we found that treatment with murine leptin facilitated female sexual behavior in ad libitum-fed hamsters, but not in food-deprived animals. In food-deprived hamsters, leptin treatment actually intensified the inhibition of lordosis. Food deprivation decreased detectable estrogen receptor immunoreactivity (ERIR) in the ventromedial hypothalamus (VMH), but the leptin-induced changes in female sexual behavior were not accompanied by parallel changes in VMH ERIR. Thus leptin facilitates estrous behavior in hamsters, but it does not overcome the lordosis-inhibiting metabolic cues produced by acute food deprivation. Because circulating leptin levels are directly related to body fat content, an implication of these findings is that elevated levels of adipose tissue could have a positive influence on sexual responsiveness.

Central vs. peripheral metabolic control of estrous cycles in Syrian hamsters. I. Lipoprivation.

Metabolic energy availability has profound effects on reproduction in a wide variety of species. We have been studying the effects of fasting on estrous cycles in Syrian hamsters as a model system for metabolic control of reproduction. In previous experiments, a 48-h period of fasting inhibited estrous cycles in lean, but not fat, hamsters. In fat hamsters the effects of fasting may have been offset by the presence of high circulating levels of free fatty acids mobilized from lipids in adipose tissue. Consistent with this idea fat hamsters treated with the inhibitor of fatty acid oxidation methyl palmoxirate (MP) showed fasting-induced anestrus. Experiment 1 was designed to examine whether vagally transmitted signals are critical for the inhibitory effects of fasting and MP treatment. Lean or fat hamsters that had received bilateral subdiaphragmatic vagotomy or sham surgery were fasted and treated with MP or vehicle. In vagotomized and sham-operated hamsters, estrous cycles were inhibited in lean fasted hamsters and in fat fasted hamsters treated with MP, but not in fat fasted hamsters treated with vehicle. Thus the results of experiment 1 indicated that vagally transmitted signals about peripheral fatty acid availability are not critical for the effects of these particular metabolic challenges on estrous cycles in Syrian hamsters. In experiment 2, hamsters without food were allowed to ingest pure glucose or fructose solutions or vegetable shortening. One-half of each group was treated with an inhibitor of glucose utilization, 2-deoxy-D-glucose (2-DG), or vehicle. If ingestion of fructose or shortening, but not glucose, had protected hamsters from 2-DG-induced anestrus, this might have indicated that peripheral fuel availability is critical for anestrus. On the contrary, 2-DG treatment induced anestrus regardless of the type of fuel ingested. Neither experiment yielded results that implicated changes in peripheral fuel availability as a critical signal in metabolic control of estrous cycles.

Food deprivation and the facilitatory effects of estrogen in female hamsters: the LH surge and locomotor activity.

Two experiments investigated short-term food deprivation effects on neuroendocrine processes influenced by estrogen. These studies were prompted by prior work indicating that food deprivation increased the number of immunocytochemically identified cells containing estradiol receptors in the medial preoptic area of ovariectomized female hamsters. Presumably, this is one way that changes in metabolic fuel availability might alter the responsiveness of one or more systems to estradiol. The purpose of this study was to investigate two effects of estradiol that might be affected by food deprivation; these were 1) the positive feedback effects of estradiol on the luteinizing hormone (LH) surge, and 2) the facilitating effects of estradiol on locomotor activity. In Experiment 1, ovariectomized hamsters were administered estradiol, before or after 48 h of food deprivation. Two days after hormone treatment, blood was obtained by cardiac puncture, once in the morning (1100 h) and twice during the afternoon (1600-1800 h). These times were chosen to best characterize the magnitude of the LH surge. Food deprivation enhanced the amplitude of the LH surge in response to estradiol when this treatment preceded, but not when it followed, the administration of estradiol. However, there was variability in the dose of estradiol at which this effect of food deprivation occurred. In Experiment 2, the locomotor (running wheel) activity of two groups of gonadally intact female hamsters was quantified; one group was tested during the early (days 1 + 2; low estradiol) part of the estrous cycle, and the other group was tested during the late (days 3 + 4; high estradiol part of the estrous cycle. In both groups, testing was performed first under ad lib feeding conditions and again during 48 h of food deprivation. On average, the days 3 + 4 group was more active than the days 1 + 2 group, reflecting their differing levels of endogenous estradiol. Food deprivation significantly increased locomotor activity, independently of the stage of the estrous cycle during which it was imposed. These results are discussed in terms of the influence that altered estradiol receptor expression in the medial preoptic area might play in generating the effects we observed following short-term food deprivation.

Effects of food deprivation on induction of neural progestin receptors by estradiol in Syrian hamsters.

Food deprivation, as well as treatment with metabolic inhibitors, suppress steroid hormone-induced estrous behavior in ovariectomized (OVX) Syrian hamsters. Previous work indicates that 48 h of food deprivation decreases the number of detectable estrogen receptor immunoreactive (ERIR) cells in the ventromedial hypothalamus (VMH) and the area just lateral to it (VLH), increases the number of ERIR cells in the medial preoptic area (MPO), and has no effect on the number of ERIR cells in the nucleus of the solitary tract in OVX hamsters. The present study examined the effects of food deprivation on neural progestin receptor binding using an in vitro binding assay and on progestin receptor immunoreactivity (PRIR) in estradiol-primed, OVX hamsters. Parallel behavior tests for sexual behavior were also performed in both experiments. OVX hamsters received 2.5 micrograms estradiol benzoate and were fed ad libitum or food deprived at the same time. Forty-eight hours later, animals were killed in preparation for the immunocytochemistry or progestin receptor assay. Binding assays indicated that 48-h food deprivation decreased progestin receptor levels in the preoptic area and had no effect in the mediobasal hypothalamus, an area that includes the VMH and the arcuate nucleus (ARH). Immunocytochemical analysis confirmed these findings. Food deprivation caused a decrease in sexual receptivity and in the number of detectable PRIR cells in the MPO and medial amygdala but had no effect on the number of detectable PRIR cells in the VMH/VLH, the ARH, or the anteroventral periventricular nucleus. These results suggest that food deprivation modulates progestin receptor binding and PRIR in a site-specific manner. In addition, the effects of food deprivation on neural ERIR and PRIR are significantly different.

Control of fertility by metabolic cues.

In female mammals, reproduction is extremely sensitive to the availability of oxidizable metabolic fuels. When food intake is limited or when an inordinate fraction of the available energy is diverted to other uses such as exercise or fattening, reproductive attempts are suspended in favor of processes necessary for individual survival. Both reproductive physiology and sexual behaviors are influenced by food availability. Nutritional effects on reproductive physiology are mediated by changes in the activity of gonadotropin-releasing hormone (GnRH) neurons in the forebrain, whereas the suppression of sexual behaviors appears to be due, at least in part, to decreases in estrogen receptor in the ventromedial hypothalamus. Work using pharmacological inhibitors of glucose and fatty acid oxidation indicates that reproductive physiology and behavior respond to short-term (minute-to-minute or hour-to-hour) changes in metabolic fuel oxidation, rather than to any aspect of body size or composition (e.g., body fat content or fat-to-lean ratio). These metabolic cues seem to be detected in the viscera (most likely in the liver) and in the caudal hindbrain (probably in the area postrema). This metabolic information is then transmitted to the GnRH-secreting or estradiol-binding effector neurons in the forebrain. There is no evidence to date for direct detection of metabolic cues by these forebrain effector neurons. This metabolic fuels hypothesis is consistent with a large body of evidence and seems to account for the infertility that is seen in a number of situations, including famine, eating disorders, excessive exercise, cold exposure, lactation, some types of obesity, and poorly controlled diabetes mellitus.

Thermoregulatory and maternal nestbuilding in Syrian hamsters: interaction of ovarian steroids and energy demand.

To investigate the relationship between energy demand, ovarian hormones and behavioral thermoregulation, we measured nestbuilding of female Syrian hamsters (Mesocricetus auratus) under conditions where energy demand and circulating ovarian hormone levels varied. Hamsters increased nestbuilding under conditions of chronically elevated estradiol and progesterone levels (late gestation; ovariectomized animals treated with estradiol +/- progesterone) and increased energy demand (late gestation or cold exposure). When hormone treatments were withdrawn, hamsters gained weight and reduced nestbuilding activity. Nestbuilding was not affected by lactation (characterized by low ovarian steroid levels and high energy demand) or by estrous cycle phase (characterized by relatively transient changes in ovarian steroid levels and subtle changes in energy demand). Thus, nestbuilding in Syrian hamsters was responsive to increased energy demand from cold exposure, late gestation, and to ovarian hormones. However, during lactation and estrous cycles, nestbuilding did not always change predictably according to known changes in energy expenditure and steroid hormone levels. Thus, levels of nestbuilding are influenced by factors in addition to ovarian hormones and energy expenditure under some circumstances.

Interactive effects of food deprivation and exercise on reproductive function in female hamsters.

Two experiments evaluated the combined effects of food deprivation and runningwheel access on estrous cycles and estrous behavior of female hamsters. In experiment 1, food deprivation on days 1 and 2 of the estrous cycle disrupted the next expected ovulation, and this effect was more, rather than less, robust in females allowed to exercise in running wheels while they were deprived. In experiment 2, a similar protocol was used except the females were ovariectomized and received sequential injections of estradiol benzoate (EB; 5 micrograms) and progesterone (P; 200 micrograms) separated by 48 h to induce lordosis, which was tested 4-5 after P. Food deprivation concomitant with hormonal treatment diminished lordosis durations, but this effect was significant only among the females that were permitted to run in activity wheels. Previous findings demonstrated that access to running wheels attenuated the inhibitory effects of short photoperiod exposure on hamster estrous cycles. In contrast, the present results indicate that this same manipulation exaggerates rather than diminishes the inhibitory effects of food deprivation on estrous cycles and hormone-induced behavioral estrus.

Manipulations of metabolic fuel availability alter estrous behavior and neural estrogen receptor immunoreactivity in Syrian hamsters.

Decreases in metabolic fuel utilization caused by food deprivation, diabetes, or treatment with metabolic inhibitors have been shown to suppress steroid-induced estrous behavior in ovariectomized Syrian hamsters. These same manipulations also caused a decrease in the number of detectable estrogen-receptor immunoreactive (ERIR) cells in the ventromedial hypothalamus (VMH) and the adjacent area lateral to it (VLH) in ovariectomized hamsters. Forty-eight hours of food deprivation or treatment with pharmacological blockers of glycolysis (2-deoxy-D-glucose) and fatty acid oxidation (methyl palmoxirate) decreased the number of detectable ERIR cells in the VMH/VLH. However, neither inhibitor given alone was sufficient to affect the number of detectable ERIR cells in the VMH/VLH, even when given in much higher doses. Therefore, the number of ERIR cells in the VMH/VLH, like steroid-induced estrous behavior, responds only to a combination of glucoprivation and lipoprivation and not to either alone. The effects of metabolic fuel restriction are not due to a general suppression of neural ERIR, because food deprivation or treatment with 2-deoxy-D-glucose and methyl palmoxirate actually increased the number of detectable ERIR cells in the medial preoptic area (mPOA) and had no effect in the nucleus of the solitary tract. Lesions destroying the area postrema (AP) prevented the decrease in ERIR cells in the VMH/VLH and the inhibition of estrous behavior caused by fuel restriction. However, AP lesions did not alter the effects of metabolic inhibitors on ERIR in the mPOA. On the other hand, subdiaphragmatic vagotomy abolished the effects of metabolic inhibitors on mPOA ERIR, but did not affect either lordosis or VMH/VLH ERIR. These results suggest that the suppression of estrous behavior induced by metabolic fuel restriction is at least in part due to a decrease in the number of ERIR neurons in the VMH/VLH. In addition, the estrogen-sensitive neurons in the VMH/VLH and mPOA receive metabolic cues via different neural pathways. The AP, but not vagus nerves, is required for ERIR neurons in the VMH/VLH to detect fuel availability; the vagus nerves, but not the AP, are necessary for estrogen-binding neurons in the mPOA to detect visceral information.

ICI 182,780: a pure antiestrogen that affects behaviors and energy balance in rats without acting in the brain.

ICI 182,780 is one of a new class of steroidal antiestrogens that differs from nonsteroidal antiestrogens, such as tamoxifen, in a number of respects. 1) It is bound by estrogen receptors with a high affinity, similar to that for estradiol. 2) It is a "pure" antiestrogen in that it does not mimic any of the effects of estradiol. 3) This class of antiestrogens does not seem to be bound by antiestrogen binding sites. 4) ICI 182,780 may not be active in the brain after peripheral administration. Indeed, ICI 182,780 blocked in vivo cell nuclear binding of [3H]estradiol in uterus, pituitary, and adipose tissue but not in hypothalamus-preoptic area. In vitro, ICI 182,780 competed for binding by neural estrogen receptors with an affinity comparable with that for estradiol. When given to ovariectomized rats, ICI 182,780 did not mimic any of the actions of estradiol. Instead, ICI 182,780 treatment completely blocked the uterotrophic effects of estradiol and attenuated the actions of estradiol on linear growth, carcass fat content, fat pad weight, and sexual receptivity. Treatment with ICI 182,780 also attenuated the estrogenic effects of tamoxifen on food intake, body weight and composition, linear growth, and uterine weight. These findings support the concept that, in addition to its actions in the brain, estradiol can act peripherally to modulate regulatory behaviors, energy balance, and estrous behavior. They are also consistent with the hypothesis that nonsteroidal antiestrogens, such as tamoxifen, affect energy balance via estrogen receptors, rather than antiestrogen binding sites.

ICI 182,780 antagonizes the effects of estradiol on estrous behavior and energy balance in Syrian hamsters.

Three experiments examined the effects of ICI 182,780, a steroidal "pure" antiestrogen that is thought to be active peripherally but not in the brain when given systemically, on energy balance, estrous behavior, and in vivo cell nuclear binding of [3H]estradiol in Syrian hamsters. Pretreatment with ICI 182,780 reduced in vivo uptake of [3H]estradiol in uterus but not in pooled hypothalamus-preoptic area. Ovariectomized Syrian hamsters were treated with estradiol benzoate (EB, 5 micrograms/day), ICI 182,780 (250 micrograms/day), or both EB and ICI 182,780 for 4 wk. Estradiol treatment caused significant decreases in food intake, body weight and fat content, and linear growth. Given alone, ICI 182,780 had no effect on these measures. When they were given concurrently, ICI 182,780 attenuated the effects of estradiol on body weight, growth, and fat content but not on food intake. Treatment with ICI 182,780 significantly diminished estrous behavior induced with either EB plus progesterone or with EB alone. These findings support the hypothesis that, in addition to its actions in the brain, estradiol acts peripherally to modulate estrous behavior and energy balance.

Estrogen-receptor immunoreactivity in hamster brain: preoptic area, hypothalamus and amygdala.

The distribution of estrogen-receptor containing cells in the preoptic area, hypothalamus and amygdala of female Syrian hamster brain was studied by immunocytochemical methods. Dense populations of estrogen-receptor immunoreactive (ER-IR) cells were found in the medial preoptic area, the bed nucleus of the stria terminalis, amygdala, ventral and lateral parts of the hypothalamus, and the arcuate nucleus. Injection of estradiol caused a decrease in estrogen-receptor immunoreactivity (ERIR) containing cells within one hour, a decrease that may reflect a change in the ability of the occupied estrogen receptor to bind the particular antibody (H222) used rather than down-regulation of the estrogen receptor. Our findings on the distribution of estrogen-receptor containing cells in these areas using an immunocytochemical technique are consistent with and extend the findings of others using autoradiographic and in vitro binding techniques to study estrogen receptor distribution in hamster brain.

Tamoxifen antagonizes the effects of estradiol on energy balance and estrous behavior in Syrian hamsters.

Ovariectomized Syrian hamsters were treated with estradiol benzoate (5 micrograms/day for 4 wk), tamoxifen (500 micrograms/day), an antiestrogen that competes with estradiol for central and peripheral estrogen receptors, or both estradiol benzoate and tamoxifen. As expected, estradiol treatment caused significant decreases in body weight and fat content without affecting food intake. Given alone, tamoxifen had no effect on body weight or composition, but when given concurrently, tamoxifen significantly attenuated the effects of estradiol. These results stand in contrast to findings in rats where nonsteroidal antiestrogens, including tamoxifen, mimic the effects of estradiol on body weight and energy metabolism and are completely devoid of any antiestrogenic actions. As in rats, tamoxifen was a potent inhibitor of estrous behavior, whether induced with estradiol alone or with sequential treatment with estradiol and progesterone. Again, as in rats, tamoxifen acted as an antagonist and a weak estrogen agonist on uterine weight. These findings support the notion that the relative agonistic and antagonistic actions of tamoxifen, and other antiestrogens, vary with species and with the estrogen-sensitive endpoint being investigated.

Energy balance in pregnant hamsters: a role for voluntary exercise?

During pregnancy or after experimental manipulations of ovarian hormone levels, Syrian hamsters exhibit changes in energy balance and body fat content without modifying their food intake. The present experiments determined whether fluctuations in voluntary exercise play a role in these changes in energy balance, as they appear to do in other species. As expected, pregnant hamsters maintained a constant level of food intake and lost approximately 40% of their body fat. These animals did not show the abrupt decrease in activity after mating that is seen in rats. Instead, they maintained their high, premating level of running wheel activity until the last 3 days of pregnancy. Similarly, ovariectomy and replacement therapy with estradiol or estradiol+progesterone caused substantial changes in energy balance in the absence of significant changes in food intake or running wheel activity. These findings indicate that, unlike rats, Syrian hamsters do not exhibit substantial changes in voluntary exercise during pregnancy or in response to manipulations of ovarian steroid levels. Therefore, neither changes in food intake nor in voluntary exercise play any important role in the pregnancy- or steroid-induced changes in energy balance in Syrian hamsters.

Tamoxifen mimics the effects of estradiol on food intake, body weight, and body composition in rats.

Treatment of ovariectomized rats with the nonsteroidal antiestrogen tamoxifen mimicked the effects of estradiol and caused significant decreases in food intake and body weight. The decreases in body weight were reflected mainly in a decreased body fat content, although tamoxifen treatment did suppress linear growth too. Similar to the effects of estradiol, tamoxifen decreased parametrial white adipose tissue wet weight and lipoprotein lipase activity. When given concurrently with estradiol, tamoxifen showed no evidence of antiestrogenic activity on any of these measures. As reported previously, tamoxifen acted as a partial agonist/antagonist for uterine weight. The effective dose of tamoxifen for suppression of food intake, body weight, and body fat content fell between 10 and 50 micrograms/day. Therefore, tamoxifen behaves like other nonsteroidal antiestrogens and mimics but fails to antagonize the actions of estradiol on many aspects of physiological and behavioral regulation of energy balance.