Could a deficiency in growth hormone signaling be beneficial to the aging brain?

Several studies have shown that growth hormone (GH)-deficient/resistant animals have a prolonged lifespan compared with their normal siblings. Studies in our laboratory have suggested that both Ames dwarf and GH receptor/GH binding protein knockout (GH-R-KO) mice do not experience age-induced cognitive aging at the same rate as their normal siblings. The studies presented here were aimed at determining whether these long-lived mice experience a delay in age-related changes in behavior. Young and old mice of both strains were tested in an open-field task. In addition, mice of the GH-R-KO strain were tested in the water maze to confirm previous findings using the inhibitory avoidance task that suggested delayed cognitive aging. In each of these studies, normal (wild-type) animals of the same age, sex, and genetic background as the mutants served as controls. Old GH-R-KO mice did not experience the decline in locomotor activity or difference in activity levels in the open-field task seen in the normal animals. Young normal and young and old Ames dwarf mice spent less time in the center of the apparatus compared with old normal animals. There were no signs of age-related changes in emotionality within the GH-R-KO strain. Water maze results also showed that while old normal animals performed poorer than the young normal animals, old GH-R-KO mice did not perform differently from the young normal or young GH-R-KO groups. Taken together, these studies support our previous findings of delayed age-induced cognitive and behavioral decline in GH deficient/resistant mice.

Maternal hyperglycemia leads to gender-dependent deficits in learning and memory in offspring.

Pregnancy in the diabetic woman has long been associated with an increased risk of congenital malformation in the offspring. However, little is known about the effects of maternal diabetes on development of the central nervous system. To begin to gain an understanding of this problem, diabetes was induced in adult female Sprague-Dawley rats by injection with streptozotocin. Only animals with serum glucose levels greater than 200 mg/dl were used. Diabetic and control females were bred, and all newborn pups were cross-fostered to nondiabetic mothers. At 60 days of age, pups were tested in an elevated plus-maze to assess differences in emotionality and anxiety. There were no significant differences between offspring of diabetic dams and controls on this measure. All pups were then housed individually, put on food restriction, and maintained at 85% of their ad libitum weight. They were then trained in a Lashley III maze, which assesses learning and retention capability. The female offspring of diabetic dams performed poorer than controls, a finding that was supported by inhibitory avoidance data from a separate group of animals. All animals were then trained in a radial-arm maze. Results failed to find differences between experimental and control animals. It was concluded that the diabetic intrauterine environment has gender-specific effects on central nervous system development.

Evidence that age-induced decline in memory retention is delayed in growth hormone resistant GH-R-KO (Laron) mice.

Although the role of growth hormone (GH) in aging is controversial, the recent production of GH-R-KO mice may provide a means for elucidating its importance. Using the inhibitory avoidance learning task as a measure of cognitive aging, the present study compared learning and retention in young and old GH-R-KO mice and their normal siblings. Results for the old normal animals agreed with the current literature, in that the ability of old animals to retain learned information declined over time. However, retention in the old GH-R-KO mice did not decline between the 24-h, 7-day and 28-day retention tests and did not differ from young animals. To determine whether performance differences seen in the old normal vs. old GH-R-KO groups were due to locomotor behavior or emotionality, both groups were tested in the elevated-plus maze. Results showed that the normal and GH-R-KO mice did not differ in number of open or closed arms entered, time spent in closed or open arms or time taken to first enter an open arm. Thus, it was concluded that inhibitory avoidance performance was not affected by differences of locomotor activity or emotionality, and that the absence of GH signaling may be associated with improved long-term memory in aging mice.

Evidence that Ames dwarf mice age differently from their normal siblings in behavioral and learning and memory parameters.

There is strong evidence supporting the deleterious effects of aging on learning and memory and behavioral parameters in normal mice. However, little is known about the Ames dwarf mouse, which has a Prop-1 gene mutation resulting in deficiencies in growth hormone, thyroid-stimulating hormone, and prolactin. These mice are much smaller and live significantly longer than their normal siblings. Using the elevated plus-maze, locomotor activity meters, and an inhibitory avoidance learning task, the present study compared Ames dwarf mice to their normal siblings. Results showed that Ames dwarf mice did not experience an age-related decline in locomotor activity when compared to their young counterparts. Furthermore, old dwarf mice did not differ from the young groups in inhibitory avoidance retention, while old normal animals performed more poorly than both young groups on this test. Elevated plus-maze behavior did not differ in the old normal versus dwarf groups, but the old groups did differ from the young. Results indicate that both old groups experienced a significant decline in anxiety with age. Taken together, these results indicate that multiple hormone deficiencies resulting from a lack of primary pituitary function have beneficial effects on cognitive function and locomotor behavior in advanced age. In fact, the Ames dwarf mouse may provide a model for studies of delayed mental as well as physical aging.

Effects of growth hormone overexpression and growth hormone resistance on neuroendocrine and reproductive functions in transgenic and knock-out mice.

Transgenic mice overexpressing growth hormone (GH) exhibit alterations in the function of the hypothalamic-pituitary-gonadal (HPG) axis and the H-P-adrenal axis. Alterations in the turnover of hypothalamic neurotransmitters, in plasma hormone levels, and in regulation of their release are associated with reproductive deficits, particularly in females. Results reported after publication of our minireview on this subject provided evidence that GH-transgenic mice have increased binding of GH to GH binding proteins in plasma, are hyperinsulinemic and insulin resistant, and have major alterations in energy budgets with increased allocation to growth. Reduced life span and fertility of these animals may be related to insufficient allocation of energy to reproduction and maintenance. Growth hormone resistance induced by transgenic expression of an antagonistic bGH analog or by targeted disruption (knock-out, KO) of the GH receptor (GH-R) gene leads to dramatic suppression of plasma levels of insulin-like growth factor-1 (IGF-1), and dwarf phenotype due to reduced growth and increased adiposity. In both models of GH resistance, there are marked reproductive deficits in females, decline of breeding performance of males, and alterations in the function of the HPG axis. In GH-R-KO females, puberty is delayed, and litter size is reduced. Fetal weights are reduced whereas placental weights are increased, and the weight of newborn pups is reduced despite an increase in the length of gestation. In GH-R-KO males, copulatory behavior and fertility are reduced, plasma PRL is elevated, and responses to luteinizing hormone releasing hormone (LHRH) in vivo and to LH in vitro are suppressed. However, reproductive deficits in GH-R-KO mice are very mild when compared to those described previously in IGF-KO animals. Apparently, the amounts of IGF-1 that may be produced locally in the absence of GH stimulation are sufficient for sexual maturation and fertility in both sexes, whereas quantitative deficits in reproductive function reflect absence of GH-dependent IGF-1 production and other consequences of eliminating GH signaling. The reproduction phenotype of the GH-R-KO mice is also mild when compared to dwarf mice that lack GH, prolactin (PRL), and thyroid stimulating hormone (TSH). This is presumably related to the presence of redundant mechanisms in the stimulatory control of the gonads by the pituitary and the ability of animals capable of producing PRL and TSH to compensate partially for the absence of GH signaling.

Effects of overexpression of growth hormone-releasing hormone on the hypothalamo-pituitary-gonadal function in the mouse.

In this investigation, the neuroendocrine alterations induced by high, chronic circulating levels of endogenous growth hormone (GH) were studied in transgenic mice with ectopic overexpression of the human growth hormone-releasing hormone (h-GH-RH) gene. In comparison with their normal littermates, transgenic h-GH-RH mice had elevated plasma levels of GH, prolactin (PRL), and corticosterone. In addition, they had elevated body, liver, kidney, spleen, and pituitary weights compared with normal mice. Testis and seminal vesicle weights were also increased in transgenic mice. Although basal plasma luteinizing hormone (LH) levels, plasma estradiol levels in females, and plasma testosterone levels in males did not differ significantly between normal and transgenic animals, the LH response to castration was severely impaired in transgenic mice of both sexes. Among the biogenic amines studied in the hypothalamus, only dopamine concentrations were significantly lower in transgenic animals compared with their normal littermates. This decrease in hypothalamic dopamine may be related to the hyperprolactinemia in transgenic animals. In vitro, pituitaries from transgenic mice released significantly higher amounts of GH, and although the basal release of LH was not different in both normal and transgenic mice, the response to gonadotropin-releasing hormone was significantly smaller in transgenic mice. Cultured anterior pituitary cells from transgenic mice secreted high quantities of GH and PRL in vitro, but these quantities significantly decreased from 1 to 8 wk in culture. These results show that high, persistent levels of circulating endogenous GH induce alterations in neuroendocrine functions related to the hypothalamo-pituitary-gonadal and the hypothalamo-pituitary-adrenal axes.

Neuroendocrine and reproductive functions in male mice with targeted disruption of the prolactin gene.

Mice with a targeted disruption (knock-out) of the PRL gene (PRL-KO) were used to study the physiological role of PRL in the control of male neuroendocrine functions related to reproduction. Compared with normal males, PRL-KO mice had significant reductions in median eminence dopamine content, plasma LH levels, LH and FSH secretion in vitro (per mg pituitary), and weights of seminal vesicles and ventral prostate. PRL was not detectable in incubation medium with pituitaries from PRL-KO mice. No alterations were detected in PRL-KO mice in median eminence norepinephrine, plasma testosterone levels, or testosterone release (per mg testis) in vitro with or without LH. No differences were detected in PRL-KO vs. normal male mice in the interval from housing with normal female mice until conception, rate of pregnancy, or the number of live pups per litter. Pituitary weight in PRL-KO mice was increased (1.78 +/- 0.22 vs. 3.35 +/- 0.20 mg; P < 0.001), presumably due to reduced feedback inhibition and hypertrophy and/or hyperplasia of nonfunctional lactotrophs. These results indicate that the absence of PRL reduces pituitary LH release, attenuates median eminence dopaminergic activity, and affects the growth of seminal vesicles and ventral prostate. Although it was previously shown that PRL can repair the reproductive defect in male pituitary dwarf mice, our current results imply that the PRL deficiency alone is not sufficient to cause male infertility, although there are obvious alterations in reproductive neuroendocrine function in PRL-KO males.

Reproductive endocrinopathy in acute streptozotocin-induced diabetic male rats. Studies on LHRH.

Streptozotocin-(STZ) treated diabetic male rats have significant reproductive endocrinopathy. To determine the functional responsiveness of luteinizing hormone-releasing hormone (LHRH) neurons in STZ-treated diabetic male rats, stimulated LHRH release was assessed using hypothalami from short-term STZ-treated, STZ-treated insulin-replaced, and control male rats. LHRH release from control, STZ-treated, and STZ-treated, insulin-replaced explants in response to an initial and second 30-min pulse of phenylephrine were not different. A terminal pulse, containing 45 mM KCl, a general secretogogue, also revealed no differences between groups in stimulated LHRH release. Glucose and testosterone levels in the controls and the diabetic rats were significantly different. Cell counts on serial brain sections processed for LHRH immunohistochemistry suggested that the number of LHRH neurons in the preoptic area (POA) and septal areas were not different between control and STZ-treated rats. Thus, the short-term STZ-treated rats of this study were diabetic, and they displayed associated endocrinopathy; however, explants obtained from control and STZ-treated rats exhibited a typical LHRH responsiveness to both phenylephrine and KCl, and appeared similar in LHRH neuron number. Therefore, these findings suggest that reproductive endocrinopathy accompanying short-term STZ-induced diabetes in male rats does not result from deficiency in LHRH neurons per se.

Differential in vivo activities of bovine growth hormone analogues.

In rodents, bovine (b) growth hormone (GH) binds only to GH receptors, while human (h) GH binds to both GH and PRL receptors. The phenotypic consequences of expression of bGH and hGH in transgenic mice are different and, in some cases, opposite. In the present study, site-directed in vitro mutagenesis of the bGH gene was used systematically to eliminate its differences from hGH at one, two, three or four suspected of conferring lactogenic activity: D11, H18, S57 and T60, respectively (corresponding to sites 12, 19, 57 and 60 of the bGH molecule). The resulting bGH analogues were expressed in cell lines and in transgenic mice. All of the seven bGH analogues produced retained their ability to bind to GH receptors and exhibited somatogenic activity in vitro and in vivo. However, none of them were able to bind to PRL receptors or to elicit detectable lactogenic response in vitro. Transgenic animals expressing any of the generated analogues were characterized by gigantism and splanchnomegaly. The effects of expression of each of the double, triple or quadruple mutants on the seminal vesicle weight resembled the effects of wild-type hGH and differed from the effects of expression of wild-type bGH. There were differences between the effects of the expression of different bGH analogues on plasma PRL levels and on the PRL response to pharmacological blockade of catecholamine synthesis. Plasma LH levels in ovariectomized females were suppressed by several of the analogues tested, an effect not seen in animals expressing wild-type bGH or hGH. Dopamine turnover in the median eminence of male mice was also altered in animals expressing different bGH analogues but not in those expressing wild-type bGH or hGH. In ovariectomized females, the effects of different bGH analogs on the turnover of dopamine and norepinephrine in the median eminence included changes resembling those detected in animals expressing hGH, as well as alterations differing from the effects of both bGH and hGH. The results indicate that biological actions of these bGH analogues cannot be characterized simply in terms of enhanced or reduced somatogenic or lactogenic activity and raise a possibility that different sites, domains or features of tri-dimensional structure of GH are involved in its actions on different cellular targets.

The effect of diabetes mellitus on endocrine and reproductive function.

The adverse effects of diabetes on the circulatory, visual, renal, and peripheral nervous system are commonly recognized and have been extensively studied. The effects of decreased insulin secretion or resistance to insulin action on endocrine glands have not been as carefully documented. Both clinical and animal research have demonstrated that diabetes mellitus is commonly associated with altered thyroid, adrenal and gonadal function. Some of these changes are reversed with insulin replacement therapy, but endocrine function is not always restored to normal even with rigorous glycemic control. Patients with poorly controlled diabetes exhibit basal and stimulated growth hormone (GH) hypersecretion, while patients with good metabolic control still present with diurnal and exercise-induced GH hypersecretion. In contrast, diabetes suppresses GH secretion in the rat. It is unclear why GH secretion is altered, but clinical and experimental evidence exists for diabetes-associated changes in GH-releasing hormone and somatostatin release as well as for changes in the pituitary response to these hypothalamic hormones. The thyroid hormones, T3 and T4, are usually suppressed in both humans and experimental animals with diabetes. This effect of diabetes appears to involve changes in hypothalamic thyrotropin-releasing hormone (TRH) secretion as well as changes in pituitary thyrotropin (TSH) release and direct effects at the level of the thyroid gland. Adrenal cortical function is often enhanced in diabetes, most likely due to alterations in glucocorticoid feedback responses. There is much conflicting data on adrenal medullary function in diabetes; responses to stress and exercise, however, are often abnormal. Finally, male and female reproductive function is often disrupted in diabetes. Data from animal studies suggest that the major cause is altered hypothalamic LHRH secretion secondary to diabetes-induced changes in hypothalamic neurotransmitter metabolism.

Neurohypophyseal vasopressin in the Syrian hamster: response to short photoperiod, pinealectomy, melatonin treatment, or osmotic stimulation.

In the present study, the effect of photoperiod on vasopressin content in the pituitary neurointermediate lobe (NIL), as well as the ability of pinealectomy to prevent and melatonin to mimic the short photoperiod-induced changes in NIL vasopressin were studied in male Syrian hamsters. The ability of melatonin to modify the hyperosmotically stimulated vasopressin release was also determined. Exposure to short photoperiod (SD) for 4 or 10 weeks increased vasopressin content in the hamster NIL. In long photoperiod (LD)-exposed hamsters, pinealectomy induced a decrease in NIL vasopressin content, whereas no effect of melatonin injections on vasopressin storage in the NIL was detected. In SD-exposed animals, pineal removal failed to alter vasopressin content in the NIL. Hypertonic saline administration led to the expected decrease in vasopressin content in the NIL both in vehicle- and melatonin-treated animals. The hyperosmotically stimulated release of vasopressin was not modified by previous treatment with melatonin. The data from the present study show that, in male Syrian hamsters, exposure of animals to SD increases the vasopressin content in the posterior pituitary, but these changes appear not to be mediated by SD-induced changes in melatonin secretion. Furthermore, the exposure of animals to SD prevents the pinealectomy-induced changes in NIL vasopressin content. Melatonin does not modify the hyperosmotically stimulated vasopressin release in the male Syrian hamster.

Oxytocin and prolactin release after hypertonic saline administration in melatonin-treated male Syrian hamsters.

The aim of the present investigations was to examine the effects of melatonin (Mel) on oxytocin (OT) release under conditions of osmotic stimulation, brought about by hypertonic saline administration, as well as to determine whether osmotically stimulated OT release in Mel-treated Syrian hamster is associated with alterations in the release of prolactin (PRL) and in norepinephrine (NE) and dopamine (DA) content in the hypothalamus. In both Mel- and vehicle-treated hamsters, injection of hypertonic saline was followed by a significant decrease in OT content in the pituitary neurointermediate lobe (NIL) and elevation of plasma OT and PRL levels. Melatonin injections had no significant affect on NIL OT content in either isotonic- or hypertonic-saline treated animals. Pretreatment with Mel did not alter plasma OT or PRL levels in isotonic saline-injected animals. However, Mel facilitated the release of OT, but prevented the release of PRL after hypertonic saline administration. Melatonin treatment reduced hypothalamic NE content (but not that of DA) in isotonic-saline treated animals. After osmotic stimulation, hypothalamic content of NE and DA was significantly lower in Mel-treated than in vehicle-treated animals. Data from the present study suggest that the osmotically-stimulated release of OT and PRL seems to be related to the activation of noradrenergic rather than dopaminergic transmission. Both dopaminergic and noradrenergic transmission may be, however, involved in mediating the effects of Mel on the osmotically-activated OT and PRL release.

Effects of growth hormone on neuroendocrine function.

Although the role of growth hormone (GH) in the control of reproductive functions is not well understood, there is considerable evidence that the states of both GH deficiency and GH excess are typically associated with reproductive deficits. To identify the possible involvement of functional alterations in the hypothalamic-pituitary system in producing these deficits, we are studying neuroendocrine function related to reproduction in transgenic animals overexpressing GH, in animals with congenital GH deficiency, and in animals with selective immunoneutralization of GH. The results indicate that GH acts on the hypothalamus to alter dopaminergic and noradrenergic control of prolactin and gonadotropin release. Life-long elevation of GH levels outside the physiological ranges disrupts feedback control of luteinizing hormone (LH) release by gonadal streroids. Plasma LH and follicle-stimulating hormone (FSH) levels and feedback control of LH release are also abnormal in GH-deficient animals indicating that physiological levels of endogenous GH are normally involved in the control of gonadotropin release. Differences between the effects of bovine vs. human GH in transgenic mice and differential effects of GH deficiency in mice and rats should facilitate identification of the mechanisms involved in the actions of GH on the hypothalamic-pituitary system.

Effects of streptozotocin-induced diabetes on the response of male rats to immobilization stress.

The effects of streptozotocin-induced (STZ) diabetes on the response to immobilization stress were evaluated in adult male rats. Rats were injected with STZ or vehicle and handled daily to minimize stress. Four weeks later, half of the animals were lightly anesthetized with ether and immobilized for 20 min. At that time the stressed and nonstressed controls were sacrificed, and blood and tissue collected for hormone and amine determinations. Immobilization caused an increase in plasma glucose levels in the controls, but caused no further increase in the already high levels seen in the diabetic rats. Basal corticosterone levels did not differ between the STZ and control rats, and the increase after immobilization was of similar magnitude. The stress-induced increase in prolactin was attenuated in the diabetic rats. Immobilization caused a significant rise in plasma norepinephrine (NE) levels in control, but not in diabetic rats. Adrenal NE content and tyrosine hydroxylase activity were not significantly affected by stress or STZ treatment. Dopamine (DA) and NE content was increased in the hypothalamus of immobilized diabetic rats as compared to nondiabetic immobilized controls. These results demonstrate that diabetic rats respond to immobilization stress, but the endocrine and sympathetic nervous system response is impaired. Changes in the stress response may be related to changes in hypothalamic amine metabolism.

The effects of short photoperiod, pinealectomy, and melatonin treatment on oxytocin synthesis and release in the male syrian hamster.

The pineal gland has been shown to affect plasma oxytocin (OT) levels, but the mechanism of this action is not apparent. In the present study, the ability of the photoperiod to affect plasma OT levels, neurointermediate lobe (NIL) OT content, and hypothalamic OT mRNA levels was studied in male Syrian hamsters. In addition, the ability of pinealectomy to prevent and melatonin (MEL) to mimic the short photoperiod-induced changes were also determined. Exposure to short days (SD) led to the expected decrease in testes weight and plasma PRL levels, but plasma OT levels were unchanged. However, NIL OT content was increased in the SD-exposed animals. Hypothalamic OT mRNA levels were not significantly altered by SD exposure. Pinealectomy blocked the effects of SD on testes weight, whereas afternoon MEL injections mimicked the effects of SD. In long day (LD)-exposed hamsters, pinealectomy induced a decrease in NIL OT content without altering hypothalamic OT mRNA levels. In SD-exposed animals, NIL OT content was not affected by pinealectomy. Melatonin injections had no significant effect on NIL OT content or hypothalamic OT mRNA levels. The data from the present study suggest that exposure of male Syrian hamsters to short photoperiods influences some aspects of OT synthesis and/or transport to produce its increased accumulation in the NIL, but does not affect OT release. These changes are apparently not the result of SD-induced changes in MEL secretion, but conceivably could be related to the previously documented effects of SD on hypothalamic catecholamine turnover.

Photoperiod effects on neurohypophyseal and tuberoinfundibular dopamine metabolism in the male hamster.

Exposure of golden hamsters to a short photoperiod (< 12.5 h light/day) leads to suppression of gonadal function secondary to reduced gonadotropin and PRL secretion. PRL secretion is decreased despite a reduction of tuberoinfundibular dopaminergic activity. In the present study, the ability of photoperiod to affect tuberohypophyseal dopamine (DA) turnover was evaluated in long day (LD; 16 h of light, 8 h of darkness) and short day (SD; 8 h of light, 16 h of darkness) male hamsters. Exposure to SD led to decreases in testicular weight within 10 weeks and decreases in plasma PRL levels within 1 week. DA turnover in the neurointermediate lobe of the pituitary, as estimated by measuring the depletion of DA 60 min after tyrosine hydroxylase inhibition with alpha-methyl-p-tyrosine (250 mg/kg), was significantly elevated 1 and 4 weeks after transfer to SD, but returned by 10 weeks to the levels seen in LD animals. After 14 days of SD exposure an enhanced lactotroph sensitivity to DA was demonstrated and may also have contributed to suppression of PRL levels. Similarly to the findings of previous studies, DA turnover in the median eminence was depressed in animals housed in SD. The DA content of the anterior pituitary was not significantly affected by photoperiod. The data from this study suggest that decreases in PRL secretion associated with the transfer of hamsters from LD to SD conditions are at least in part caused by an increase in DA turnover by neurohypophyseal neurons. However, the involvement of other PRL-inhibiting or -stimulating factors in mediating the effects of photoperiod on PRL secretion cannot be ruled out.

Infertility in transgenic mice overexpressing the bovine growth hormone gene: disruption of the neuroendocrine control of prolactin secretion during pregnancy.

Transgenic female mice overexpressing the bovine growth hormone (bGH) gene with the phosphoenolpyruvate carboxykinase (PEPCK) promoter exhibit severe reproductive deficits. Although these animals ovulate and conceive normally, pregnancy is arrested due to luteal failure, leading to the loss of embryos during early gestation. The results of replacement therapy suggested that luteal failure was secondary to prolactin (PRL) deficiency. The objective of this study was to examine the neuroendocrine control of PRL secretion during early pregnancy in PEPCKbGH-1 transgenic mice. Normal and transgenic littermates were killed by decapitation on Day 7 postcoitum (p.c.) at 1500, 1800, or 2100 h, i.e., the period including the expected diurnal PRL surge in pregnant mice. In normal females, plasma PRL levels were significantly elevated at 1800 h when compared to the levels measured at 1500 or 2100 h, but no temporal variation in PRL levels was found in transgenic mice. In normal females, the content of dopamine in the median eminence was reduced at 1800 h, i.e., at the time of the PRL surge. In contrast, no temporal changes were detected in the median eminence dopamine content in transgenic mice. Twice-daily injections of domperidone, a dopamine receptor blocker, increased the incidence of pregnancy in transgenic females. After treatment with aromatic amino acid decarboxylase inhibitor NSD-1015 on Day 7 p.c., plasma levels of PRL were similarly elevated in transgenic and normal females. However, the accumulation of 5-hydroxytryptophan (5-HTP) in the medial basal hypothalamus after this treatment was significantly smaller in transgenic than in normal females.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuroendocrine and reproductive consequences of overexpression of growth hormone in transgenic mice.

Availability of recombinant growth hormone (GH) and development of long-acting formulations of this material will undoubtedly lead to widespread use of GH in animal industry and in medicine. GH can act, directly or indirectly, on multiple targets, but its influence on the reproductive system and on the hormonal control of reproduction is poorly understood. Overexpression of GH genes in transgenic animals provides a unique opportunity to study the effects of long-term GH excess. Transgenic mice overexpressing bovine, ovine, or rat GH (hormones with actions closely resembling, if not identical to, those of endogenous [mouse] GH), exhibit enhancement of growth, increased adult body size, and reduced life-span as well as a number of endocrine and reproductive abnormalities. Ectopic overexpression of bovine GH (bGH) driven by metallothionein or phosphoenolpyruvate carboxykinase promoters is associated with altered activity of hypothalamic neurons which produce somatostatin, loss of adenohypophyseal GH releasing hormone (GHRH) receptors, and suppression of endogenous (mouse) GH release. Elevation of plasma levels of GH (primarily bGH) and insulin-like growth factor (IGF-I) in these transgenic mice leads to increases in the number of hepatic GH and prolactin (PRL) receptors, in the serum levels of GH-binding protein (GHBP), in the percent of GHBP complexed with GH, and in the circulating insulin levels. In addition, plasma adrenocorticotropic hormone (ACTH) and corticosterone levels are elevated. Plasma levels of luteinizing hormone (LH), as well as its synthesis and release, are not consistently affected, but follicle-stimulating hormone (FSH) levels are suppressed, apparently due to pre- and post-translational effects. Pituitary lactotrophs exhibit characteristics of chronic enhancement of secretory activity, and plasma PRL levels are elevated. Prolactin responses to mating or to pharmacological blockade of dopamine synthesis are abnormal. Reproductive life span and efficiency are reduced in both sexes, with the severity and frequency of reproductive deficits being related to plasma bGH levels. Most transgenic females expressing high levels of bGH are sterile due to luteal failure. Overexpression of human GH which, in the mouse, interacts with both GH and PRL receptors leads to additional endocrine and reproductive abnormalities including stimulation of LH beta mRNA levels and LH secretion, loss of responsiveness to testosterone feedback, overstimulation of mammary glands, enhanced mammary tumorigenesis, and hypertrophy of accessory reproductive glands in males.

Effects of delta 9-tetrahydrocannabinol on copulatory behavior and neuroendocrine responses of male rats to female conspecifics.

Male rats exposed to sexually receptive females, exhibit a rapid increase in plasma levels of luteinizing hormone (LH) and prolactin, and concomitant increases in noradrenergic activity in the medial basal hypothalamus (MBH) and median eminence (ME) as well as in dopaminergic activity in the MBH. Delta-9-tetrahydrocannabinol (THC; 5 mg/kg b.wt., PO), the chief psychoactive constituent of marijuana, blocked the MBH and ME noradrenergic response and the dopaminergic response in the MBH in male rats exposed for 20 min to sexually receptive females, and suppressed the expected increases in plasma LH and prolactin levels. Moreover, THC treatment decreased the percentage of animals exhibiting copulatory behavior and increased the latency periods to mount and intromit. These findings indicate that THC interferes with the neuroendocrine and behavioral responses of male rats to the presence of a receptive female.