Estrogen receptor in rat pancreatic islets

Long Term Sodium Nitrate Administration Positively Impacts Metabolic and Obesity Indices in Ovariectomized Rats

BACKGROUND

In postmenopausal women, nitric oxide (NO) deficiency is associated with obesity and type 2 diabetes (T2D). This study aims at determining the long-term effects of low-dose nitrate administration on metabolic and obesity indices in ovariectomized (OVX) rats.

METHODS

OVX rat model was induced using the two dorsolateral skin incision method. Two months after ovariectomy, rats were divided into three groups (n = 10/group): Control, OVX, and OVX+nitrate, and the latter received sodium nitrate at a dose of 100 mg/L in their drinking water for nine months. Fasting serum glucose and lipid profile were measured every month. A glucose tolerance test was performed at months 1, 3, and 9 (the end of the study). Obesity indices were calculated, and histological analyses were performed on the gonadal adipose tissues at month 9.

RESULTS

OVX rats had impaired fasting glucose, glucose intolerance, and dyslipidemia with higher obesity indices at month 9. Nitrate improved glucose and lipid metabolism in OVX rats and decreased body weight (6.9%), body mass index (12.5%), Lee index (5.4%), adiposity index (23.9%), abdominal circumference (10.5%), and thoracic circumference (17.1%). Also, nitrate decreased adipocyte area by 49% and increased adipocyte density by 193% in gonadal adipose tissue.

CONCLUSION

Long-term low-dose nitrate administration improves glucose and lipid metabolism in OVX rats in association with decreasing OVX-induced adiposity, increasing adipocyte density, and decreasing adipocyte area. These findings provide support for a potential therapeutic role of nitrate in postmenopausal women with some features of metabolic syndrome.

Comparison of the effects of fetal hypothyroidism on glucose tolerance in male and female rat offspring

Thyroid hormones are vital for survival of mammalian species and play critical roles in growth, development, and metabolism. Both fetal hypothyroidism and sex can affect carbohydrate metabolism during adult life. This study aims to assess carbohydrate metabolism in male and female offspring born from mothers who were hypothyroid during pregnancy. Pregnant rats were divided into two groups; the controls consumed water and the hypothyroid group received water containing 0.025 % 6-propyl-2-thiouracial throughout gestation. The intravenous glucose tolerance test (0.5 g/kg glucose) was carried out in 3-month-old offspring. Findings showed that compared to controls, male fetal hypothyroid rats during adulthood had glucose intolerance (area under the curve: 446.4 ± 9.7 vs. 486.4 ± 8.8, p < 0.01 in control and fetal hypothyroid groups, respectively) whereas females had improved glucose tolerance (478.1 ± 7.0 vs. 455.9 ± 8.5, p < 0.01). In conclusion, sex could modulate the effects of fetal hypothyroidism on glucose tolerance in rats.

Female mice are protected against high-fat diet induced metabolic syndrome and increase the regulatory T cell population in adipose tissue

Sex differences in obesity-induced complications such as type 2 diabetes have been reported. The aim of the study was to pinpoint the mechanisms resulting in different outcome of female and male mice on a high-fat diet (HFD). Mice fed control or HFD were monitored for weight, blood glucose, and insulin for 14 weeks. Circulating chemokines, islet endocrine function and blood flow, as well as adipose tissue populations of macrophages and regulatory T-lymphocytes (T_reg) were thereafter assessed. Despite similar weight (43.8±1.0 and 40.2±1.5 g, respectively), male but not female mice developed hyperinsulinemia on HFD as previously described (2.5±0.7 and 0.5±0.1 pmol/l, respectively) consistent with glucose intolerance. Male mice also exhibited hypertrophic islets with intact function in terms of insulin release and blood perfusion. Low-grade, systemic inflammation was absent in obese female but present in obese male mice (IL-6 and mKC, males: 77.4±17 and 1795±563; females: 14.6±4.9 and 240±22 pg/ml), and the population of inflammatory macrophages was increased in intra-abdominal adipose tissues of high-fat-fed male but not female mice. In contrast, the anti-inflammatory T_reg cell population increased in the adipose tissue of female mice in response to weight gain, while the number decreased in high-fat-fed male mice. In conclusion, female mice are protected against HFD-induced metabolic changes while maintaining an anti-inflammatory environment in the intra-abdominal adipose tissue with expanded T_reg cell population, whereas HFD-fed male mice develop adipose tissue inflammation, glucose intolerance, hyperinsulinemia, and islet hypertrophy.

Sex steroids effects on the endocrine pancreas

The endocrine pancreas is central in the physiopathology of diabetes mellitus. Nutrients and hormones control endocrine pancreatic function and the secretion of insulin and other pancreatic islet hormones. Although the pancreas is not usually considered as a target of steroids, increasing evidence indicates that sex steroid hormones modify pancreatic islet function. The biological effects of steroid hormones are transduced by both, classical and non-classical steroid receptors that in turn produce slow genomic and rapid non-genomic responses. In this review, we focused on the effects of sex steroid hormones on endocrine pancreatic function, with special emphasis in animal studies.

Is there an estrogenic component in the metabolic syndrome?

One of the major upcoming concerns leading to health related problems in the industrialized societies is the metabolic syndrome which is characterized by central obesity, hypertension, raised fasting glucose and triglyceride levels. The focus of this review is on a potential estrogenic linkage between the metabolic mechanisms involved into the development of this disease cluster and specific estrogen related regulatory pattern. The candidate molecules for this link are insulin and insulin-like growthfactor, C-reactive protein, peroxisome-proliferation-activatingreceptorgamma, and leptin which all seem to interact with each other and show a responsiveness to changing estrogen levels. From this perspective they might also represent target molecules for a phytochemical intervention with phytoestrogens.

Oestrogens and insulin secretion

There is a persistent perception that oestrogens have an adverse effect on carbohydrate metabolism. It might therefore be expected that their use would result in a corresponding increase in the incidence of diabetes. Recent evidence from clinical trials suggesting that women on postmenopausal oestrogen hormone replacement therapy (HRT) have a reduced incidence of type 2 diabetes therefore appears paradoxical. Short-term supraphysiological oestrogen administration has an adverse effect on glucose tolerance, resulting from suppression of first-phase insulin secretion and increased insulin resistance. Oestrogen-induced increases in glucocorticoid activity could account for these effects. Oestrogen-induced deterioration in glucose tolerance is, however, accompanied by a reduction in fasting glucose, an effect that could be accounted for by glucagon antagonism. These short-term effects contrast with long-term preservation of insulin secretion and glucose homeostasis by oestrogens. In animal studies, ovariectomy is associated with decreased insulin secretion and increased risk of diabetes, whereas oestrogen administration protects against diabetes and increases the insulin response to glucose. The mechanism is uncertain, but direct effects on the pancreas via steroid receptors or indirect effects via oestrogen-induced glucagon antagonism and subclinical increases in glucocorticoids and growth hormone could all contribute. Recent evidence that HRT increases the risk of cardiovascular disease suggests that it should not be used for the prevention of diabetes, but the mechanism responsible for this benefit merits further investigation and might lead to new therapies.

Effect of 17beta-estradiol on insulin secretion and cytosolic calcium in Min6 mouse insulinoma cells and human islets of Langerhans

OBJECTIVE

Female gonadal steroids can exert an insulinotropic effect in vivo. The objective of this study was to investigate the effects in vitro of 17-beta-estradiol (17beta-E2) on changes in cytosolic calcium ([Ca]i) and on insulin secretion from the MIN6 mouse insulinoma cell line and human primary islets of Langerhans.

METHODS

Stimulus-induced changes in [Ca]i were measured in Fura-2-loaded cells by single cell microfluorimetry. The effects of 17beta-E2 on insulin secretion were measured in static incubation experiments, and the rate and pattern of secretory responses were studied in multi-channel perifusion experiments.

RESULTS

17Beta-E2 (1-100 nmol/L) enhanced basal (2 mmol/L glucose) insulin secretion but had no effect on secretory responses to 20 mmol/L glucose or to depolarizing stimuli (100 micromol/L tolbutamide, 20 mmol/L KCl). Approximately 60% of MIN6 cells responded to 17beta-E2 (1-100 nmol/L) with a small but sustained increase in [Ca]i, whereas 98% of MIN6 cells responded to tolbutamide (100 micromol/L). Similar effects were observed in experiments using human primary beta cells. In contrast, 17beta-E2 had no detectable effect on the increases in [Ca]i evoked by tolbutamide (100 micromol/L) or glucose (20 mmol/L).

CONCLUSIONS

Our observations are consistent with a rapid effect of 17beta-E2 to depolarize beta cells leading to an influx of extracellular Ca and the initiation of insulin secretion by the consequent elevations in [Ca]i. We suggest that this may offer a mechanism through which circulating estradiol can influence beta-cell responsiveness to other signals.

Models of pancreatic regeneration in diabetes

The number of functionally intact beta cells in the islet organ is of decisive importance for the development, course and outcome of diabetes mellitus. Generally speaking, the total beta-cell mass reflects the balance between the renewal and loss of these cells. Assuming that virtually all forms of diabetes mellitus are characterized by an insufficient extent of beta cell replication needed to compensate for the loss or dysfunction of beta cells occurring in diabetes, elucidation of the regenerating potential in experimentally induced diabetic animal would be of interest as alternative therapy for diabetes. Here we have attempted to take a stock of different models developed in the last few years, which permit investigation of regenerative process from various angles. The review focuses on factors responsible for induction of islet neogenesis in the diabetic pancreas, ultimately leading to pancreatic regeneration and possible reversal of diabetes. On the whole the study of these models will enhance our understanding of regenerative potential of diabetic pancreas and factors necessary to trigger stem cells' population within the pancreas so as to suggest an alternative therapeutic approach for the control and/or cure of diabetes.

Sex steroids influence pancreatic islet hypertrophy and subsequent autoimmune infiltration in nonobese diabetic (NOD) and NODscid mice

Female nonobese diabetic (NOD) mice more frequently develop autoimmune diabetes than NOD males. Orchidectomy of the latter aggravates insulitis and diabetes. Because clear differences in immune function have not been observed between prediabetic females and males, before or after castration, we hypothesized that sex-related differences in diabetes incidence are related to target organ-specific actions of sex steroids. Previously, we showed that prediabetic NOD females develop hyperinsulinemia and subsequently mega-islets. Infiltration of the first inflammatory leukocytes is predominantly associated with these mega-islets. Here, we determined the relationship between sex hormones, mega-islet formation, and infiltrating cells in NOD and nonobese diabetic/severe combined immune-deficient (NODscid) mice. Mega-islet formation was reduced in NOD males compared with NOD females, and orchidectomy increased it, indicating a relationship between androgen levels and mega-islet formation. Moreover, enhanced mega-islet formation in castrated NOD males was associated with increased numbers of infiltrating leukocytes. Castrated NODscid males also exhibited increased mega-islet formation and dendritic cell infiltration, indicating that lymphocytes are not required for castration-induced effects. In conclusion, we show that androgens influence pancreatic islets and autoimmune infiltration in NOD and NODscid mice. This suggests that the gender difference in diabetes incidence in NOD mice is related to target organ-specific androgen effects.

Modulatory effect of hormones on insulin secretion in vitro in the toad

The aim of this work was to demonstrate the possible direct effect of several hormones upon glucose-induced insulin secretion in amphibians. Hence, pancreas pieces of Bufo arenarum were incubated for 60 min at 25 degrees with 2 and 8 mM glucose plus the addition of hormones known to affect insulin secretion in mammals, measuring the release of insulin by radioimmunoassay. Glucagon (1 microM), ACTH (2.5 microM), human and bovine growth hormone (4.6 and 2.1 microM), prolactin (0.27 microM), corticosterone (0.4 microM), androstanolone (10(-2) microM), estradiol and estrone (10 microM), triiodothyronine and thyroxine (1 microM) enhanced significantly the glucose-induced insulin secretion. Androstanolone, human and bovine growth hormone, triiodothyronine and thyroxine only exerted such effect in the presence of 8 mM glucose. Conversely, somatostatin (1 microM), adrenalin (1 microM), clonidine (2 microM), dexamethasone (0.4 microM), and 2-hydroxyestradiol (5 microM) decreased significantly the glucose-induced insulin release. However, the effect of somatostatin was only apparent in the presence of high glucose. The direct effect of all these hormones--tested for the first time in the amphibian pancreas--was similar to that described in the mammalian pancreas, thus suggesting that such hormones might participate, at least in vitro, in the fine-tuning of insulin secretion in amphibians.

Is there a menopausal metabolic syndrome?

Estradiol-17 beta has beneficial effects on a range of metabolic risk factors for coronary heart disease and the decline in estrogen concentrations at the menopause would be expected to have adverse effects. Review of the literature on effects of the menopause and of estradiol-17 beta provides evidence for the following changes occurring at or after the menopause: increased total cholesterol and triglycerides; decreased high density lipoprotein (HDL) and HDL subfraction 2; increased low density lipoprotein, particularly in the small, dense subfraction; increased lipoprotein (a); increased insulin resistance; decreased insulin secretion; decreased insulin elimination; increased android fat distribution; impaired vascular function; increased factor VII and fibrinogen, and reduced sex-hormone binding globulin. Many of these changes will themselves have adverse effects on other metabolic risk factors. This complex of inter-correlated adverse changes in metabolic risk factors justifies identification of a distinct menopausal metabolic syndrome which originates in estrogen deficiency and which could contribute to the increased risk of coronary heart disease seen in postmenopausal women. Estrogen replacement can diminish the expression of this syndrome.

Histological study of pancreatic beta-cell loss in relation to the insulitis process in the non-obese diabetic mouse

Non-obese diabetic (NOD) mice spontaneously develop an autoimmune diabetes with higher incidence in females than in males. In order to elucidate possible factors involved in the different incidence of diabetes between male and female mice, we studied the progression of pancreatic beta-cell loss in relation to mononuclear cell infiltration of the pancreas (insulitis). We examined the pancreas of 76 NOD mice (39 males and 37 females) of different ages. The beta-cell content was assessed by immunoperoxidase staining of sections with an anti-insulin serum and the severity of insulitis was determined by haematoxylin staining of the same sections. A semi-quantitative criterion was used to grade both parameters. The results showed that females have a faster loss of beta-cell mass, which progressively decreases with the increase of severity of insulitis. In males, a medium to severe degree of insulitis is required before initial loss of beta cells occurs. Under the age of 10 weeks there was a significantly lower content of beta cells in females than males (2.84 +/- 0.03 vs 2.67 +/- 0.07; P = 0.02). Since we never observed a significant difference in the degree of mononuclear cell infiltration in age-matched males and females, these data support the hypothesis of weaker beta-cell resistance to immunological attack in female mice. Thus beta-cell sensitivity, in addition to immunological activity, is an important factor in the pathogenesis of insulin dependent diabetes.

Metabolic fuels and reproduction in female mammals

A complete reproductive cycle of ovulation, conception, pregnancy, and lactation is one of the most energetically expensive activities that a female mammal can undertake. A reproductive attempt at a time when calories are not sufficiently available can result in a reduced return on the maternal energetic investment or even in the death of the mother and her offspring. Numerous physiological and behavioral mechanisms link reproduction and energy metabolism. Reproductive attempts may be interrupted or deferred when food is scarce or when other physiological processes, such as thermoregulation or fattening, make extraordinary energetic demands. Food deprivation suppresses both ovulation and estrous behavior. The neural mechanisms controlling pulsatile release of gonadotropin-releasing hormone (GnRH) and, consequently, luteinizing hormone secretion and ovarian function appear to respond to minute-to-minute changes in the availability of metabolic fuels. It is not clear whether GnRH-secreting neurons are able to detect the availability of metabolic fuels directly or whether this information is relayed from detectors elsewhere in the brain. Although pregnancy is less affected by fuel availability, both lactational performance and maternal behaviors are highly responsive to the energy supply. When a reproductive attempt is made, changes in hormone secretion have dramatic effects on the partitioning and utilization of metabolic fuels. During ovulatory cycles and pregnancy, the ovarian steroids, estradiol and progesterone, induce coordinated changes in the procurement, ingestion, metabolism, storage, and expenditure of metabolic fuels. Estradiol can act in the brain to alter regulatory behaviors, such as food intake and voluntary exercise, as well as adenohypophyseal and autonomic outputs. At the same time, ovarian hormones act on peripheral tissues such as adipose tissue, muscle, and liver to influence the metabolism, partitioning and storage of metabolic fuels. During lactation, the peptide hormones, prolactin and growth hormone, rather than estradiol and progesterone, are the principal hormones controlling partitioning and utilization of metabolic fuels. The interactions between metabolic fuels and reproduction are reciprocal, redundant, and ubiquitous; both behaviors and physiological processes play vital roles. Although there are species differences in the particular physiological and behavioral mechanisms mediating nutrition-reproduction interactions, two findings are consistent across species: 1) Reproductive physiology and behaviors are sensitive to the availability of oxidizable metabolic fuels. 2) When reproductive attempts are made, ovarian hormones play a major role in the changes in ingestion, partitioning, and utilization of metabolic fuels.

Biology of pancreatic cancer

Pancreatic cancer is the fifth leading cause of death from malignant disease in Western society. Apart from the fortunate few patients who present with a resectable small pancreatic adenocarcinoma, conventional treatment offers no hope of cure and has little palliative value. Over the past two decades major steps have been made in our understanding of the biology of pancreatic growth and neoplasia. This review sets out to explore these advances, firstly in the regulation of normal pancreatic growth, and secondly the mechanism which may be involved in malignant change of the exocrine pancreas. From an understanding of this new biology, new treatment strategies may be possible for patients with pancreatic cancer.

Zonal distribution of fatty acid synthase in liver parenchyma of male and female rats

1. A sensitive radiochemical assay was established to determine the activity of fatty acid synthase in microdissected liver tissue of less than 1 microgram dry mass. 2. In female rats, the enzyme activity in perivenous tissue was twice that in periportal liver tissue while it was homogeneously distributed in livers of male animals. The overall activity was higher in female than in male animals. 3. The absolute activity, as well as the perivenous/periportal ratio, was reduced during starvation and in diabetes. They were greatly increased after refeeding to values above those observed in animals during normal feeding. 4. Ovariectomy or administration of testosterone to female rats resulted in a significant reduction of the zonal heterogeneity. 5. Castration or administration of estradiol to male animals was followed by an increase in the enzyme activity exclusively in the perivenous tissue, resulting in a zonal heterogeneity as observed in female rats.

The isolation and characterization of estrogen binding proteins in the pancreas of male and female hamsters

Specific estradiol binding proteins (EBP) that have been described in the pancreatic tissues of a number of species are thought to be important in maintaining the structural and functional integrity of the pancreas. However, possible sex-related differences in the presence and characteristics of EBP have not been examined. In the present study, we have analyzed the pancreatic tissues of male and female Syrian golden hamsters for the presence of EBP and progesterone binding protein (PBP), and further characterized these sites. Our results indicate the presence of only one class of EBP with a high capacity (greater than 500 fmol/mg protein) and low affinity (Kd greater than 1.0 nM) in the pancreatic cytosol of female hamsters. On the other hand, there appeared to be two distinct classes of EBP in the male pancreas. One class of EBP in the male pancreas had a high binding affinity (Kd = less than 0.05 nM) and low capacity (less than 10 fmol/mg protein); we have arbitrarily called these Type I EBP. The second class of EBP in the male pancreas which resembled EBP in the female pancreas had a high capacity (greater than 100 fmol/mg protein) and a low binding affinity (Kd = greater than 1.0 nM); we have called these Type II EBP. The sucrose-density gradient profile of EBP for male and female hamster pancreas demonstrated the presence of both an 8S binding protein and a 4S binding protein in the male pancreas; the female pancreas had only a 4S binding protein. PBP were not detected in pancreas of either male or female hamsters. We conclude that significant sex-related differences are present in the EBP populations of the hamster pancreas.

Sex steroid receptors in the stomach, liver, pancreas, and gastrointestinal tract of the baboon

Sex steroids have been shown to have a marked effect on the physiologic activities of the liver and the gastrointestinal tract. We performed autoradiographic studies using [3H]estradiol and [3H]dihydrotestosterone on male and female baboons for the purpose of identifying estrogen or androgen receptors, or both, in the liver, pancreas, stomach, and small and large intestines of baboons. Evidence for the presence of estrogen and androgen receptors was made apparent by high concentrations of silver grains over the nuclei of the cells of these tissues. Androgen receptors were largely confined to the nuclei of the smooth muscle cells of the tunica muscularis of the gut wall and the connective tissue interstitial cells of the liver, pancreas, stomach, and intestines. Estrogen receptors were prominent in the nuclei of the vascular smooth muscle cells in the liver, pancreas, gut, and the majority of the endocrine islet cells. These observations suggest that a variety of different cell types of the liver, pancreas, and gastrointestinal tract contain estrogen and androgen receptors that might modulate their cellular activities and influence several different physiologic processes.

Effect of median eminence lesions and hormonal replacement on the prolactin receptors in the adrenal gland and Langerhans islets from ovariectomized adult rats

The effect of hyperprolactinemia induced by median eminence lesions (MEL) and ACTH and glucocorticoid replacement on prolactin (Prl) receptors was studied in the adrenal, isolated Langerhans islets and the liver. Adult rats were ovariectomized 15 days before MEL and they were divided in the following groups: 1) SHAM: injected with saline solution 3 times in alternate days; 2) MEL: saline solution; 3) MEL + ACTH: 50 micrograms: 10 IU/rat, s.c. (Synacthen) and 4) MEL + DEXA: 10 micrograms/rat (dexamethasone). For measuring total lactogenic binding sites an in vitro treatment of the membrane fraction with 4M MgCl2 was used. MEL originated a significant increase in Prl serum levels, which was not altered by injections of ACTH or dexamethasone. In contrast, serum corticosterone (B) levels in MEL rats were significantly lowered, and it was restored by ACTH. Unexpectedly, B levels increased when dexamethasone was administered to MEL rats. Prl receptors were diminished in the adrenal gland and Langerhans islets from MEL animals, as compared with the SHAM group. ACTH and glucocorticoid administration did not affect the pancreatic Prl receptors, while the adrenal gland exhibited a further lowering of Prl binding sites during ACTH treatment. Since no effect was found when dexamethasone was injected, a possible direct action of ACTH is suggested. On the other hand, Prl receptors were induced in the liver by MEL, and this action was abolished by dexamethasone and ACTH. Binding affinity in every tissue studied remained unchanged. Our data suggest that endogenous Prl is able to regulate its own receptors not only in the liver, but also in the adrenal gland and pancreatic islets.

The synthetic protease substrate N-benzoyl-L-argininyl-p-nitroanilide activates specific binding of [3H]estradiol to a protein in rat pancreas: relationship of structure to activity

N-benzoyl-L-arginyl-p-nitroanilide (BAN), a synthetic substrate for trypsin-like proteolytic enzymes, is a potent activator of [3H]estradiol-binding to a protein present in rat pancreas. When partially purified, this protein is almost devoid of [3H]estradiol-binding activity in the absence of an endogenous accessory factor. BAN can mimic the natural coligand in this steroid binding reaction. The effect of BAN is specific since a number of derivatives of this substance are inactive or may even inhibit steroid binding. It is unlikely that BAN exerts this stimulatory action indirectly, possibly by preventing proteolytic inactivation of the [3H]estradiol-binding protein, since preincubation of the protein in the absence of BAN resulted neither in reduced rate, nor extent, of steroid binding following BAN addition. Also, a number of protease inhibitors had no effect on the binding reaction. Of those inhibitors tested, only antipain significantly enhanced binding of [3H]estradiol, but only about 20 percent as effectively as BAN.

An overview of pancreatic exocrine secretion

Genes for all proteins have encoded in their DNA sequences, information that specifies where these proteins will localize within the cell. Nascent translation products of transcripts of these genes, that possess a specific NH2-terminal signal sequence, are able to translocate into a specialized membranous conducting system called the endoplasmic reticulum (ER), or can be incorporated directly into a target organelle (i.e. mitochondrion). Nascent polypeptides lacking this signal sequence remain in the cytosol. Once segregation into the ER has occurred each protein appears to migrate at a characteristic rate to a connecting organelle; the Golgi Complex. Here, enzymatic modifications of these proteins determines the organelle with which each will eventually become associated. In secretory tissues such as the exocrine pancreas, many different proteins are directed into specialized secretory structures called zymogen granules. These granules are maintained in a "ready-to-release" state by steroid hormones. In the absence of estrogens and glucocorticoids the zymogen granules disappear. Physiologically, secretion from the exocrine pancreas is brought about by parasympathetic nerve stimulation, or by the gut hormone cholecystokinin (CCK). Interaction of acetylcholine or CCK with specific receptors on pancreatic acinar cells initiates the process of exocytosis; that is, fusion of the zymogen granule membrane with the plasma membrane resulting in extracellular release of the contents of the secretory granule.

The effect of sex steroids on insulin binding by target tissues in the rat

The effect of estradiol, progesterone and norgestrel on serum insulin and glucose levels and on insulin binding to adipocytes, hepatocytes and diaphragm muscle cell membranes has been evaluated in castrated male rats. Estradiol administration (5 micrograms/day X 6) significantly increased basal plasma insulin levels and the amount of insulin bound to fat and liver cells as well as muscle cell membranes. Progesterone treatment (5 mg/day X 6) caused a slight increase of basal insulin levels and a decrease of insulin binding to fat cells. Norgestrel treatment (5 mg/day X 6) decreased both insulin levels and the amount of insulin bound to adipocytes; a much lower dose of norgestrel, 6 micrograms/day X 7, also caused a decline in adipocyte insulin binding due to an apparent increase in the dissociation constant of the high affinity binding sites. These studies demonstrate that ovarian sex steroids have a significant effect on insulin binding to target cells. This animal model would assist in determining the mechanisms involved in changes of carbohydrate metabolism which occur during the menstrual cycle, pregnancy, the menopausal state and with the use of oral contraceptives.

Prolactin regulation of prolactin binding sites in pancreatic islets and adrenal glands of ovariectomized rats

The role of prolactin (Prl) in the regulation of Prl binding to its specific binding sites was studied in the Langerhans islets, adrenal gland and liver of adult ovariectomized female rats. Animals were sc injected twice daily during 10 days with ovine Prl (1 mg/kg BW), sulpiride (30 mg/kg BW) and bromocriptine (3 mg/kg BW). At the end of the treatment period, the animals were killed and serum was collected for Prl assay. Total Prl binding sites were measured in the membrane fraction of tissue by desaturating the occupied membrane receptors in vitro with 4M MgCl2. Serum levels of Prl were significantly higher in sulpiride-treated animals, whereas bromocriptine administration rendered undetectable values. Prolactin and sulpiride treatment significantly reduced Prl binding to the adrenal gland and Langerhans islets, whereas it greatly increased Prl binding to the liver. On the other hand, bromocriptine increased Prl binding sites in the adrenal gland and Langerhans islets, but in the liver caused no apparent effect. The binding affinity (Ka) in each tissue remained unchanged under the different experimental conditions. In addition, the binding of Prl to pancreas islets membranes was lower in late pregnancy when compared with control rats. All of these data provide strong evidence in favor of a role for Prl in regulating the number of its own tissue binding sites.

Prolactin binding in rat Langerhans islets

Membrane preparations of collagenase-dispersed Langerhans islets of female Wistar rats exhibit specific binding sites for 125I-labelled ovine prolactin (125I-oPrl). Almost negligible binding was detected in islets of male animals. The binding is a saturable and time-temperature dependent process, equilibrium being reached after 16 h incubation at 0 degrees C. The bound oPrl is not displaceable by hFSH, hLH, bGH or hGH. In contrast with other cell fractions, the 12,000 g pellet accounts for more than 80% of the specific binding of 125I-oPrl. Scatchard plots of data obtained in saturation studies indicate a single class of binding sites with Ka = 0.21 x 10(10)M-1. Protein and phospholipid moieties are essential for the receptor activity, since after trypsin or phospholipase C digestions marked loss of binding was verified. In islets of streptozotocin diabetic rats a marked reduction in the number of binding sites was observed. These findings may suggest that some of the actions of prolactin on endocrine pancreas could be explained by its specific interaction with islet cell membranes.