Malgorzata Szczesna

Seasonal effects of central leptin infusion on secretion of melatonin and prolactin and on SOCS-3 gene expression in ewes

Recent studies have demonstrated photoperiodic changes in leptin sensitivity of seasonal mammals. Herein, we examined the interaction of season (long days (LD) versus short days (SD)) and recombinant ovine leptin (roleptin) on secretion of melatonin and prolactin (PRL) and on mRNA expression of suppressor of cytokine signaling-3 (SOCS-3) in the medial basal hypothalamus (MBH) in sheep. Twenty-four Polish Longwool ewes, surgically fitted with third ventricle (IIIV) cannulas, were utilized in a replicated switchback design involving 12 ewes per season. Within-season and replicate ewes were assigned randomly to one of three treatments (four ewes/treatment) and infused centrally three times at 0, 1 and 2 h beginning at sunset. Treatments were 1) control, Ringer-Locke buffer; 2) L1, roleptin, 0.5 microg/kg BW; and 3) L2, roleptin, 1.0 microg/kg BW. Jugular blood samples were collected at 15-min intervals beginning immediately before the start of infusions and continued for 6 h. At the end of blood sampling, a washout period of at least 3 days elapsed before ewes were re-randomized and treated with one of the treatments described above (four ewes/treatment). Ewes were then killed and brains were collected for MBH processing. Leptin treatments increased (P<0.001) circulating leptin concentrations compared with controls during both seasons in a dose-dependent manner. Overall, mean plasma concentrations of melatonin were greater (P<0.001) during LD than SD. However, leptin treatments increased melatonin concentrations during SD in a dose-dependent manner and decreased it during LD. Similarly, plasma concentrations of PRL were greater (P<0.001) during LD than SD. However, unlike changes in melatonin, circulating PRL decreased (P<0.001) in response to leptin during LD. Semi-quantitative PCR revealed that leptin increased (P<0.001) SOCS-3 expression in the MBH region during LD in a dose-dependent manner. Data provide evidence that secretion of photoperiodic hormones such as melatonin and PRL are inversely regulated by leptin during SD and LD. However, the increase in expression of SOCS-3 in the MBH during LD compared with SD fails to fully explain these effects.

Seasonal changes in the interactions among leptin, ghrelin, and orexin in sheep

The adaptation of the physiology of an animal to changing conditions of light and food availability is evident at the behavioral and hormonal levels. Melatonin, leptin, ghrelin, and orexin, which exhibit rhythmic secretion profiles under ad libitum feeding conditions, are sensitive to changes in daylength, forming a tight web of interrelationships in the regulation of energy balance. The aim of this study was to determine the effects of central injections of leptin, ghrelin, and orexin on the reciprocal interactions among these hormones and the influence of photoperiod on these responses. Twenty-four ovariectomized and estradiol-implanted ewes were used in a replicated switchback design. The ewes were assigned randomly to 1 of 6 treatment groups, and the treatments were infused into their third ventricles 3 times at 0, 1, and 2 h, with 0 h being at dusk. The treatments were as follows: 1) control, Ringer-Locke buffer; 2) leptin, 0.5 μg/kg BW; 3) ghrelin, 2.5 μg/kg BW; 4) orexin B, 0.3 μg/kg BW; 5) leptin antagonist, 50 μg/kg BW, then ghrelin, 2.5 μg/kg BW; and 6) leptin antagonist, 50 μg/kg BW, then orexin B, 0.3 μg/kg BW. Blood samples (5 mL) were collected at 15-min intervals for 6 h. The administration of leptin increased (P < 0.05) plasma concentrations of melatonin during short-day (ShD) photoperiods and decreased (P < 0.05) them during long-day (LD) photoperiods, whereas ghrelin decreased (P < 0.05) melatonin concentrations during ShD photoperiod, and orexin had no effect (P > 0.1). Leptin attenuated (P < 0.05) ghrelin concentrations relative to the concentration in controls during ShD. The plasma concentrations of orexin were reduced (P < 0.05) after leptin infusions during LD and ShD photoperiods; however, ghrelin had the opposite effect (P < 0.05) on orexin concentration. Orexin increased (P < 0.05) ghrelin concentrations during LD. Ghrelin and orexin concentrations were increased (P < 0.05) after leptin antagonist infusions. Our data provide evidence that the secretion of leptin, ghrelin, and orexin are seasonally dependent, with relationships that are subject to photoperiodic regulation, and that leptin is an important factor that regulates ghrelin and orexin releases in sheep.

Seasonal effects of central leptin infusion and prolactin treatment on pituitary SOCS-3 gene expression in ewes

Suppressors of cytokine signalling (SOCS) negatively regulate cytokine-induced signalling pathways and may be involved in leptin and prolactin (PRL) interactions. Herein, we examined the effect of PRL on SOCS-3 mRNA expression in pituitary explants and investigated whether leptin could modify the expression of SOCS-3 mRNA in pituitary explants. In the first experiment, we used pituitaries isolated from 16 ewes decapitated in March, May, July and October (four per month). Tissues were cut into 50 mg explants, which were treated with control or medium containing PRL (100 or 300 ng/ml). Incubation was maintained for different time intervals: 0, 60, 120, 180, 240 or 300 min. Real-time PCR was used to measure SOCS-3 mRNA levels. In the second study, we used 24 ewes surgically fitted with third ventricle cannulas (12 were used during the long-day period, and 12 were used during the short-day (SD) period). Each ewe was administered an i.c.v. injection of Ringer-Locke buffer or leptin (0.5 or 1.0 μg/kg body weight). Explants of anterior pituitaries were collected and snap frozen 1 h after injection. Semi-quantitative expression of SOCS-3 mRNA was performed using reverse transcription-PCR. PRL stimulated SOCS-3 expression in the pituitaries collected in March (P<0.05) and May (P<0.01 and P<0.05 for lower and higher doses respectively), inhibited SOCS-3 expression in pituitaries collected in July (P<0.01) and had no effect in pituitaries collected in October. Treatment with leptin increased SOCS-3 expression during the SDs in a dose-dependent manner (P<0.01). The results demonstrated that photoperiod may be involved in leptin and PRL effects on SOCS-3 expression in sheep.

Cross-talk between leptin, ghrelin and orexins in the central nervous system of seasonal animals – a review

Abstract The maintenance of energy homeostasis is achieved with ‘detectors’ that receive signals from the external and internal environment and with multidirectional ‘communication routes’ including neuronal networks and body fluids, such as blood and cerebrospinal fluid. Changes in the energy demands of organisms are caused by current physiological status and environmental conditions, including season and food availability. Little is known about the interactions between the metabolic indicators involved in the maintenance of energy homeostasis, e.g., leptin, orexins and ghrelin. Sheep and other seasonal animals are highly adaptable to their environments because of the plasticity of their neural and endocrine systems. Sheep exhibit leptin resistance and are thus an extremely interesting model for research on the relationship between hormonal indicators of energy metabolism. The paper is focused mainly on the anatomical and functional communication between leptin, ghrelin and orexins, which play principal roles in the adaptation of energetic demands to environmental fluctuations.

Role of Leptin in the Reproduction and Metabolism: Focus on Regulation by Seasonality in Animals

The hypothesis of the existence of a peripheral factor that provides the brain with information on energy status was first proposed in the 1950s (Kennedy, 1953). This hypothesis formed the basis for further investigations that eventually led to the characterization of the obese (ob/ob) mouse, a homozygous mutant that lacks a critical factor for the regulation of body weight (Friedman & Halaas, 1998). This key element of the system regulating food intake has proven to be leptin, a protein hormone produced in adipose tissue. The concentration of this hormone in the blood provides an organism with information about its nutritional status and energy reserves. Leptin acts on hunger and satiety centers in the hypothalamus that affect the regulation of appetite (Halaas et al., 1995). This hormones activity has primarily been observed in the central nervous system, especially within various parts of the hypothalamus and hypothalamic nuclei. Leptin activity was confirmed in the arcuate nucleus (ARC), ventromedial hypothalamus (VMH), dorso-medial hypothalamus (DMH), mammillary nuclei, lateral hypothalamic area (LHA) and preoptic area (POA) by Elmquist and colleagues (1998), Williams and colleagues (1999) and Morgan & Mercer (2001). In peripheral tissues, leptin directly stimulates lipolysis and inhibits lipogenesis. Direct effects of leptin were also observed in pancreatic β cells, indicating effects on the regulation of glucose homeostasis independent of the central nervous system (Kieffer et al., 1997; Zieba et al., 2003) and suggesting that leptin may affect energy balance in various ways. The metabolic status of an organism, which is defined in part by the availability of energy and nutrients to tissues, influences almost all biological functions. Among these functions, reproductive capacity is one of the most important. In linking energy homeostasis to feeding behavior and procreative functions, leptin plays a crucial role in the regulation of reproductive processes, acting at all levels of the gonadotropic axis. Additionally, apart from the mechanisms of energy homeostasis and regulation of reproduction, where leptin plays relatively well-known roles, this protein is also an important regulator of neuroendocrine functions (Wauters et al., 2000). Its impact has been observed on different levels of hormonal axes, ranging from releasing hormone secretion from the hypothalamus and influencing pituitary hormone secretion to a direct influence on the secretory activity of peripheral tissues.

The Action of Di-(2-Ethylhexyl) Phthalate (DEHP) in Mouse Cerebral Cells Involves an Impairment in Aryl Hydrocarbon Receptor (AhR) Signaling

Di-(2-ethylhexyl) phthalate (DEHP) is used as a plasticizer in various plastic compounds, such as polyvinyl chloride (PVC), and products including baby toys, packaging films and sheets, medical tubing, and blood storage bags. Epidemiological data suggest that phthalates increase the risk of the nervous system disorders; however, the impact of DEHP on the brain cells and the mechanisms of its action have not been clarified. The aim of the present study was to investigate the effects of DEHP on production of reactive oxygen species (ROS) and aryl hydrocarbon receptor (AhR), as well as Cyp1a1 and Cyp1b1 mRNA and protein expression in primary mouse cortical neurons and glial cells in the in vitro mono-cultures. Our experiments showed that DEHP stimulated ROS production in both types of mouse neocortical cells. Moreover, the results strongly support involvement of the AhR/Cyp1A1 signaling pathway in the action of DEHP in neurons and glial cells. However, the effects of DEHP acting on the AhR signaling pathways in these two types of neocortical cells were different. In neurons, AhR mRNA expression did not change, but AhR protein expression decreased in response to DEHP. A similar trend was observed for Cyp1a1 and Cyp1b1 mRNA and protein expression. Failure to induce Cyp1a1 in neurons was confirmed by EROD assay. In primary glial cells, a decrease in AhR protein level was accompanied by a decrease in AhR mRNA expression. In glial cells, mRNA and protein expression of Cyp1a1 as well as Cyp1a1-related EROD activity were significantly increased. As for Cyp1b1, both in neurons and glial cells Cyp1b1 mRNA expression did not significantly change, whereas Cyp1b1 protein level were decreased. We postulate that developmental exposure to DEHP which dysregulates AhR/Cyp1a1 may disrupt defense processes in brain neocortical cells that could increase their susceptibility to environmental toxins.

The effects of leptin on plasma concentrations of prolactin, growth hormone, and melatonin vary depending on the stage of pregnancy in sheep1

The effects of hyperleptinemia and leptin resistance during gestation are unclear. Leptin, an important neuroendocrine regulator, has anorexic effects, but its interactions with other metabolic hormones during pregnancy are unclear. We examined potential roles of leptin in regulating prolactin (PRL), GH, and melatonin plasma concentrations during pregnancy in Polish Longwool ewes. Twelve estrus-synchronized ewes carrying twins after mating were randomly assigned to receive i.v. injections of saline or recombinant ovine leptin (2.5 or 5.0 µg/kg BW). Blood samples were collected (15-min intervals over 4 h) immediately before the first injection at dusk and kept under red light. Treatments were repeated at 2-wk intervals, starting before mating and continuing from days 30 to 135 of gestation. Concentrations of plasma PRL, GH, and melatonin were determined using a validated RIA. The effects of leptin on hormone plasma concentrations varied depending on pregnancy stage and leptin dose. PRL plasma concentrations were affected at most stages of pregnancy and before gestation. In non-, very early- (day 30), and late- (day 120 and 135) pregnant ewes, exogenous leptin stimulated PRL (P < 0.001) plasma concentrations, while during the second month of gestation, it decreased PRL concentrations (P < 0.01). Leptin affected GH plasma concentrations (P < 0.05) only during the first 2 mo of pregnancy, with no effects during the second part of gestation or before pregnancy. In early-pregnant ewes (day 30 and 45), leptin decreased melatonin plasma concentrations (P < 0.05), but at day 60, leptin stimulated melatonin plasma concentrations at low (P < 0.01) and high doses (P < 0.05), with no effects in ewes after 105 d of gestation. These data indicate specific pregnancy-induced endocrine adaptations to changes in energy homeostasis, supporting the hypothesis that leptin affects PRL, GH, and melatonin release during gestation.

Induction of the Secretion of LH and GH by Orexin A and Ghrelin is Controlled in Vivo by Leptin and Photoperiod in Sheep

Abstract The influence of leptin on orexin A and the interaction of leptin with ghrelin in regulating the gonadotropic and somatotropic axes in seasonally polyestrous animals are not well understood. This study examined the effects of these factors as well as the mediating roles of specific ovine leptin antagonist (SOLA; mutant D23L/L39A/D40A/F41A) and photoperiod on luteinizing hormone (LH) and growth hormone (GH) secretion. Twenty-four ovariectomized, estradiol-implanted ewes were used in a replicated switchback design. The ewes were assigned randomly to 1 of 6 treatments (infused into the third ventricle 3 times at 0 (dusk), 1, and 2 h) as follows: control, Ringer-Locke buffer; leptin, 0.5 μg/kg b.w.; orexin A, 0.3 μg/kg b.w.; ghrelin, 2.5 μg/kg b.w.; SOLA, 50 μg/kg b.w. + orexin A, 0.3 μg/kg b.w.; and SOLA, 50 μg/kg b.w. + ghrelin, 2.5 μg/kg b.w. Blood samples (5 ml) were collected at 15-min intervals for 4 h. SOLA + orexin A resulted in an increase (P<0.01) in the LH plasma concentration during short-day (SD) and long-day (LD) photoperiods. However, ghrelin and SOLA + ghrelin had the opposite effect. SOLA + orexin A resulted in an increase (P<0.001) in the GH concentration compared with leptin or orexin A during the LD season. Ghrelin and SOLA + ghrelin increased the GH concentration (P<0.01) regardless of the season. In summary, LH and GH secretion are seasonally dependent on relationships that are subject to photoperiodic regulation, and leptin is an important regulator of the effects of ghrelin and orexin A on the activities of the gonadotropic and somatotropic axes in sheep.