Plasma leptin concentrations during extended fasting and graded glucose infusions: relationships with changes in glucose, insulin, and FFA.

Despite numerous studies, the in vivo regulation of plasma leptin levels in response to nutritional factors continues to remain unclear. We investigated temporal and dose-response relationships of plasma leptin in response to physiological changes in insulin/glucose. After an overnight fast of 10 h, lean, healthy subjects were investigated for an additional 16 h of either extended fasting or one of three levels of glycemia/insulinemia induced by stepwise increasing iv glucose infusions. During extended fasting, plasma leptin values declined steadily and significantly. Plasma leptin levels remained constant at glucose concentrations between 5.8-6.5 mmol/liter, which maintained normoinsulinemia at 41.5-45.4 pmol/liter and FFA at 106-123 mg/liter, but leptin concentrations were increased at higher rates of glucose infusion (with plasma glucose rising to 8.7 mmol/liter). Concentrations of serum leptin were inversely related to FFA levels during extended fasting and at all levels of glycemia. Our data indicate that in lean healthy subjects, physiological changes in glycemia and insulinemia significantly alter plasma FFA and leptin concentrations. The increases in leptin concentrations demonstrate dose-dependent relationships that appear to relate to changes in FFA levels as well as to changes in glycemia/insulinemia.

Relationships of plasma leptin levels to changes in plasma free fatty acids in women who are lean and women who are abdominally obese.

Regulation of leptin production by the hormonal and metabolic milieu is poorly understood. Because abdominal obesity is commonly associated with elevated plasma free fatty acid (FFA) flux, we examined the effects of augmenting FFA on plasma leptin levels in women who were lean and of suppressing FFA in women with abdominal obesity. In study 1, nine subjects who were lean, after a 12-hour overnight fast, received either intravenous saline or Intralipid plus heparin to increase the plasma FFA concentration to approximately 1000 mumol/ L. After 3 hours of additional fasting, subjects underwent 3-hour hyperglycemic clamps. In study 2, seven subjects with abdominal obesity were evaluated by a similar protocol, but lipolysis and plasma FFA flux were instead maximally suppressed by acipimox. In the individuals who were lean, leptin levels were unchanged during clamping. Increasing plasma FFA reduced plasma leptin from 7.66 +/- 0.66 to 7.05 +/- 0.66 (p = 0.03), but 3 hours of hyperglycemia plus hyperinsulinemia had no additional effect on leptin levels (7.15 +/- 0.71). Basal leptin levels, 4-fold higher in the subjects with obesity, were reduced from 34.6 +/- 2.4 micrograms/L to 32.3 +/- 1.1 micrograms/L (p = 0.004) during the clamp period. When plasma FFA flux was suppressed, however, plasma leptin levels after clamped hyperglycemia/hyperinsulinemia were increased to 38.9 +/- 1.2 micrograms/L (p = 0.014 vs. time 0 and 0.001 vs. saline protocol). Changes in leptin concentrations are not correlated with changes in FFA. These results suggest that plasma FFA concentration does not regulate plasma leptin levels in basal, extended fasting, or hyperglycemic/hyperinsulinemic states.

Leptin: a significant indicator of total body fat but not of visceral fat and insulin insensitivity in African-American women.

The recently cloned adipose tissue hormone leptin has been proposed to be involved in the neuroendocrine regulation of adiposity and its metabolic sequelae. Visceral fat is known to predict reduced insulin sensitivity and associated adverse metabolic profiles. In this study, we report the first evaluation of the relationships between leptin levels and total body fat, visceral fat, and insulin sensitivity in a cohort of premenopausal African-American women. Thirty-four subjects were analyzed for total fat mass and visceral fat by dual-energy X-ray absorptiometry and computerized axial tomography, respectively. Insulin sensitivity (SI) was assessed using Bergman's minimal model. Results showed that fasting leptin levels strongly correlated with total body fat mass (r = 0.797, P < 0.001). Correlations of leptin with visceral fat (r = 0.54, P < 0.001) and SI (r = -0.419, P = 0.02) were dependent on total body fat. In conclusion, leptin levels reflect total body fat mass, and although visceral fat is known to predict reduced insulin sensitivity independently, leptin did not. Our data thus suggest that diverse mechanisms are responsible for the regulation of total body versus visceral fat distribution, with its metabolic and health risks.

Reversible thioridazine-induced magnetic resonance imaging-documented pituitary enlargement associated with hyperprolactinemia.

OBJECTIVE: To document a case of reversible thioridazine-induced pituitary enlargement associated with hyperprolactinemia in a patient with schizophrenia. METHODS: We describe a 19-year-old woman with paranoid schizophrenia who was taking thioridazine (a phenothiazine), in whom hyperprolactinemia, galactorrhea, oligomenorrhea, and a reversible anatomic pituitary abnormality developed. Serial magnetic resonance imaging (MRI) studies were used to assess the status of the pituitary gland during various pharmaceutical therapies. RESULTS: Laboratory evaluation revealed increased serum prolactin (PRL) levels that ranged from 76 to 135 mg/L. Results of thyroid function tests were normal, and gonadotropins and estradiol levels were low, consistent with hyperprolactinemia. MRI revealed asymmetric enlargement of the right side of the pituitary gland. Discontinuing the thioridazine therapy resulted in normalization of the serum PRL and resolution of the pituitary abnormality. Subsequent worsening of the patient's psychiatric condition necessitated a course of electroconvulsive therapy and initiation of treatment with clozapine, a D4 dopamine receptor antagonist. At 1-year follow-up, at which time the patient was maintained on clozapine and was not taking thioridazine, both serum PRL levels and MRI findings remained normal. CONCLUSION: Our patient was shown to have asymmetric pituitary enlargement associated with thioridazine-induced hyperprolactinemia, which reversed when use of the drug was discontinued. In patients with serum PRL levels in excess of 100 mg/L during antipsychotic drug therapy, evaluation for a prolactinoma is warranted.

Dynamics of prolactin secretion from diethylstilbestrol-induced rat prolactinoma tissue in vitro.

Experiments were performed to determine whether PRL secretion in the rat diethylstilbestrol (DES)-induced prolactinoma model is affected by the addition of thyrotropin-releasing hormone (TRH) and/or immunoneutralization of intrapituitary vasoactive intestinal polypeptide (VIP) in vitro. Male Fischer 344 rats were implanted with either a 10 mg DES or placebo pellet 30 days prior to obtaining the anterior pituitary glands for perifusion. The anterior pituitaries were quartered and used in three different perifusion experiments. In Experiment I, placebo-treated tissue channels were perifused for 2 baseline hr followed consecutively by a 30-min exposure to 1:100 nonimmune rabbit serum (NRS), a 30-min wash, and a final 30-min exposure to 10(-5) M TRH. Additional placebo channels were run as above except 1:100 VIP antiserum (AVIP) was substituted for NRS and AVIP was added to the TRH. In Experiment II, the same perifusion protocol was used as in Experiment I, except DES-induced tumor tissue was used instead of placebo tissue. Results from Experiment I and II reveal that AVIP significantly decreased PRL secretory rate in both DES and placebo groups. In the tumor group, both TRH alone and in the presence of AVIP significantly increased the PRL secretory rate. In Experiment III DES-induced tumor tissue channels were perifused with a similar protocol, except the concentrations of NRS and AVIP were increased to 1:10. Both NRS and AVIP significantly decreased PRL secretory rate; however, AVIP had a significantly greater effect than NRS. In this experiment, 1:10 AVIP overcame the stimulatory effect of TRH. In conclusion, AVIP decreases and TRH increases, even in the presence of AVIP, PRL release in DES-induced prolactinoma tissue in vitro. Increasing the AVIP concentration 10-fold diminished the PRL-releasing action of TRH in the tumor tissue. These data suggested that PRL secretion is not autonomous in these prolactinomas and can be affected by exogenous TRH and partial immunoneutralization of endogenous VIP.

Vasoactive intestinal polypeptide antiserum affects rat prolactin mRNA in 40-day but not 110-day diethylstilbestrol-induced prolactinoma tissue.

Experiments were designed to examine whether vasoactive intestinal polypeptide (VIP), a known stimulator of basal prolactin (PRL) secretion, regulates PRL gene expression in the rat diethylstilbestrol (DES)-induced prolactinoma model. The VIP-induced increase in PRL release could result from increased PRL synthesis and/or decreased PRL degradation. Male Fischer 344 rats were implanted with 10 mg DES pellets 40 or 110 days prior to obtaining the anterior pituitary glands for cell dispersal. Cells were incubated in 1:10 normal rabbit serum or VIP antiserum (AVIP). After incubation, cells were pelleted, washed, and pooled for total nucleic acid extraction. The rat PRL (rPRL) mRNA abundance was quantitated using a solution hybridization/ribonuclease protection assay. Supernatant was collected and analyzed for PRL content using radioimmunoassay. Results from this experiment reveal partial immunoneutralization of intrapituitary VIP significantly decreased PRL secretory rate by rapid reduction in rRPL mRNA in the 40-day tumors. However, in the 110-day tumors the rPRL mRNA steady-state levels were unchanged but the basal release of PRL continued to be decreased by AVIP. These results indicate VIP exerts its effects on PRL secretion through at least two mechanisms.

Vasoactive intestinal polypeptide and thyrotropin-releasing hormone stimulate newly synthesized, not stored, prolactin.

Experiments were designed to determine whether vasoactive intestinal polypeptide (VIP), reported to stimulate basal PRL secretion, affects PRL processing by lactotrophs. Initially, rat anterior pituitary quarters were incubated for 2 h with [3H]leucine, with and without 10(-5) M VIP, and immunoreactive and immunoprecipitable rPRL were measured during 56 mM KCl perifusion to determine total and 3H-labeled PRL, respectively. Inclusion of VIP increased immunoreactive PRL (P less than 0.05), decreased immunoprecipitable PRL (P less than 0.01), and, therefore, decreased the specific activity of labeled PRL (P less than 0.001). These results suggested an enhanced release of newly synthesized PRL before KCl depolarization, thus decreasing the release of labeled PRL. To discriminate between the two PRL pools, newly synthesized and storage, pituitary quarters were incubated with and without 10(-5) M VIP for 4 h with [14C]leucine, 2 h in cold medium and 2 h with [3H]leucine. Immunoprecipitable PRL was measured during perifusion with 56 mM KCl. Data were depicted as the 3H/14C disintegrations per min ratio of PRL released/3H/14C disintegrations per min of total tissue to account for any differences in tissue labeling. This ratio was greater for tissue labeled in the presence of VIP (P less than 0.002). To determine whether VIP, as a secretagogue, differentiates between the newly synthesized and storage pools, VIP was added after pulse chase, as previously described. No preferential release was observed between the two groups. Finally, using the same [3H]- and [14C]leucine-labeling protocol with and without 10(-5) M VIP, tissue was perifused with medium 199 for 1 h, with 10(-5) M TRH for 30 min, with medium 199 for 30 min, and with 56 mM KCl for 1 h. Inclusion of VIP increased the 3H/14C released/3H/14C total tissue ratio during basal perifusion (P less than 0.04) and TRH exposure (P less than 0.05). Within the control group, the TRH ratio was greater than basal (P less than 0.003). These experiments suggest that newly synthesized PRL is preferentially secreted over stored PRL from tissue incubated with VIP during pulse-chase labeling; however, addition of VIP as a secretagogue did not affect either PRL pool preferentially.