A screen for modulators reveals that orexin-A rapidly stimulates thyrotropin releasing hormone expression and release in hypothalamic cell culture.

In the paraventricular nucleus of the mammalian hypothalamus, hypophysiotropic thyrotropin releasing hormone (TRH) neurons integrate metabolic information and control the activity of the thyroid axis. Additional populations of TRH neurons reside in various hypothalamic areas, with poorly defined connections and functions, albeit there is evidence that some may be related to energy balance. To establish extracellular modulators of TRH hypothalamic neurons activity, we performed a screen of neurotransmitters effects in hypothalamic cultures. Cell culture conditions were chosen to facilitate the full differentiation of the TRH neurons; these conditions had permitted the characterization of the effects of known modulators of hypophysiotropic TRH neurons. The major end-point of the screen was Trh mRNA levels, since they are generally rapidly (0.5-3h) modified by synaptic inputs onto TRH neurons; in some experiments, TRH cell content or release was also analyzed. Various modulators, including histamine, serotonin, ß-endorphin, met-enkephalin, and melanin concentrating hormone, had no effect. Glutamate, as well as ionotropic agonists (kainate and N-Methyl-d-aspartic acid), increased Trh mRNA levels. Baclofen, a GABAB receptor agonist, and dopamine enhanced Trh mRNA levels. An endocannabinoid receptor 1 inverse agonist promoted TRH release. Somatostatin increased Trh mRNA levels and TRH cell content. Orexin-A rapidly increased Trh mRNA levels, TRH cell content and release, while orexin-B decreased Trh mRNA levels. These data reveal unaccounted regulators, which exert potent effects on hypothalamic TRH neurons in vitro.

The systemic inhibition of nitric oxide production rapidly regulates TRH mRNA concentration in the paraventricular nucleus of the hypothalamus and serum TSH concentration. Studies in control and cold-stressed rats.

Neurons of the paraventricular nuclei of the hypothalamus (PVN) that synthesize the peptide thyrotropin releasing hormone (TRH) control energy homeostasis. Identifying the circuits which regulate these neurons is critical to fully understand integration of metabolic information and the mechanisms that set thyroid hormone levels. We tested the hypothesis that nitric oxide (NO) acutely controls PVN TRH expression and thyrotropin (TSH) secretion by the anterior pituitary. The subcutaneous treatment of rats with N(G)-nitro-L-arginine methyl ester (L-NAME), an inhibitor of NO synthases, enhanced PVN TRH mRNA and medio-basal hypothalamic TRH levels, and reduced serum TSH concentration. Analysis of the effect of a NO donor in primary cultures of hypothalamic or anterior pituitary cells suggested that the effect of NO includes a direct action on hypothalamic neurons. The cold stress-induced increase in TSH release was inhibited by sc L-NAME. Therefore, production of NO may control the activity of the hypothalamus-pituitary-thyroid axis.

An improved method for the expression of TRH in serum-supplemented primary cultures of fetal hypothalamic cells.

Primary cultures of dispersed cells from fetal nervous tissue are extensively used for studying multiple neuronal properties. Analyses of the developmental expression of thyrotropin releasing hormone (TRH; pglu-his-pro-NH(2)) biosynthesis in primary cultures of fetal dissociated hypothalamic cells have shown that cellular TRH levels per dish increase with time in culture, after a lag period of a few days, but do not attain the values observed in vivo, hampering its use as a model system for the study of peptide biosynthesis and release. We have demonstrated that homologous conditioned medium (CM) enhances TRH expression in dissociated cell cultures from fetal mice hypothalamus, maintained in presence of serum. We report here experimental conditions that allow the expression, during the second or third week in vitro, of higher cellular TRH levels than previously described in primary cultures of dissociated hypothalamic cells from 17-day rat fetuses. The medium used was Dulbecco's Modified Eagle Medium (DMEM) supplemented with fetal bovine serum (10%), vitamins, glucose, glutamine and insulin (DMEM-S). Cellular levels of TRH/mg protein increased with cell density between 1 and 2.7x10(6) cells per 35-mm dish. Addition of 10(-5) M cytosine arabinoside (CAr) at the 4th day in vitro (DIV) improved TRH cell content per dish compared to addition at 5 DIV; 2.5-5x10(-5) M bromodeoxyuridine added at seeding reduced cell survival and did not enhance TRH levels, in comparison to CAr-treated cultures. Addition of ascorbic acid (0.5-1x10(-4) M) increased TRH levels per dish. Substitution of DMEM by DMEM-F12 (1:1) did not improve TRH levels. Cellular levels of TRH, in Neurobasal plus B27 (a serum-free medium), were similar to levels in serum-supplemented media. In the optimized conditions, a small number of pro-TRH mRNA expressing cells (2% of total cells) was detected by in situ hybridization; 40% coexpressed the pro-protein convertase PC1 mRNA. Conditioning the medium, controlling glial proliferation, and adding ascorbic acid improved the expression of TRH in primary culture of hypothalamic cells in DMEM-S.