Pyroglutamyl peptidase II (PPII), a highly specific membrane-bound metallopeptidase that inactivates TRH in the extracellular space, is tightly regulated by thyroid hormone in cells of the anterior pituitary. Whether PPII has any role in the region where axons containing hypophysiotropic TRH terminate, the median eminence, is unknown. For this purpose, we analyzed the cellular localization and regulation of PPII mRNA in the mediobasal hypothalamus in adult, male rats. PPII mRNA was localized in cells lining the floor and infralateral walls of the third ventricle and coexpressed with vimentin, establishing these cells as tanycytes. PPII mRNA extended in a linear fashion from the tanycyte cell bodies in the base of the third ventricle to its cytoplasmic and end-feet processes in the external zone of the median eminence in close apposition to pro-TRH-containing axon terminals. Compared with vehicle-treated, euthyroid controls, animals made thyrotoxic by the i.p. administration of 10 microg L-T(4) daily for 1-3 d, showed dramatically increased accumulation of silver grains in the mediobasal hypothalamus and an approximately 80% increase in enzymatic activity. PPII inhibition in mediobasal hypothalamic explants increased TRH secretion, whereas i.p. injection of a specific PPII inhibitor increased cold stress- and TRH-induced TSH levels in plasma. We propose that an increase in circulating thyroid hormone up-regulates PPII activity in tanycytes and enhances degradation of extracellular TRH in the median eminence through glial-axonal associations, contributing to the feedback regulation of thyroid hormone on anterior pituitary TSH secretion.
This review presents the findings that led to the discovery of TRH and the understanding of the central mechanisms that control hypothalamus-pituitary-thyroid axis (HPT) activity. The earliest studies on thyroid physiology are now dated a century ago when basal metabolic rate was associated with thyroid status. It took over 50 years to identify the key elements involved in the HPT axis. Thyroid hormones (TH: T 4 and T 3 ) were characterized first, followed by the semi-purification of TSH whose later characterization paralleled that of TRH. Studies on the effects of TH became possible with the availability of synthetic hormones. DNA recombinant techniques permitted the identification of all the elements involved in the HPT axis, including their mode of regulation. Hypophysiotropic TRH neurons, which control the pituitary-thyroid axis, were identified among other hypothalamic neurons which express TRH. Three different deiodinases were recognized in various tissues, as well as their involvement in cell-specific modulation of T 3 concentration. The role of tanycytes in setting TRH levels due to the activity of deiodinase type 2 and the TRH-degrading ectoenzyme was unraveled. TH-feedback effects occur at different levels, including TRH and TSH synthesis and release, deiodinase activity, pituitary TRH-receptor and TRH degradation. The activity of TRH neurons is regulated by nutritional status through neurons of the arcuate nucleus, which sense metabolic signals such as circulating leptin levels. Trh expression and the HPT axis are activated by energy demanding situations, such as cold and exercise, whereas it is inhibited by negative energy balance situations such as fasting, inflammation or chronic stress. New approaches are being used to understand the activity of TRHergic neurons within metabolic circuits. A historical perspective on the hypothalamic control of the thyroid axisThe advancement of any scientific field requires the combination of creative new ideas with the development of technologies and knowledge in related areas; understanding the function of the hypothalamus-pituitarythyroid axis (HPT) is no exception (Figs 1 and 2). Since the end of the 19th century, European physicians and surgeons associated neck swelling (thyroid enlargement, goiter), with iodine deficiency, cretinism, and myxoedema, This paper is part of a thematic review section on 60 years of neuroendocrinology. The Guest Editors for this section were Ashley Grossman and Clive Coen defining hypothyroid conditions. Magnus-Levy (1895) was the first to demonstrate that respiratory metabolism was increased in hyperthyroidism and decreased in myxoedema. Indirect calorimetry allowed measurements of basal metabolic rate (BMR) and the evaluation of thyroid activity in clinical practice (Du Bois & Du Bois 1915, Harris & Benedict 1918. Soon it was recognized that stressful conditions such as fever, acidosis, or starvation modify BMR (Rowe 1920). In 1919, levothyroxine (3,3 0 ,5,5 0 -tetraiodothyronine or T 4 ) was characterized, and then ...
Thyrotropin releasing hormone (TRH) is released from the median eminence in response to neural stimuli evoked by different physiologic conditions (i.e. cold stress or suckling). The paraventricular nucleus (PVN) synthesizes pro-TRH and responds to negative thyroid hormone feedback. With the aim of determining if TRH biosynthesis is regulated in coordination with its release, we quantified TRH mRNA levels in PVN and in preoptic area-anterior hypothalamus (POA-AH) of rats sacrificed at different times during cold (0.5, 1,2 or 6 h) or suckling (15, 30 and 60 min) stimulus; TRH-like immunoreactivity (TRH-LI) in medial basal hypothalamus (MBH) and in POA-AH as well as corticosterone, triiodothyronine and prolactin levels in serum were also measured. Increases of serum hormones were observed in both paradigms as has been reported. MBH TRH-LI content decreased during suckling by 33% (p < 0.01) after 1 h, but did not change after cold stimulation. At short stimulation times, PVN TRH mRNA levels were 85% (30 min of suckling) and 97% (1 h in the cold) higher than their respective controls, decreasing to normal after 1-2 h. In the POA-AH, another TRH synthesizing region not involved in TRH hypophysiotropic function, a similar transient enhancement of TRH mRNA (146%) was observed only in cold stimulated animals after 30 min, consistent with its suggested role in thermogenesis. These results show a fast and transient response of TRH mRNA in PVN evoked by a neural stimulus.
The hypothalamic-pituitary thyroid (HPT) axis modulates energy homeostasis. Its activity decreases in conditions of negative energy balance but the effects of chronic exercise on the axis are controversial and unknown at hypothalamic level. Wistar male rats were exposed for up to 14 days to voluntary wheel running (WR), or pair-feeding (PF; 18% food restriction), or to repeated restraint (RR), a mild stressor. WR and RR diminished food intake; body weight gain decreased in the 3 experimental groups, but WAT mass and serum leptin more intensely in the WR group. WR, but not RR, produced a delayed inhibition of central markers of HPT axis activity. At day 14, in WR rats paraventricular nucleus-pro-TRH mRNA and serum TSH levels decreased, anterior pituitary TRH-receptor 1 mRNA levels increased, but serum thyroid hormone levels were unaltered, which is consistent with decreased secretion of TRH and clearance of thyroid hormones. A similar pattern was observed if WR animals were euthanized during their activity phase. In contrast, in PF animals the profound drop of HPT axis activity included decreased serum T3 levels and hepatic deiodinase 1 activity; these changes were correlated with an intense increase in serum corticosterone levels. WR effects on HPT axis were not associated with changes in the activity of the hypothalamic-pituitary adrenal axis, but correlated positively with serum leptin levels. These data demonstrate that voluntary WR adapts the status of the HPT axis, through pathways that are distinct from those observed during food restriction or repeated stress.
A suitable preparation to study the effect of dopamine (DA) on in vitro LHRH secretion is presented. Enzymatic degradation of LHRH in the incubation medium is completely inhibited by bacitracin (2 X 10(-5) M). Ahigh potassium concentration (56mM) induces an increase in LHRH release from entire pieces of mediobasal hypothalamus (MBH), but not from a synaptosomal pellet; this release is inhibited when calcium is omitted. The depolarization-induced LHRH in the MBH. In contrast, DA (10(-6)M) is not effective in vitro on MBH from ovariectomized rats but induces a fast release of LHRH from MBH of normal male and estradiol-pretreated ovariectomized rats. The preparation presented here appears to be of great interest in investigating amine-steroid-LHRH interactions at the cellular level.
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