Advances in fluorescent calcium indicating dyes over the past decade have identified calcium signaling as the tool by which astrocytes communicate among themselves and with neighboring neurons. Studies of astrocyte-neuron interactions have shown that calcium signaling is a potent modulator of the strength of both excitatory and inhibitory synapses. The concept that astrocytes possess a mechanism for rapid cell communication has not been incorporated, however, into the supportive functions of astrocytes. Because many of the classical tasks of astrocytes are linked to the blood-brain barrier, we have here examined the expression of proteins required for calcium signaling in their vascular end-foot processes. The gap junction protein, Cx43, was expressed intensively around the vessels interconnecting astrocytic end-foot processes. These gap junctions permitted diffusion of Lucifer yellow, specifically along the path of glial end feet apposed to the vessel wall. The purinergic receptors, P2Y(2) and P2Y(4), were also strongly expressed at the gliovascular interface and colocalized with GFAP around larger vessels in cortex. Multiphoton imaging of freshly prepared brain slices loaded with Fluo-4/AM revealed that ATP mobilized cytosolic calcium in astrocytic end feet, whereas electrical stimulation triggered calcium waves propagating along the vessel wall. Brain endothelial cells and pericytes were physically separated from astrocytes by the basal lamina and responded only weakly to ATP. These observations identify astrocytic end-foot processes plastered at the vessel wall as a center for purinergic signaling. It is speculated that calcium signaling may play a role in astrocytic functions related to the blood-brain barrier, including blood flow regulation, metabolic trafficking, and water homeostasis.
A single injection of estradiol valerate (EV) produces anovulatory acyclicity and polycystic ovaries (PCO) in the rat. Basal serum luteinizing hormone (LH) concentrations are attenuated whereas serum follicle stimulating-hormone (FSH) concentrations are in the high normal range in these animals. Subsequent unilateral ovariectomy restores ovulatory cycles and normal histology in the remaining ovary without correcting the aberrant basal serum gonadotropin concentrations. This suggests that although the blocked surge mechanism is correctable, a second relatively intractable, ovary-independent impairment compromises basal gonadotropin production. To identify and characterize this second component, we have examined hypothalamic-pituitary function in PCO rats after bilateral ovariectomy. Adult (200-250 g), normal cyclic Wistar rats were injected with 2 mg EV or with vehicle (control). Nine weeks later all animals were ovariectomized and PCO was confirmed in the EV-treated animals. Animals were killed at 0, 2, 7, 14, and 28 days after ovariectomy, and hypothalamic content of luteinizing hormone-releasing hormone (LHRH) and pituitary and serum concentrations of LH and FSH were measured. LH and FSH responses to exogenous LHRH were assessed. Serum progesterone, testosterone, and estradiol concentrations were determined at 28 days. Hypothalamic LHRH decreased significantly in all animals over the 28-day period. Although LHRH values did not differ at Time 0, by 28 days there was significantly less LHRH in the hypothalami of control than in PCO rats. This pattern of depletion was mirrored by corresponding reciprocal patterns of increasing serum gonadotropin concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)
Abstract. Pituitary thyrotrope tumours are a rare cause of hyperthyroidism. Prior in vitro studies of these tumours have revealed various patterns of differentiation and secretory activity. We have characterized the histological, biochemical, molecular and physiological features of a thyrotrope adenoma in order to define its origin and autonomy. Histochemical and electron micrograph findings confirmed the diagnosis of a thyrotrope cell adenoma. Immunostaining was positive for TSH and GH in the cytoplasm of the adenoma cells. Tissue extracts contained TSH-IR which co-eluted with authentic hTSH when analysed by gel filtration. Tumour fragments studied in a tissue culture system secreted TSH, α-subunit and GH. TRH (30 nmol/l) stimulated TSH and GH secretion. T3 (1.5 nmol/l) inhibited GH release and had no effect on TSH secretion. GnRH (50 nmol/l), dexamethasone (10−4 mol/l), SRIH (1 μmol/l) and TRH-glycine, a tetrapeptide precursor of TRH, stimulated TSH release. Dexamethasone inhibited GH and α-subunit secretion. Stable transcripts for α- and β-subunits of TSH and GH messenger RNAs were detected by molecular hybridization in cytosolic fractions. Immunohistochemistry, in vitro secretory function, and mRNA analysis suggest multidirectional differentiation of the tumour cells. TRH-glycine may have a direct stimulatory effect upon pituitary thyrotropes.
In the present study we have examined the in vivo effects of thyroid hormone and TRH on secretory tissue concentrations of TRH and TRH-Gly (pGlu-His-Pro-Gly), a TRH precursor. Within secretory granules, TRH-Gly is converted to TRH through alpha-amidation of the C-terminal proline residue, using Gly as the NH2 donor. Using specific RIA, we measured the TRH-Gly immunoreactivity (TRH-Gly-IR) and TRH-IR concentrations in tissues from the reproductive and gastrointestinal systems, adrenals, and other internal organs in euthyroid, hypothyroid, and T4-treated 250-g Sprague-Dawley male rats. TRH-Gly-IR concentrations were more than 2-fold higher than TRH-IR concentrations within the adrenal, pancreas, bowel, and stomach at the time of death. Untreated hypothyroidism and exogenous TRH significantly increased adrenal TRH-Gly-IR levels. Pancreatic TRH-Gly levels increased about 2-fold in hypothyroid rats. Incubation at 60 C significantly increased TRH-Gly-IR levels in the pancreas, adrenal, bowel, stomach, and epididymis by 14-, 3-, 6-, 6-, and 6-fold, respectively. Also after 60 C incubation increases in the TRH-Gly-IR/TRH-IR ratio of 2.7-, 4-, and 1.7-fold were observed in the pancreas, epididymis, and bowel, respectively. Pooled tissue extracts were fractionated by cation exchange and reverse phase HPLC for characterization of TRH-Gly-IR. Both chromatographic methods revealed a major peak of TRH-Gly-IR coeluting with synthetic TRH-Gly. Incubation at 60 C caused 13.5-, 4.1-, 1.5-, and 5-fold increments in the TRH-Gly-IR for adrenal, pancreas, prostate, and thyroid, respectively, compared to the immediately extracted control aliquots. Cation exchange and reverse phase HPLC also revealed production of higher mol wt TRH precursor peptides after incubation at 60 C for 4 or 20 h. Only the TRH-Gly-IR peak coeluting with pGlu-His-Pro-Gly was converted into TRH by rat brain alpha-amidating enzyme. The data suggest that biosynthesis of TRH occurs in rat extrahypothalamic tissues and may be modulated by thyroid status, iv TRH, and selective thermal inactivation of enzymes that convert prepro-TRH to TRH.
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