Elevation of calcitonin immunoreactivity in the pituitary and thyroid glands of genetically obese rats (fa/fa)

A high-fat diet increases calcitonin secretion in the rat

We have studied the effects of diet-induced obesity on thyroidal calcitonin, plasma calcitonin, calcium and phosphorus in rats. Twelve 9-week-old female rats were randomly divided into two groups. One group was fed a low-fat diet while the other was fed a high-fat diet. Both diets had 0.76% Ca, 0.56% P and 2.2 U/g vitamin D; however, the high-fat diet had hydrogenated vegetable oil added at 405 g/kg. All rats were pair-fed and consumed 11 g/day per rat for 27 weeks at which time the rats were fasted overnight and exsanguinated. The rats on the high-fat diet weighted 406 +/- 21 g (mean +/- SEM) versus 292 +/- 13 g for controls and had higher levels of serum calcitonin (104 +/- 12 versus 57 +/- 9 pg/ml). The obese rats also had increased thyroidal calcitonin by radioimmunoassay and increased thyroidal C-cells by immunohistology. The increased calcitonin levels occurred without a concomitant increase in calcium levels. These data indicate that a high-fat diet in rats stimulates C-cell growth and calcitonin secretion.

Calcium/calmodulin-mediated action of calcitonin on lipid metabolism in rats

The effects of calcitonin on lipid metabolism were investigated in three kinds of rats, one strain of rabbits, and a primary culture of rat hepatocytes. In a short-term experiment, calcitonin decreased serum cholesterol and triglycerides after injection in rats on either an ordinary or high-fat diet. In a long-term experiment, calcitonin decreased the serum cholesterol and triglycerides in uremic rats, hypothalamic obese rats, and Watanabe-heritable hyperlipidemic rabbits. In cultured hepatocytes, calcitonin reduced the incorporation of [14C]acetate into cholesterol and triglycerides in a dose-dependent way. Treatment with W7, a calmodulin inhibitor, overcame the decrease caused by calcitonin in serum lipids in rats and in the synthesis of triglycerides from acetate or palmitate in the hepatocytes, but did not alter the intracellular cAMP level or incorporation of [32P]Pi into PI in the cells. The results suggest that calcitonin lowers serum lipid levels and lipogenesis in hepatocytes in a calcium/calmodulin-dependent way.

Pituitary cells secrete calcitonin in the reverse hemolytic plaque assay

Rat pituitary cells were evaluated in the reverse hemolytic plaque assay for calcitonin (CT) secretion. The secretion of CT could be demonstrated by the formation of hemolytic plaques around single pituitary cells when a specific CT antibody was used. Approximately 0.1 percent of the cells secreted CT in the basal state. Phorbol stimulated CT secretion by up to 25-fold. The diameter of the hemolytic plaques around pituitary cells from genetically obese (Zucker) rats was significantly greater than normal rats (24 versus 37 microns). This study demonstrates that pituitary cells secrete CT and that the secretion may be regulated by pharmacological agents (phorbol) and physiological signals (obesity).

Anatomical mapping of the rat hypothalamus for calcitonin-induced anorexia

The primary physiological function of calcitonin, a peptide hormone secreted by the thyroid gland, is to modulate plasma calcium concentrations. Calcitonin also has several effects on the central nervous system including an inhibition of feeding behavior. In the present study synthetic salmon calcitonin (15 ng in 0.3 microliter) was found to produce a marked suppression of eating when infused in several hypothalamic areas. The greatest inhibition was produced by infusions into the paraventricular nucleus of the hypothalamus, the perifornical area and several areas on the floor of the hypothalamus. A less marked inhibition of eating was produced by infusions in the nucleus accumbens. Infusions in the olfactory tubercule, the ventrolateral hypothalamus, the medial forebrain bundle and the posterior nucleus of the hypothalamus had no effect. It is concluded that the anorectic effects of calcitonin on the central nervous system are mediated by several hypothalamic and extrahypothalamic sites.

Pituitary immunoreactive calcitonin-like material: lack of evidence for cross-reactivity with pro-opiomelanocortin

In mammals, calcitonin (CT) is synthesized, stored, and secreted by intrathyroidal C cells. Several reports have suggested the presence of immunoreactive CT in the pituitary gland. We have studied the rat pituitary gland using a radioimmunoassay for CT and have also found immunoreactive CT-like material. Assay of extracts of whole rat pituitary glands was performed using a radioimmunoassay for human CT, which gave identical dilution curves with synthetic human CT (hCT), synthetic rat CT (rCT), and mouse and rat thyroid extracts, but not with a variety of other pituitary and hypothalamic peptides. Immunoreactive CT (iCT) content of extracts of whole pituitary glands ranged from 6 to 72 pg/mg wet weight of tissue (60-840 pg/whole pituitary gland), whereas iCT was not measureable (less than 5 pg/mg tissue) in similar extracts of hypothalamus and cerebral cortex. Gel filtration studies of pituitary extracts showed a peak of iCT, which eluted with 125I-rCT and diluted in parallel with rCT. To investigate whether the pituitary iCT was related to pro-opiomelanocortin, extracts of ACTH-producing AtT20/D16 cells from mice, which contain the ACTH precursor in large quantities, were examined and no iCT was found. Immunohistochemical studies of rat pituitary glands with peroxidase-antiperoxidase and immunofluorescent techniques showed positive staining for CT in cells in the pars anterior, but not in the pars intermedia of pars nervosa; this staining was not eliminated when the antiserum was absorbed with CT under conditions that completely obliterated staining of rat thyroid glands. Double staining demonstrated essentially two distinct populations of cells, one positive for CT and another positive for ACTH, with less than 1% of the cells positive for both ACTH and CT. Immunoreactive CT-like material was present in the pituitary glands of rats thyroparathyroidectomized 18 days before they were killed, but was diminished. Biosynthetic labeling in vitro of rat pituitary glands with 3H-leucine showed incorporation into prolactin; there was no incorporation into CT. No in vitro secretion of iCT by whole rat pituitary glands either basally or after high K+ stimulation was observed. We conclude that: (1) a substance that has certain immunologic and size characteristics of CT is present in minute amounts in the pituitary gland of rats; (2) this material is not a part of the ACTH precursor; and (3) positive immunohistochemical staining in pituitary glands may not be specific for authentic CT.

Serum calcitonin, calcium and thyroxine in young and old Zucker fatty rats (fa/fa)

We determined the serum levels of calcitonin (CT), calcium (Ca), and thyroxine (Ti) in lean (?/+) and fatty (fa/fa) male Zucker rats 10 weeks and 10-12 months of age. The most dramatic finding was a high level of serum CT (3.24 +/- 1.18 ng/ml) in young fatties whereas sera from young leans were all below the limit of assay detection (less than 0.120 ng/ml, p less than 0.01). Young fat rats also had elevated levels of both Ca (11.2 +/- 0.2 vs. 9.7 +/- 0.2 mg/dl, p less than 0.001) and Ti (6.7 +/- 0.48 vs. 4.72 +/- 0.28 micrograms/dl, p less than 0.01). In older animals the mean serum level of CT increased further in the fatties and became readily measurable in leans (5.67 +/- 1.94 vs. 1.49 +/- 0.55, p less than 0.01). Thyroid C-cells, identified immunohistochemically, were abundant in both leans and fatties at this age but were substantially more numerous in the fat rats (p less than 0.001). Calcium levels increased somewhat in the older leans, but still remained higher in the fat rats (p less than 0.05). Thyroxine values were essentially the same for old animals of both genotypes (5.07 +/- 0.61 vs. 5.54 +/- 0.88). Age effects were not significant for any measure in the fat animals, but in the leans there were significant age-related increases in CT (p less than 0.02) and serum Ca (p less than 0.05).

Extraction of a substance with calcitonin-like immunoreactivity from pituitary glands of intact and thyroidectomized rats

We have previously demonstrated the presence of calcitonin (CT)-like immunoreactivity in the pituitary glands of a number of vertebrate species. Subsequent work by ourselves and others has confirmed this finding by immunohistology and radioimmunoassay (RIA) of pituitary extracts. However, no data have been reported on the site of biosynthesis of the CT-like pituitary peptide, or the relationship of pituitary levels of the substance to experimental alterations of systemic CT levels. In the present study, we measured the content of CT-like peptide in rat pituitaries by using gel filtration chromatography and an RIA, which recognizes rat and human calcitonin. The CT-like peptide has an elution position on gel filtration similar to that of rat and human calcitonin. Its RIA binding appears indistinguishable from that of rat thyroidal CT. Various conditions for extraction were evaluated, and homogenization in acetic acid at 100 degrees C gave the best results. The CT-like content of rat pituitaries was generally 75-125 pg/gland. Presence of CT-like peptide in rat pituitaries was not abolished by prior thyroidectomy. We conclude that the CT-like pituitary peptide is not synthesized in the thyroid, but is similar to thyroidal CT in the characteristics studied.

Calcitonin: regional distribution of the hormone and its binding sites in the human brain and pituitary

Immunoreactive calcitonin (CT), indistinguishable from human CT-(1-32) and its sulfoxide, has been identified in extracts of the hypothalamus, the pituitary, and the thyroid obtained from human subjects at autopsy. DCT concentrations were highest in a region encompassing the posterior hypothalamus, the median eminence, and the pituitary; intermediate in the substantia nigra, the anterior hypothalamus, the globus pallidus, and the inferior colliculus; and low in the caudate nucleus, the hippocampus, the amygdala, and the cerebral and cerebellar cortices. Specific CT binding measured with 125I-labeled salmon CT was highest in homogenates of the posterior hypothalamus and the median eminence, shown to contain the highest concentrations of endogenous CT in the brain; CT binding was less than 12% of hypothalamic binding in all of the other regions of the brain examined and was negligible in the pituitary. Half-maximal binding was achieved with 0.1 nM nonradioactive salmon CT-(1-32), and the binding was directed to structural or conformational sites, or both, in the COOH-terminal half of salmon CT. The rank order of the inhibition of the binding by CT from different species and analogues of the human hormone was the same as in receptors on a human lymphoid cell line (Moran, J., Hunziker, W. & Fischer, J. A. (1978) Proc. Natl. Acad. Sci. USA 75, 3984-3988). The functional role of CT and of its binding sites in the brain remains to be elucidated.

Presence of immunoreactive calcitonin in the hypothalamus and pituitary lobes of rats

We have found calcitonin-like immunoreactive material in extracts of hypothalami from six-month old, male rats. The level of this immunoreactivity, 0.21 ng/hypothalamus, is substantial considering out lower limit of detection of 0.006 ng of rat calcitonin. However, the hypothalamus contains less calcitonin-like immunoreactive material than either the anterior lobe (1.16 ng) or neurointermediate lobe (0.81 ng) of the pituitary. Taken together these three sources of calcitonin-like immunoreactive material contain less than one thousandth the immunoreactivity found in the thyroid. The exact nature of the calcitonin-like immunoreactive material found in these extrathyroidal sites and its physiological role, if any, remain to be discovered. The recent report of the occurrence of calcitonin receptors in the hypothalamus and other brain regions in conjunction with our finding of calcitonin-like immunoreactivity in the hypothalamus suggests that calcitonin-like molecules may be active within the brain.

Immunoreactive calcitonin in the central nervous system of the pigeon

To determine whether calcitonin (CT) is present in avian central nervous system (CNS), as it has been recently found in the CNS of other species, we studied extracts of pigeon (Columbia livia) brain by immunochemical methods. A sensitive and specific radioimmunoassay for salmon CT was used together with gel filtration and high performance liquid chromatography (HPLC). Extracts of hypothalamus contained 31.5 +/- 9.65 ng/g wet weight as salmon CT-like immunoreactivity while extracts of midbrain and brain stem contained 17.0 +/- 5.00 and 2.85 +/- 2.1 ng/g wet weight respectively. Extracts of whole pituitary gland, other areas of the CNS and vazrious peripheral tissues were below the detection limits of our assay, but salmon CT-like immunoreactivity was present in ultimobranchial gland (UBG), thyroid gland and lung tissue extracts. On Sephadex G-50 chromatography extracts of hypothalamic, midbrain, UBG and thyroid gland gave an immunoreactive peak which co-eluted with synthetic salmon CT. However, on HPLC the material in pigeon hypothalamus, midbrain, UBG and thyroid gland eluted in an identical manner when compared to each other but the major peak was 2 ml after that of synthetic salmon CT. These results clearly show that a salmon CT-like immunoreactive molecule is present in pigeon hypothalamus and midbrain, in addition to its main locations in the UBG and thyroid gland.

Levels of gastrin-cholecystokinin-like immunoreactivity in the brains of genetically obese and non-obese rats

Levels of gastrin-cholecystokinin-like immunoreactivity were measured in three brain regions (cortex, diencephalon, brainstem) and the pituitary gland in groups of genetically obese Zucker rats and their non-obese littermates. The obese animals had significantly increased body weights and significantly lowered brain weights. However, levels of gastrin-cholecystokinin-like immunoreactivity were not different between the two groups in any of the regions measured. These results contrast with a recent report [11] in which ob/ob mice were found to have decreased levels of cholecystokinin in their brains.