Parathyroid gland calcium receptor mRNA levels are unaffected by chronic renal insufficiency or low dietary calcium in rats

Extracellular ionized calcium (Ca(2+)) is the primary physiological regulator of parathyroid hormone (PTH) secretion and the G protein-coupled receptor (CaR) that mediates this response has been cloned from bovine and human parathyroid glands. The Ca(2+) set-point for the regulation of PTH secretion is right-shifted in primary hyperparathyroidism (1°HPT), but whether there is a similar shift in 2°HPT is unclear. Additionally, the molecular defects associated with such changes in the set-point remain uncharacterized. These experiments were designed to determine (1) if changes in set-point occur in rats with 2°HPT induced by chronic renal insufficiency (CRI) or dietary Ca deficiency, and (2) whether any changes in set-point are mirrored by changes in steady-state mRNA levels for the parathyroid CaR. CaR mRNA levels were quantified in pairs of glands from individual rats using a solution hybridization assay. Blood urea nitrogen and PTH levels were ～ 4-fold higher in rats with CRI induced by 5/6 nephrectomy 7 weeks earlier. Rats with CRI were also significantly hypocalcemic and hyperphosphatemic. The setpoint was unchanged in CRI rats and CaR mRNA levels were also unaffected. Normal rats fed a 0.02% Ca diet for 6 weeks were markedly hypocalcemic, and had 10- and 15-fold increases in plasma PTH and 1,25-dihydroxyvitamin D(3) levels, respectively. Technical problems prevented assessment of the set-point in these animals, but parathyroid gland CaR mRNA levels were identical in both dietary groups. Thus, neither alterations in mRNA levels for the CaR nor changes in the set-point play demonstrable roles in the pathogenesis of 2°HPT in these models.     

The influence of the progression of secondary hyperparathyroidism on the set point of the parathyroid hormone-calcium curve

The influence of secondary hyperparathyroidism (2 HPT) on the set point of the parathyroid hormone (PTH)-Ca(2+) curve is controversial. In vitro experiments have shown an increase in the set point. However, clinical studies with hemodialysis patients have provided a variety of results (increases, decreases and no changes in the set point have been reported). The present study was designed to investigate the influence of the progression of 2 HPT on the set point of the PTH-Ca(2+) curve. The PTH-Ca(2+) curve and the expression of parathyroid calcium receptor (CaR mRNA) and vitamin D receptor (VDR mRNA) have been studied in normal rabbits (group I, n=9) and in nephrectomized rabbits (group II, n=18) at two stages after inducing 2 HPT: 2-3 weeks (group IIA) and 5-6 weeks (group IIB). In group I, the set point of the PTH-Ca(2+) curve was 1.63+/-0.03 mM. A progressive hypocalcemia was detected during the evolution of 2 HPT (groups IIA and IIB). Rabbits from group IIA had a significant (P<0.001) decrease in the set point to values of 1.45+/-0.02 mM. However, the set point increased significantly in group IIB (P<0.001) to 1.56+/-0.03 mM. CaR mRNA was similarly decreased in groups IIA (39+/-12%) and IIB (48+/-7%). No changes were detected in VDR mRNA. In conclusion, a reduction in the set point of the PTH-Ca(2+) curve in response to decreased extracellular Ca(2+) was detected in the early phases of 2 HPT. However, with the progression of 2 HPT the set point tended to increase even though extracellular Ca(2+) was markedly decreased. The increase in the set point in the course of 2 HPT seems to be a complex process that cannot be fully explained by changes in parathyroid CaR mRNA or VDR mRNA.     

Parathyroid hormone (PTH) secretion, PTH mRNA and calcium-sensing receptor mRNA expression in equine parathyroid cells, and effects of interleukin (IL)-1, IL-6, and tumor necrosis factor-alpha on equine parathyroid cell function

Parathyroid hormone (PTH) is secreted by the chief cells of the parathyroid gland in response to changes in ionized calcium (Ca(2+)) concentrations. In this study, we measured PTH secretion, and PTH mRNA and calcium-sensing receptor (CaR) mRNA expression by equine parathyroid chief cells in vitro. We also evaluated the effects of interleukin (IL)-1beta, IL-6, and tumor necrosis factor (TNF)-alpha on PTH secretion, and PTH and CaR mRNA expression. The relationship between PTH and Ca(2+) was inversely related. PTH secretion decreased from 100% (day 0) to 13% (day 30). PTH mRNA expression declined from 100% (day 0) to 25% (day 30). CaR mRNA decreased from 100% (day 0) to 16% (day 30). Chief cells exposed to high (2.0 mM) Ca(2+) concentrations had a lower PTH mRNA expression compared with low Ca(2+) concentrations. Ca(2+) concentrations had no effect on CaR mRNA expression. The inhibitory effect of high Ca(2+) concentrations on PTH secretion also declined over time. After day 10, there was no significant difference in PTH secretion between low and high Ca(2+ )concentrations. IL-1beta decreased both PTH secretion (75%) and PTH mRNA expression (73%), and resulted in a significant overexpression of CaR mRNA (up to 142%). The effects of IL-1beta were blocked by an IL-1 receptor antagonist. IL-1beta decreased the Ca(2+) set-point from 1.4 mM to 1.2 mM. IL-6 decreased PTH secretion (74%), but had no effect on PTH and CaR mRNA expression. TNF-alpha had no effect on PTH secretion, and PTH and CaR mRNA expression. In summary, the decreased responsiveness of parathyroid cells to Ca(2+) from 0 to 30 days can be explained, in part, by the reduced CaR expression. IL-1beta and IL-6 but not TNF-alpha affected parathyroid function in vitro and may be important in influencing PTH secretion in the septic horse.     

Relationship between parathyroid calcium-sensing receptor expression and potency of the calcimimetic, cinacalcet, in suppressing parathyroid hormone secretion in an in vivo murine model of primary hyperparathyroidism

Cinacalcet HCl, an allosteric modulator of the calcium-sensing receptor (CaR), has recently been approved for the treatment of secondary hyperparathyroidism in patients with chronic kidney disease on dialysis, due to its suppressive effect on parathyroid hormone (PTH) secretion. Although cinacalcet's effects in patients with primary and secondary hyperparathyroidism have been reported, the crucial relationship between the effect of calcimimetics and CaR expression on the parathyroid glands requires better understanding. To investigate its suppressive effect on PTH secretion in primary hyperparathyroidism, in which hypercalcemia may already have stimulated considerable CaR activity, we investigated the effect of cinacalcet HCl on PTH-cyclin D1 transgenic mice (PC2 mice), a model of primary hyperparathyroidism with hypo-expression of CaR on their parathyroid glands. A single administration of 30 mg/kg body weight (BW) of cinacalcet HCl significantly suppressed serum calcium (Ca) levels 2 h after administration in 65- to 85-week-old PC2 mice with chronic biochemical hyperparathyroidism. The percentage reduction in serum PTH was significantly correlated with CaR hypo-expression in the parathyroid glands. In older PC2 mice (93-99 weeks old) with advanced hyperparathyroidism, serum Ca and PTH levels were not suppressed by 30 mg cinacalcet HCl/kg. However, serum Ca and PTH levels were significantly suppressed by 100 mg/kg of cinacalcet HCl, suggesting that higher doses of this compound could overcome severe hyperparathyroidism. To conclude, cinacalcet HCl demonstrated potency in a murine model of primary hyperparathyroidism in spite of any presumed endogenous CaR activation by hypercalcemia and hypo-expression of CaR in the parathyroid glands.     

Non-autonomy of parathyroid hormone secretion in acute primary hyperparathyroidism

A patient with acute primary hyperparathyroidism treated with mithramycin preoperatively, underwent neck exploration and two enlarged parathyroid glands were excised: one huge adenoma (6g) and another smaller gland. Mithramycin was administered preoperatively to lower life-threatening hypercalcaemia, and parathyroid slices from the huge adenoma removed at surgery were submitted in vitro to various calcium concentrations in the media to determine the influence of calcium on parathyroid adenoma secretory pattern in acute primary hyperparathyroidism. Mithramycin induced a significant decline in calcium levels and significant elevations of calciotrophic hormones (intact PTH, mid-region specific PTH, calcitonin and calcitriol). Significant suppression in PTH output in vitro was achieved by increasing calcium levels in the media. These results exclude autonomous PTH secretion (non-calcium dependent) as a possible aetiology of acute primary hyperparathyroidism. We suggest that a sudden increase in the set-point of the diseased parathyroid cells in the presence of a huge cell mass accounts, in large part, for both the marked hypercalcaemia and elevated PTH levels in this patient.     

1,25-dihydroxyvitamin D suppresses circulating levels of parathyroid hormone in a patient with primary hyperparathyroidism and coexistent sarcoidosis

CONTEXT: PTH is excessively secreted to develop hypercalcemia and accelerate bone turnover in patients with primary hyperparathyroidism. PTH stimulates the production of 1,25-dihydroxyvitamin D [1,25(OH)2D] that in turn suppresses the synthesis of PTH in parathyroid cells. OBJECTIVE: The objective of the study was to clarify whether 1,25(OH)2D indeed inhibits circulating levels of PTH and influences bone turnover, even in a patient with primary hyperparathyroidism. DESIGN, SETTING, AND PATIENT: We evaluated PTH levels in a patient with primary hyperparathyroidism and coexistent sarcoidosis whose serum 1,25(OH)2D levels were independent of PTH. INTERVENTIONS AND MAIN OUTCOME MEASURES: The present case was treated with prednisolone before and after surgical resection of parathyroid adenoma, and Ca-regulating hormones and bone markers were measured. RESULTS: Serum Ca and PTH levels significantly decreased after parathyroid surgery, whereas serum 1,25(OH)2D levels remained high. Prednisolone administration promptly decreased serum 1,25(OH)2D levels and reciprocally increased PTH levels despite consistent serum Ca levels either before or after surgery. PTH levels were negatively correlated with serum 1,25(OH)2D levels before and after surgery. Urine N-telopeptides, serum osteocalcin, and bone-type alkaline phosphatase all decreased to physiological ranges after parathyroid surgery. CONCLUSIONS: These results suggest that 1,25(OH)2D indeed inhibits the production of PTH not to exacerbate hypercalcemia in a patient with primary hyperparathyroidism. Furthermore, PTH but not 1,25(OH)2D may primarily be involved in the stimulation of bone turnover.     

Familial hypocalciuric hypercalcemia and other disorders with resistance to extracellular calcium.

Cloning of the CaR has increased understanding of the normal control of mineral ion homeostasis and has clarified the pathophysiology of PTH-dependent hypercalcemia. Cloning of the CaR has enabled identification of FHH and NSHPT as inherited conditions with generalized resistance to Ca2+o, which is caused in many cases by inactivating mutations in the CaR gene. In most kindreds with FHH, there is resetting of Ca2+o to a mildly elevated level that does not require an increase in the circulating level of PTH above the normal range to maintain it. FHH is not accompanied by the usual symptoms, signs, and complications of hypercalcemia. The kidney participates in the genesis of the hypercalcemia in FHH by avidly reabsorbing Ca2+; consequently, there is no increased risk of forming urinary calculi in most cases. Generally, there is no compelling rationale for attempting to lower the level of Ca2+o in these patients to a nominal normal level. In contrast, in primary hyperparathyroidism, the Ca2+o resistance is limited to the pathologic parathyroid glands, and the rest of the body suffers the consequences of high circulating levels of calcium, PTH, or both. In this condition, removal of the offending parathyroid glands is often the treatment of choice. Parathyroidectomy may also be appropriate in disorders with generalized resistance to Ca2+o owing to inactivating CaR mutations in the following special circumstances: in selected families with FHH in which there is unusually severe hypercalcemia, frankly elevated PTH levels, or atypical features such as hypercalciuria; in cases of NSHPT with severe hypercalcemia and hyperparathyroidism; and in the occasional mild case of homozygous FHH owing to CaR mutations that confer mild-to-moderate resistance to Ca2+o that escapes clinical detection in the neonatal period. As discussed elsewhere in this issue, selective calcimimetic CaR activators are being tested in clinical trials, which potentiate the activation of the CaR by Ca2+o, thereby resetting the elevated set point for Ca2+o-regulated PTH release in primary and secondary hyperparathyroidism toward normal. It is hoped that these agents may become an effective medical therapy for the acquired Ca2+o resistance in primary and secondary hyperparathyroidism and perhaps for that present in the unusual cases of FHH and NSHPT, resetting the "calciostat" downward and thereby reducing Ca2+o and PTH toward normal.     

A novel calcium-sensing receptor antagonist transiently stimulates parathyroid hormone secretion in vivo

Circulating calcium (Ca(2+)) is a primary regulator of bone homeostasis through its action on PTH secretion. Extracellular Ca(2+) modulates PTH secretion through a cell surface G protein-coupled receptor, the calcium-sensing receptor (CaR). The expression of the CaR suggests a critical role in cellular regulation by calcium in various organs, including parathyroid gland, bone, and kidney. Despite an obvious pharmacological utility for CaR antagonists in the treatment of disease, only a limited number of such classes of compounds exist. We have identified a novel class of small molecules with specific activity at the CaR. This class of compounds is represented by compound 1. It possesses potent antagonist activity at the human CaR with IC(50) values of 64 nm and 230 nm in inhibiting intracellular Ca(2+) flux and inositol phosphate generation in vitro, respectively. When administered to male rats in vivo, compound 1 robustly increased serum PTH levels. The stimulation of PTH secretion was rapid and transient when administered either iv or orally. The pharmacokinetic profile of compound 1 after oral administration revealed that maximal plasma levels of compound were reached within 1 h and the half-life of the compound to be approximately 2 h in rats. These data describe a representative compound of a novel chemical class than previously described allosteric modulators that offer a new avenue for the development of improved treatments of osteoporosis.     

Hysteresis and calcium set-point for the calcium parathyroid hormone relationship in healthy horses

Abnormalities in calcium (Ca(2+)) homeostasis are reported in horses with several pathological conditions; however, there is little information on Ca(2+) regulation in horses. The objectives of the present study were to determine the Ca(2+) set-point in healthy horses, to determine whether the Ca(2+)/parathyroid hormone (PTH) response curves were characterized by hysteresis, and to determine if the order of experimentally induced hypocalcemia or hypercalcemia had an effect on PTH secretion. The Ca(2+) set-point and hysteresis were determined in 12 healthy horses by infusing Na(2)EDTA and calcium gluconate. The Ca(2+) set-point was 1.37 +/- 0.05 mmol/L, which is higher than values reported for humans and dogs (1.0-1.2 mmol/L). Hysteresis was present during hypocalcemia and hypercalcemia. Horses in which hypocalcemia was followed by hypercalcemia secreted more PTH (7440 +/- 740 pmol min/L) than horses in which hypercalcemia was followed by hypocalcemia (5990 +/- 570 pmol min/L). This study has demonstrated that the Ca(2+) set-point in the horse is higher than in other domestic animals and man. We have shown that the Ca(2+)/PTH relationship in horses is sigmoidal and displays hysteresis during both hypocalcemia and hypercalcemia, and that extracellular Ca(2+) concentrations may affect the response of the parathyroid gland to hypocalcemia.     

Mitogen-activated protein kinase cascade in human normal and tumoral parathyroid cells

The calcium-sensing receptor (CaR) activation has recently been shown to modulate the ERK1 and ERK2 cascade in different cell lines. The present study investigated this pathway in human normal and tumoral parathyroid cells. In cells from normal parathyroids and almost all hyperplasia increasing extracellular calcium concentrations (Ca(o)(2+)) induced a significant activation of ERK1 and -2, the percent stimulation over basal activity (at 0.5 mM Ca(o)(2+)) being 545 +/- 140 and 800 +/- 205 in normal cells and 290 +/- 71 and 350 +/- 73 in hyperplasia at 1 and 2 mM Ca(o)(2+), respectively. This effect was mediated by CaR because it was mimicked by the receptor agonist gadolinium and neomycin. Basal and Ca(o)(2+)-stimulated ERK1 and -2 activity was nearly abolished by the PKC inhibitor calphostin C, and PKA changes did not affect ERK1 and -2 activity. PI3K blockade by wortmannin, known to prevent G protein betagamma subunit effect on ERK1 and -2, induced a 30% reduction of the Ca(o)(2+)-stimulated ERK1 and -2 activity. Adenomatous cells showed high PKC-dependent ERK1 and -2 activity in resting conditions that was unresponsive to high Ca(o)(2+). A role of MAPK on PTH secretion was suggested by the finding that PD98059, a specific MEK inhibitor, abolished the inhibitory effect of 1.5 mM Ca(o)(2+) on PTH release from normal parathyroid cells. In conclusion, these data first demonstrate that CaR activation, through the PKC pathway and, to a lesser extent, PI3K, increases ERK1 and -2 activity in normal parathyroid cells and this cascade seems to be involved in the modulation of PTH secretion by Ca(o)(2+). Interestingly, this signaling pathway is disrupted in parathyroid tumors.     

Clinical lessons from the calcium-sensing receptor

The extracellular calcium ion (Ca(2+)(e))-sensing receptor (CaR) enables key tissues that maintain Ca(2+)(e) homeostasis to sense changes in the Ca(2+)(e) concentration. These tissues respond to changes in Ca(2+)(e) with functional alterations that will help restore Ca(2+)(e) to normal. For instance, decreases in Ca(2+)(e) act via the CaR to stimulate secretion of parathyroid hormone-a Ca(2+)(e)-elevating hormone-and to increase renal tubular calcium reabsorption; each response helps promote normalization of Ca(2+)(e) levels. Further work is needed to determine whether the CaR regulates other parameters of renal function (e.g. 1,25-dihydroxyvitamin D(3) synthesis, intestinal absorption of mineral ions, and/or bone turnover). Identification of the CaR has also elucidated the pathogenesis and pathophysiology of inherited disorders of mineral and electrolyte metabolism; moreover, acquired abnormalities of Ca(2+)(e)-sensing can result from autoimmunity to the CaR, and reduced CaR expression in the parathyroid may contribute to the abnormal parathyroid secretory control that is observed in primary and secondary hyperparathyroidism. Finally, calcimimetics-allosteric activators of the CaR-treat secondary hyperparathyroidism effectively in end-stage renal failure.     

Functional deletion of the calcium-sensing receptor in a case of neonatal severe hyperparathyroidism

Heterozygous inactivating mutations of the calcium-sensing receptor (CaR) cause familial hypocalciuric hypercalcemia, whereas homozygous or compound heterozygous inactivating mutations normally cause neonatal severe hyperparathyroidism. In a case of neonatal severe hyperparathyroidism characterized by moderately severe hypercalcemia and very high PTH levels, coupled with evidence of hyperparathyroidism and effects on brain development not previously demonstrated, we detected point mutations on separate alleles of the CaR, resulting in premature stop codon substitutions at G94 and R648. This led to severely truncated receptors and an effective so-called knockout of functional CaR. FLAG-tagged, truncated receptors were expressed in HEK293 cells for functional analysis. Confocal microscopy demonstrated cytoplasmic localization of the G94stop receptor, whereas the R648stop receptor was present both in the cytoplasm and associated with the cell membrane. Only the R648stop receptor could be detected by Western analysis. Functional assays in which R648stop and wild-type receptor were cotransfected into HEK293 cells demonstrated a reduction in wild-type Ca(2+)-responsiveness by the R648stop receptor, even at physiological Ca(2+) levels, thus simulating familial hypocalciuric hypercalcemia in relatives of the infant who were heterozygous for the R648stop mutation. The R648stop receptor alone was nonresponsive to Ca(2+). This case contributes to our understanding of the clinical manifestation of a CaR knockout.     

Ca(2+) receptor from brain to gut: common stimulus, diverse actions.

An extracellular Ca(2+)-sensing receptor (CaR) plays central roles in Ca(2+) homeostasis by regulating parathyroid hormone (PTH)secretion and renal Ca(2+) handling. The CaR is also expressed in intestine and bone, where its functions in mineral metabolism are not yet well defined. The receptor is also present in various types of cells seemingly uninvolved in systemic mineral ion homeostasis (such as neuronal and glial cells in the brain and various epithelial cells), where its actions are poorly understood but might involve the regulation of local ionic homeostasis and/or diverse cellular processes, such as cellular differentiation and proliferation.     

Differentiation of human parathyroid cells in culture

Continuous culture of parathyroid cells has proven difficult, regardless from which species the cells are derived. In the present study, we have used a defined serum-free low calcium containing medium to culture human parathyroid cells obtained from patients with parathyroid adenomas due to primary hyperparathyroidism. No fibroblast overgrowth occurred, and the human parathyroid chief cells proliferated until confluent. After the first passage the cells ceased to proliferate, but still retained their functional capacity up to 60 days, demonstrated by Ca(2+)-sensitive changes in the release of parathyroid hormone (PTH) and as adequate cytoplasmic calcium ([Ca2+](i)) responses to changes in ambient calcium as measured by microfluorimetry. Low calcium concentrations enhanced, and vitamin D(3) and retinoic acids (RA) dose-dependently inhibited cell proliferation during the first passage, as determined by [(3)H]thymidine incorporation, immunohistochemistry for proliferating cell nuclear antigen and cell counting. Signs of differentiation were present as the set-points, defined as the external calcium concentration at which half-maximal stimulation of [Ca2+](i) (set-point(c)), or half-maximal inhibition of PTH release (set-point(p)) occur, were higher in not proliferating compared with proliferating cells in P0. Inhibition of cell proliferation was accompanied by signs of left-shifted set-points, indicating a link between proliferation and differentiation. The results demonstrate that human parathyroid chief cells cultured in a defined serum-free medium can be kept viable for a considerable time, and that signs of differentiation occur after proliferation has ceased. The low calcium stimulated cell proliferation may also be inhibited by vitamin D and RA.     

Parathyroid crisis as first manifestation of primary hyperparathyroidism

We report the case of a 61-year-old woman who suffered a parathyroid crisis due to a parathyroid adenoma. The patient presented with the typical clinical symptoms of hypercalcemia. Ca(+2) and PTH were markedly increased. Initially, she was treated conservatively until Ca(+2) returned to normal levels. Then, she underwent surgical excision of a newly diagnosed parathyroid adenoma. Parathyroid crisis (PC), also known as parathyroid storm or acute primary hyperparathyroidism, is a rare and serious complication of primary hyperparathyroidism (PH). Fewer than 200 cases have been described in the literature. Prognosis is poor: mortality is 100% in non-operable cases and 20% in cases in which parathyroidectomy is performed. We emphasize the importance of early diagnosis and aggressive treatment.     

Drugs inhibiting parathyroid hormone (PTH) secretion by control of the calcium receptor (calcimimetics)--effect on the set point of calcium-regulated PTH secretion

Calcimimetics are positive allosteric modulators that activate the parathyroid calcium receptor (CaR) and thereby immediately suppress parathyroid hormone (PTH) secretion. Preclinical studies have demonstrated that calcimimetics inhibit PTH secretion and parathyroid gland hyperplasia and ameliorates bone qualities in rats with chronic renal insufficiency. Clinical trials with cinacalcet hydrochloride, a calcimimetic compound, have shown that calcimimetics possess lowering effects not only on serum PTH levels but also on serum phosphorus levels in dialysis patients with secondary hyperparathyroidism (2HPT). Thus, calcimimetics have considerable potential as an innovative medical approach to manage 2HPT. In this review, the similarities are extrapolated between the pharmacological effect of calcimimetics on the set point of Ca-regulated PTH secretion and clinical observations in affected subjects with activating CaR mutations.     

Compounds modulating parathyroid hormone (PTH) secretion

The control of parathyroid hormone (PTH) secretion is strictly regulated by the parathyroid Ca receptor (CaR). Calcimimetics and calcilytics selectively act on the parathyroid CaR to inhibit and enhance PTH secretion, respectively. According to the recent pharmacological two-state model, calcimimetics act on the CaR as allosteric agonists to stabilize an active conformation of CaR. Conversely, calcilytics act on the CaR as allosteric inverse agonists to stabilize an inactive conformation of CaR. These compounds that can alter circulating levels of PTH and bone turnover might provide novel treatments for adynamic bone disease in patients with chronic renal failure.     

Hyperparathyroidism is associated with reduced expression of a parathyroid calcium receptor mechanism defined by monoclonal antiparathyroid antibodies

Parathyroid tissue from patients with hyperparathyroidism (HPT) exhibited reduced immunohistochemical reactivity with monoclonal antiparathyroid antibodies, previously shown to stain intensely the surface of normal human parathyroid cells and to interfere with a receptor mechanism of these cells which is involved in the sensing and gating of Ca2+. Parathyroid hormone (PTH) release and cytoplasmic Ca2+ concentrations (Ca2+i) of dispersed cells from the pathological parathyroid glands had right-shifted dependencies on extracellular Ca2+, and exposure to the antibodies rendered both Ca2+i and PTH release almost completely insensitive to changes in ambient Ca2+. The results suggest that reduced expression of a parathyroid calcium receptor mechanism may be an important cause for the aberrant PTH release in HPT.