Low calcium diet in dogs causes a greater increase in parathyroid function measured with an intact hormone than with a carboxylterminal assay

Acute and chronic regulation of circulating PTH: significance in health and in disease

Circulating human parathyroid hormone (PTH) is immunoheterogenous. It is composed of 80% carboxyl-terminal (C) fragments and of 20% PTH(1-84). This composition contrasts with the biological activity of the hormone, which is only related to PTH(1-84), creating a paradox between circulating PTH composition and PTH bioactivity. PTH molecular forms are either secreted by the parathyroid glands or generated by the peripheral metabolism of PTH(1-84) in the liver. The kidney has a major role in the disposal of C-PTH fragments. Secretion of PTH molecular forms by the parathyroid glands is highly regulated under a variety of clinical conditions, suggesting that C-PTH fragments could exert some biological effects of their own. Recent data suggest that C-PTH fragments can exert biological actions opposite to those of PTH(1-84) by acting on a C-PTH receptor not yet cloned. They can decrease calcium concentration, phosphate excretion, bone resorption and 1,25(OH)₂ synthesis. The clinical implications of this new concept are reviewed.

Influence of Secondary Hyperparathyroidism Induced by Low Dietary Calcium, Vitamin D Deficiency, and Renal Failure on Circulating Rat PTH Molecular Forms

Rats(r) with secondary hyperparathyroidism were studied to define the relationship between vitamin D metabolites and rPTH levels measured by 3 different rat ELISAs. Controls and renal failure (RF) rats were on a normal diet, while 2 groups on a low-calcium (-Ca) or a vitamin D-deficient (-D) diet. RF was induced surgically. Mild RF rats had normal calcium and 25(OH)D but reduced 1,25(OH)(2)D levels (P < .001) with a 2.5-fold increased in rPTH (P < .001). Severe RF rats and those on a -Ca or -D diet had reduced calcium (P < .01) and 25(OH)D levels (P < .05), with rPTH increased by 2 (-Ca diet; P < .05), 4 (-D diet; P < .001), and 20-folds (RF; P < .001) while 1,25(OH)(2)D was high (-Ca diet: P < .001) or low (-D diet, RF: P < .001). 25(OH)D and 1,25(OH)(2)D were positively and negatively related on the -Ca and -D diets, respectively. rPTH molecular forms behaved as expected in RF and on -Ca diet, but not on -D diet with more C-rPTH fragments when less were expected. This may be related to the short-time course of this study compared to prior studies.

Dynamics of secretion and metabolism of PTH during hypo- and hypercalcaemia in the dog as determined by the 'intact' and 'whole' PTH assays

BACKGROUND

Recent evidence has shown that the assay for 'intact' parathyroid hormone (I-PTH) not only reacts with 1-84 PTH but also with large non-1-84 PTH fragments, most of which is probably 7-84 PTH. As a result, an assay specific for 1-84 PTH named 'whole' PTH (W-PTH) has been developed. The present study was designed: (i) to determine whether the W-PTH assay reliably measures PTH values in the dog; (ii) to evaluate differences between the W-PTH and I-PTH assays during hypo- and hypercalcaemia; and (iii) to assess the peripheral metabolism of W-PTH and I-PTH.

METHODS

In normal dogs, hypocalcaemia was induced by EDTA infusion and was followed with a 90 min hypocalcaemic clamp. Hypercalcaemia was induced with a calcium infusion.

RESULTS

I-PTH and W-PTH values increased from 36+/-8 and 13+/-3 pg/ml (P=0.01) at baseline to a maximum of 158+/-40 and 62+/-15 pg/ml (P=0.02 vs I-PTH) during hypocalcaemia. The W-PTH/I-PTH ratio, 38+/-4% at baseline, did not change during the induction of hypocalcaemia, but sustained hypocalcaemia increased (P<0.05) this ratio. During hypercalcaemia, maximal suppression for I-PTH was 2.0+/-0.5 and only 5.7+/-0.6 pg/ml for W-PTH, due to a decreased sensitivity of the W-PTH assay at values <5 pg/ml. The disappearance rate of PTH was determined in five additional dogs which underwent a parathyroidectomy (PTX). At 2.5 min after PTX, W-PTH was metabolized more rapidly, with a value of 25+/-2% of the pre-PTX value vs 30+/-3% for I-PTH (P<0.05).

CONCLUSIONS

(i) The W-PTH/I-PTH ratio is less in the normal dog than in the normal human, suggesting that the percentage of non-1-84 PTH measured with the I-PTH assay is greater in normal dogs than in normal humans; (ii) the lack of change in the W-PTH/I-PTH ratio during acute hypocalcaemia is different from the situation observed in humans; and (iii) the dog appears to be a good model to study I-PTH and W-PTH assays during hypocalcaemia.

Parathyroid hormone metabolites in renal failure: bioactivity and clinical implications

Non-(1-84) parathyroid hormones (PTHs) are large circulating carboxyl-terminal PTH (C-PTH) fragments with a partially preserved amino-terminal structure. They were discovered during high-performance liquid chromatography (HPLC) analysis of circulating PTH molecular forms detected by an intact PTH (I-PTH) assay. Like other C-PTH fragments, they accumulate in blood in renal failure and account for up to 50% of I-PTH. They are secreted by the parathyroid glands in humans, and are generated by the peripheral metabolism of hPTH(1-84) in rats. The exact structure of non-(1-84)PTH fragments is not known. To study the possible role of non-(1-84) in PTH biology, hPTH(7-84) has been used as a surrogate, being the only large C fragment available on the market. In anesthetized, thyroparathyroidectomized rats, hPTH(7-84) caused hypocalcemia beyond that induced by surgery. It also blocked the calcemic response to hPTH(1-84) or hPTH(1-34). Other smaller C-PTH fragments, such as hPTH(39-84) and hPTH(53-84), were synergistic to hPTH(7-84) effects. hPTH(7-84) did not bind to the PTH/PTHrP receptor, but only to the C-PTH receptor in ROS 17/2.8 clonal cells, and did not stimulate cyclic adenosine monophosphate (cAMP) production by the same cells, suggesting that its hypocalcemic action was mediated via a receptor different from the PTH/PTHrP receptor, and that the calcium concentration resulted from the sum of the positive effect of hPTH(1-84) on the PTH/PTHrP receptor and of the negative effect of hPTH(7-84) and of C-PTH fragments on the C-PTH receptor. These data will change our understanding of circulating calcium regulation, which must now be viewed as the end result of opposite actions on two PTH receptors. PTH immunoheterogeneity, a highly regulated phenomenon, contributes to this dual biological effect, generating an agonist for the two different receptors. Clinically these results could have some implications in our knowledge of the PTH resistance of renal failure, of renal osteodystrophy, and of certain aspects of the uremic syndrome.

Synthetic carboxyl-terminal fragments of parathyroid hormone (PTH) decrease ionized calcium concentration in rats by acting on a receptor different from the PTH/PTH-related peptide receptor

Even if the carboxyl-terminal (C-) fragments/intact (I-) PTH ratio is tightly regulated by the ionized calcium (Ca(2+)) concentration in humans and animals, in health and in disease, the physiological roles of C-PTH fragments and of the C-PTH receptor remain elusive. To explore these issues, we studied the influence of synthetic C-PTH peptides of various lengths on Ca(2+) concentration and on the calcemic response to human (h) PTH-(1-34) and hPTH-(1-84) in anesthetized thyroparathyroidectomized (TPTX) rats. We also looked at the capacity of these PTH preparations to react with the PTH/PTHrP receptor and with a receptor for the carboxyl (C)-terminal portion of PTH (C-PTH receptor) in rat osteosarcoma cells, ROS 17/2.8. The Ca(2+) concentration was reduced by 0.19 +/- 0.03 mmol/liter over 2 h in all TPTX groups. Infusion of solvent over 2 more h had no further effect on the Ca(2+) concentration (-0.01 +/- 0.01 mmol/liter), whereas infusion of hPTH-(7-84) or a fragment mixture [10% hPTH-(7-84) and 45% each of hPTH-(39-84) and hPTH-(53-84)] 10 nmol/h further decreased the Ca(2+) concentration by 0.18 +/- 0.02 (P<0.001) and 0.07+/-0.04 mmol/liter (P< 0.001), respectively. Infusion of hPTH-(1-84) or hPTH-(1-34) (1 nmol/h) increased the Ca(2+) concentration by 0.16 +/- 0.03 (P < 0.001) and 0.19 +/- 0.03 mmol/liter (P < 0.001), respectively. Adding hPTH-(7-84) (10 nmol/h) to these preparations prevented the calcemic response and maintained Ca(2+) concentrations equal to or below levels observed in TPTX animals infused with solvent alone. Adding the fragment mixture (10 nmol/h) to hPTH-(1-84) did not prevent a normal calcemic response, but partially blocked the response to hPTH-(1-34), and more than 3 nmol/h hPTH-(7-84) prevented it. Both hPTH-(1-84) and hPTH-(1-34) stimulated cAMP production in ROS 17/2.8 clonal cells, whereas hPTH-(7-84) was ineffective in this respect. Both hPTH-(1-84) and hPTH-(1-34) displaced (125)I-[Nle(8,18),Tyr(34)]hPTH-(1-34) amide from the PTH/PTHrP receptor, whereas hPTH-(7-84) had no such influence. Both hPTH-(1-84) and hPTH-(7-84) displaced (125)I-[Tyr(34)]hPTH-(19-84) from the C-PTH receptor, the former preparation being more potent on a molar basis, whereas hPTH-(1-34) had no effect. These results suggest that C-PTH fragments, particularly hPTH-(7-84), can influence the Ca(2+) concentration negatively in vivo and limit in such a way the calcemic responses to hPTH-(1-84) and hPTH-(1-34) by interacting with a receptor different from the PTH/PTHrP receptor, possibly a C-PTH receptor.

Influence of Ca2+ concentration on the clearance and circulating levels of intact and carboxy-terminal iPTH in pentobarbital-anesthetized dogs

The role of hormone secretion and hormone clearance in the differential control of circulating levels of intact (I-) and carboxy-terminal (C-) immunoreactive parathyroid hormone (iPTH) was evaluated in 18 pentobarbital-anesthetized dogs. Catheters were installed in the aorta, left renal, and hepatic veins for sampling. Hepatic and renal blood flows were calculated from sulfobromophtalein (BSP) and p-aminohippuric acid (PAH) extraction and clearance. I- and C-iPTH were measured during a 1 h of infusion of CaCl2 or Na2EDTA. High-performance liquid chromatography (HPLC) profiles of I- and C-iPTH in and out of the liver and kidney were also obtained. Data on two dogs (one CaCl2 and one Na2EDTA infusion) were pooled for the analysis of one parathyroid function using a four-parameter mathematical model. Results obtained in the basal state and during analysis of the parathyroid function were also compared with those of 24 awakened dogs. Results are means +/- SD. Anesthetized dogs had lower levels of Ca2+ (1.29 +/- 0.03 vs. 1.34 +/- 0.04 mmol/l; p < 0.001) and higher levels of I- (11.5 +/- 5.7 vs. 3.0 +/- 1.9 pmol/l, p < 0.001) and C-iPTH (52 +/- 20.9 vs. 22.8 +/- 10.5 pmol/l; p < 0.001) than awakened dogs. Their stimulated (S) and nonsuppressible (NS) I-iPTH levels were increased 2- and 4-fold, respectively, while similar C-iPTH levels rose only 1.35- and 1.75-fold; this caused their S (4.4 +/- 0.7 vs. 6.8 +/- 1.9; p < 0.001) and NS (24.6 +/- 11.8 vs. 49.8 +/- 27.5; p < 0.05) C-iPTH/I-iPTH ratios to decrease. This was not explained by different renal clearance rates of I- and C-iPTH since both were similar at approximately 10 ml/kg/minute and unaffected by Ca2+ concentration. Clearance of all I- and C-iPTH HPLC molecular forms by the kidney appeared equal. A 50% decrease in the hepatic clearance of I-iPTH to approximately 12 ml/kg/minute in pentobarbital-anesthetized dogs, related to a lower hepatic blood flow, explained the higher levels of S and NS I-iPTH in these animals. I-iPTH hepatic clearance was unaffected by Ca2+ concentration. C-iPTH hepatic clearance was much lower at approximately 5 ml/kg/minute, abolished by hypercalcemia, and reduced by the influence of anesthesia on hepatic blood flow. This also explained the higher S C-iPTH levels in anesthetized animals. I-PTH(1-84) detected by the C-iPTH assay explained only 37.6% of the hepatic C-iPTH clearance in hypocalcemia and 73.3% in hypercalcemia. Overall, our results indicate that total C-iPTH clearance is about 40.2% that of I-iPTH in hypocalcemia and 41.3% in hypercalcemia. This would only explain a 2.4- to 2.5-fold difference in circulating levels of I- and C-iPTH if secretion rates were equal; the larger difference observed in S and NS C-iPTH/I-iPTH ratio values is thus mainly explained by different production rates.

Lack of involution of hyperplastic parathyroid glands in dogs: adaptation via a decrease in the calcium stimulation set point and a change in secretion profile

This study analyzes the parathyroid function in four dogs before and after 2 years of a low-calcium, high-sodium, vitamin D-deficient diet and the involution of the same function following (1) correction of dietary calcium deficiency and administration of i.v. 1,25-(OH)2D (0.25 micrograms twice per day) during 1 month, (2) after an additional month of normal dog chow supplemented with oral vitamin D (25 micrograms per day), and, finally, (3) after 5 and 17 months of a diet with normal levels of calcium and vitamin D. The parathyroid function was evaluated through i.v. infusion of CaCl2 and Na2 EDTA with measurement of intact (I) and carboxyl-terminal (C) immunoreactive parathyroid hormone (iPTH). The C-iPTH/I-iPTH ratio was calculated to assess the modulation of molecular forms of iPTH induced by the various treatments. The 2 years of calcium and vitamin D deprivation lowered ionized calcium (1.23 +/- 0.04, p < 0.05) and 25-OHD (4.02 +/- 2.06 nM, p < 0.005) and tended to decrease 1,25-(OH)2D (80.8 +/- 8.6 pM); it increased basal I- and C-iPTH levels approximately eightfold (I-iPTH, 40.2 +/- 20.7, p < 0.05; C-iPTH, 185.4 +/- 94.9, p < 0.05) and stimulated I-iPTH (60.2 +/- 23.0 pM, p < 0.05) and C-iPTH (239.6 +/- 80.7 pM, p < 0.05) fivefold. A greater rise in nonsuppressible I-iPTH levels than in C-iPTH levels led to a decreased C-iPTH/I-iPTH ratio in hypercalcemia (12.5 +/- 2.8 versus 27.8 +/- 6.05 pM, p < 0.005).(ABSTRACT TRUNCATED AT 250 WORDS)

Immunological evidences for post-translational control of the parathyroid function by ionized calcium in dogs

To outline the role of post-translational events in the control of the parathyroid function in vivo, we have studied the parathyroid function of normal dogs receiving i.v. infusions of CaCl2 and Na2EDTA with intact (I), carboxylterminal (C) and midcarboxylterminal (M) iPTH assays and evaluated the influence of ionized calcium on circulating molecular forms of iPTH via alterations in C/I, M/I and M/C iPTH ratios. Furthermore, the use of the mathematical model fitting the sigmoidal relationship between ionized calcium and iPTH ratios was improved through the generation of more iPTH ratio points in the ascending part of the sigmoid function. Quantitatively, the response to hypocalcemia was highest with M (98.7 +/- 36.8 pmol/l; P < 0.0167 vs. L and P < 0.0001 vs. I) and higher with L (83.1 +/- 26.1 pmol/l; P < 0.0001 vs. I) than with I (12.1 +/- 3.2 pmol/l). Similar results were observed for the non-suppressible fraction of iPTH measured by the three iPTH assays in hypercalcemia. The slope of the sigmoid function was more acute for I than for C or M, while all three secretion set-points were similar at 1.30 mmol/l. Qualitatively, all iPTH ratios increased from hypo- to hypercalcemia, results being more pronounced for the M/I and C/I iPTH ratios (7.66 +/- 2.57 to 73.9 +/- 41.4 and 6.76 +/- 1.93 to 49.8 +/- 27.5) than for the M/C iPTH ratio (1.24 +/- 0.48 to 1.82 +/- 1.16). The slopes of the three ratios were similar as were the set-points, but in this last case, values were higher (1.40 mmol/l) than for secretion set-points. These results indicate that dog parathyroid function is similar to that of man. The lower set-points for secretion and higher ones for regulating M/I and C/I iPTH ratios favor an optimal amount of I in face of decreasing ionized calcium and permit to control the non-suppressible fraction of iPTH secretion via M and C fragments production in face of increasing ionized calcium. These events are important to understand the implication and signification of post-translational events in the parathyroid glands and in peripheral blood in the phenomenon of PTH immunoheterogeneity. They further outline that the tools used here will be useful to study similar phenomenons in individuals in face of diseased parathyroid glands.

Chronic adaptation of dog parathyroid function to a low-calcium-high-sodium-vitamin D-deficient diet

The development of secondary hyperparathyroidism was studied in relation to changes in serum ionized Ca (Ca2+), 25-OHD, and 1,25-(OH)2D concentrations in six dogs maintained on a low-Ca (0.05%), high-Na (1.6%), and vitamin D-deficient diet for 91 weeks. Blood samples and evaluations of the parathyroid function were obtained before and after 3, 12, 24, 36, and 91 weeks of diet. Serum iPTH was measured by an intact hormone (I) and a carboxy-terminal (C) assay. The sigmoidal relationship between ionized Ca and iPTH values was evaluated mathematically. Results are means +/- SD. Statistically significant changes over a time period were evaluated by an ANOVA for repeated measurements. Over the first 3 weeks, serum Ca2+, 25-OHD, and 1,25-(OH)2D did not change but stimulated I-iPTH increased 84.3 +/- 39.9% (p less than 0.005) and C-iPTH only 25.3 +/- 12.2% (p less than 0.01), a significant difference (p less than 0.02). The increase in stimulated I-iPTH reached 487.4 +/- 139.6% (p less than 0.0001) and 418.4 +/- 76.9% (p less than 0.0001) for C-iPTH by the end of the study. Similar significant increases were seen in basal and nonsuppressible iPTH at or after week 12.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation and inhibition of protein kinase C in cultured bovine parathyroid cells: effect on the release of C-terminal fragments of parathyroid hormone

The response of the parathyroid gland to low Ca2+ may be mediated in part by protein kinase C (PKC). We assessed the effect of two PKC activators, SC-9 and SC-10, and one PKC inhibitor, H-7, on Ca(2+)-regulated PTH release and degradation in primary cultures of bovine parathyroid cells. Both SC-9 and SC-10 stimulated PTH release, compared to high Ca2+ alone, in parathyroid cells incubated in high Ca2+, with maximal PTH release of at least twofold occurring at a concentration of either activator of 10 nM (p less than 0.05). We have previously shown that another PKC activator, PMA, not only enhances PTH release in the presence of high Ca2+ but suppresses low Ca(2+)-stimulated PTH secretion. In the present study, neither SC-9 nor SC-10 caused a comparable suppression of PTH release at low Ca2+. However, the PKC inhibitor, H-7 (1 microM), blocked low Ca(2+)-stimulated (compared to the low Ca2+ control) PTH secretion by approximately 50% (p less than 0.01) and did not affect high Ca2+ suppression of PTH secretion. H-7 (1 microM) was able to oppose the stimulation of PTH release by the PKC activators SC-9, SC-10, and PMA at high Ca2+ and negated the PTH release-inhibiting effect of PMA at low Ca2+. Culture medium from these experiments was subjected to reversed-phase HPLC and the eluted fractions analyzed by RIA for the presence of intact and C-terminal fragments of PTH.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-deficient diet in ovariectomized dogs limits the effects of 17 beta-estradiol and nandrolone decanoate on bone

Postmortem measurements by dual-photon absorptiometry of the femur and the second lumbar vertebra in adult dogs indicated bone loss after ovariectomy, which was more pronounced when calcium-deficient diet was given in ovariectomized dogs. This bone loss was nonhomogeneous throughout the femur. Ovariectomy resulted in trabecular and cortical bone loss, and additional calcium-deficient diet resulted in a further highly significant trabecular bone loss at the proximal epiphysis of the femur and in the vertebra. This bone loss was presumably the result of increased bone turnover, as reflected by the highly significant increase in serum alkaline phosphatase. Estrogens could only partially prevent the bone loss induced by calcium deficiency after ovariectomy, and nandrolone decanoate was not effective. We conclude that (1) ovariectomy results in bone loss in adult dogs, (2) this bone loss is more pronounced after calcium-deficient diet, (3) calcium deficiency could be a limiting factor for the preventive effect of estrogens and nandrolone decanoate, and (4) dual-photon absorptiometry allows the evaluation of nonhomogeneous bone loss throughout excised bones.