Phosphate homeostasis is maintained by a counterbalance between efflux from the kidney and influx from intestine and bone. FGF23 is a bone-derived phosphaturic hormone that acts on the kidney to increase phosphate excretion and suppress biosynthesis of vitamin D. FGF23 signals with highest efficacy through several FGF receptors (FGFRs) bound by the transmembrane protein Klotho as a coreceptor. Since most tissues express FGFR, expression of Klotho determines FGF23 target organs. Here we identify the parathyroid as a target organ for FGF23 in rats. We show that the parathyroid gland expressed Klotho and 2 FGFRs. The administration of recombinant FGF23 led to an increase in parathyroid Klotho levels. In addition, FGF23 activated the MAPK pathway in the parathyroid through ERK1/2 phosphorylation and increased early growth response 1 mRNA levels. Using both rats and in vitro rat parathyroid cultures, we show that FGF23 suppressed both parathyroid hormone (PTH) secretion and PTH gene expression. The FGF23-induced decrease in PTH secretion was prevented by a MAPK inhibitor. These data indicate that FGF23 acts directly on the parathyroid through the MAPK pathway to decrease serum PTH. This bone-parathyroid endocrine axis adds a new dimension to the understanding of mineral homeostasis.
Parathyroid hormone (PTH) and fibroblast growth factor 23 (FGF23) target the kidney to cause a phosphaturia. FGF23 also acts on the parathyroid to decrease PTH expression, but in chronic kidney disease (CKD) there are high-serum PTH and FGF23 levels and resistance of the parathyroid to FGF23. We now report that PTH acts on bone to increase FGF23 expression and characterize the signal transduction pathway whereby PTH increases FGF23 expression. Remarkably, we show that PTH is necessary for the high-FGF23 levels of early kidney failure due to an adenine high-phosphorus diet. Parathyroidectomy before the diet totally prevented the fivefold increase in FGF23 levels in kidney failure rats. Moreover, parathyroidectomy of early kidney failure rats corrected their high-FGF23 levels. Therefore, in early kidney failure, the high-FGF23 levels are dependent on the high-PTH levels. PTH infusion for 3 days to mice with normal renal function increased serum FGF23 and calvaria FGF23 mRNA levels. To demonstrate a direct effect of PTH on FGF23, we added PTH to rat osteoblast-like UMR106 cells. PTH increased FGF23 mRNA levels (4-fold) and this effect was mimicked by a PKA activator, forskolin. PTH also decreased SOST mRNA levels (3-fold). SOST codes for sclerostin, a Wnt pathway inhibitor, which is a PTH receptor (PTH1R) target. The effect of PTH was prevented by added sclerostin. Therefore, PTH increases FGF23 expression which involves the PKA and Wnt pathways. The effect of PTH on FGF23 completes a bone-parathyroid endocrine feedback loop. Importantly, secondary hyperparathyroidism is essential for the high-FGF23 levels in early CKD.
Most patients with chronic kidney disease develop secondary hyperparathyroidism with disabling systemic complications. Calcimimetic agents are effective tools in the management of secondary hyperparathyroidism, acting through allosteric modification of the calcium-sensing receptor (CaR) on the parathyroid gland (PT) to decrease parathyroid hormone (PTH) secretion and PT cell proliferation. This study showed that rats that were fed an adenine high-phosphorus diet had increased serum PTH and PTH mRNA levels at 7 and 21 d. For studying the effect of activation of the CaR by the calcimimetics R-568 on PTH gene expression, R-568 was given by gavage to uremic rats for the last 4 d of a 7-d adenine high-phosphorus diet. R-568 decreased both PTH mRNA and serum PTH levels. The effect of the calcimimetic on PTH gene expression was posttranscriptional and correlated with differences in protein-RNA binding and posttranslational modifications of the trans acting factor AUF1 in the PT. The AUF1 modifications as a result of uremia were reversed by treatment with R-568 to those of normal rats. Therefore, uremia and activation of the CaR mediated by calcimimetics modify AUF1 posttranslationally. These modifications in AUF1 correlate with changes in protein-PTH mRNA binding and PTH mRNA levels. T he elevated parathyroid hormone (PTH) and disordered mineral metabolism associated with secondary hyperparathyroidism (HPT) complicate the clinical course of most patients with late-stage chronic kidney disease (CKD) and, when advanced, are associated with markedly increased morbidity and mortality (1). The hallmark of secondary HPT is the high levels of circulating PTH, which result from increased PTH secretion, increased PTH gene expression and synthesis, and increased parathyroid gland (PT) cell proliferation (2). The elucidation of PTH gene regulation in CKD is central to the understanding and control of the pathogenesis of secondary HPT (2-4). A limited number of preformed secretory granules contain mature PTH in the PT, and the increased PTH secretion demands the synthesis of new hormone (5-7). Accordingly, treatments that are designed to regulate PTH gene expression and translation may be of substantial clinical benefit.Data from clinical trials have demonstrated that calcimimetic therapy can reduce PTH, serum calcium and phosphorus, and the calcium-phosphorus product (Ca ϫ P) (8,9) and lead to the achievement of Kidney Disease Outcomes Quality Initiative target levels for PTH and Ca ϫ P in many more patients (10). In addition, calcimimetics, which act through the allosteric modulation of the calcium-sensing receptor (CaR), have been shown effectively to decrease PT cell proliferation in a rat model of secondary HPT (11). Therefore, there is considerable interest in determining the mechanisms by which this novel therapeutic class regulates PTH. To date, there have been no reports on the effects of calcimimetics on PTH gene expression. In this study, we examined the effect of the calcimimetic R-568 on PTH mRNA levels, protein-RNA b...
Background: The parathyroid calcium receptor determines parathyroid hormone secretion and the response of parathyroid hormone gene expression to serum Ca 2+ in the parathyroid gland. Serum Ca 2+ regulates parathyroid hormone gene expression in vivo post-transcriptionally affecting parathyroid hormone mRNA stability through the interaction of trans-acting proteins to a defined cis element in the parathyroid hormone mRNA 3'-untranslated region. These parathyroid hormone mRNA binding proteins include AUF1 which stabilizes and KSRP which destabilizes the parathyroid hormone mRNA. There is no parathyroid cell line; therefore, we developed a parathyroid engineered cell using expression vectors for the full-length human parathyroid hormone gene and the human calcium receptor.
Abstract. The sensing and response to extracellular phosphate (Pi) concentration is preserved from prokaryotes to mammals and ensures an adequate supply of Pi in the face of large differences in its availability. In mammals, the kidneys are central to Pi homeostasis. Renal Pi reabsorption is mediated by a Na/Pi co-transporter that is regulated by a renal Pi sensing system and humoral factors. The signal transduction by which Pi regulates type II Na/Pi activity is largely unknown. It is shown that calcineurin inhibitors specifically and dramatically decrease type II Na/Pi gene expression in a proximal tubule cell line and in vivo. Mice with genetic deletion of the calcineurin A gene had a marked decrease in type II Na/Pi mRNA levels and remarkably did not show the expected increase in type II Na/Pi mRNA levels after the challenge of a low-Pi diet. In contrast, the regulation of renal 25(OH)-vitamin D 1␣-hydroxylase gene expression by Pi was intact. This is the first demonstration that calcineurin has a crucial role in the signal transduction pathway regulating renal Pi homeostasis both in vitro and in vivo. These results suggest that the use of calcineurin inhibitors contributes to the renal Pi wasting seen in renal transplant patients.Phosphate (Pi) homeostasis is essential to life and is dependent on active renal reabsorption. In diseases of phosphorus (P) homeostasis, such as X-linked hypophosphatemia or oncogenic osteomalacia, there is a tremendous renal P loss with severe bone disease (1). In contrast, in chronic renal failure, the P retention leads to secondary hyperparathyroidism with disabling bone disease and vascular calcification associated with a high mortality (2). The kidney has an intrinsic P sensing system that regulates the activity of apical brush border membrane type II Na/Pi co-transporters (3). However, it is still not known how the organism senses changes in serum P.There are three mammalian Na/Pi co-transporter families: types I through III. Type II Na/Pi activity is responsible for Ͼ80% of renal P reabsorption and contains three isoforms-IIa through c-of which IIa is the major factor in renal P reabsorption and regulation in adult mice (4). Type II Na/Pi activity is increased by a low serum P and decreased by parathyroid hormone (PTH) and FGF23 (4 -8). The regulation of type II Na/Pi is at the level of recruitment of new transporters to the apical proximal tubule membrane, the level of synthesis of new transporters and their breakdown (5,9). In addition, there is regulation at the level of type II Na/Pi gene expression, which in vivo is mainly posttranscriptional (10,11). In the rat, a cis acting element in the type II Na/Pi co-transporter (Na/Pi-2) mRNA at the junction of the coding region and the 3'-untranslated region (UTR) interacts with trans acting renal cytosolic proteins and determines Na/Pi-2 mRNA stability in response to dietary P restriction (12). An additional level of regulation of Na/Pi-2 is its translational control by a low-P diet (10).The renal type II Na/Pi co-transporte...
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