In vivo evidence for an interplay of FGF23/Klotho/PTH axis on the phosphate handling in renal proximal tubules.

Phosphate homeostasis is primarily maintained in the renal proximal tubules, where the expression of sodium/phosphate cotransporters (Npt2a and Npt2c) is modified by the endocrine actions of both fibroblast growth factor 23 (FGF23) and parathyroid hormone (PTH). However, the specific contribution of each regulatory pathway in the proximal tubules has not been fully elucidated in vivo. We have previously demonstrated that proximal tubule-specific deletion of the FGF23 coreceptor Klotho results in mild hyperphosphatemia with little to no change in serum levels of FGF23, 1,25(OH)2D3, and PTH. In the present study, we characterized mice in which the PTH receptor PTH1R was specifically deleted from the proximal tubules, either alone or in combination with Klotho ( PT-PTH1R-/- and PT-PTH1R/KL-/-, respectively). PT-PTH1R-/- mice showed significant increases in serum FGF23 and PTH levels, whereas serum phosphate levels were maintained in the normal range, and Npt2a and Npt2c expression in brush border membrane (BBM) did not change compared with control mice. In contrast, PT-PTH1R/KL-/- mice displayed hyperphosphatemia and an increased abundance of Npt2a and Npt2c in the renal BBM, along with increased circulating FGF23 levels. While serum calcium was normal, 1,25(OH)2D3 levels were significantly decreased, leading to extremely high levels of PTH. Collectively, mice with a deletion of PTH1R alone in proximal tubules results in only minor changes in phosphate regulation, whereas deletion of both PTH1R and Klotho leads to a severe disturbance, including hyperphosphatemia with increased sodium/phosphate cotransporter expression in BBM. These results suggest an important interplay between the PTH/PTH1R and FGF23/Klotho pathways to affect renal phosphate handling in the proximal tubules.

Interrelated role of Klotho and calcium-sensing receptor in parathyroid hormone synthesis and parathyroid hyperplasia.

The pathogenesis of parathyroid gland hyperplasia is poorly understood, and a better understanding is essential if there is to be improvement over the current strategies for prevention and treatment of secondary hyperparathyroidism. Here we investigate the specific role of Klotho expressed in the parathyroid glands (PTGs) in mediating parathyroid hormone (PTH) and serum calcium homeostasis, as well as the potential interaction between calcium-sensing receptor (CaSR) and Klotho. We generated mouse strains with PTG-specific deletion of Klotho and CaSR and dual deletion of both genes. We show that ablating CaSR in the PTGs increases PTH synthesis, that Klotho has a pivotal role in suppressing PTH in the absence of CaSR, and that CaSR together with Klotho regulates PTH biosynthesis and PTG growth. We utilized the tdTomato gene in our mice to visualize and collect PTGs to reveal an inhibitory function of Klotho on PTG cell proliferation. Chronic hypocalcemia and ex vivo PTG culture demonstrated an independent role for Klotho in mediating PTH secretion. Moreover, we identify an interaction between PTG-expressed CaSR and Klotho. These findings reveal essential and interrelated functions for CaSR and Klotho during parathyroid hyperplasia.

Klotho expression in osteocytes regulates bone metabolism and controls bone formation.

Osteocytes within the mineralized bone matrix control bone remodeling by regulating osteoblast and osteoclast activity. Osteocytes express the aging suppressor Klotho, but the functional role of this protein in skeletal homeostasis is unknown. Here we identify Klotho expression in osteocytes as a potent regulator of bone formation and bone mass. Targeted deletion of Klotho from osteocytes led to a striking increase in bone formation and bone volume coupled with enhanced osteoblast activity, in sharp contrast to what is observed in Klotho hypomorphic (kl/kl) mice. Conversely, overexpression of Klotho in cultured osteoblastic cells inhibited mineralization and osteogenic activity during osteocyte differentiation. Further, the induction of chronic kidney disease with high-turnover renal osteodystrophy led to downregulation of Klotho in bone cells. This appeared to offset the skeletal impact of osteocyte-targeted Klotho deletion. Thus, our findings establish a key role of osteocyte-expressed Klotho in regulating bone metabolism and indicate a new mechanism by which osteocytes control bone formation.

Parathyroid hormone controls paracellular Ca2+ transport in the thick ascending limb by regulating the tight-junction protein Claudin14.

Renal Ca2+ reabsorption is essential for maintaining systemic Ca2+ homeostasis and is tightly regulated through the parathyroid hormone (PTH)/PTHrP receptor (PTH1R) signaling pathway. We investigated the role of PTH1R in the kidney by generating a mouse model with targeted deletion of PTH1R in the thick ascending limb of Henle (TAL) and in distal convoluted tubules (DCTs): Ksp-cre;Pth1rfl/fl Mutant mice exhibited hypercalciuria and had lower serum calcium and markedly increased serum PTH levels. Unexpectedly, proteins involved in transcellular Ca2+ reabsorption in DCTs were not decreased. However, claudin14 (Cldn14), an inhibitory factor of the paracellular Ca2+ transport in the TAL, was significantly increased. Analyses by flow cytometry as well as the use of Cldn14-lacZ knock-in reporter mice confirmed increased Cldn14 expression and promoter activity in the TAL of Ksp-cre;Pth1rfl/fl mice. Moreover, PTH treatment of HEK293 cells stably transfected with CLDN14-GFP, together with PTH1R, induced cytosolic translocation of CLDN14 from the tight junction. Furthermore, mice with high serum PTH levels, regardless of high or low serum calcium, demonstrated that PTH/PTH1R signaling exerts a suppressive effect on Cldn14. We therefore conclude that PTH1R signaling directly and indirectly regulates the paracellular Ca2+ transport pathway by modulating Cldn14 expression in the TAL. Finally, systemic deletion of Cldn14 completely rescued the hypercalciuric and lower serum calcium phenotype in Ksp-cre;Pth1rfl/fl mice, emphasizing the importance of PTH in inhibiting Cldn14. Consequently, suppressing CLDN14 could provide a potential treatment to correct urinary Ca2+ loss, particularly in patients with hypoparathyroidism.

Parathyroid hormone 1 receptor is essential to induce FGF23 production and maintain systemic mineral ion homeostasis.

Parathyroid-hormone-type 1 receptor (PTH1R) is extensively expressed in key regulatory organs for systemic mineral ion homeostasis, including kidney and bone. We investigated the bone-specific functions of PTH1R in modulating mineral ion homeostasis by generating a novel mouse model in which PTH1R is ablated in the limb mesenchyme using Prx1Cre transgenic mice. Such ablation decreased FGF23 protein and serum levels by 50%, despite normal Fgf23 mRNA levels in long bones. Circulating calcium and PTH levels were unchanged, but inorganic phosphate and 1,25(OH)2D3 levels were significantly decreased and accompanied by elevated urinary calcium and phosphate wasting. Key renal genes for balancing mineral ion homeostasis, calbindinD28k, Klotho, and Napi2a were suppressed by 30-40%. Intermittent hPTH(1-34) injections increased Fgf23 mRNA (7.3-fold), Nurr1 mRNA (3.1-fold), and serum intact-FGF23 (1.6-fold) in controls, but failed to induce Fgf23, Nurr1 mRNA, or intact FGF23 production in mutants. Moreover, a significant elevation in serum C-terminal-FGF23 levels (4-fold) was detected in both genotypes. PTH markedly downregulated Galnt3 expression (2.7-fold) in controls but not in mutants. These results demonstrate the pivotal role of PTH1R in long bones to regulate systemic mineral ion homeostasis and the direct induction of FGF23 by PTH1R signaling.

Conditional Deletion of Indian Hedgehog in Limb Mesenchyme Results in Complete Loss of Growth Plate Formation but Allows Mature Osteoblast Differentiation.

Indian hedgehog (Ihh) is widely recognized as an essential factor for proper skeletal development. Previous in vivo studies using mutant Ihh mouse models were limited by perinatal lethality or carried out after a growth plate formed. Thus the important role of Ihh in mesenchymal cell differentiation has not been investigated. In this study, we established Prx1-Cre;Ihh(fl/fl) mice to ablate Ihh specifically in limb mesenchyme to allow us to observe the phenotype continuously from prenatal development to 3 weeks of age. Mutant mice displayed severe limb abnormalities characterized by complete lack of secondary ossification center and growth plate, indicating an essential role for Ihh in the development of these structures. Interestingly, we discovered that osteoblast differentiation and bone formation could occur in conditions of deficient Ihh. This is a novel finding that has not been observed because of the early lethality of previous Ihh mutants. Mature osteoblasts expressing osteocalcin could be detected in the center of mutant bones at postnatal day 10 (P10). Osteoclasts and blood vessel formation were also present, suggesting active bone remodeling. Histomorphometric analyses show a significant increase in osteoclast number with no major changes in bone formation rate at 3 weeks of age. Mutant long bones in the limbs were deformed, with cortices comprised of irregular woven bone. Also, there was a marked decrease in gene expression of osteoblastic and osteocytic markers. Moreover, mutant long bones displayed bone dysplasia in which we observed increased osteoclast activity and partially reduced osteoblastic and osteocytic differentiation that lead ultimately to loss of bone structures at 3 weeks of age. In summary, our data show for the first time, the presence of mature osteoblasts in long bones of the limbs despite the complete loss of growth plate formation due to Ihh deficiency. These data indicate an important function for Ihh in regulating limb mesenchymal cell differentiation.

Vitamin D endocrine system and osteocytes.

The physiological role of the osteocyte, the most numerous of the three bone cell types, was significantly underestimated until recently. It is now known that they not only coordinate bone remodeling but also have an endocrine function as part of the regulatory network for calcium and phosphate homeostasis. Vitamin D and osteocytes interact in numerous ways to accomplish these activities. The major source of active vitamin D (1,25(OH)2D3) is the kidney but there is evidence that osteocytes can produce it as well. Renal 1,25(OH)2D3 regulates osteocyte production of fibroblast growth factor 23 (FGF23), a powerful phosphaturic factor with far-reaching physiological effects. The function of 1,25(OH)2D3 produced by osteocytes themselves is poorly understood and is an area of active research. Osteocytes affect local bone remodeling by producing regulatory factors for osteoblasts and osteoclasts in response to mechanical loading and to endocrine signals such as serum 1,25(OH)2D3. In addition, 1,25(OH)2D3 may inhibit mineralization in osteocyte lacunae. Whether 1,25(OH)2D3 has a role in osteocytic perilacunar remodeling is currently unknown. This short review presents the current state of our knowledge about the physiologically and clinically significant roles of vitamin D signaling in osteocytes.

Deletion of Zfp521 rescues the growth plate phenotype in a mouse model of Jansen metaphyseal chondrodysplasia.

Jansen metaphyseal chondrodysplasia (JMC) is caused by a constitutively activating mutation of the parathyroid hormone (PTH)/PTH-related protein (PTHrP) receptor (PTHR1) and is characterized by widening of the metaphyses, reduction of long bone length, and short stature. A transgenic mouse expressing this mutation under the collagen α1(II) promoter has been generated to investigate the mechanisms responsible for this chondrodysplasia. We recently identified zinc finger protein 521 (Zfp521) as a downstream target gene of PTHrP signaling. Interestingly, loss of Zfp521 from chondrocytes leads to reduced cell proliferation and increased differentiation in the growth plate. Thus, we hypothesized that specifically ablating Zfp521 from Jansen chondrocytes could sufficiently rescue the chondrodysplasia phenotype. Our results show that Zfp521 expression is up-regulated in Jansen mouse growth plate chondrocytes and that PTHR1 is required for Zfp521 expression. Its ablation from Jansen chondrocytes restored normal cell differentiation, thus initiating chondrocyte apoptosis at the chondro-osseous junction, leading to partial rescue of endochondral bone formation shown by proper bone length. This study provides the first genetic evidence that Zfp521 is required downstream of PTHR1 signaling to act on chondrocyte proliferation, differentiation, and cell death.

Partial rescue of postnatal growth plate abnormalities in Ihh mutants by expression of a constitutively active PTH/PTHrP receptor.

Indian hedgehog (Ihh) is essential for chondrocyte proliferation/differentiation and osteoblast differentiation during prenatal endochondral bone formation. Ihh expression in postnatal chondrocytes has a non-redundant role in maintaining a growth plate and sustaining trabecular bone after birth. Loss of Ihh in postnatal chondrocytes results in fusion of the growth plate and a decrease in trabecular bone. In order to normalize this abnormal chondrocyte phenotype and to investigate whether a putative rescue of the growth plate anomalies is sufficient to correct the severe alterations in the bone, we expressed a constitutively active PTH/PTHrP receptor (an Ihh downstream target) in the chondrocytes of Col2 alpha 1-Cre ER; Ihh(dld) mice by mating Col2 alpha 1-Cre ER; Ihh(fl/fl) mice with Col2 alpha 1-constitutively active PTH/PTHrP receptor transgenic mice (Jansen, J). Col2 alpha 1-Cre ER; Ihh(f/f); J mice were then injected with tamoxifen at P0 to generate Col2 alpha 1-Cre ER; Ihh(d/d); J mice. In contrast with the previously reported growth plate phenotype of Col2 alpha 1-Cre ER; Ihh(d/d) mice that displayed ectopic chondrocyte hypertrophy at P7, growth plates of Col2 alpha 1-Cre ER; Ihh(d/d); J double mutants were well organized, and exhibited a gene expression pattern similar to the one of control mice. However, expression of osteoblast markers and Dkk1, a Wnt signaling target, remains decreased in the bone collar of Col2 alpha 1-Cre ER; Ihh(d/d); J mice when compared to control mice despite the rescue of abnormal chondrocyte differentiation. Moreover, proliferation of chondrocytes was still significantly impaired in Col2 alpha 1-Cre ER; Ihh(d/d); J mice, and this eventually led to the fusion of the growth plate at P14. In summary, we have demonstrated that expression of a Jansen receptor in chondrocytes was able to rescue abnormal chondrocyte differentiation but not impaired chondrocyte proliferation and the bone anomalies in mice lacking the Ihh gene in chondrocytes after birth. Taken together, our findings suggest that Ihh has both PTHrP-dependent and -independent functions during postnatal endochondral bone development.

In vivo genetic evidence for klotho-dependent, fibroblast growth factor 23 (Fgf23) -mediated regulation of systemic phosphate homeostasis.

A major breakthrough in systemic phosphate homeostasis regulation was achieved by the demonstration of strikingly similar physical, morphological, and biochemical phenotypes of fibroblast growth factor 23 (Fgf23) and klotho ablated mice, which led to identification of klotho as an Fgf23 signaling cofactor. Here, we generated Fgf23 and klotho double-knockout (Fgf23(-/-)/klotho(-/-)) mice to test the hypothesis whether Fgf23 has a klotho-independent function. Fgf23(-/-)/klotho(-/-) mice are viable and have high serum phosphate levels, similar to Fgf23(-/-) and klotho(-/-) single-knockout mice. In addition, the Fgf23(-/-)/klotho(-/-) mice have increased renal expression of the sodium/phosphate cotransporter NaP(i)2a and of 1- alpha-hydroxylase concomitant with increased serum levels of 1,25-dihydroxyvitamin-D, as also observed in the Fgf23(-/-) and klotho(-/-) mice. Moreover, Fgf23(-/-)/klotho(-/-) mice show soft tissue and vascular calcification, severe muscle wasting, hypogonadism, pulmonary emphysema, distention of intestinal wall, and skin atrophy, all of which are also seen in Fgf23(-/-) and klotho(-/-) mice. Notably, injection of bioactive FGF23 protein into Fgf23(-/-)/klotho(-/-) and klotho(-/-) mice does not lower serum phosphate, whereas in wild-type and Fgf23(-/-) mice, it reduces serum phosphate. Together, these results provide compelling evidence that Fgf23 does not have a klotho-independent role in the regulation of systemic phosphate and vitamin D homeostasis.