Parathyroid hormone receptor signaling induces bone resorption in the adult skeleton by directly regulating the RANKL gene in osteocytes.

PTH upregulates the expression of the receptor activator of nuclear factor κB ligand (Rankl) in cells of the osteoblastic lineage, but the precise differentiation stage of the PTH target cell responsible for RANKL-mediated stimulation of bone resorption remains undefined. We report that constitutive activation of PTH receptor signaling only in osteocytes in transgenic mice (DMP1-caPTHR1) was sufficient to increase Rankl expression and bone resorption. Resorption in DMP1-caPTHR1 mice crossed with mice lacking the distal control region regulated by PTH in the Rankl gene (DCR(-/-)) was similar to DMP1-caPTHR1 mice at 1 month of age, but progressively declined to reach values undistinguishable from wild-type (WT) mice at 5 months of age. Moreover, DMP1-caPTHR1 mice exhibited low tissue material density and increased serum alkaline phosphatase activity at 5 month of age, and these indices of high remodeling were partially and totally corrected in compound DMP1-caPTHR1;DCR(-/-) male mice, and less affected in female mice. Rankl expression in bones from DMP1-caPTHR1 mice was elevated at both 1 and 5 months of age, whereas it was high, similar to DMP1-caPTHR1 mice at 1 month, but low, similar to WT levels at 5 months in compound mice. Moreover, PTH increased Rankl and decreased Sost and Opg expression in ex vivo bone organ cultures established from WT mice, but only regulated Sost and Opg expression in cultures from DCR(-/-) mice. PTH also increased RANKL expression in osteocyte-containing primary cultures of calvarial cells, in isolated murine osteocytes, and in WT but not in DCR(-/-) osteocyte-enriched bones. Thus, PTH upregulates Rankl expression in osteocytes in vitro, ex vivo and in vivo, and resorption induced by PTH receptor signaling in the adult skeleton requires direct regulation of the Rankl gene in osteocytes.

Physiology of calcium, phosphate and magnesium.

The physiology of calcium and the other minerals involved in its metabolism is complex and intimately tied in with the physiology of bone. Five principal humoral factors are involved in maintaining plasma levels of calcium, magnesium and phosphate and coordinating the balance between these and their content in bone. The transmembrane transport of these elements is dependent on a series of complex mechanisms that are controlled by these hormones. The plasma concentration of calcium is initially sensed by a calcium-sensing receptor which then sets up a cascade of events that initially determines parathyroid hormone secretion and eventually results in a specific action within the target organs, mainly bone and kidney. This chapter describes the physiology of these humoral factors and relates them to the pathological processes that give rise to disorders of calcium and bone metabolism. It details the stages in the calcium cascade and describes the effects on the various target organs. The pathology of disorders of bone and calcium metabolism is described in detail in the relevant chapters.

Control of bone mass and remodeling by PTH receptor signaling in osteocytes.

Osteocytes, former osteoblasts buried within bone, are thought to orchestrate skeletal adaptation to mechanical stimuli. However, it remains unknown whether hormones control skeletal homeostasis through actions on osteocytes. Parathyroid hormone (PTH) stimulates bone remodeling and may cause bone loss or bone gain depending on the balance between bone resorption and formation. Herein, we demonstrate that transgenic mice expressing a constitutively active PTH receptor exclusively in osteocytes exhibit increased bone mass and bone remodeling, as well as reduced expression of the osteocyte-derived Wnt antagonist sclerostin, increased Wnt signaling, increased osteoclast and osteoblast number, and decreased osteoblast apoptosis. Deletion of the Wnt co-receptor LDL related receptor 5 (LRP5) attenuates the high bone mass phenotype but not the increase in bone remodeling induced by the transgene. These findings demonstrate that PTH receptor signaling in osteocytes increases bone mass and the rate of bone remodeling through LRP5-dependent and -independent mechanisms, respectively.

The parathyroid hormone family of peptides: structure, tissue distribution, regulation, and potential functional roles in calcium and phosphate balance in fish.

Parathyroid hormone (PTH) and PTH-related protein (PTHrP) are two factors that share amino acid sequence homology and act via a common receptor. In tetrapods, PTH is the main endocrine factor acting in bone and kidney to regulate calcium and phosphate. PTHrP is an essential paracrine developmental factor present in many tissues and is involved in the regulation of ossification, mammary gland development, muscle relaxation, and other functions. Fish apparently lack an equivalent of the parathyroid gland and were long thought to be devoid of PTH. Only in recent years has the existence of PTH-like peptides and their receptors in fish been firmly established. Two forms of PTH, two of PTHrP, and a protein with intermediate characteristics designated PTH-L are encoded by separate genes in teleost fish. Three receptors encoded by separate genes in fish mediate PTH/PTHrP actions, whereas only two receptors have so far been found in terrestrial vertebrates. PTHrP has been more intensively studied than PTH, from lampreys to advanced teleosts. It is expressed in many tissues and is present in high concentration in fish blood. Administration of this peptide alters calcium metabolism and has marked effects on associated gene expression and enzyme activity in vivo and in vitro. This review provides a comprehensive overview of the physiological roles, distribution, and molecular relationships of the piscine PTH-like peptides.

Mechanisms involved in skeletal anabolic therapies.

Since parathyroid hormone (PTH) is the only proven anabolic therapy for bone, it becomes the benchmark by which new treatments will be evaluated. The anabolic effect of PTH is dependent upon intermittent administration, but when an elevated PTH level is maintained even for a few hours it initiates processes leading to new osteoclast formation, and the consequent resorption overrides the effects of activating genes that direct bone formation. Identification of PTH-related protein (PTHrP) production by cells early in the osteoblast lineage, and its action through the PTH1R upon more mature osteoblastic cells, together with the observation that PTHrP+/- mice are osteoporotic, all raise the possibility that PTHrP is a crucial paracrine regulator of bone formation. The finding that concurrent treatment with bisphosphonates impairs the anabolic response to PTH, adds to other clues that osteoclast activity is necessary to complement the direct effect that PTH has in promoting differentiation of committed osteoblast precursors. This might involve the generation of a coupling factor from osteoclasts that are transiently activated by receptor activator of nuclear factor-kappaB ligand (RANKL) in response to PTH. New approaches to anabolic therapies may come from the discovery that an activating mutation in the LRP5 gene is responsible for an inherited high bone mass syndrome, and the fact that this can be recapitulated in transgenic mice, whereas inactivating mutations result in severe bone loss. This has focused attention on the Wnt/frizzled/beta-catenin pathway as being important in bone formation, and proof of the concept has been obtained in experimental models.

Osteoblastic activation in the hematopoietic stem cell niche.

Hematopoietic stem cells (HSC) are rare primitive cells capable of reconstituting all blood cell lineages throughout the life of an individual. The microenvironment in which stem cells reside is essential for their survival, self-renewal, and differentiation. This microenvironment, or HSC niche, has been difficult to define in bone and bone marrow, but recent studies from our laboratory and others have shown that osteoblasts, the bone-forming cells, are an essential regulatory component of this complex cellular network. We established that parathyroid hormone (PTH), through activation of the PTH/PTHrP receptor (PTH1R) in osteoblastic cells, could alter the HSC niche resulting in HSC expansion in vivo and in vitro and improving dramatically the survival of mice receiving bone marrow transplants. These findings are of great clinical appeal, because they suggest that a strategy aimed at modifying supportive cells in a stem cell niche can expand HSC. While a number of molecules have been found to be important for hematopoietic/osteoblastic interactions, we have focused on the Jagged1/Notch signaling pathway, which was necessary for the PTH-dependent HSC expansion. Since the Jagged1/Notch signaling pathway has been implicated in the microenvironmental control of stem cell self-renewal in several organ systems, definition of Jagged1 modulation, which is currently poorly understood, should provide additional molecular targets for stem cell regulation and advance the understanding of stem cell-microenvironmental interactions.

Role of calcium channels in carboxyl-terminal parathyroid hormone receptor signaling.

Parathyroid hormone (PTH), an 84-amino acid polypeptide, is a major systemic regulator of calcium homeostasis that activates PTH/PTHrP receptors (PTH1Rs) on target cells. Carboxyl fragments of PTH (CPTH), secreted by the parathyroids or generated by PTH proteolysis in the liver, circulate in blood at concentrations much higher than intact PTH-(1-84) but cannot activate PTH1Rs. Receptors specific for CPTH fragments (CPTHRs), distinct from PTH1Rs, are expressed by bone cells, especially osteocytes. Activation of CPTHRs was previously reported to modify intracellular calcium within chondrocytes. To further investigate the mechanism of action of CPTHRs in osteocytes, cytosolic free calcium concentration ([Ca(2+)](i)) was measured in the PTH1R-null osteocytic cell line OC59, which expresses abundant CPTHRs but no PTH1Rs. [Ca(2+)](i) was assessed by single-cell ratiometric microfluorimetry in fura-2-loaded OC59 cells. A rapid and transient increase in [Ca(2+)](i) was observed in OC59 cells in response to the CPTH fragment hPTH-(53-84) (250 nM). No [Ca(2+)](i) signal was observed in COS-7 cells, in which CPTHR binding also cannot be detected. Neither hPTH-(1-34) nor a mutant CPTH analog, [Ala(55-57)]hPTH-(53-84), that does not to bind to CPTHRs, increased [Ca(2+)](i) in OC59 cells. The [Ca(2+)](i) response to hPTH-(53-84) required the presence of extracellular calcium and was blocked by inhibitors of voltage-dependent calcium channels (VDCCs), including nifedipine (100 nM), omega-agatoxin IVA (10 nM), and omega-conotoxin GVIA (100 nM). We conclude that activation of CPTHRs in OC59 osteocytic cells leads to a rapid increase in influx of extracellular calcium, most likely through the opening of VDCCs.

The mid-region of parathyroid hormone (1-34) serves as a functional docking domain in receptor activation.

Elucidating the bimolecular interface between parathyroid hormone (PTH) and its cognate G protein-coupled receptor (PTHR1) should yield insights into the basis of molecular recognition and the mechanism of ligand-mediated intracellular signaling for a system that is critically important in regulating calcium levels in blood. We used photoaffinity scanning (PAS) to identify key ligand-receptor interactions for residues from the unstructured mid-region domain of PTH-(1-34). Four PTH analogues, containing a single photoreactive p-benzoylphenylalanine (Bpa) residue in position 11, 15, 18, or 21, were found to photo-cross-link within receptor regions [165-176], [183-189], [190-298], and [165-176], respectively. Addition of these mid-region contacts as constraints to our previously proposed model of the PTH-PTHR1 complex and extensive molecular simulation experiments enables substantial refinement of the model. Specifically, (1) the overall receptor-bound conformation of the hormone is not extended, but bent; (2) helix [169-176] of the N-terminal extracellular domain (N-ECD) of the receptor is redirected toward the heptahelical bundle; and (3) the hormone traverses between the top of transmembrane (TM) helices 1 and 2, rather than between TM-7 and TM-1. This significantly alters the model of both the receptor-bound tertiary structure of the hormone and the topological orientation of the C-terminus of the N-ECD in the hormone-receptor bimolecular complex. We propose that the mid-region of PTH-(1-34) has a role in fixing, by extensive contacts with the receptor, the entry of the N-terminal helix of the hormone into the heptahelical bundle between TM-1 and TM-2. This anchorage would orient the amino terminus into position to activate the receptor.

[Hereditary skeletal dysplasias and FGFR3 and PTHR1 signaling pathways]. / Dysplasies osseuses héréditaires et voies de signalisation associées aux récepteurs FGFR3 et PTHR1.

Skeletal development is a highly sophisticated process involving, as a first step, migration and condensation of mesenchymal cells into osteoprogenitor cells. These cells further differentiate into chondrocytes and osteoblasts through multiple differentiation stages requiring a set of specific transcriptional factors. Defective endochondral ossification in human is associated with a large number of inherited skeletal dysplasias caused by mutations in genes encoding extracellular matrix components, growth factors and their receptors, signaling molecules and transcription factors. This review summarizes some of the recent findings on a series of chondrodysplasias caused by mutations in FGFR3 and PTHR1, two receptors expressed in the cartilage growth plate and mediating two main signaling pathways. Data from human diseases and relevant animal models provide new clues for understanding how signaling molecules and their interaction with key transcription factors control and regulate the development and growth of long bones.

Parathyroid hormone secretion and action: evidence for discrete receptors for the carboxyl-terminal region and related biological actions of carboxyl- terminal ligands.

PTH is a major systemic regulator of the concentrations of calcium, phosphate, and active vitamin D metabolites in blood and of cellular activity in bone. Intermittently administered PTH and amino-terminal PTH peptide fragments or analogs also augment bone mass and currently are being introduced into clinical practice as therapies for osteoporosis. The amino-terminal region of PTH is known to be both necessary and sufficient for full activity at PTH/PTHrP receptors (PTH1Rs), which mediate the classical biological actions of the hormone. It is well known that multiple carboxyl-terminal fragments of PTH are present in blood, where they comprise the major form(s) of circulating hormone, but these fragments have long been regarded as inert by-products of PTH metabolism because they neither bind to nor activate PTH1Rs. New in vitro and in vivo evidence, together with older observations extending over the past 20 yr, now points strongly to the existence of novel large carboxyl-terminal PTH fragments in blood and to receptors for these fragments that appear to mediate unique biological actions in bone. This review traces the development of this field in the context of the evolution of our understanding of the "classical" receptor for amino-terminal PTH and the now convincing evidence for these receptors for carboxyl-terminal PTH. The review summarizes current knowledge of the structure, secretion, and metabolism of PTH and its circulating fragments, details available information concerning the pharmacology and actions of carboxyl-terminal PTH receptors, and frames their likely biological and clinical significance. It seems likely that physiological parathyroid regulation of calcium and bone metabolism may involve receptors for circulating carboxy-terminal PTH ligands as well as the action of amino-terminal determinants within the PTH molecule on the classical PTH1R.

Parathyroid hormone: past and present.

Research on parathyroid hormone (PTH) has undergone four rather distinctive phases, beginning just before the turn of the 20th century. Early debates about the function of the parathyroids were resolved by 1925, when understanding the role of PTH led to comprehending the action of the glands in calcium physiology. Elucidation of the pathophysiology of hormone excess (severe bone loss) and deficiency (hypocalcemia) continued over the following decades. With the advent of advances in chemical and molecular biology, the structure of PTH and its principal receptor (PTHrP-receptor [PTHR1]) were established. Tests with purified hormonal peptide in humans led to the surprising, even paradoxical, finding that PTH can be used pharmacologically to build bone, providing a dramatic therapeutic impact on osteoporosis. These developments have stimulated the field of calcium and bone biology and posed new questions about the role of PTH as well as possible new directions in therapy.

In vitro and in vivo activities of C-terminally truncated PTH peptides reveal a disconnect between cAMP signaling and functional activity.

There is considerable evidence implicating the cAMP-signaling pathway in the anabolic action of PTH; and to date, all PTH and PTHrp peptides that stimulate cyclic AMP are active in animal models of osteogenesis. We have tested two C-terminally truncated peptides, PTH(1-29) and a modified PTH(1-21) (MPTH(1-21)), in in vitro and in vivo assays of PTH action. Each of the C-terminally truncated peptides was of low nanomolar potency in assays of receptor binding and cAMP stimulation. However, when we tested these peptides for functional response in Saos-2 cells stably transfected with a cyclic AMP response element (CRE) reporter, the C-terminally truncated peptides were two to four times less potent than would be expected from their binding and cAMP-stimulating properties. Furthermore, PTH(1-29), although active, was approximately 20-fold less potent than PTH(1-34) in a rat model of osteogenesis while MPTH(1-21) was inactive. The relative lack of activity of these peptides in vivo suggests that while activation of the cAMP pathway may be important for the anabolic effect of PTH fragments, it is not, of itself, predictive of their in vivo activity.

PTH revisited.

Recent investigations of parathyroid hormone (PTH) have advanced our understanding of its circulating forms as well as its action. It is now clear that first-generation immunoradiometric assays of so-called intact "PTH" not only measured full-length PTH(1-84) but also recognized large PTH fragments lacking the amino-terminus. New, second generation assays detect only full-length PTH. Under diverse pathological settings, second generation assays display lower levels of PTH (1-84). By measuring full-length PTH (bioactive PTH) and the combined full-length plus amino-terminal PTH fragments, the amount of non-PTH(1-84) in circulation can be estimated. The primary amino-terminal fragment is likely to be PTH(7-84). A considerable controversy surrounds the pathological significance of PTH(7-84) and its relation to adynamic bone disease. While these findings were emerging, other work uncovered the apparent basis by which PTH receptors signal through cAMP in some instances but through Ca/inositol phosphate in others. This signaling switch is dictated by the cytoplasmic adapter protein NHERF1 (EBP50), which is expressed in a cell-selective fashion. Other provocative findings may provide a means of unifying determinations of PTH(7-84) with the effects of NHERF1 on PTH receptor signaling. These latter studies reveal that in cells expressing NHERF1, PTH(7-84) has no effect on PTH receptor signaling or internalization. However, in cells lacking or expressing low levels of NHERF1, PTH(7-84) internalizes the PTH receptor without accompanying activation. Together, these findings suggest that the accumulation of PTH(7-84) in renal failure may lead to PTH resistance by internalizing and down-regulating PTH receptors.

Parathyroid hormone-related protein and lung biology.

Parathyroid hormone-related protein (PTHrP) is expressed in normal and malignant lung and has roles in development, homeostasis, and pathophysiology of injury and cancer. Its effects in developing lung include regulation of branching morphogenesis and type II cell maturation. In adult lung, PTHrP stimulates disaturated phosphatidylcholine secretion, inhibits type II cell growth, and sensitizes them to apoptosis. In lung cancer, PTHrP may play a role in carcinoma progression, or metastasis. The protein could be a useful marker for assessing lung maturity or type II cell function, predicting risk of injury, and detecting lung cancer. PTHrP-based therapies could also prove useful in lung injury and lung cancer.

Ligand-selective dissociation of activation and internalization of the parathyroid hormone (PTH) receptor: conditional efficacy of PTH peptide fragments.

G protein-coupled receptors (GPCRs) mediate the action of many hormones, cytokines, and sensory and chemical signals. It is generally thought that receptor desensitization and internalization require occupancy and activation of the GPCR. PTH and PTHrP receptor (PTH1R) belongs to GPCR class B and is the major regulator of extracellular calcium homeostasis. Using kidney distal convoluted tubule cells transfected with a human PTH1R/enhanced green fluorescent protein fusion protein, quantitative, real-time fluorescence microscopy was used to analyze receptor internalization. In these cells, which are the target of the calcium-sparing action of PTH, PTH(1-34) activated adenylyl cyclase (AC) and phospholipase C (PLC) and PTH1R endocytosis. PTH(1-31), however, stimulated AC and PLC but not PTH1R endocytosis. Conversely, PTH(7-34) rapidly stimulated PTH1R internalization without activating AC or PLC. PTH(2-34) and (3-34) caused PTH1R internalization intermediate between PTH(1-34) and (7-34). PTH1R sequestration occurred in a dynamin- and clathrin-dependent manner. Directly activating AC inhibited PTH1R internalization in response to PTH(7-34). PTH1R endocytosis was sensitive to protein kinase C inhibition. PTH(1-34), (7-34), and (1-31) evoked PTH1R phosphorylation. Removal of most of the C terminus of the PTH1R eliminated receptor phosphorylation and the cAMP/protein kinase C sensitivity of internalization. PTH(1-34) and (7-34) internalized the truncated PTH1R with identical kinetics, and the response was unaffected by forskolin. Thus, the PTH1R C terminus contains regulatory sequences that are involved in, but not required for, PTH1R internalization. The results demonstrate that receptor activation and internalization can be selectively dissociated.

Parathyroid hormone-related peptide and cardiovascular system.

The parathyroid hormone-related peptide (PTHrP) was initially identified in the early eighties, as the humoral mediator causing hypercalcaemia associated with malignancy. However, recently PTHrP was also shown to mediate a wide range of local paracrine/autocrine and intracrine functions in various tissues under physiological and pathological conditions. Indeed, PTHrP is a polyhormone, which can act through different receptors, including the type 1 parathyroid hormone (PTH) receptor 1 (PTH-1R). In the cardiovascular system, PTHrP appears to have potent effects on vascular smooth muscle cells and cardiomyocytes, where it participates in different pathological conditions, such as ischemia and heart failure. Therefore, it is conceivable that further studies on the regulation of PTHrP expression, characterization of its autocrine/paracrine/intracrine functions and definition of its intracellular signal transduction pathways in cardiomyocytes and cardiac vascular smooth muscle cells can elucidate the potential role of PTHrP in cardiovascular pathophysiology.

[The PTH/PTHrP receptor: biological implications]. / El receptor PTH/PTHrP: implicaciones biológicas.

Since its discovery in 1923, the parathyroid hormone (PTH), was thought to be the sole hormone capable of stimulating bone resorption, renal tubular calcium reabsorption, calcitriol synthesis, and urinary excretion of phosphate. However, in 1987, the PTHrP (PTH-related peptide), was demonstrated to share most of the biological actions of PTH through the activation of the same receptor. This receptor was cloned in 1992 and named PTH/PTHrP receptor or PTH-R1. Both, PTH and PTHrP bind with great affinity to PTH-R1 and stimulate a signal transduction system involving different G-proteins, phospholipase C, and adenylate cyclase. A third member of the PTH family, the TIP-39 (tuberoinfundibular peptide), binds and activates another PTH receptor (PTH-R2). There is evidence for other PTH receptors, a PTH-R3, probably specific for PTHrP in keratinocytes, kidney, placenta and a PTH-R4 specific for C-terminal PTH fragments. Activating mutations in the PTH-R1 gene cause Jansen type metaphyseal chondrodysplasia, whereas inactivating mutations are responsible for Blomstrand type rare chondrodysplasia and enchondromatosis. The renal and bone PTH-R1 expression is upregulated in vitamin D deficient rats and by endotoxin, interleukin-2, dexamethasone, T3, and TGF beta. On the contrary, PTH, PTHrP, angiotensin-II, IGF-1, PGE2, vitamin D, and chronic renal failure decrease its expression. In conclusions, the biological implications of the identification and cloning of different PTH receptors are at their beginning. The almost ubiquitous distribution of PTHrP and PTH-R1, the numerous PTHrP and PTH fragments, let us suppose the existence of other PTH-related receptors, and a great complexity of the bone and mineral metabolism.