Laurent Beck

NHERF1 mutations and responsiveness of renal parathyroid hormone.

Impaired renal phosphate reabsorption, as measured by dividing the tubular maximal reabsorption of phosphate by the glomerular filtration rate (TmP/GFR), increases the risks of nephrolithiasis and bone demineralization. Data from animal models suggest that sodium-hydrogen exchanger regulatory factor 1 (NHERF1) controls renal phosphate transport. We sequenced the NHERF1 gene in 158 patients, 94 of whom had either nephrolithiasis or bone demineralization. We identified three distinct mutations in seven patients with a low TmP/GFR value. No patients with normal TmP/GFR values had mutations. The mutants expressed in cultured renal cells increased the generation of cyclic AMP (cAMP) by parathyroid hormone (PTH) and inhibited phosphate transport. These NHERF1 mutations suggest a previously unrecognized cause of renal phosphate loss in humans.

Phosphate-Dependent Regulation of MGP in Osteoblasts: Role of ERK1/2 and Fra-1†‡

Inorganic phosphate (Pi) and the matrix Gla protein (MGP) are key regulators of bone formation. We have recently shown that Pi upregulates MGP in growth plate chondrocytes, which may represent a negative feedback loop for the control of mineralization. Osteoblasts from Fra‐1‐deleted mice express low levels of MGP, whereas the expression of MGP is elevated in Fra‐1 transgenic osteoblasts, suggesting a role for Fra‐1 in MGP expression and bone formation. In this study, we aimed at deciphering the relationships between Pi and MGP in osteoblasts to determine the molecular mechanisms involved in the Pi‐dependent regulation of MGP. In MC3T3‐E1 cells and primary calvaria‐derived osteoblasts, Pi increased MGP and Fra‐1 expression at both the mRNA and protein levels. We also found that Pi enhanced the phosphorylation of ERK1/2. U0126 (MEK1/2 inhibitor) suppressed Pi‐stimulated MGP and Fra‐1 expression, indicating that ERK1/2 is required for Pi‐dependent regulation of MGP and Fra‐1. In addition, using in vitro DNA binding and chromatin immunoprecipitation assays, we showed that Fra‐1 interacts with the MGP promoter in response to Pi in MC3T3‐E1 cells. Finally, we found that in fra‐1 knockdown MC3T3‐E1 osteoblasts, the level of MGP expression is no more significantly upregulated by Pi. We further showed that primary osteoblasts from Fra‐1‐deficient mice failed to exhibit a Pi‐dependent stimulation of MGP expression. These data show, for the first time, that Pi regulates MGP expression in osteoblasts through the ERK1/2‐Fra‐1 pathway.

Recent findings in phosphate homeostasis.

Purpose of reviewWe summarize the most recent findings on the proteins that interact with sodium/inorganic phosphate (Na/Pi) cotransporters, the factors that regulate Pi homeostasis and their role in pathology. Recent findingsStudies in animal models and cell lines identified proteins mandatory to correct trafficking of the kidney-specific Na/Pi cotransporter NPT2a and its control by the parathyroid hormone. Expression of the intestinal cotransporter NPT2b is controlled by calcitriol, the ubiquitin ligase Nedd-4 and the serum glucocorticoid inducible kinase. Recent data confirm that fibroblast growth factor 23 plays a central role in the control of Pi homeostasis. Mice disrupted for or overexpressing this gene exhibit significant alteration of Pi transport and calcitriol metabolism. In humans, fibroblast growth factor 23 mutations are responsible for autosomal hypophosphataemic rickets or tumoral calcinosis. This gene also seems to be involved in hyperparathyroidism in patients with chronic kidney disease. Several new phosphaturic factors have been identified. Moderate increases in serum Pi concentration may have deleterious effects on lifespan in humans with chronic kidney disease. Disruption of the Klotho gene in mice is associated with hyperphosphataemia and decreased lifespan. Polymorphisms in this gene, in humans and in mice, influence vascular calcification and survival. SummaryPi homeostasis depends on the activity of Na/Pi cotransporters in intestine and kidney. Na/Pi transporter activity is regulated by cellular and endocrine factors, among which fibroblast growth factor 23 plays a central role. Adequate control of Pi homeostasis is crucial, as a moderate increase in serum Pi concentration and polymorphisms in genes involved in Pi metabolism may influence the aging process and lifespan.

Sodium-phosphate cotransporters, nephrolithiasis and bone demineralization.

Purpose of reviewWe discuss how recent findings obtained in disorders of phosphate metabolism in humans and in animal models have provided insights into the pathogenesis of renal stone formation and bone demineralization. Recent findingsMice that are null for the sodium-phosphate cotransporter (NPT)2a gene (NPT2a−/− mice) exhibit hypophosphataemia, increased urinary phosphate excretion, hypercalciuria and nephrolithiasis, but no bone demineralization. Mice null for the sodium-hydrogen exchanger regulatory factor (NHERF)1 (NHERF1−/− mice) also exhibit hypophosphataemia and increased renal phosphate excretion with decreased renal NPT2a expression, but they present with a severe sex-dependent bone demineralization. Heterozygous loss-of-function mutations in the NPT2a gene in humans induce hypophosphataemia, increased urinary phosphate excretion, hypercalciuria, nephrolithiasis in males (to date) and bone demineralization of variable severity in both sexes. Patients and experimental animals with increased circulating levels of fibroblast growth factor 23 present with hypophosphataemia, increased urinary phosphate excretion, inappropriate calcitriol synthesis and rickets/osteomalacia, but no nephrolithiasis except when treated. Low-phosphate diet in spontaneously hypercalciuric rats and disruption of the 1-α-hydroxylase gene in NPT2a−/− mice prevent renal stone formation. SummaryIncreased urinary phosphate excretion is a risk factor for renal calcium stone formation when it is associated with hypercalciuria. As yet undefined interplay between NPT2a, NHERF1 and possibly other cotransporters or associated proteins in bone cells may account for the diversity of bone phenotypes observed in disorders of phosphate metabolism with impaired renal phosphate reabsorption. The pathogenesis of both renal stone and bone demineralization appear to be affected by species, sex and mutation type, among other factors.

Inorganic phosphate regulates Glvr-1 and -2 expression: Role of calcium and ERK1/2

Sodium-dependent phosphate cotransporters are key regulators of phosphate homeostasis and play a major role in mineralized tissues remodelling. However, factors influencing their expression remain under consideration. In our study, modulation of type III sodium-dependent phosphate cotransporters expression by inorganic phosphate (Pi) was investigated in the murine odontoblast-like cell line MO6-G3. Experiments were designed to determine the effects of phosphate release on dental cells during tooth decay. By real-time RT-PCR we demonstrated that Glvr-1 and -2 expressions are up-regulated by Pi. The increase in Glvr-1 and -2 expressions was correlated with ERK1/2 phosphorylation and calcium/phosphate crystals formation in cultured wells. Using calcium-free culture conditions or the specific inhibitor of ERK phosphorylation (UO126), we demonstrated that Pi effects on Glvr-1 and -2 up-regulation require the presence of calcium and involve ERK signalling pathways. This study contributes to give new insights in the control of Pi transport during carious diseases.

Inverse Regulation of Early and Late Chondrogenic Differentiation by Oxygen Tension Provides Cues for Stem Cell-Based Cartilage Tissue Engineering

Background/Aims: Multipotent stem/stromal cells (MSC) are considered promising for cartilage tissue engineering. However, chondrogenic differentiation of MSC can ultimately lead to the formation of hypertrophic chondrocytes responsible for the calcification of cartilage. To prevent the production of this calcified matrix at the articular site, the late hypertrophic differentiation of MSCs must be carefully controlled. Given that articular cartilage is avascular, we hypothesized that in addition to its stimulatory role in the early differentiation of chondrogenic cells, hypoxia may prevent their late hypertrophic conversion. Methods: Early and late chondrogenic differentiation were evaluated using human adipose MSC and murine ATDC5 cells cultured under either normoxic (21%O2) or hypoxic (5%O2) conditions. To investigate the effect of hypoxia on late chondrogenic differentiation, the transcriptional activity of hypoxia-inducible factor-1alpha (HIF-1α) and HIF-2α were evaluated using the NoShift DNA-binding assay and through modulation of their activity (chemical inhibitor, RNA interference). Results: Our data demonstrate that low oxygen tension not only stimulates the early chondrogenic commitment of two complementary models of chondrogenic cells, but also inhibits their hypertrophic differentiation. Conclusion: These results suggest that hypoxia can be used as an instrumental tool to prevent the formation of a calcified matrix in MSC-based cartilage tissue engineering.

Klotho gene, phosphocalcic metabolism, and survival in dialysis.

The discovery that two recently identified molecules, klotho and fibroblast growth factor 23 (FGF23), played an important role in calcium, phosphate, and vitamin D metabolism has transformed our traditional physiological view in which bone and mineral homeostasis was mainly regulated by parathyroid hormone, vitamin D, and calcitonin, according to mineral body needs. FGF23 is a 251-amino acid secreted protein produced by osteoblasts and osteocytes in bone following the stimulation by phosphate and vitamin D or the inhibition by dentin matrix protein 1. Originally isolated from tumoral cells of patients with tumor-induced osteomalacia and hypophosphatemia, FGF23 inhibits phosphate reabsorption in renal proximal tubular cells and 1alpha-hydroxylase activity, resulting in decreased synthesis of calcitriol. To exert these actions, FGF23 requires the conversion, by klotho, of the canonical FGF receptor 1 (IIIc) in a specific high affinity FGF23 receptor. On the other hand, klotho is a putative antiaging gene identified in 1997 when a particular mouse strain, created by random insertion mutagenesis, was found to be short-lived and displayed premature atherosclerosis, osteopenia, skin atrophy, pulmonary emphysema, hyperphosphatemia, hypercalcemia, and high serum calcitriol levels. The gene of klotho encodes a 1012-amino acid cell-surface protein with a short cytoplasmic tail and an extracellular domain that consists in tandem duplicated copies of a beta-glucuronidase-like sequence, which can be released into the circulation as soluble forms after being cleaved by metalloproteinases such as ADAM10 and ADAM17. By modulating FGF23 action, klotho regulates urinary phosphate excretion and calcitriol synthesis. By virtue of its beta-glucuronidase activity, klotho deglycosylates the calcium channel TRPV5 (transient receptor potential vallinoid-5) and regulates urinary calcium excretion. klotho also binds to Na(+),K(+)-ATPase in parathyroid cells and regulates calcium-stimulated PTH secretion. Finally, klotho extends life span via several mechanisms, including the reduction of calcitriol synthesis, serum calcium, and phosphorus levels; the induction of insulin resistance; and by increasing the resistance to oxidative stress.

Olive and grape seed extract prevents post-traumatic osteoarthritis damages and exhibits in vitro anti IL-1β activities before and after oral consumption

Polyphenols exert a large range of beneficial effects in the prevention of age-related diseases. We sought to determine whether an extract of olive and grape seed standardized according to hydroxytyrosol (HT) and procyanidins (PCy) content, exerts preventive anti-osteoathritic effects. To this aim, we evaluated whether the HT/PCy mix could (i) have in vitro anti-inflammatory and chondroprotective actions, (ii) exert anti-osteoarthritis effects in two post-traumatic animal models and (iii) retain its bioactivity after oral administration. Anti-inflammatory and chondroprotective actions of HT/PCy were tested on primary cultured rabbit chondrocytes stimulated by interleukin-1 beta (IL-1β). The results showed that HT/PCy exerts anti-inflammatory and chondroprotective actions in vitro. The preventive effect of HT/PCy association was assessed in two animal models of post-traumatic OA in mice and rabbits. Diet supplementation with HT/PCy significantly decreased the severity of post-traumatic osteoarthritis in two complementary mice and rabbit models. The bioavailability and bioactivity was evaluated following gavage with HT/PCy in rabbits. Regular metabolites from HT/PCy extract were found in sera from rabbits following oral intake. Finally, sera from rabbits force-fed with HT/PCy conserved anti-IL-1β effect, suggesting the bioactivity of this extract. To conclude, HT/PCy extract may be of clinical significance for the preventive treatment of osteoarthritis.