Homozygous ablation of fibroblast growth factor-23 results in hyperphosphatemia and impaired skeletogenesis, and reverses hypophosphatemia in Phex-deficient mice
Fibroblast growth factor-23 (FGF-23), a recently identified molecule that is mutated in patients with autosomal dominant hypophosphatemic rickets (ADHR), appears to be involved in the regulation of phosphate homeostasis. Although increased levels of circulating FGF-23 were detected in patients with different phosphate-wasting disorders such as oncogenic osteomalacia (OOM) and X-linked hypophosphatemia (XLH), it is not yet clear whether FGF-23 is directly responsible for the abnormal regulation of mineral ion homeostasis and consequently bone development. To address some of these unresolved questions, we generated a mouse model, in which the entire Fgf-23 gene was replaced with the lacZ gene. Fgf-23 null (Fgf-23-/-) mice showed signs of growth retardation by day 17, developed severe hyperphosphatemia with elevated serum 1,25(OH)2D3 levels, and died by 13 weeks of age. Hyperphosphatemia in Fgf-23-/- mice was accompanied by skeletal abnormalities, as demonstrated by histological, molecular, and various other morphometric analyses. Fgf-23-/-) mice had increased total-body bone mineral content (BMC) but decreased bone mineral density (BMD) of the limbs. Overall, Fgf-23-/- mice exhibited increased mineralization, but also accumulation of unmineralized osteoid leading to marked limb deformities. Moreover, Fgf-23-/- mice showed excessive mineralization in soft tissues, including heart and kidney. To further expand our understanding regarding the role of Fgf-23 in phosphate homeostasis and skeletal mineralization, we crossed Fgf-23-/- animals with Hyp mice, the murine equivalent of XLH. Interestingly, Hyp males lacking both Fgf-23 alleles were indistinguishable from Fgf-23/-/ mice, both in terms of serum phosphate levels and skeletal changes, suggesting that Fgf-23 is upstream of the phosphate regulating gene with homologies to endopeptidases on the X chromosome (Phex) and that the increased plasma Fgf-23 levels in Hyp mice (and in XLH patients) may be at least partially responsible for the phosphate imbalance in this disorder.
Nearly every extracellular ligand that has been found to play a role in regulating bone biology acts, at least in part, through MAPK pathways. Nevertheless, much remains to be learned about the contribution of MAPKs to osteoblast biology in vivo. Here we report that the p38 MAPK pathway is required for normal skeletogenesis in mice, as mice with deletion of any of the MAPK pathway member-encoding genes MAPK kinase 3 (Mkk3), Mkk6, p38a, or p38b displayed profoundly reduced bone mass secondary to defective osteoblast differentiation. Among the MAPK kinase kinase (MAP3K) family, we identified TGF-β-activated kinase 1 (TAK1; also known as MAP3K7) as the critical activator upstream of p38 in osteoblasts. Osteoblast-specific deletion of Tak1 resulted in clavicular hypoplasia and delayed fontanelle fusion, a phenotype similar to the cleidocranial dysplasia observed in humans haploinsufficient for the transcription factor runt-related transcription factor 2 (Runx2). Mechanistic analysis revealed that the TAK1-MKK3/6-p38 MAPK axis phosphorylated Runx2, promoting its association with the coactivator CREB-binding protein (CBP), which was required to regulate osteoblast genetic programs. These findings reveal an in vivo function for p38β and establish that MAPK signaling is essential for bone formation in vivo. These results also suggest that selective p38β agonists may represent attractive therapeutic agents to prevent bone loss associated with osteoporosis and aging.
Fibroblast growth factor 23 null mice (Fgf-23 −/− ) have a short lifespan and show numerous biochemical and morphological features consistent with premature aging-like phenotypes, including kyphosis, severe muscle wasting, hypogonadism, osteopenia, emphysema, uncoordinated movement, T cell dysregulation, and atrophy of the intestinal villi, skin, thymus, and spleen. Aging is a complex biological process controlled by multiple genetic and environmental factors (1-4). Studies involving molecular mechanisms of human aging and its progression are challenging, as it takes decades to develop some of the age-related features. Since extensive subsets of age-associated phenotypes define human aging, the availability of animal models exhibiting multiple aging features are useful, not only to analyze the molecular mechanisms of age-related changes in various organs, but also for the in vivo screening of molecules that counteract age-associated syndromes including anti-oxidant agents and hormones (5,6). DNA damage through oxidative stress, among others, is thought to be an important contributing factor in aging, and has been extensively studied in animals (1,3,(7)(8)(9)(10)(11). However, the potential role of humoral factor(s) regulating the aging process has not been studied in similar depth and detail. In this study, we show that genetic ablation of Fgf-23 results in a syndrome that resembles premature aging. (12,19,20).In this study, using in vivo genetic manipulation approaches, we present a novel role of Fgf-23 in premature aging and show that the premature aging-like phenotype in Fgf-23 −/− mice is partly mediated through increased vitamin D activities. MATERIALS AND METHODS Experimental miceWe recently generated . Animals were maintained in accordance with the NIH Guide for the Care and Use of Laboratory Animals and were employed using protocols approved by the institution's subcommittee on animal care (IACUC). Macroscopic phenotypeThe total body weight of all mice was taken every 3-5 days starting at 2.5 wk of age until death. Survival of various groups of animals was recorded until death of control, Fgf-23 −/− , and double mutant Fgf-23 −/− /1α(OH)ase −/− mice. Biochemical measurementsBlood was obtained either by retro-orbital or tail bleeding of 3-, 6-, 9-and 11-wk-old wildtype, Fgf-23 −/− , and Fgf-23 −/− /1α(OH)ase −/− littermates. Serum was isolated by centrifugation at 3000 g for 10 min and stored at −80°C. Serum phosphorus and serum calcium were determined by colorometric measurements using the Stanbio Phosphorus Liqui-UV Test and Calcium (Arsenazo) LiquiColor Test, respectively. Total blood of 4-wk-old mice was used to determine routine hematological parameters such as cell counts. Skeletal analysesSkeletal changes in Fgf-23 −/− mice and their control littermates were analyzed by X-ray, quantitative CT (pQCT) and PIXImus measurements. Alizarin red S staining of total body skeletons, routine histology, and von Kossa staining were executed as described in our earlier studies (22). Immunohistochemica...
Maintenance of physiologic phosphate balance is of crucial biological importance, as it is fundamental to cellular function, energy metabolism, and skeletal mineralization. Fibroblast growth factor-23 (FGF-23) is a master regulator of phosphate homeostasis, but the molecular mechanism of such regulation is not yet completely understood. Targeted disruption of the Fgf-23 gene in mice (Fgf-23−/−) elicits hyperphosphatemia, and an increase in renal sodium/phosphate co-transporter 2a (NaPi2a) protein abundance. To elucidate the pathophysiological role of augmented renal proximal tubular expression of NaPi2a in Fgf-23−/− mice and to examine serum phosphate–independent functions of Fgf23 in bone, we generated a new mouse line deficient in both Fgf-23 and NaPi2a genes, and determined the effect of genomic ablation of NaPi2a from Fgf-23−/− mice on phosphate homeostasis and skeletal mineralization. Fgf-23−/−/NaPi2a−/− double mutant mice are viable and exhibit normal physical activities when compared to Fgf-23−/− animals. Biochemical analyses show that ablation of NaPi2a from Fgf-23−/− mice reversed hyperphosphatemia to hypophosphatemia by 6 weeks of age. Surprisingly, despite the complete reversal of serum phosphate levels in Fgf-23−/−/NaPi2a−/−, their skeletal phenotype still resembles the one of Fgf23−/− animals. The results of this study provide the first genetic evidence of an in vivo pathologic role of NaPi2a in regulating abnormal phosphate homeostasis in Fgf-23−/− mice by deletion of both NaPi2a and Fgf-23 genes in the same animal. The persistence of the skeletal anomalies in double mutants suggests that Fgf-23 affects bone mineralization independently of systemic phosphate homeostasis. Finally, our data support (1) that regulation of phosphate homeostasis is a systemic effect of Fgf-23, while (2) skeletal mineralization and chondrocyte differentiation appear to be effects of Fgf-23 that are independent of phosphate homeostasis.
FGF-23 Is a Negative Regulator of Prenatal and Postnatal Erythropoiesis
Background: FGF-23, a bone-derived hormone, regulates phosphate and vitamin D in the kidney. Results: Genetic and pharmacological manipulations of FGF-23 alter erythropoiesis and HSC frequency both in young adult age and embryonically. Conclusion: Fgf-23 regulates erythropoiesis through Epo and independent of vitamin D. Significance: These findings provide a new target for treating blood disorders associated with bone and renal defects.
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