Increased FGF-23 levels are linked to ineffective erythropoiesis and impaired bone mineralization in myelodysplastic syndromes
Heike Weidner, Ulrike Baschant, Franziska Lademann, Maria G. Ledesma Colunga, Ekaterina Balaian, Christine Hofbauer, Barbara M. Misof, Paul Roschger, Stéphane Blouin, William G. Richards, Uwe Platzbecker, Lorenz C. Hofbauer, Martina Rauner
Heike Weidner, Ulrike Baschant, Franziska Lademann, Maria G. Ledesma Colunga, Ekaterina Balaian, Christine Hofbauer, Barbara M. Misof, Paul Roschger, Stéphane Blouin, William G. Richards, Uwe Platzbecker, Lorenz C. Hofbauer, Martina Rauner
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Research Article Bone biology Hematology

Increased FGF-23 levels are linked to ineffective erythropoiesis and impaired bone mineralization in myelodysplastic syndromes

Abstract

Myelodysplastic syndromes (MDS) are clonal malignant hematopoietic disorders in the elderly characterized by ineffective hematopoiesis. This is accompanied by an altered bone microenvironment, which contributes to MDS progression and higher bone fragility. The underlying mechanisms remain largely unexplored. Here, we show that myelodysplastic NUP98‑HOXD13 (NHD13) transgenic mice display an abnormally high number of osteoblasts, yet a higher fraction of nonmineralized bone, indicating delayed bone mineralization. This was accompanied by high fibroblast growth factor-23 (FGF-23) serum levels, a phosphaturic hormone that inhibits bone mineralization and erythropoiesis. While Fgf23 mRNA expression was low in bone, brain, and kidney of NHD13 mice, its expression was increased in erythroid precursors. Coculturing these precursors with WT osteoblasts induced osteoblast marker gene expression, which was inhibited by blocking FGF-23. Finally, antibody-based neutralization of FGF-23 in myelodysplastic NHD13 mice improved bone mineralization and bone microarchitecture, and it ameliorated anemia. Importantly, higher serum levels of FGF‑23 and an elevated amount of nonmineralized bone in patients with MDS validated the findings. C‑terminal FGF‑23 correlated negatively with hemoglobin levels and positively with the amount of nonmineralized bone. Thus, our study identifies FGF-23 as a link between altered bone structure and ineffective erythropoiesis in MDS with the prospects of a targeted therapeutic intervention.

Authors

Heike Weidner, Ulrike Baschant, Franziska Lademann, Maria G. Ledesma Colunga, Ekaterina Balaian, Christine Hofbauer, Barbara M. Misof, Paul Roschger, Stéphane Blouin, William G. Richards, Uwe Platzbecker, Lorenz C. Hofbauer, Martina Rauner

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Figure 1

Myelodysplastic NHD13 mice display decreased bone mineralization and high levels of FGF-23.

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Myelodysplastic NHD13 mice display decreased bone mineralization and hig...
Femora, vertebrae as well as tibiae, and serum of 2-month-old (2M) and 6-month-old (6M) WT (WT) and NUP98/HOXD13 (NHD13) mice were collected for histomorphometric and serum analysis. (A) Representative images of von Kossa/van Gieson–stained vertebra and tartrate-resistant acid phosphatase–stained (TRAP-stained) vertebra of 6-month-old WT and NHD13 mice are depicted using the CellSens program and Microscope Axio Imager M1 (Carl Zeiss). In the TRAP‑staining, osteoclasts are stained in red, while arrows indicate osteoblasts. Osteoid is stained in pink by von Kossa/van Gieson. Magnification: whole vertebra 2.5× (scale bars: 200 μm); zoom of trabeculae 20× (scale bars: 50 μm). (B) Quantitative data of trabecular number in TRAP‑stained femora (2M, n = 6–8; 6M, n = 9–11), (C–F) osteoclasts (2M, n = 5–7; 6M, n = 9–13), and osteoblasts per bone perimeter (2M, n = 6–8; 6M, n = 9–13) in femora, as well as measurement of bone-resorbing marker C‑terminal telopeptide of type 1 collagen (CTX‑1) (2M, n = 6–10; 6M, n = 7–10) and bone-forming marker procollagen type 1 N‑terminal propeptide (P1NP) (2M, n = 7–8; 6M, n = 7–13) in the serum by ELISA. (G) Double calcein labeling was used to assess bone formation rate in tibiae (2M, n = 5–8; 6M, n = 6–9). (H and I) Osteoid volume per bone volume (2M, n = 8–9; 6M, n = 6–9) and osteoid width (2M, n = 7–10; 6M, n = 6–11) were determined in von Kossa/van Gieson–stained tibiae. (J) C‑terminal FGF‑23 serum levels were measured by ELISA (2M, n = 5–8; 6M WT, n = 6–8). Data in B–J are shown as mean ± SD of 3 independent experiments and were analyzed by the 2-sided Student′s t test. *P < 0.05; **P < 0.01; ***P < 0.001 vs. age-matched WT mice.