Bone-derived C-terminal FGF23 cleaved peptides increase iron availability in acute inflammation

Fibroblast growth factor 23 (FGF23) is a phosphate and vitamin D regulating hormone produced in the bone by osteocytes.^1-4 A complex network of classical mediators of bone and mineral metabolism regulates FGF23 production.^5-8 High levels of parathyroid hormone, phosphate, calcitriol, and calcium stimulate Fgf23 transcription.^6,9-11 Consequently, FGF23 is secreted into the circulation as an intact, biologically active hormone (intact FGF23 [iFGF23]). Nonclassical stimuli also control FGF23 production, including true iron deficiency, inflammation and functional iron deficiency, erythropoietin administration, and acute blood loss.^12-18 However, in these settings, increased FGF23 production is associated with increased proteolytic cleavage to yield FGF23 cleavage peptides that have not been shown to have a biological activity in bone and mineral metabolism.^13,19,20 Although the well-established function of iFGF23 is to maintain normal phosphate homeostasis, there is emerging evidence supporting extrarenal FGF23 targets.^21-23 FGF23-derived cleavage peptides are ineffective in regulating phosphate and vitamin D metabolism, but they may play a role in mediating some of these more recently discovered extrarenal FGF23 functions.

A tightly regulated coupling between FGF23 transcription and downstream proteolytic cleavage results in varying proportions of circulating intact (iFGF23), N-terminal FGF23, and C-terminal (Cter-FGF23) peptides, referred to as total FGF23. O-glycosylation of iFGF23 by GALNT3 at its major 176-RXXR-179 cleavage site prevents proteolytic cleavage.²⁴ Conversely, phosphorylation at the same site by family with sequence similarity 20, member C (Fam20C) enables cleavage of iFGF23 by proprotein convertases serine kinases.^25-27 The fact that both FGF23 production and cleavage are induced by inflammation, iron deficiency, anemia, and EPO, with minimal impact on circulating iFGF23 levels,^12-18 supports a possible role of FGF23-cleaved peptides under these conditions. Consistent with this hypothesis, we have shown that excess total FGF23 correlated with prevalent anemia, change in hemoglobin (Hb) over time, and development of anemia.²⁸ FGF23 has also been shown to induce anemia, suggesting that iFGF23 or FGF23-derived peptides might have a direct impact on iron metabolism and/or erythropoiesis.²⁹ 

Increased production of the iron regulatory hormone hepcidin in response to inflammatory cytokines is a major cause of functional iron deficiency and anemia.³⁰ Hepcidin is the main regulator of plasma iron concentrations, which acts by modulating cellular iron export to plasma and extracellular fluid and, thus, is the principal regulator of iron absorption and its distribution to tissues. During inflammatory conditions, bone morphogenetic proteins (BMP) signaling in hepatocytes increases the secretion of hepcidin,^31-34 which downregulates the iron exporter ferroportin, thus limiting iron entry into the bloodstream from absorptive enterocytes, macrophages, and hepatocytes body stores.

Here, we tested the role of Cter-FGF23 peptides on iron metabolism during acute inflammation. We show that bone represents the major source of Cter-FGF23 peptides during acute inflammation. We also show that furin is the major protease responsible for FGF23 cleavage in response to interleukin-1β (IL-1β) administration. Importantly, we demonstrate that Cter-FGF23 depletion, owing to the genetic deletion of Fgf23 or Furin, aggravates functional iron deficiency in acute inflammation. Finally, we show that exogenous administration and/or genetic overexpression of Cter-FGF23 increases iron bioavailability by antagonizing BMP-dependent hepcidin production. Together, our data show that bone-produced Cter-FGF23 peptides are new iron conserving molecules and that Cter-FGF23 peptides could represent a therapy to alleviate inflammation-induced anemia.

A 6-week-old male, wild type (WT), Fgf23^KO, and Cre-recombinase mice driven by dentin matrix protein 1 promoter (DMP1^Cre+) were purchased from The Jackson Laboratory. Fgf23^flox/flox mice³⁵ were from the laboratory of W.C. (University of California San Francisco, San Francisco, CA), Furin^flox/flox mice³⁶ were from the laboratory of J.W.M.C. (Center for Human Genetics, KU Leuven, Leuven, Belgium), and Dmp1^KO mice were provided by Jian Q. Feng’s laboratory (Baylor College of Dentistry at Texas A&M Health Science Center, Dallas, TX). Flox mice were crossed with Dmp1-Cre mice to generate Fgf23^flox/flox-Dmp1^Cre-, Fgf23^flox/flox-Dmp1^Cre+, Furin^flox/flox-Dmp1^Cre-, and Furin^flox/flox-Dmp1^Cre+. Dmp1^Cre- served as WT littermate controls. We created the Fgf23 conditional transgenic mouse (Cter-Fgf23^Dmp1-cTg), as detailed in supplemental Methods, available on the Blood website. All experiments were approved by the Northwestern University Institutional Animal Care and Use Committee.

Proteins were purchased and used as detailed in supplemental Data.

Mice were implanted with 5 mm × 5 mm absorbable gelatin sponges (Gelfoam; Pfizer, New York, NY) containing MC3T3-E1 cells stably overexpressing the sequence encoding the aa 179 to 251 Cter-FGF23 peptide or an empty vector (Ctr). Briefly, MC3T3-E1 were seeded on gelatin sponges in vitro in cell culture medium. After 15 hours, the mice were anesthetized, and the sponge was implanted subcutaneously in the mid-dorsal area. Blood and tissues were collected 24 hours after implanting the sponge.

Tissues were collected and prepared as detailed in supplemental Data.

Biochemistry assays were performed as detailed in supplemental Data.

Cortical bones, bone marrow, calvaria, liver, spleen, kidney and heart were harvested from mice and cultured in 6-well plates in optimized minimum essential medium supplemented with 1% fetal bovine serum. Supernatants were collected after 24 hours and secreted cFGF23 and iFGF23 were measured immediately.

Primary cells were cultured as previously described³⁷ and detailed in supplemental Data.

MC3T3-E1 cells transfected with a secreted luciferase under the control of the 1.5 Kb promoter of Fgf23 sequence were cultured as previously described^37,38 and detailed in supplemental Data.

Mouse cell line FL83B hepatocytes (CRL-2390; ATCC, Manassas, VA) were plated at 3.0 × 10⁴ per cm² in F-12K medium for 21 days, and then fasted for 16 hours before challenge with OPTI-MEM minimal medium containing 1% fetal bovine serum. FL83B cells were stimulated with 10 ng/mL BMP2/6/9 in presence or absence of 50 ng/mL of Cter-FGF23.

RNA was isolated, purified, and expression measured as previously described^12,38,39 and detailed in supplemental Data and supplemental Table 1.

Serum and cell protein extracts were analyzed as detailed in supplemental Data.

Decalcified mouse tibia paraffin sections (5 μm) were hydrated and treated with unmasking solution and nonspecific site blockade. FGF23 detection was performed using primary antibodies (1:500; Quidel, San Diego, CA), anti-goat secondary antibody, avidin-biotin coupling, and peroxidase revelation (Vector Labs, Burlingame, CA). Images were captured by bright field microscopy (Leica Microsystems, Buffalo Grove, IL).

Data analysis was performed with Statistica (TIBCO Software Inc, Palo Alto, CA) using Student t test and analysis of variance. The sizes of the different data sets were determined according to the minimal number of animals estimated to reach statistical significance and biological relevance during assessment of the primary outcome for the experiment. Data are presented as mean ± standard error of the mean. P values < 0.05 were considered statistically significant.

Acute inflammation induced by 50 ng/g of IL-1β in mice increases osteoblast/osteocyte Fgf23 transcription and circulating cFGF23 levels but not iFGF23.^12,Fgf23 promoter reporter MC3T3-E1 osteoblasts show a dose-dependent increase in Fgf23 transcription in response to IL-1β (Figure 1A). MC3T3-E1 producing a double tagged FGF23 (red fluorescent protein at the N-terminal and GFP at the C-terminal domain) under the control of Fgf23 1.2 Kb promoter also show a time-dependent increase in FGF23 production and secretion of mainly FGF23 fragments (supplemental Videos 1-3). Recent studies have shown that FGF23 can be secreted by other cells/organs under challenge.¹⁸ To determine the major site of production and recruit all available sources of FGF23 in acute inflammation, we administered a 5× higher dose of IL-1β (ie, 250 ng/g) to WT mice. This further increased both cFGF23 and iFGF23, leading to an increase in i/cFGF23 ratio (Figure 1B-D). This higher dose of IL-1β also increased Fgf23 messenger RNA (mRNA) by 20-fold in calvarium and by ∼60-fold in the cortical bone (P < .05), which are enriched in osteocytes. Acute inflammation also modestly increased Fgf23 expression in kidney, spleen, and liver (Figure 1E). In vitro, short-term organ cultures from WT mice treated in vivo or in vitro with either saline or IL-1β confirmed increased secretion of both c and iFGF23 in the same organs in response to inflammatory stimuli (supplemental Figure 1) and further support that osteocytes are the major source of FGF23 in response to inflammation.

To further test whether osteocytes are the major source of circulating FGF23 in acute inflammation, we created osteocyte-specific Fgf23 knockout mice using a Dmp1-Cre recombinase and repeated saline and IL-1β treatments. Vehicle-treated Fgf23^Dmp1-cKO mice showed lower circulating levels of cFGF23 but normal iFGF23 levels. In acute inflammation, Fgf23^Dmp1-cKO mice secreted a dramatically lower quantity of both c and iFGF23 than that of WT littermates (−92% of circulating cFGF23% and −80% of iFGF23), leading to a slight increase in i/c FGF23 ratio and a mild increase in serum phosphate and calcitriol levels (Figure 2A-E). Inflammation increased Fgf23 mRNA in the cortical bone of WT but not of Fgf23^Dmp1-cKO mice (Figure 2F). Immunohistochemistry showed increased FGF23 in the cortical bone of IL-1β-treated WT but not in IL-1β-treated Fgf23^Dmp1-cKO mice (Figure 2G). Of note, IL-1β increased neutrophil count similarly in WT and Fgf23^Dmp1-cKO mice (supplemental Figure 2). Primary osteoblasts isolated from the cortical bone of WT and Fgf23^Dmp1-cKO mice showed increased Fgf23 mRNA and supernatant c and iFGF23 levels in response to IL-1β in WT but not in Fgf23^Dmp1-cKO cells (Figure 2H-J). Together, these data show that mature osteoblasts/osteocytes are the main cells producing FGF23 in response to inflammation.

To determine the sequence of events leading to excess FGF23 in acute inflammation, we assessed the hourly response to a single injection of IL-1β in WT mice for 6 hours. IL-1β increased Fgf23 mRNA in the cortical bone as early as 1 hour after injection (Figure 3A), followed by an increase in serum cFGF23 levels with a maximum peak at 5 hours (Figure 3B). Levels of iFGF23 followed the same pattern, albeit at lower levels (Figure 3C). i/cFGF23 ratio was reduced 2 hours after injection (Figure 3D) and remained low until 6 hours, suggesting early modifications of FGF23 cleavage. IP of FGF23 in serum using antibodies directed against a C-terminal motif of FGF23 confirmed the presence of iFGF23 and cleaved peptides, at predicted sizes (Figure 3E). The expression of Galnt3, which protects FGF23 from cleavage, was reduced in the cortical bone only after 4 hours (Figure 3F), and the expression of Fam20c, which promotes FGF23 cleavage, peaked at 3 hours after IL-1β injection (Figure 3G). Six hours after IL-1β injection, out of the 9 different proteases predicted to recognize the FGF23 cleavage site, we observed a nonsignificant increase in Pcsk2 expression in the cortical bone and a significant increase in Furin (supplemental Figure 3). In contrast with late modifications in Galnt3 and Fam20c expression, Furin mRNA increased as early as 1 hour after IL-1β injection, coinciding with the acute increase in cFGF23 levels (Figure 3H). Given that FGF23 is mostly produced as FGF23 cleaved peptides in acute inflammation (supplemental Videos 1-3), we tested whether cleavage of FGF23 occurs before or after secretion. Bone explants from Fgf23^KO mice devoid of endogenous FGF23 production and treated with exogenous iFGF23 and IL-1β showed that only a small percentage of iFGF23 was cleaved in response to IL-1β (Figure 3I-K). This suggests that, in acute inflammation, FGF23 peptides result from intracellular cleavage by furin in osteocytes and are subsequently secreted. Accordingly, osteocyte-specific Furin knockout mice showed a reduced amount of serum cFGF23 levels in response to acute inflammation, compared with that of IL-1β-treated WT littermates, and a further increase in iFGF23 levels, despite a similar increase in Fgf23 transcription, lower phosphate, and normal calcitriol levels (Figure 3L-Q). Administration of IL-1β resulted in a similar increase in neutrophils in both WT and Furin^Dmp1-cKO mice (supplemental Figure 4A). As a result of reduced Furin expression in bone and increased iFGF23 levels, IL-1β-treated Furin^Dmp1-cKO mice showed an increase in phosphaturia (supplemental Figure 4C). We also observed a reduction in Hb levels in inflamed Furin^Dmp1-cKO mice, likely owing to an independent role of Furin on inflammation-driven hemolysis (supplemental Figure 4D).

IL-1β administration to WT mice induces functional iron deficiency, leading to a time dependent decrease in circulating iron and transferrin saturation (TSAT) (Figure 4A-B). These expected effects are mainly because of increased hepatic production of the iron regulatory hormone hepcidin, encoded by Hamp, which blocks cellular iron export by binding to ferroportin (Figure 4C-E).⁴⁰ Consequently, transcription of bone marrow erythroferrone (Erfe), a hormone that inhibits hepcidin production, increases (Figure 4F).⁴¹ Fgf23^Dmp1-cKO mice, which produced ∼90% less cFGF23 during inflammation, showed a further reduction of serum iron and TSAT in response to IL-1β administration, owing to a surprising increase in hepatic Hamp and circulating hepcidin levels that occurred despite a further increase in Erfe, compared with that of WT littermates (Figure 4G-K). A similar effect was observed in response to inflammation induced by heat-killed Brucella abortus particles (supplemental Figure 5A-G). Impaired FGF23 cleavage in Furin^Dmp1-cKO mice also further increased Hamp and hepcidin in acute inflammation, leading to further reductions in serum iron and TSAT (Figure 4L-O), despite a further increase in Erfe (supplemental Figure 4E), suggesting that Cter-FGF23 cleaved peptides increase iron bioavailability by suppressing hepcidin production independently of erythroferrone.

To further investigate whether bone-produced Cter-FGF23 regulates iron metabolism, we created a Cter-Fgf23 conditional transgenic mouse overexpressing Cter-Fgf23 in osteocytes (Cter-Fgf23^Dmp1-cTg). Cter-Fgf23^Dmp1-cTg mice showed a dramatic increase in circulating total cFGF23 and only a modest increase in iFGF23 levels, confirming that these mice secrete mainly Cter-FGF23 peptides (Figure 5A-C). Importantly, serum phosphate levels were normal compared with that of WT littermates (Figure 5D). Excess Cter-FGF23 reduced serum hepcidin levels, leading to increases in serum iron and TSAT (Figure 5E-G). Hb levels also increased in Cter-Fgf23^Dmp1-cTg mice (Figure 5H), likely because of increased iron bioavailability. Cter-FGF23-treated WT mice show reduced liver Hamp expression and circulating hepcidin levels, increased serum iron and TSAT, and normal phosphate levels (Figure 5I-M), despite normal Erfe expression (supplemental Figure 5H). In contrast, animals with a primary increase in iFGF23, such as hypophosphatemic Dmp1^KO mice, show unchanged serum iron, TSAT, and Hb compared with that of WT littermates, further suggesting that iFGF23 is not involved in systemic iron regulation (Figure 5N-S). Administration of Cter-FGF23 peptides to Fgf23^KO mice, devoid of endogenous FGF23, did not reduce serum hepcidin, likely owing to the confounding effects of hyperphosphatemia and hypervitaminosis D on hepcidin secretion.^42,43 However, administration of Cter-FGF23 peptides prevented the induction of liver Hamp expression and circulating hepcidin levels by inflammation and maintained serum iron and TSAT at normal levels compared with Fgf23^KO littermates treated with IL-1β alone (Figure 5T-Z). This further demonstrates that Cter-FGF23 peptides do not compete with iFGF23 signaling and act via a fibroblast growth factor receptor–independent mechanism to reduce hepcidin.

BMP2 and BMP6 are the major hepcidin regulators and stimulate its expression through BMPR/Smad 1/5/9 mechanism.^38,44-46 BMP9 is the most potent inducer of hepcidin in vitro, but its role is disputed in vivo.³¹ In WT mice, circulating levels of BMP2 increase and peak as early as 1 hour after IL-1β injection, whereas BMP9 levels peak only at 4 hours (Figure 6A-B). An equivalent enzyme-linked immunosorbent assay currently does not exist to measure circulating BMP6 levels. In the liver, Bmp2 and Bmp9 mRNA were increased as early as 1 hour after IL-1β injection, and Bmp2, Bmp6, and Bmp9 mRNA were all increased by 6 hours (Figure 6C-F; supplemental Figure 5I-J). Injection of BMP2,6,9 to WT mice increased liver Hamp and circulating hepcidin levels, leading to reductions in serum iron and TSAT and normal phosphate levels (Figure 6G-K). Cter-FGF23 cotreatment partially prevented the effects induced by BMP2 and BMP9 but did not antagonize the effects of BMP6. In parallel, we implanted WT mice with subcutaneous scaffolds containing cells overexpressing Cter-FGF23 peptides or empty plasmid. Injection of BMP2/6/9 in these mice showed a similar response to that of mice coinjected with Cter FGF23 and BMPs (supplemental Figure 5K-O). We also treated Cter-Fgf23^Dmp1-cTg mice with BMP2/9 and show that overexpression of Cter-FGF23 reduced hepcidin induction by BMP2/9 (supplemental Figure 5P-S). We further confirmed these results in vitro by treating FL83B immortalized hepatocytes with BMP2/6/9, in the presence or absence of Cter-FGF23 (Figure 6L). To determine binding partners of Cter-FGF23 peptides, we treated cultured osteoblasts collected from Fgf23^KO mice with exogenous Cter-FGF23 peptides for 2 hours and performed IP/MS analyses after treatment. We identified binding peptide sequences belonging to BMP2 and BMP9 (Table 1). To study the putative interactions of BMP2 and BMP9 with Cter-FGF23, we used the AlphaFold structure of murine iFGF23 (Q9EPC2) (Figure 6M) and AlphaFold2 to isolate Cter-FGF23 peptide structure (Figure 6N) and the most likely predicted structure of the isolated peptide (Figure 6O). We also obtained the structure of murine BMP2 (P21274) and BMP9 (Q9WV56) from the AlphaFold Protein Structure Database and used pyDock and UCSF ChimeraX 1.3 to simulate and visualize docking between Cter-FGF23 peptides and BMPs. BMP2 is a dimeric protein, and 2 known receptor-binding motifs have been identified in the BMP2 ligand. A large epitope 1 (wrist) is a high-affinity binding site for BMPR-IA, and a smaller epitope 2 (knuckle) is a low-affinity binding site for BMPR-II (Figure 6P). Cter-FGF23 peptides are predicted to bind to 2 regions in the monomeric BMP2, including BMPR-II binding site (not shown), or to the dimeric BMP2 (Figure 6Q). We obtained similar predicted interactions between BMP9 and Cter-FGF23, with a high-affinity binding in the BMP9/BMPR-II region (Figure 6R). We also observed similar interactions with the least likely AlphaFold2 predicted models of Cter-FGF23 (not shown). Accordingly, Cter-Fgf23^Dmp1-cTg mice did not show increased hepcidin secretion in response to IL-1β administration and showed a reduction in the SMAD/BMP pathway activation in liver RNA-seq analyses, despite a slight increase in both Bmp2 and Bmp6 transcripts in IL-1β-treated Cter-Fgf23^Dmp1-cTg mice vs IL-1β-treated WT (supplemental Figure 6). Taken together, these data suggest that Cter-FGF23 antagonizes BMP2 and BMP9-dependent stimulation of hepcidin by preventing the binding of BMP2 and BMP9 to BMP receptors.

Circulating FGF23 levels are regulated by a balance between Fgf23 transcription and FGF23 cleavage.^12,13 Associations between excess FGF23 and inflammation have generated interest in possible new functions for iFGF23 and FGF23-derived peptides. Indeed, we and others have shown that increased iFGF23 promotes inflammation.^21,47 We also showed that inflammation is a potent driver of FGF23 production.^12,39 In contrast with hyperphosphatemia, hyperparathyroidism, and other acquired or genetic conditions leading to increased iFGF23,^1-4 acute inflammation triggers an increase in FGF23 production and a concomitant increase in FGF23 cleavage. This leads to a dramatic increase in circulating total FGF23, assessed by increased cFGF23, but only a modest increase in iFGF23.^12,39 The mechanisms leading to excess FGF23 cleaved peptides remain largely undefined, and the biological significance of excess Cter-FGF23 has been under debate, considering that these peptides are devoid of a phosphaturic effect. Here, we show that both Cter-FGF23 and N-terminal FGF23 peptides are secreted from cells producing iFGF23 in response to IL-1β treatment. We demonstrate that bone is the major source of FGF23 production during acute inflammation. Most importantly, we also show that bone-produced Cter-FGF23 directly regulates iron metabolism, increases iron bioavailability, and prevents severe hypoferremia during acute inflammation by antagonizing BMP-induced hepcidin production.⁴⁸ 

FGF23 is mainly secreted from osteocytes and osteoblasts in bone.^1-4 Recent published evidence^14,18,49-52 shows that, in addition to bone, intact and cleaved FGF23 are also produced by bone marrow. Several reports suggest that inflammation-induced FGF23 excess might be the result of increased FGF23 secretion by multiple organs.^53,54 In this study, we show that bone, the main source of circulating FGF23 in physiological conditions, is also the main contributor to FGF23 production in acute inflammation. Indeed, bone-specific deletion of Fgf23 leads to 80% to 90% reduction in both intact and cFGF23. In this study, we provide an active mechanism leading to excess Cter-FGF23 during inflammation. FGF23 peptides are generated by increased post-transcriptional cleavage of iFGF23 176-RXXR-179 site.⁵⁵ O-glycosylation at the cleavage site by polypeptide N-acetylgalactosaminyl-transferase 3 (GALNT3) protects FGF23 from cleavage and ensures its secretion,^25,56 whereas phosphorylation at the cleavage site by Fam20C inhibits O-glycosylation and promotes cleavage.²⁷ Previous studies have shown that multiple proteases have the capacity to subsequently cleave FGF23 in vitro and in vivo.^26,27,57-59 Furin-like proteases have been previously described as the most likely candidates responsible for FGF23 cleavage but the exact enzyme has not been clearly identified. In addition to increased Fgf23 transcription in osteocytes, we show that inflammation leads to a reduction of Galnt3 expression that is paralleled by an increase in Fam20c expression and a very acute and sustained increase in Furin expression. Together, this represents a strong combination toward a rapid increase in FGF23 cleavage directly after it is produced. We further found that in acute inflammation, deletion of furin prevents the sharp increase in the levels of Cter-FGF23, suggesting that the coordinated increases in the expression of Fgf23 and Furin are largely responsible for excess Cter-FGF23 in response to inflammation. Although furin can process both intracellular and extracellular proteins, our data suggest that iFGF23 is cleaved intracellularly before secretion.

The dramatic increase in both Fgf23 transcription and FGF23 cleavage questions the physiological need for increased Fgf23 transcription in inflammatory conditions. Until now, the possibility for physiological and pathological effects of FGF23-derived peptides remained uncertain, because most studies focused on the function of iFGF23 only. The C-terminal domain is unique to each member of the FGF family. For FGF23, it allows binding to its coreceptor alpha klotho,^60-62 which is involved in the phosphaturic response to iFGF23. As such, a few reports have suggested that Cter-FGF23 peptides might antagonize iFGF23 signaling; however, these studies relied on the administration of Cter-FGF23 of human origin to rodents,^63-66 which might elicit different cross-species effects. However, in this study, neither the administration of murine Cter-FGF23 to WT or hyperphosphatemic animals devoid of endogenous Fgf23 production nor the bone conditional overexpression of Cter-FGF23 led to modifications of circulating phosphate levels, suggesting that Cter-FGF23 peptides do not interfere with iFGF23 signaling and iFGF23-mediated regulation of phosphate homeostasis. Excess FGF23 might be a causal factor for anemia and was associated with prevalent anemia, change in Hb over time, and development of anemia in patients with chronic kidney disease.²⁸ FGF23 has also been shown to induce anemia,²⁹ but these studies did not differentiate between iFGF23 and total cFGF23. In this study, to our knowledge, we show for the first time that Cter-FGF23 is a direct and powerful regulator of iron metabolism. Using Dmp1^KO mice, an established model of hypophosphatemic rickets with primary iFGF23 excess, we excluded bone-produced iFGF23 as a causative factor for perturbed iron metabolism or anemia, because these mice show normal iron and Hb levels. Genetic deletion of Fgf23 from bone, that leads to a decline in both Cter and iFGF23 levels, paradoxically aggravated iron deficiency in mice exposed to IL-1β injections, and we replicated these effects in mice harboring a genetic deletion of Furin in bone that prevents FGF23 cleavage and results in inadequately low levels of Cter-FGF23 in response to inflammation. Together these data suggest that increased Cter-FGF23 production is an adaptive response to prevent severe hypoferremia and aggravated anemia in inflammation.

Increased production of hepcidin in response to inflammatory cytokines is a major cause of functional iron deficiency and anemia.⁶⁷ BMP signaling in hepatocytes increases the secretion of hepcidin.^31-33 These findings show that Cter-FGF23 directly regulates iron metabolism by reducing hepcidin secretion by acting as a BMP antagonist. Whether Cter-FGF23 has other physiological functions remains to be studied. Similarly, as Cter-FGF23 peptides are only minimally increased during chronic inflammation,¹² it remains to be determined whether this increase is sufficient to reduce hepcidin and increase iron bioavailability in chronic conditions.

In multiple studies, total cFGF23, rather than iFGF23, is associated with adverse outcomes, including anemia, change in Hb over time, and mortality.^28,68 Our studies propose an active and iFGF23-independent mechanism for the iron conserving properties of bone-derived Cter-FGF23 peptides. Our results suggest that the coordinated increase in FGF23 production and cleavage in osteocytes is an initial adaptive response to alleviate the burden of anemia of inflammation and, ultimately, support an active coupling between the regulation of iron and phosphate metabolisms.

This manuscript used services from the Northwestern Proteomics Core and NUseq Core.

This study was supported by grants from National Institutes of Health to V.D. (R01DK102815, R01DK114158, R01DK132657), A.M. (R01DK101730, R01DK131046, R01DK132342), and P.J. (R01-DK124220, R01-HL148012, R01-HL150729).

Contribution: V.D. designed the study; G.C., A.M., and V.D. drafted the manuscript; and all authors contributed to data acquisition and data interpretation, revised the manuscript, reviewed and approved the final version of the manuscript.

Conflict-of-interest disclosure: V.D. received research funding from Akebia and has received research funding from Vifor Pharma and consulting honoraria from Keryx Biopharmaceuticals, Vifor Pharma, Luitpold, and Amgen, outside of the submitted work. The remaining authors declare no competing financial interests.

Correspondence: Valentin David, Division of Nephrology and Hypertension, Department of Medicine, Center for Translational Metabolism and Health, Institute for Public Health and Medicine, Northwestern University Feinberg School of Medicine, Searle 10th floor, 320 East Superior St, Chicago, IL 60611; e-mail: valentin.david@northwestern.edu.