Hepcidin-25 concentrations are markedly increased in patients with chronic kidney disease and are inversely correlated with estimated glomerular filtration rates.

BACKGROUND: Hepcidin-25 regulates iron homeostasis by binding the iron transporter ferroportin, causing its degradation. Increased hepcidin-25 causes decreased intestinal iron absorption and release from intracellular stores. Our objective in this study was to measure hepcidin-25 levels in patients with chronic kidney disease (CKD) to determine if they might contribute to the anemia of CKD. METHODS: We used a hepcidin-25-specific enzyme-linked immunosorbent assay to measure hepcidin-25 in 103 CKD patients and 100 healthy individuals. We assessed in CKD subjects the correlation of hepcidin-25 with creatinine, estimated glomerular filtration rate (eGFR), hemoglobin, blood urea nitrogen, serum iron, transferrin, and ferritin. RESULTS: Hepcidin-25 concentrations in CKD patients were significantly increased compared to healthy subjects (60.4 ± 6.1 µg/l vs. 3.0 ± 0.5 µg/l, P < 0.001). Hepcidin-25 concentrations were directly correlated with creatinine (R = 0.28, P = 0.004) and inversely correlated with eGFR (R = -0.32, P = 0.001). Hepcidin-25 levels were also correlated with transferrin (R = -0.28, P = 0.004) and ferritin (R = 0.80, P < 0.001). CONCLUSION: The direct correlation of hepcidin-25 with creatinine and its inverse correlation with eGFR suggest that hepcidin-25 levels increase as renal function deteriorates, possibly due to decreased hepcidin-25 renal clearance.

Circulating human hepcidin-25 concentrations display a diurnal rhythm, increase with prolonged fasting, and are reduced by growth hormone administration.

BACKGROUND: Hepcidin-25 reduces iron absorption by binding to the intestinal iron transporter ferroportin and causing its degradation. Currently, little is known about the basal regulation of circulating hepcidin-25. In addition, although erythropoietin administration has been reported to decrease the circulating hepcidin concentration, information is limited regarding how other stimulators of erythropoiesis, such as growth hormone (GH), might alter hepcidin-25 concentrations. METHODS: We used a sensitive and specific hepcidin-25 dual-monoclonal antibody sandwich immunoassay to measure hepcidin-25 in healthy human volunteers at various time points throughout the day and during 3 days of fasting and subsequent refeeding. We also measured hepcidin-25 concentrations in healthy volunteers after GH administration. RESULTS: In healthy individuals, hepcidin-25 concentrations displayed a diurnal variation, with concentrations being lowest in the early morning and steadily increasing throughout the day before declining during the evening hours, a pattern that was not influenced by food intake. Prolonged fasting produced statistically significant increases in hepcidin-25 concentrations. Refeeding reversed this process, and GH administration markedly decreased hepcidin-25 concentrations. CONCLUSIONS: Our results indicate that in humans, hepcidin-25 exhibits diurnal changes that can be altered by prolonged fasting, which increases hepcidin-25 concentrations approximately 3-fold after 3 days of fasting, possibly owing to a suppression of erythropoiesis that may occur during the fasting state to preserve tissue iron concentrations. In contrast, GH administration decreased hepcidin-25 concentrations by approximately 65%, presumably by stimulating erythropoiesis. These results indicate that circulating hepcidin-25 concentrations display much more dynamic and rapid variation than might have been anticipated previously.

A dual-monoclonal sandwich ELISA specific for hepcidin-25.

BACKGROUND: Hepcidin, a key regulator of iron metabolism, binds to the iron transporter ferroportin to cause its degradation. In humans, hepcidin deficiency has been linked to hemochromatosis and iron overload, whereas increased concentrations have been reported in anemia of cancer and chronic disease. There is currently an unmet clinical need for a specific immunoassay with a low limit of quantification to measure serum concentrations of hepcidin-25, the active form of the protein. METHODS: We generated 2 antihepcidin-25 monoclonal antibodies and used them to build a sandwich ELISA. We correlated ELISA results to hepcidin-25 measurements by LC-MS and used ELISA to measure serum hepcidin-25 concentrations in normal individuals, cancer patients, and patients with rheumatoid arthritis. RESULTS: The sandwich ELISA was highly specific for hepcidin-25, having a limit of quantification of 0.01 µg/L (10 pg/mL). Serum concentrations of hepcidin-25 measured by ELISA correlated with hepcidin-25 concentrations measured by using an independent LC-MS assay (r = 0.98, P < 0.001). Hepcidin-25 concentrations were increased in patients with cancer (median 54.8 µg/L, 25%-75% range 23.2-93.5 µg/L, n = 34) and rheumatoid arthritis (median 10.6 µg/L, 25%-75% range 5.9-18.4 µg/L, n = 76) compared with healthy individuals (median 1.20 µg/L, 25%-75% range 0.42-3.07 µg/L, n = 100). CONCLUSIONS: The use of 2 monoclonal antibodies in a sandwich ELISA format provides a robust and convenient method for measuring concentrations of the active form of hepcidin. This ELISA should help to improve our understanding of the role of hepcidin in regulating iron metabolism.

A novel method for quantitative measurement of a biomarker in the presence of a therapeutic monoclonal antibody directed against the biomarker.

Therapeutic monoclonal antibodies (MoAb) have become important tools in the treatment of numerous diseases. Many of these MoAb are present in the blood at very high levels due to high dosing and long half-lives. Quantification of biomarkers bound by these therapeutic MoAb can be an important factor in determining efficacy and dosing requirements. However, quantitation of these biomarkers with reasonable accuracy can be very difficult to accomplish due to concomitant binding of the therapeutic MoAb. We describe here a novel method for quantifying total (free plus bound) biomarker concentration in the presence of high levels of therapeutic MoAb using a single non-competing MoAb in a capture/elution format. This assay has the capability to accurately detect and quantitate circulating ng/ml biomarker levels in the presence of 200 microg/ml or more of therapeutic MoAb.

Comparison of assay formats for drug-tolerant immunogenicity testing.

BACKGROUND: Immunogenicity testing is required for safety assessment of biotherapeutic drugs. Because levels observed during biotherapeutic administration can approach the mg/ml range, establishing drug tolerance is significantly important for assay development. RESULTS: Three assay formats for immunogenicity assessment were tested with respect to drug tolerance: Meso Scale Discovery(®) bridging (MSDB), solid-phase extraction with acid dissociation (SPEAD) and affinity capture elution (ACE). Six biotherapeutic drugs were analyzed by the three methods; four monoclonal antibodies, one Fc fusion protein and one Pegylated protein. Overall, ACE performed best for assays involving therapeutic monoclonal antibodies and also functioned well for therapeutic proteins. Despite several advantages, the MSDB assays displayed a potentially significant hook effect. SPEAD was comparable in performance to ACE for the biotherapeutic drugs tested, but suffers the disadvantage of being reagent-intensive. CONCLUSIONS: Novel assay formats offer significant advantages for immunogenicity testing, particularly in the design of assays that are tolerant to circulating levels of the biotherapeutic drug.