Regulatory Significance of the EPO-ERFE-Hepcidin Axis in Iron Utilization and Erythropoiesis
Regulatory Significance of the EPO-ERFE-Hepcidin Axis in Iron Utilization and Erythropoiesis
Erythropoiesis is not an isolated marrow event, but the result of coordinated coupling among erythropoietic drive, systemic iron export, and the efficiency of iron utilization. The central significance of the EPO-ERFE-hepcidin axis lies in its ability to convert marrow iron demand into a whole-body iron redistribution program, thereby allowing stored iron and recycled iron to enter the bioavailable iron pool according to erythroid demand.
Keywords: EPO; ERFE; hepcidin; iron utilization; erythropoiesis; functional iron deficiency; ineffective erythropoiesis
1. Regulatory Cascade of the EPO-ERFE-Hepcidin Axis
1.1 Upstream driving role of EPO
EPO is positioned upstream in this axis. Hypoxia, blood loss, shortened erythrocyte lifespan, or exogenous erythropoietic stimulation can all increase EPO, thereby enhancing the proliferation and differentiation of erythroid progenitors and precursors in the marrow. As a consequence, the immediate iron demand of the erythroid system rises in parallel.
The significance of EPO does not lie in directly releasing iron, but in first establishing erythropoietic demand. In experimental settings, if EPO is already markedly elevated while downstream iron export does not increase accordingly, the marrow phenotype does not primarily reflect insufficient erythropoietic stimulation, but rather a lag in the iron-supply response.
1.2 Marrow-to-liver signaling role of ERFE
ERFE is produced by erythroid precursors and serves as a key intermediary molecule after EPO stimulation. Its principal function is to transmit the marrow iron-demand signal to the liver, resulting in suppression of hepcidin expression.
The research value of ERFE within this axis is mainly reflected in the following aspects:
(1) Determining whether the marrow has entered a high iron-demand state.
(2) Distinguishing between “elevated EPO with insufficient marrow signaling” and “elevated EPO with an established marrow-derived suppressive signal.”
(3) Identifying marrow-derived output under persistent high erythropoietic drive in ineffective erythropoiesis.
1.3 Effector role of hepcidin
Hepcidin is produced by hepatocytes and serves as the master gatekeeper of systemic iron homeostasis. Its direct target is ferroportin. When hepcidin is increased, ferroportin undergoes internalization and degradation, resulting in reduced intestinal iron absorption and decreased iron release from macrophages and hepatocytes. When hepcidin is decreased, systemic iron export is enhanced, making circulating iron more readily available to the marrow for erythropoiesis.
Accordingly, the significance of hepcidin is not simply to indicate “iron excess” or “iron deficiency,” but to determine whether iron can exit storage sites and recycling sites.
1.4 Terminal significance of ferroportin and circulating iron
Ferroportin lies immediately downstream of hepcidin regulation and is the key channel through which iron exits cells and enters the circulation. This layer determines whether two major iron fluxes can be established:
(1) Intestinally absorbed iron entering the transferrin-bound iron pool.
(2) Recycled iron released from macrophages back into the circulation.
Because erythropoiesis depends predominantly on recycled iron, short-term regulation is often reflected first in macrophage iron release rather than in intestinal iron absorption.
Table 1. Hierarchical roles within the EPO-ERFE-hepcidin axis
Regulatory level | Main source | Direct target | Major physiologic effect | Key interpretive focus |
EPO | Kidney | Marrow erythroid precursors | Establishes erythropoietic drive | Whether erythroid demand has been initiated |
ERFE | Erythroid precursors | Hepatic hepcidin expression | Suppresses hepcidin | Whether the marrow iron-demand signal has been successfully conveyed to the liver |
Hepcidin | Hepatocytes | Ferroportin | Controls intestinal iron absorption and macrophage iron release | Whether the iron-export gate has been opened |
Ferroportin/circulating iron | Intestinal epithelium, macrophages, hepatocytes, plasma | Marrow erythroid system | Provides substrate for heme synthesis | Whether iron has truly entered the marrow bioavailable iron pool |
2. Regulatory Significance Under Physiologic Conditions
2.1 Basal coordination in steady-state erythropoiesis
During steady-state erythropoiesis, the EPO-ERFE-hepcidin axis is not continuously activated at high amplitude. Under these conditions, erythrocyte production remains relatively stable, ERFE usually fluctuates at low levels, and hepcidin dynamically balances iron stores, mild erythropoietic demand, and recycling efficiency.
The significance of this stage is not strong iron mobilization, but retention of the capacity for rapid amplification. Once stress erythropoiesis is initiated, the amplitude of axis activation increases markedly.
2.2 Rapid iron supply during stress erythropoiesis
Acute blood loss, acute hypoxia, ESA stimulation, and recovery from acute hemolysis are the most typical scenarios in which this axis is activated. In these settings, EPO rises first, ERFE subsequently increases, hepcidin declines, and systemic iron export is enhanced.
This sequence determines the key focus of experimental interpretation:
(1) Erythropoietic demand is established first.
(2) The marrow iron-demand signal is then transmitted to the liver.
(3) The iron-export gate is subsequently opened.
(4) Changes in circulating iron and reticulocytes appear last.
If only endpoint serum iron or hemoglobin is assessed, the intermediate phase in which the axis has already been activated but iron redistribution is not yet complete can easily be overlooked.
2.3 Recycled iron is prioritized over newly absorbed iron
Most of the iron required for adult erythropoiesis is derived from the re-release of iron recycled by macrophages from senescent erythrocytes, rather than from newly absorbed iron. After hepcidin declines, the earliest effect is usually enhanced release of recycled iron from macrophages, followed only later by increased intestinal absorption.
This distinction has direct implications for study design:
(1) In short-term interventions, changes in recycled iron usually precede intestinal absorption effects.
(2) Short-term downregulation of hepcidin does not necessarily cause an immediate decline in iron stores.
(3) The state of the macrophage system can substantially influence short-term manifestations of this axis.
2.4 Rhythmic iron supply during hemoglobinization
Marrow access to iron does not guarantee effective erythropoiesis. What ultimately determines output quality is the efficiency with which iron is utilized after entering erythroid precursors, including:
(1) Transferrin receptor-mediated uptake.
(2) Mitochondrial heme synthesis.
(3) Coupling between iron-sulfur cluster metabolism and erythroid maturation.
(4) Intracellular iron redistribution within pre-maturation erythroid cells.
Therefore, the EPO-ERFE-hepcidin axis addresses whether iron can be delivered to the marrow, rather than whether the marrow can efficiently convert that iron into mature erythrocytes.
3. Axis Shifts Under Pathologic Conditions
3.1 Absolute iron deficiency
In absolute iron deficiency, the organism may still enhance iron mobilization through increased EPO, upregulated ERFE, and suppressed hepcidin; however, the mobilizable iron pool itself is already insufficient. In this context, the axis reflects compensation rather than correction.
Typical features include:
(1) Increased erythropoietic demand.
(2) A tendency toward opening the iron-export gate.
(3) Insufficiency of both iron stores and circulating iron.
(4) Persistent limitation of erythropoiesis by lack of substrate.
Under these conditions, low hepcidin does not indicate sufficient iron supply, but only that the system is reducing resistance to iron export as much as possible.
3.2 Functional iron deficiency
In functional iron deficiency, the problem is not absence of body iron, but failure of iron to effectively enter the marrow bioavailable iron pool. This state commonly occurs in chronic inflammation, chronic disease, and some ESA-treated settings. Its core contradictions include:
(1) Iron stores are present.
(2) Hepcidin is relatively elevated.
(3) Iron release from macrophages and the liver is suppressed.
(4) Transferrin saturation is insufficient.
(5) The marrow exhibits restricted iron supply.
Accordingly, ferritin may be normal or even increased, while the erythroid system still displays an iron-deficient phenotype.
3.3 Anemia of inflammation
In anemia of inflammation, inflammatory mediators such as IL-6 can directly drive hepcidin elevation. Even when the marrow has erythropoietic demand, the suppressive effect of ERFE on hepcidin may be partially offset by inflammatory upstream signaling. The result is iron sequestration, hypoferremia, and reduced erythroid output.
Interpretation in this condition should focus on obstruction of iron flux rather than absolute iron deficiency. If iron supply is judged only on the basis of ferritin, iron-restricted erythropoiesis can easily be underestimated.
3.4 Chronic kidney disease
In chronic kidney disease, abnormalities of this axis involve multiple superimposed layers:
(1) Endogenous EPO is insufficient, reducing erythropoietic drive.
(2) Inflammation and impaired renal function together maintain hepcidin at a high level.
(3) After exogenous ESA treatment, ERFE may increase, but hepcidin may not decline adequately.
(4) The marrow ultimately shows an established erythropoietic stimulus but persistent restriction of iron supply.
Therefore, ESA hyporesponsiveness in CKD cannot be explained solely by EPO deficiency, nor solely by inadequate iron supplementation. It should instead be analyzed within the framework of overall mismatch in the EPO-ERFE-hepcidin axis.
3.5 Ineffective erythropoiesis
In β-thalassemia and some forms of MDS with ineffective erythropoiesis, EPO remains chronically elevated, ERFE is persistently overexpressed, and hepcidin is continuously suppressed, leading to sustained enhancement of intestinal iron absorption and systemic iron release. However, erythroid maturation efficiency remains poor, and iron cannot be effectively incorporated into mature erythrocytes.
The key contradictions in this state include:
(1) Persistently high erythropoietic drive.
(2) Continuous marrow-derived suppression of hepcidin signaling to the liver.
(3) Increased systemic iron input.
(4) Inadequate erythroid maturation efficiency.
(5) Diversion of excess iron into the liver and other organs.
Table 2. Typical patterns of the EPO-ERFE-hepcidin axis in different scenarios
Scenario | EPO | ERFE | Hepcidin | Iron-utilization outcome | Main consequence |
Acute blood loss/hypoxia/ESA stimulation | ↑ | ↑ | ↓ | Rapid mobilization of iron to the marrow | Supports stress erythropoiesis |
Absolute iron deficiency | ↑ or relatively ↑ | ↑ | ↓ | Intention to export iron is present, but the iron pool is insufficient | Erythropoiesis remains substrate-limited |
Functional iron deficiency/anemia of inflammation | ↑ or normal | May increase but is constrained | ↑ | Iron is restricted within storage and recycling pools | Iron-restricted erythropoiesis |
Chronic kidney disease | ↓ or fluctuating after exogenous supplementation | Variable | Usually ↑ | Axis mismatch | ESA hyporesponsiveness and inadequate iron supply |
Ineffective erythropoiesis | Persistently ↑ | Persistently ↑ | Persistently ↓ | Increased iron input but poor erythroid utilization efficiency | Anemia with iron overload |
4. Experimental Interpretation and Study Design
4.1 Limitations of single markers
EPO, ERFE, and hepcidin cannot individually define the status of this axis.
(1) Elevated EPO only indicates that erythropoietic drive has been established.
(2) Elevated ERFE only indicates that the marrow has emitted a suppressive signal.
(3) A change in hepcidin only indicates the state of the iron-export gate.
What truly reflects whether erythroid iron supply is effective is the combined analysis of these markers with Hb, reticulocytes, sTfR, Ret-He, TSAT, serum iron, and ferritin.
4.2 Marker combinations with greater interpretive value
More informative combinations in research include:
(1) EPO + ERFE + hepcidin: to determine whether the axis is transmitting signals in the expected direction.
(2) Hepcidin + TSAT + ferritin: to distinguish iron storage status from bioavailable iron status.
(3) sTfR + Ret-He + reticulocytes: to evaluate erythroid iron demand and immediate erythropoietic output.
(4) CRP/IL-6 + hepcidin: to identify inflammation-driven elevation of hepcidin.
(5) Renal function markers + EPO + hepcidin: to identify multilayer mismatch in CKD.
4.3 Necessity of time-series analysis
The core molecules of this axis do not change synchronously. After erythropoietic stimulation, EPO changes first, ERFE then rises, hepcidin subsequently declines, and only afterward do circulating iron and erythroid output change. If only a single time point is collected, critical regulatory windows can easily be missed.
Time-series designs are particularly suitable for the following scenarios:
(1) ESA stimulation experiments.
(2) Blood-loss recovery models.
(3) Hypoxia or HIF-stabilization models.
(4) Dynamic comparisons before and after iron supplementation.
(5) Inflammation-erythropoiesis interaction studies.
4.4 Common interpretive biases
The most common biases in studies of the EPO-ERFE-hepcidin axis include:
(1) Interpreting high ferritin directly as sufficient iron supply.
(2) Interpreting low hepcidin directly as absolute iron deficiency.
(3) Interpreting elevated ERFE directly as effective erythropoiesis.
(4) Ignoring reshaping of the hepcidin background by inflammation and renal dysfunction.
(5) Focusing only on the Hb endpoint rather than on erythroid output and iron-flux processes.
Table 3. Marker combinations and experimental applications
Marker combination | Main question addressed | More suitable research scenarios |
EPO + ERFE + hepcidin | Whether the axis is activated sequentially | Erythropoietic stimulation, hypoxia, and ESA studies |
Hepcidin + TSAT + ferritin | Whether stored iron and bioavailable iron are concordant | Iron deficiency, inflammation, CKD |
sTfR + Ret-He + reticulocytes | Whether marrow iron supply meets immediate erythropoietic needs | Functional iron deficiency, iron-supplementation intervention |
CRP/IL-6 + hepcidin | Whether hepcidin elevation is inflammation-driven | Anemia of inflammation, chronic disease |
EPO + hepcidin + renal function markers | Whether erythropoietic drive and iron release are aligned in CKD | Analysis of ESA responsiveness |
5. Products Related to Research on the EPO-ERFE-Hepcidin Axis
Table 4. Gene Tools for Upstream Erythropoietic Signaling and Hepcidin Transcriptional Regulation
Product type | Catalog No. | Name | Grade and purity | Suitable research use/application |
Gene silencing | EPO Human Pre-designed siRNA Set A | — | Used to selectively reduce the upstream variable EPO and determine whether marrow iron-demand signaling is correspondingly weakened | |
Gene silencing | EPOP Human Pre-designed siRNA Set A | — | Used to extend analysis of the EPO-related regulatory network and assess the role of accessory factors in stabilizing erythropoietic input | |
Gene silencing | EPOR Human Pre-designed siRNA Set A | — | Used to distinguish between insufficient EPO and insufficient receptor responsiveness as two distinct causes of impaired erythropoiesis | |
Gene silencing | ERFE Human Pre-designed siRNA Set A | — | Used to reduce ERFE and assess its role in hepcidin suppression by marrow iron-demand signaling | |
Gene silencing | BMP6 Human Pre-designed siRNA Set A | — | Used to attenuate pro-hepcidin input from the hepatic side and determine whether ERFE-mediated suppression becomes more apparent | |
Gene silencing | SMAD1 Human Pre-designed siRNA Set A | — | Used to dissect the contribution of the Smad1 layer within BMP-SMAD signaling to hepcidin transcription | |
Gene silencing | SMAD2 Human Pre-designed siRNA Set A | — | Used to assess whether Smad2 participation influences the hepatic background level of hepcidin expression | |
Gene silencing | SMAD3 Human Pre-designed siRNA Set A | — | Used to compare changes in Smad3 with hepcidin transcriptional activity | |
Gene silencing | SMAD4 Human Pre-designed siRNA Set A | — | Used to determine whether Smad4 is a key node in the hepatic transcriptional complex | |
Gene silencing | SMAD5 Human Pre-designed siRNA Set A | — | Used to evaluate the strength of Smad5 function between BMP input and hepcidin output | |
Gene silencing | SMAD9 Human Pre-designed siRNA Set A | — | Used to explore the auxiliary role of Smad9 in hepatic iron sensing and transcriptional regulation | |
Gene silencing | SMAD6 Human Pre-designed siRNA Set A | BioReagent, for DNA and RNA applications, sterile, DNase- and RNase-free | Used to relieve negative feedback inhibition and determine whether hepcidin can be more readily upregulated by upstream pathways | |
Gene silencing | SMAD7 Human Pre-designed siRNA Set A | BioReagent, sterile, for DNA and RNA applications, DNase- and RNase-free | Used to analyze the risk of sustained high hepcidin expression after reduction of a negative regulatory factor |
Table 5. Products for Erythropoietic Modeling and Pathway Loss-of-Function Validation
Product type | Catalog No. | Name | Grade and purity | Suitable research use/application |
mRNA tool | EPO mRNA | BioReagent, Integrity of mRNA ≥85% (CE); 1.0 mg/mL | Used to rapidly establish an exogenous enhanced-erythropoiesis model and observe the temporal relationship between EPO elevation and hepcidin suppression | |
mRNA tool | EPO mRNA(N1-Me-pUTP) | BioReagent, Integrity of mRNA ≥85% (CE); 1.0 mg/mL | Suitable for stable-expression conditions and for assessing the amplitude of ERFE response under enhanced erythropoietic drive | |
Gene-editing support | pLenti-EPO-sgRNA | pLenti-EPO-sgRNA | Used for protein-level validation of EPO-deficient models as control material for weakened upstream initiating signals | |
Gene-editing support | pLenti-EPO-sgRNA | pLenti-EPO-sgRNA | Used for transcriptional validation of EPO-deficient models | |
Gene-editing support | pLenti-BMP6-sgRNA | pLenti-BMP6-sgRNA | Used for protein-level validation after BMP6 deletion and for analyzing hepcidin changes when hepatic input is weakened | |
Gene-editing support | pLenti-BMP6-sgRNA | pLenti-BMP6-sgRNA | Used for mRNA-level validation after BMP6 deletion | |
Gene-editing support | pLenti-SMAD1-sgRNA | pLenti-SMAD1-sgRNA | Used for protein-level validation of SMAD1-deficient models | |
Gene-editing support | pLenti-SMAD1-sgRNA | pLenti-SMAD1-sgRNA | Used for transcriptional validation of SMAD1-deficient models | |
Gene-editing support | pLenti-SMAD2-sgRNA | pLenti-SMAD2-sgRNA | Used for protein-level validation of SMAD2-deficient models | |
Gene-editing support | pLenti-SMAD2-sgRNA | pLenti-SMAD2-sgRNA | Used for transcriptional validation of SMAD2-deficient models | |
Gene-editing support | pLenti-SMAD3-sgRNA | pLenti-SMAD3-sgRNA | Used for protein-level validation of SMAD3-deficient models | |
Gene-editing support | pLenti-SMAD3-sgRNA | pLenti-SMAD3-sgRNA | Used for transcriptional validation of SMAD3-deficient models | |
Gene-editing support | pLenti-SMAD4-sgRNA | pLenti-SMAD4-sgRNA | Used for protein-level validation of SMAD4-deficient models | |
Gene-editing support | pLenti-SMAD4-sgRNA | pLenti-SMAD4-sgRNA | Used for transcriptional validation of SMAD4-deficient models | |
Gene-editing support | pLenti-SMAD5-sgRNA | pLenti-SMAD5-sgRNA | Used for protein-level validation of SMAD5-deficient models | |
Gene-editing support | pLenti-SMAD5-sgRNA | pLenti-SMAD5-sgRNA | Used for transcriptional validation of SMAD5-deficient models | |
Gene-editing support | pLenti-SMAD6-sgRNA | pLenti-SMAD6-sgRNA | Used for protein-level validation of SMAD6-deficient models | |
Gene-editing support | pLenti-SMAD6-sgRNA | pLenti-SMAD6-sgRNA | Used for transcriptional validation of SMAD6-deficient models | |
Gene-editing support | pLenti-SMAD9-sgRNA | pLenti-SMAD9-sgRNA | Used for protein-level validation of SMAD9-deficient models | |
Gene-editing support | pLenti-SMAD9-sgRNA | pLenti-SMAD9-sgRNA | Used for transcriptional validation of SMAD9-deficient models |
Table 6. Products for Axis Activation and Functional Intervention of the Iron-Export Gate
Product type | Catalog No. | Name | Grade and purity | Suitable research use/application |
Recombinant protein | Recombinant Human EPO Protein | Carrier-free, bioactive, ActiBioPure™, azide-free, high performance, Fc tag, ≥95% (SDS-PAGE & HPLC) | Suitable for establishing acute human erythropoietic stimulation models and assessing whether ERFE and hepcidin change sequentially | |
Recombinant protein | Recombinant Human Erythropoietin/EPO Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, azide-free, high performance, His tag, ≥95% (SDS-PAGE), see COA | Suitable for comparing the degree of amplification of erythroid iron-demand signaling under different erythropoietic intensities | |
Recombinant protein | Recombinant Human Erythropoietin/EPO Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, ≥90% (SDS-PAGE), see COA | Suitable for routine EPO stimulation experiments and dose-response analysis | |
Recombinant protein | Recombinant Mouse Erythropoietin/EPO Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, His tag, ≥90% (SDS-PAGE) | Suitable for mouse stress erythropoiesis and ineffective erythropoiesis models | |
Recombinant protein | Recombinant Human IL-6 GMP Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, ≥97% (SDS-PAGE & SEC-HPLC) | Suitable for generating highly consistent inflammatory input and comparing competition between inflammatory and erythropoietic signaling | |
Recombinant protein | Recombinant Human IL-6 Protein | Carrier-free, bioactive, ActiBioPure™, high performance, ≥95% (SDS-PAGE), see COA | Suitable for inducing high-hepcidin states and assessing whether ERFE-mediated suppression is overridden | |
Recombinant protein | Recombinant Human IL-6 Protein | Carrier-free, bioactive, ActiBioPure™, high performance, ≥95% (SDS-PAGE), see COA | Suitable for general inflammatory stimulation experiments | |
Recombinant protein | Recombinant Human IL-6 Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, His tag, ≥95% (SDS-PAGE), see COA | Suitable for use in receptor-level experiments to assess ligand-receptor efficiency | |
Recombinant protein | Recombinant Human IL-6 Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, ≥95% (SDS-PAGE) | Suitable for inflammatory-input models in human cells | |
Recombinant protein | Recombinant Human IL-6 Protein | Carrier-free, bioactive, ActiBioPure™, azide-free, high performance, His tag, ≥95% (SDS-PAGE) | Suitable for cell-function stimulation under azide-free conditions | |
Recombinant protein | Recombinant Human IL-6 Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, His tag, ≥95% (SDS-PAGE) | Suitable for studies of the inflammation-hepcidin pathway | |
Recombinant protein | Recombinant Human IL-6 Protein | Carrier-free, bioactive, ActiBioPure™, high performance, ≥95% (SDS-PAGE), see COA | Suitable for parallel replicates and condition optimization | |
Recombinant protein | Recombinant Human IL-6/IL-6R alpha Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, high performance, His tag, ≥90% (SDS-PAGE) | Suitable for testing whether ligand-receptor complex input more strongly drives high-hepcidin states | |
Recombinant protein | Recombinant Human IL-6R Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, azide-free, high performance, His tag, ≥90% (SDS-PAGE) | Suitable for receptor-binding and blockade validation | |
Recombinant protein | Recombinant Human IL-6R alpha Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, His tag, ≥95% (SDS-PAGE) | Suitable for analyzing the effect of the IL-6R layer on inflammatory input strength | |
Recombinant protein | Recombinant Mouse IL-6 Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, azide-free, high performance, His tag, ≥95% (SDS-PAGE) | Suitable for mouse anemia-of-inflammation models | |
Recombinant protein | Recombinant Mouse IL-6 Protein | ActiBioPure™, Bioactive, Animal Free, Carrier Free, Azide Free, High performance, ≥96% (SDS-PAGE & HPLC) | Suitable for mouse inflammatory stimulation experiments | |
Recombinant protein | Recombinant Mouse IL-6R alpha Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, His tag, ≥90% (SDS-PAGE) | Suitable for mouse receptor-level studies | |
Recombinant protein | Recombinant Rat IL-6 Protein | ActiBioPure™, Bioactive, Animal Free, Carrier Free, Azide Free, High performance, ≥96% (SDS-PAGE & HPLC) | Suitable for rat inflammation-hepcidin models | |
Recombinant protein | Recombinant Human SMAD2 Protein | Carrier-free, His tag, ≥90% (SDS-PAGE), see COA | Suitable for validating the extent of SMAD2 involvement | |
Recombinant protein | Recombinant Human SMAD4 Protein | Carrier-free, His tag, ≥90% (SDS-PAGE), see COA | Suitable for analyzing the role of SMAD4 in the hepcidin transcriptional complex | |
Recombinant protein | Recombinant Human Smad3 Protein | Carrier-free, azide-free, His tag, ≥90% (SDS-PAGE) | Suitable for SMAD3-related signaling studies | |
Recombinant protein | Recombinant Human Smad3 Protein | Carrier-free, azide-free, His tag, ≥95% (SDS-PAGE) | Suitable for high-purity SMAD3 functional studies | |
Receptor protein | Recombinant Human Erythropoietin R Protein | Animal-free, carrier-free, bioactive, ActiBioPure™, azide-free, His tag, Fc tag, ≥95% (SDS-PAGE) | Suitable for EPO-EPOR binding validation, receptor blockade, or competition assays | |
Functional peptide | Hepcidin-1 (mouse), TFA | BioReagent, ≥95% (HPLC) | Suitable for supplementation of hepcidin in mouse in vivo or in vitro models to directly test whether high hepcidin is sufficient to suppress iron supply | |
Functional peptide | Hepcidin-20 (human), trifluoroacetate salt | BioReagent, ≥95% (HPLC) | Suitable for comparing the effects of different hepcidin isoforms on ferroportin regulation | |
Functional peptide | Hepcidin-25 (human), trifluoroacetate salt | BioReagent, ≥95% (HPLC) | Suitable for establishing active human hepcidin supplementation models and directly validating suppression of systemic iron export |
Table 7. Products for Inflammation-Hepcidin Blockade and Pathway Protein Validation
Product type | Catalog No. | Name | Grade and purity | Suitable research use/application |
Antibody/antagonist | LY2787106 (anti-Hepcidin) | Carrier-free, recombinant, ExactAb™, low endotoxin, azide-free, validated, animal-free, ≥95% (SDS-PAGE & SEC-HPLC), see COA | Suitable for relieving iron-export restriction under high-hepcidin conditions and determining whether functional iron deficiency is hepcidin-driven | |
Antibody/antagonist | APX-007 (anti-IL-6Ra) | Carrier-free, recombinant, ExactAb™, low endotoxin, azide-free, validated, animal-free, ≥95% (SDS-PAGE & SEC-HPLC), see COA | Suitable for blocking IL-6R-level inflammatory input and assessing whether high-hepcidin states can be reversed | |
Antibody/antagonist | Chugai SK2 (anti-IL-6) | Carrier-free, recombinant, ExactAb™, low endotoxin, azide-free, validated, animal-free, ≥95% (SDS-PAGE & SEC-HPLC), see COA | Suitable for direct neutralization of IL-6 to determine whether inflammatory input dominates hepcidin elevation | |
Antibody/antagonist | MEDI-5117 (anti-IL-6) | Carrier-free, recombinant, ExactAb™, low endotoxin, azide-free, validated, animal-free, ≥95% (SDS-PAGE & SEC-HPLC), see COA | Suitable for blockade of the IL-6 pathway and analysis of reversibility of inflammation-associated high hepcidin | |
Antibody | BMP6 Antibody | Carrier Free, ExactAb™, Validated, 1.0 mg/mL | Suitable for assessing whether BMP6 background drive contributes to maintenance of high hepcidin expression | |
Antibody | IL-6 Antibody | ExactAb™, validated, 1.0 mg/mL | Suitable for confirming inflammatory background and providing upstream evidence for abnormal hepcidin elevation | |
Antibody | IL-6 Mouse mAb | Carrier-free, ExactAb™, azide-free, validated, high performance, ≥95% (SDS-PAGE), 1.0 mg/mL | Suitable for IL-6 protein detection and inflammatory-gradient comparison | |
Antibody | IL-6 Mouse mAb | ExactAb™, validated, carrier-free, azide-free, high performance, ≥95% (SDS-PAGE), 0.5 mg/mL | Suitable for IL-6 validation in low-input samples | |
Antibody | IL-6 Mouse mAb | Carrier-free, ExactAb™, azide-free, validated, high performance, ≥95% (SDS-PAGE), 1.0 mg/mL | Suitable for IL-6 detection in inflammatory models | |
Antibody | IL-6 Mouse mAb | ExactAb™, validated, carrier-free, azide-free, high performance, ≥95% (SDS-PAGE), 1.0 mg/mL | Suitable for validation of IL-6 protein expression | |
Antibody | IL-6 Mouse mAb | Carrier-free, ExactAb™, azide-free, validated, see COA | Suitable for routine IL-6 detection | |
Antibody | IL-6 Mouse mAb | Carrier-free, ExactAb™, azide-free, validated, see COA | Suitable for routine IL-6 detection | |
Antibody | MADH7/SMAD7 Antibody | Validated, 1.0 mg/mL | Suitable for analyzing whether BMP/SMAD negative feedback participates in restricting hepcidin transcription | |
Antibody | Recombinant Phospho-Smad2 (S250) Antibody | Knockdown-validated | Suitable for determining whether SMAD2 enters an activated state | |
Antibody | Recombinant Phospho-Smad3 (S423 + S425) Antibody | Knockout-validated | Suitable for directly assessing whether activated SMAD3 participates in hepatic hepcidin transcription | |
Antibody | Recombinant SMAD Family Member 1 Antibody | Knockdown-validated | Suitable for SMAD1 detection | |
Antibody | Recombinant SMAD3 Antibody | ExactAb™, Validated, recombinant, 1 mg/mL | Suitable for SMAD3 detection | |
Antibody | Recombinant SMAD5 Antibody | Knockdown-validated | Suitable for SMAD5 detection | |
Antibody | Recombinant Smad1 Antibody | ExactAb™, Validated, recombinant, 0.8 mg/mL | Suitable for Smad1 detection | |
Antibody | Recombinant Smad2 Antibody | Knockout-validated | Suitable for Smad2 detection | |
Antibody | Recombinant Smad2 Antibody | Knockdown-validated | Suitable for Smad2 detection | |
Antibody | Recombinant Smad2 Antibody | Recombinant, ExactAb™, validated, see COA | Suitable for Smad2 detection | |
Antibody | Recombinant Smad4 Antibody | ExactAb™, Validated, recombinant, 0.6 mg/mL | Suitable for Smad4 detection | |
Antibody | Recombinant Smad4 Antibody | Knockdown-validated | Suitable for Smad4 detection | |
Antibody | SMAD5 Mouse mAb | ExactAb™, Validated, 1.6 mg/mL | Suitable for SMAD5 detection | |
Antibody | SMAD6 Antibody | Validated, ExactAb™, 1.0 mg/mL | Suitable for detecting SMAD6-mediated negative regulatory input | |
Antibody | SMAD9 Antibody | Carrier-free, ExactAb™, validated, high performance, see COA | Suitable for SMAD9 detection |
Table 8. Products for Quantitative Axis Assessment and Functional Readouts of Iron Availability
Product type | Catalog No. | Name | Grade and purity | Suitable research use/application |
ELISA kit | Human Erythropoietin (EPO) ELISA Kit | BioReagent | Suitable for quantitative evaluation of erythropoietic drive in human samples | |
ELISA kit | Human Erythropoietin/EPO ELISA Kit | BioReagent | Suitable for parallel validation of human EPO levels | |
ELISA kit | Human Erythropoietin Receptor (EPOR) ELISA Kit | BioReagent | Suitable for comparing EPOR expression backgrounds across models | |
ELISA kit | Rat Erythropoietin (EPO) ELISA Kit | BioReagent | Suitable for EPO quantification in rat blood-loss, hypoxia, and renal-anemia models | |
ELISA kit | Rat Erythropoietin/EPO ELISA Kit | BioReagent | Suitable as an alternative for rat EPO measurement | |
ELISA kit | Mouse Erythropoietin (EPO) ELISA Kit | BioReagent | Suitable for mouse stress erythropoiesis and ineffective erythropoiesis models | |
ELISA kit | Mouse Erythropoietin/EPO ELISA Kit | BioReagent | Suitable as an alternative for mouse EPO measurement | |
ELISA kit | Monkey Erythropoietin (EPO) ELISA Kit | BioReagent | Suitable for assessing erythropoietic drive in primate models | |
ELISA kit | Human Hepcidin (Hepcidin) ELISA Kit | BioReagent | Suitable for quantitative assessment of iron-export gate status in human samples, especially for anemia stratification and pre-/post-intervention comparison | |
ELISA kit | Rat Hepcidin (Hepcidin) ELISA Kit | BioReagent | Suitable for dynamic assessment of hepcidin in rat blood-loss, inflammation, and CKD models | |
ELISA kit | Mouse Hepcidin (Hepcidin) ELISA Kit | BioReagent | Suitable for quantitative hepcidin analysis in mouse stress erythropoiesis and ineffective erythropoiesis models | |
ELISA kit | Human Bone Morphogenetic Protein 6 (BMP6) ELISA Kit | BioReagent | Suitable for joint quantification of BMP6 and hepcidin to assess the strength of hepatic input | |
ELISA kit | Human Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable for quantifying inflammatory input and correlating it with hepcidin changes | |
ELISA kit | Human Interleukin 6 Receptor (IL-6R) ELISA Kit | BioReagent | Suitable for analyzing whether receptor-level signaling contributes to inflammation-associated high hepcidin | |
ELISA kit | Rabbit Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable for inflammatory-background detection in rabbit models | |
ELISA kit | Rat Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable for IL-6 quantification in rat inflammatory models | |
ELISA kit | Rat Interleukin 6 Receptor (IL-6R) ELISA Kit | BioReagent | Suitable for rat IL-6R detection | |
ELISA kit | Mouse Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable for IL-6 quantification in mouse inflammatory models | |
ELISA kit | Mouse Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable as an alternative choice for mouse IL-6 quantification | |
ELISA kit | Mouse Interleukin 6 Receptor (IL-6R) ELISA Kit | BioReagent | Suitable for mouse IL-6R detection | |
ELISA kit | Monkey Interleukin 6 (IL-6) ELISA Kit | BioReagent | Suitable for inflammatory-background detection in primates | |
ELISA kit | Human SMAD3 ELISA Kit | BioReagent | Suitable for quantitative tracking of SMAD3 changes in relation to hepcidin transcriptional status | |
ELISA kit | Human Mothers Against Decapentaplegic Homolog 2 (Smad2) ELISA Kit | BioReagent | Suitable for quantitative Smad2 detection | |
ELISA kit | Human SMAD Family Member 3 (SMAD3) ELISA Kit | BioReagent | Suitable for quantitative Smad3 detection | |
ELISA kit | Human Mothers Against Decapentaplegic Homolog 4 (Smad4) ELISA Kit | BioReagent | Suitable for quantitative Smad4 detection | |
ELISA kit | Human SMAD Family Member 5(Smad5) ELISA Kit | BioReagent | Suitable for quantitative Smad5 detection | |
ELISA kit | Human Mothers Against Decapentaplegic Homolog 7 (Smad7) ELISA Kit | BioReagent | Suitable for quantitative Smad7 detection | |
ELISA kit | Rat SMAD3 ELISA Kit | BioReagent | Suitable for rat Smad3 detection | |
ELISA kit | Rat Mothers Against Decapentaplegic Homolog 3 (Smad3) ELISA Kit | BioReagent | Suitable for rat Smad3 detection | |
ELISA kit | Rat Mothers Against Decapentaplegic Homolog 7 (Smad7) ELISA Kit | BioReagent | Suitable for rat Smad7 detection | |
ELISA kit | Mouse SMAD3 ELISA Kit | BioReagent | Suitable for mouse Smad3 detection | |
ELISA kit | Mouse Mothers Against Decapentaplegic Homolog 4 (Smad4) ELISA Kit | BioReagent | Suitable for mouse Smad4 detection | |
Nucleic acid tool | IL-6 aptamer sodium | — | Suitable for IL-6 binding or antagonism studies to refine the inflammatory driver layer | |
Reporter system | Lenti-IL-6 promoter-Luc-EF1α-mCherry-T2A-Puro | 10^8 TU/mL | Suitable for monitoring successful establishment of inflammatory input and matching it temporally with hepcidin changes | |
Transferrin | Recombinant Human Holo-Transferrin | Animal-free, carrier-free, bioactive, ActiBioPure™, low endotoxin, high performance, for cell culture, ≥95% (SDS-PAGE), iron content >1000 ppm | Suitable for selectively increasing bioavailable iron input and distinguishing between iron-supply insufficiency and utilization defects | |
Probe | FerroOrange | ≥98% | Suitable for directly assessing whether hepatic iron release is truly converted into intracellular Fe2+ available to cells |
The significance of the EPO-ERFE-hepcidin axis lies in its ability to translate marrow erythropoietic demand into a systemic iron redistribution command. When this axis functions normally, erythropoietic drive, the iron-export gate, and marrow utilization remain directionally aligned. When the axis is blocked, iron may remain trapped in storage and recycling compartments. When the axis is chronically overactivated, iron overload may emerge in the setting of ineffective erythropoiesis. In research design and result interpretation, the key is not to compare a single marker in isolation, but to determine whether erythropoietic signaling, marrow-derived suppressive signaling, and the systemic iron-export gate still operate in the same regulatory direction.
