Ligand Systems, Receptor Activation, and Biological Effects of the FGF Pathway
Ligand Systems, Receptor Activation, and Biological Effects of the FGF Pathway
The FGF (fibroblast growth factor) pathway is one of the most important growth factor signaling networks in multicellular organisms, spanning embryonic development, tissue homeostasis, metabolic regulation, injury repair, and tumor progression. The research focus of this pathway is not limited to FGF-FGFR binding itself, but rather lies in how ligand subgroups, receptor splice variants, co-receptors, extracellular matrix context, and downstream signaling branches collectively determine the final output. As a result, this pathway displays marked tissue specificity and context dependence.
Keywords: FGF; FGFR; fibroblast growth factor receptor; Klotho; RAS-MAPK; PI3K-AKT; PLCγ; developmental signaling pathway
1. Basic Composition of the FGF Family
1.1 Ligand Family
The FGF family contains a relatively large number of members and, in humans, generally includes FGF1 through FGF23, although not all members function in exactly the same manner. Based on mode of action and molecular characteristics, they can be broadly divided into paracrine, endocrine, and intracellular classes.
(1) Paracrine FGFs
These members include FGF1, FGF2, FGF4, FGF7, FGF8, FGF9, FGF10, and FGF18. They usually depend on heparan sulfate proteoglycans (HSPGs) to stabilize the ligand-receptor complex, act over short distances, and are more strongly associated with regulation of proliferation, differentiation, and migration within the local microenvironment.
(2) Endocrine FGFs
Representative members are FGF19, FGF21, and FGF23. These FGFs bind HSPGs relatively weakly and are therefore better suited for longer-range action in the fluid phase, but they usually require Klotho-family co-receptors to enable efficient signal recognition.
(3) Intracellular FGFs
Members such as the FGF11 subfamily are more strongly involved in intracellular regulatory processes and are generally not interpreted as classical secreted FGFR ligands. Accordingly, they are usually not treated as a main axis in studies of the classical FGF-FGFR pathway.
1.2 Receptor Family
The classical receptors of the FGF pathway are FGFR1, FGFR2, FGFR3, and FGFR4. All belong to the receptor tyrosine kinase family and share a similar modular structure, including extracellular immunoglobulin-like domains, a transmembrane region, and an intracellular tyrosine kinase domain. FGFR1-3 also possess important alternative splicing isoforms, particularly the IIIb and IIIc variants, and this difference directly determines the response spectrum of different tissues to FGF ligands.
Table 1. Basic Composition of the FGF Family and FGFR System
Category | Representative Members | Major Features |
Paracrine FGFs | FGF1, FGF2, FGF7, FGF8, FGF10, FGF18, etc. | HSPG-dependent, primarily local in action |
Endocrine FGFs | FGF19, FGF21, FGF23 | Klotho-dependent, with more prominent systemic regulation |
Classical receptors | FGFR1, FGFR2, FGFR3, FGFR4 | Receptor tyrosine kinases mediating major signaling output |
Accessory factors | HSPG, α-Klotho, β-Klotho | Determine ligand recognition efficiency and tissue specificity |
2. Receptor Structure and Accessory Recognition Systems
2.1 Structural Features of FGFRs
The extracellular region of FGFRs generally contains three immunoglobulin-like domains, among which the D2 and D3 regions form the key interface for ligand recognition, while the acidic box region participates in receptor autoinhibition and conformational regulation. The intracellular kinase domain is responsible for phosphorylation of tyrosine residues and provides binding sites for downstream adaptor proteins.
2.2 Significance of Splice Variants
The IIIb/IIIc splicing differences of FGFR1, FGFR2, and FGFR3 are a major foundation of FGF pathway research. Different splice variants show distinct expression patterns in epithelial and mesenchymal tissues. As a result, the same FGF may exhibit completely different receptor preferences and biological outcomes in different tissue settings. In other words, tissue specificity in the FGF pathway is not determined simply by whether FGFR is present, but rather by which FGFR isoform is expressed.
2.3 Roles of HSPG and Klotho
HSPG is a key stabilizing factor in paracrine FGF signaling. It not only increases the efficiency of FGF-FGFR binding, but also participates in receptor dimerization and local gradient formation.
The Klotho family mainly serves endocrine FGFs. Among these, α-Klotho is more commonly associated with FGF23, whereas β-Klotho is more frequently involved in FGF19 and FGF21 signaling. Klotho is not merely an accessory molecule, but a key determinant of whether endocrine FGFs can be recognized by specific tissues.
3. Activation Mechanism of the FGF Pathway
3.1 Ligand Binding and Receptor Dimerization
Classical FGF pathway activation begins with binding of an FGF ligand to the extracellular domain of FGFR. In paracrine FGFs, this process usually also requires HSPG to form a stable FGF-FGFR-HSPG complex. Once this complex is formed, two FGFR molecules are brought into proximity and dimerize, thereby enabling trans-phosphorylation of the intracellular kinase domains.
3.2 Phosphorylation of Tyrosine Residues
After FGFR activation, multiple intracellular tyrosine residues become phosphorylated and form docking platforms for distinct downstream signaling molecules. Among these, FRS2 (fibroblast growth factor receptor substrate 2) is one of the most representative proximal adaptor proteins in the FGF pathway. Once phosphorylated, FRS2 can further recruit molecules such as GRB2, SOS, and GAB1, thereby connecting to the major RAS-MAPK and PI3K-AKT axes.
4. Major Downstream Signaling Branches
4.1 RAS-RAF-MEK-ERK Pathway
This is the most classical pro-proliferative and pro-differentiation output axis of the FGF pathway. After FGFR activation, the FRS2-GRB2-SOS complex promotes RAS activation, followed sequentially by activation of RAF, MEK, and ERK. This pathway mainly participates in cell-cycle progression, initiation of developmental programs, and remodeling of transcriptional profiles.
4.2 PI3K-AKT-mTOR Pathway
This pathway is mainly associated with cell survival, metabolism, and anti-apoptotic signaling. Through nodes such as FRS2 and GAB1, FGFR connects to PI3K, which then activates AKT and mTOR, thereby enhancing cellular tolerance to nutrient fluctuations, stress, and injury.
4.3 PLCγ Pathway
FGFR can also directly or indirectly activate PLCγ, leading to cleavage of PIP2 into IP3 and DAG and subsequently mobilizing intracellular Ca²⁺- and PKC-related responses. This branch is more commonly associated with migration, secretion, and local membrane-signaling events.
4.4 Other Branches
In specific cellular contexts, the FGF pathway can also influence branches such as STAT, SRC, JNK, and p38, although these do not dominate under all FGF stimulation conditions. In most cases, RAS-MAPK and PI3K-AKT remain the major framework for interpreting FGF signaling output.
Table 2. Major Downstream Branches of the FGF Pathway and Their Functional Biases
Downstream Pathway | Core Nodes | Major Functional Bias |
RAS-RAF-MEK-ERK | FRS2, GRB2, RAS, ERK | Proliferation, development, differentiation, transcriptional remodeling |
PI3K-AKT-mTOR | PI3K, AKT, mTOR | Survival, metabolism, anti-apoptosis |
PLCγ-PKC-Ca²⁺ | PLCγ, PKC, Ca²⁺ | Migration, secretion, membrane signal regulation |
Other branches | STAT, SRC, etc. | Context-dependent regulation |
5. Major Biological Functions of the FGF Pathway
5.1 Embryonic Development and Organogenesis
The FGF pathway is one of the most important morphogenetic signaling systems in developmental biology. It participates in limb bud formation, patterning of the nervous system, skeletal development, and formation of organs such as the lung and kidney, and determines cell-fate choices through concentration gradients, ligand distribution, and receptor expression patterns. Many developmental processes involving positional specification and differentiation windows are closely linked to the spatiotemporal control of FGF signaling.
5.2 Tissue Homeostasis and Injury Repair
In adult tissues, the FGF pathway participates in epithelial renewal, angiogenesis, wound healing, and maintenance of stem-cell niches. For example, FGF2 has prominent roles in vascular and stromal responses, whereas FGF7 and FGF10 are more commonly associated with epithelial regeneration and tissue repair.
5.3 Bone and Cartilage Metabolism
FGFR3 is especially representative in the regulation of skeletal development. Excessively strong FGFR3 activation suppresses chondrocyte proliferation and skeletal elongation, and its dysregulation is therefore closely associated with skeletal developmental disorders. FGF18, FGFR3, and related axes are major research subjects in bone and cartilage biology.
5.4 Metabolic Regulation
FGF19, FGF21, and FGF23 occupy central positions in bile acid metabolism, energy metabolism, and phosphate-calcium homeostasis, respectively. In particular, FGF21 has become an important molecule in metabolic disease research because of its close association with lipid metabolism, glucose metabolism, and stress adaptation.
6. FGF Pathway Dysregulation and Disease Associations
6.1 Developmental Abnormalities and Genetic Diseases
Abnormalities in the FGF-FGFR system can lead to multiple developmental disorders. For example, activating mutations in FGFR2 and FGFR3 can cause craniofacial developmental abnormalities and skeletal dysplasia. These diseases demonstrate that the FGF pathway is not merely a pro-growth pathway, but rather a finely tuned regulatory system that is highly sensitive to signal intensity, timing, and tissue location.
6.2 Tumor-Associated Abnormalities
In many tumors, the FGF pathway can be aberrantly activated through the following mechanisms:
(1) FGFR gene amplification or overexpression
(2) Activating mutations or fusions in FGFR
(3) Autocrine or paracrine amplification of FGF ligands
(4) Cooperative activation of downstream PI3K-AKT or RAS-MAPK nodes
In tumors, the FGF pathway may function either as a driver signal or as an alternative pathway after drug resistance develops. Its research value therefore lies not only in whether it is abnormal, but also in whether it supports pathway compensation and survival maintenance.
6.3 Metabolic and Renal-Bone Disorders
The FGF23-α-Klotho axis is closely associated with phosphate metabolism, vitamin D balance, and mineral abnormalities related to chronic kidney disease. FGF19 and FGF21 are more commonly studied in the context of hepatic metabolism, lipid metabolism, and insulin sensitivity. This area indicates that the FGF pathway is not limited to cell proliferation biology, but is also deeply involved in maintenance of endocrine homeostasis.
7. Key Research Focuses and Common Readouts of the FGF Pathway
7.1 Receptor-Level Readouts
Studies of the FGF pathway usually begin with the FGFR expression profile, splice-isoform type, and phosphorylation status. Common indicators include total FGFR1-4 protein, receptor phosphorylation levels, and changes in membrane localization.
7.2 Proximal Signaling Readouts
FRS2 and its phosphorylation status are key readouts of proximal activation in the FGF pathway. Compared with other receptor tyrosine kinases, FRS2 has stronger indicator value in the FGF pathway, and is therefore highly useful for validating whether signaling is directly driven by FGFR.
7.3 Downstream Readouts
Common indicators include p-ERK, p-AKT, p-PLCγ, and, in some contexts, STAT-related markers. These readouts are used to define signaling bias and form the core basis for interpreting the biological outcomes of FGF signaling.
7.4 Functional Readouts
Common experiments include:
(1) Proliferation and colony-formation assays
(2) Migration and invasion assays
(3) Detection of differentiation markers
(4) Analysis of metabolism-related endpoints
Table 3. Common Experimental Readouts of the FGF Pathway
Research Level | Common Indicators | Major Significance |
Receptor level | FGFR1-4 expression, receptor phosphorylation | Determines the starting point of pathway activation |
Proximal signaling level | FRS2, p-FRS2 | Determines whether direct FGFR signaling has occurred |
Downstream level | p-ERK, p-AKT, p-PLCγ | Determines signaling bias |
Functional level | Proliferation, migration, differentiation, metabolic endpoints | Determines biological consequences |
8. Products Related to the FGF Pathway
Table 4. Product Table of Classical Paracrine FGF Ligands
Category | Catalog No. | Product Name | Grade and Purity | Suitable Research Direction / Use |
Classical ligand | Recombinant Human FGF acidic/FGF1 Protein | ActiBioPure™, Bioactive, Carrier Free, High performance, ≥95%(SDS-PAGE) | Used for classical FGF1-FGFR stimulation, receptor activation validation, and ligand supplementation experiments | |
Classical ligand | Recombinant Human FGF basic/FGF2 Protein | Carrier Free,Bioactive,ActiBioPure™,High performance,PBS Only,≥90%(SDS-PAGE),See COA | Used for classical bFGF stimulation, establishment of proliferative responses, and FGFR-dependence validation | |
Classical ligand | Recombinant Human FGF basic/FGF2/bFGF(155aa) Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High performance,PBS Only,≥95%(SDS-PAGE) | Used for comparing different FGF2 conformations or formulation conditions | |
Classical ligand | Recombinant Human KGF/FGF-7 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,High performance,PBS Only,≥95%(SDS-PAGE) | Used for research on the FGF7-FGFR2b axis and epithelial repair | |
Classical ligand | Recombinant human FGF10 protein (Active) | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,High performance,PBS Only,≥95%(SDS-PAGE) | Used for studies of the FGF10-FGFR2b axis, epithelial-mesenchymal interaction, and developmental models | |
Classical ligand | Recombinant Human FGF-18 Protein | Carrier Free,Bioactive,ActiBioPure™,High performance,PBS Only,≥95%(SDS-PAGE),See COA | Used for research on FGF18-related bone and cartilage biology and the FGFR3 axis | |
Classical ligand | Recombinant Human FGF8 Protein | ActiBioPure™, Bioactive, Animal Free, Carrier Free, Azide Free, High performance, ≥95%(SDS-PAGE) | Used for FGF8-related developmental signaling and ligand-specific stimulation studies | |
Classical ligand | Recombinant Human FGF-9 Protein | Carrier Free,Bioactive,ActiBioPure™,High performance,His Tag,≥95%(SDS-PAGE),See COA | Used for FGF9-related developmental and stromal signaling studies | |
Classical ligand | Recombinant Human FGF-4 Protein | Carrier Free,Bioactive,ActiBioPure™,High performance,PBS Only,≥95%(SDS-PAGE) | Used for FGF4-related embryonic development and receptor-response studies | |
Ligand detection antibody | FGF2 Mouse mAb | Carrier Free,ExactAb™,Azide Free,Validated,High performance,PBS Only,≥95%(SDS-PAGE),1.0 mg/mL | Used for FGF2 protein detection and validation of secretion levels | |
Ligand detection antibody | Recombinant FGF2 Antibody | ExactAb™, Validated, Recombinant, High performance, 0.103 mg/mL | Used for FGF2 protein detection and methodological validation |
Table 5. Product Table of Endocrine FGFs and FGFR Receptors
Category | Catalog No. | Product Name | Grade and Purity | Suitable Research Direction / Use |
Endocrine ligand | Recombinant Human FGF19 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,≥98%(SDS-PAGE) | Used for studies of the FGF19-FGFR4 axis and hepatobiliary metabolism | |
Endocrine ligand | Recombinant Human FGF-21 Protein | Carrier Free,Azide Free,His Tag,PBS Only,≥95%(SDS-PAGE) | Used for metabolic FGF21 branches and endocrine FGF signaling studies | |
Endocrine ligand | Recombinant Human FGF-23 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High performance,His Tag,≥95%(SDS-PAGE),See COA | Used for research on the FGF23-Klotho axis and phosphate-calcium homeostasis | |
Ligand blocking antibody | 1A6 (anti-FGF19) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGF19 neutralization and determination of FGF19 dependence | |
Ligand blocking antibody | Burosumab (Anti-FGF23) | Carrier Free, Recombinant, ExactAb™, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGF23 neutralization and intervention in endocrine FGF branches | |
Receptor protein | Recombinant Human FGFR1 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,High performance,His Tag,Fc Tag,≥95%(SDS-PAGE) | Used for FGFR1 binding, competition, and receptor reconstitution experiments | |
Receptor protein | Recombinant Human FGFR2 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,Azide Free,His Tag,Fc Tag,≥95%(SDS-PAGE) | Used for FGFR2 receptor binding and ligand-preference studies | |
Receptor protein | Recombinant Human FGFR2 alpha (IIIb) Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High performance,Fc Tag,PBS Only,≥90%(SDS-PAGE),See COA | Used for isoform-specific recognition studies of FGFR2 IIIb | |
Receptor protein | Recombinant Human FGFR2 alpha (IIIc) Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,His Tag,≥95%(SDS-PAGE) | Used for isoform-specific recognition studies of FGFR2 IIIc | |
Receptor protein | Recombinant Human FGFR3 (IIIc) Fc Chimera Protein | Animal Free,Carrier Free,Fc Tag,PBS Only,≥95%(SDS-PAGE),See COA | Used for studies of FGFR3 IIIc subtype binding and ligand selectivity | |
Receptor protein | Recombinant Human FGFR4 Protein | Animal Free,Carrier Free,Bioactive,ActiBioPure™,High performance,His Tag,PBS Only,≥95%(SDS-PAGE) | Used for FGFR4 binding and research on FGF19/FGF21 branches | |
Receptor detection antibody | Recombinant FGFR2 Antibody | ExactAb™, Validated, Recombinant, 1.5 mg/mL | Used for FGFR2 protein detection | |
Receptor detection antibody | Recombinant FGFR3 Antibody | Recombinant, ExactAb™, Validated, High performance, See COA | Used for FGFR3 protein detection | |
Receptor detection antibody | Recombinant FGFR4 Antibody | ExactAb™, Recombinant, Validated, See COA | Used for FGFR4 protein detection |
Table 6. Product Table of FGF/FGFR Blocking Antibodies and Inhibitors
Category | Catalog No. | Product Name | Grade and Purity | Suitable Research Direction / Use |
FGFR2 blocking antibody | Aprutumab (anti-FGFR2) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGFR2 blockade and validation of FGFR2 dependence | |
FGFR2 blocking antibody | Bemarituzumab (anti-FGFR2) | Animal Free, Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, ≥95%(SDS-PAGE&SEC-HPLC), Lot by Lot | Used for FGFR2-targeted blockade and studies corresponding to therapeutic antibodies | |
FGFR3 blocking antibody | LY3076226 (anti-FGFR3) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGFR3 blockade and FGFR3-dependent studies | |
FGFR3 blocking antibody | Vofatamab (anti-FGFR3) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGFR3 pathway blockade and antibody comparison studies | |
FGFR4 blocking antibody | U3-1784 (anti-FGFR4) | Carrier Free, Recombinant, ExactAb™, Low Endotoxin, Azide Free, Validated, Animal Free, ≥95%(SDS-PAGE&SEC-HPLC), See COA | Used for FGFR4 blockade and studies of the FGF19-FGFR4 axis | |
Pan-FGFR inhibitor | AZD4547 | Moligand™, ≥99% | Used for classical FGFR inhibition and pathway-dependence validation | |
Pan-FGFR inhibitor | BGJ398 (NVP-BGJ398) | Moligand™, ≥98% | Used for FGFR pathway inhibition and small-molecule control studies | |
Pan-FGFR inhibitor | CH5183284 (Debio-1347) | Moligand™, ≥99% | Used for FGFR kinase inhibition and comparison of sensitivity | |
Pan-FGFR inhibitor | Futibatinib | Moligand™, ≥98% | Used for studies of irreversible FGFR inhibition | |
Pan-FGFR inhibitor | LY2874455 | Moligand™, ≥99% | Used for intervention across the overall FGF-FGFR axis | |
Pan-FGFR inhibitor | PD-161570 | ≥98%(HPLC) | Used for FGFR inhibition and historical benchmark-compound control | |
Pan-FGFR inhibitor | PD-166866 | ≥98%(HPLC) | Used for studies of FGFR tyrosine kinase inhibition | |
FGFR1/3 inhibitor | PD173074 | Moligand™, ≥99% | Used for biased intervention studies targeting FGFR1/FGFR3 | |
FGFR4-selective inhibitor | BLU-9931 | Moligand™, ≥97% | Used for selective FGFR4 inhibition studies | |
FGFR4-selective inhibitor | Roblitinib (FGF401) | Moligand™, ≥98% | Used for classical validation of selective FGFR4 inhibition | |
Allosteric inhibitor | SSR128129E | ≥98% | Used for studies of allosteric FGFR inhibition and mechanistic comparison | |
Pan-FGFR inhibitor | FGFR-IN-1 | ≥99% | Used for rapid validation of FGFR pathway inhibition | |
FGFR2-selective intervention | FGFR2-IN-1 | ≥99% | Used for selective FGFR2 inhibition studies | |
FGFR3-selective intervention | FGFR3-IN-5 |
| Used for selective FGFR3 inhibition studies | |
FGFR4-selective intervention | FGFR4-IN-1 | ≥99% | Used for selective FGFR4 inhibition studies | |
Targeted degrader | PROTAC FGFR2 degrader 1 |
| Used for FGFR2 protein degradation studies and non-simple inhibition models | |
Oligonucleotide intervention | IONIS-FGFR4Rx |
| Used for post-transcriptional intervention targeting FGFR4 |
Table 7. Product Table of Quantitative Detection Reagents for the FGF/FGFR Pathway
Category | Catalog No. | Product Name | Grade and Purity | Suitable Research Direction / Use |
Human ligand ELISA | Human Fibroblast Growth Factor 2, Basic (FGF2/bFGF) ELISA Kit | BioReagent | Used for quantitative detection of FGF2/bFGF secretion | |
Human ligand ELISA | Human Fibroblast Growth Factor 10 (FGF-10) ELISA Kit | BioReagent | Used for quantitative detection of FGF10 | |
Human ligand ELISA | Human Fibroblast Growth Factor 18 (FGF-18) ELISA Kit | BioReagent | Used for quantitative detection of FGF18 | |
Human ligand ELISA | Human Fibroblast Growth Factor 19 (FGF-19) ELISA Kit | BioReagent | Used for quantitative detection of FGF19 | |
Human ligand ELISA | Human Fibroblast Growth Factor 21 (FGF-21) ELISA Kit | BioReagent | Used for quantitative detection of FGF21 | |
Human ligand ELISA | Human Fibroblast Growth Factor 23 (FGF-23) ELISA Kit | BioReagent | Used for quantitative detection of FGF23 | |
Human receptor ELISA | Human Fibroblast Growth Factor Receptor 1 (FGFR1) ELISA Kit | BioReagent | Used for quantitative detection of FGFR1 | |
Human receptor ELISA | Human Fibroblast Growth Factor Receptor 2 (FGFR2) ELISA Kit | BioReagent | Used for quantitative detection of FGFR2 | |
Human receptor ELISA | Human Fibroblast Growth Factor Receptor 3 (FGFR3) ELISA Kit | BioReagent | Used for quantitative detection of FGFR3 | |
Human receptor ELISA | Human Fibroblast Growth Factor Receptor 4 (FGFR4) ELISA Kit | BioReagent | Used for quantitative detection of FGFR4 | |
Mouse ligand ELISA | Mouse Fibroblast Growth Factor 21 (FGF21) ELISA Kit | BioReagent | Used for quantitative detection of mouse FGF21 | |
Mouse ligand ELISA | Mouse Fibroblast Growth Factor 23 (FGF-23) ELISA Kit | BioReagent | Used for quantitative detection of mouse FGF23 | |
Rat ligand ELISA | Rat Fibroblast Growth Factor 21 (FGF-21) ELISA Kit | BioReagent | Used for quantitative detection of rat FGF21 | |
Rat ligand ELISA | Rat Fibroblast Growth Factor 23 (FGF-23) ELISA Kit | BioReagent | Used for quantitative detection of rat FGF23 |
The core of the FGF pathway lies not merely in FGF-FGFR binding, but in a stratified signaling network jointly defined by ligand subgroups, receptor isoforms, HSPG- or Klotho-mediated recognition systems, and multiple downstream signaling axes.
For more related articles, please see below:
[2] Wnt/β-Catenin Signaling Pathway
[4] Metabolic signaling pathway
[5] Wnt Signaling
[7] JAK-STAT Cell Signaling Pathway
[8] PD-1/PD-L1 Signaling Pathway
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