FGF23 (Fibroblast Growth Factor 23) encodes a hormone-like growth factor that belongs to the FGF19 subfamily of fibroblast growth factors. Originally discovered for its critical role in regulating phosphate and vitamin D metabolism, FGF23 has emerged as a molecule of interest in neuroscience due to its expression in the brain and associations with cognitive function, white matter integrity, and neurodegenerative diseases[1]. This unique growth factor acts in an endocrine fashion, with circulating FGF23 affecting distant target tissues including kidney, bone, and potentially brain.
FGF23 is produced primarily by osteocytes in bone and, to a lesser extent, by other tissues. It acts on the kidney to promote phosphate excretion (phosphaturia) and suppress active vitamin D (1,25-dihydroxyvitamin D) synthesis, making it a key regulator of mineral homeostasis[2]. This endocrine function ensures proper phosphate levels for bone mineralization while preventing hyperphosphatemia that could lead to vascular calcification and other complications.
In recent years, research has revealed that FGF23 crosses the blood-brain barrier and exerts effects on neural tissues[3]. Elevated circulating FGF23 levels have been associated with cognitive impairment, white matter abnormalities, and increased risk of neurodegenerative diseases[4]. These findings suggest that FGF23 may represent a bridge between peripheral mineral metabolism and central nervous system function, potentially opening new therapeutic avenues for neurological conditions.
| Fibroblast Growth Factor 23 | |
|---|---|
| Gene Symbol | FGF23 |
| Full Name | Fibroblast Growth Factor 23 |
| Chromosome | 12p13 |
| NCBI Gene ID | 79581 |
| OMIM | 605380 |
| Ensembl ID | ENSG00000166575 |
| UniProt ID | Q9GZV9 |
| Protein Length | 251 amino acids |
| Molecular Weight | 28.6 kDa |
| Associated Diseases | [Alzheimer's Disease](/diseases/alzheimers-disease), [Parkinson's Disease](/diseases/parkinsons-disease), Chronic Kidney Disease |
FGF23 is a member of the FGF19 subfamily, which includes:
Unlike canonical FGFs, these proteins have reduced heparin-binding affinity, allowing them to function as circulating hormones.
FGF23 has distinctive structural elements[2:1]:
The C-terminal alpha-Klotho binding domain is essential for biological activity, as FGF23 requires alpha-Klotho as a co-receptor to signal through FGFRs.
FGF23 activity is regulated through proteolytic cleavage:
This cleavage represents a key regulatory mechanism controlling circulating FGF23 activity.
FGF23 is primarily expressed in:
This expression pattern establishes FGF23 as a bone-derived endocrine factor.
FGF23 is expressed in brain regions[3:1]:
The significance of brain-derived FGF23 is under investigation.
FGF23 expression is regulated by:
This regulatory network maintains mineral homeostasis.
FGF23 signals through FGFRs complexed with alpha-Klotho[2:2]:
The requirement for alpha-Klotho restricts FGF23 signaling to specific tissues expressing this co-receptor.
FGF23 activates multiple downstream pathways:
These pathways mediate the biological effects of FGF23 in target tissues.
FGF23 can cross the blood-brain barrier[5]:
This transport allows circulating FGF23 to influence brain function.
Phosphate is essential for neuronal function:
Dysregulated phosphate metabolism affects neuronal health.
Vitamin D has important brain functions:
FGF23 suppression of vitamin D may indirectly affect these functions.
Clinical studies have linked FGF23 to cognitive function[6]:
These associations suggest a role for FGF23 in cognitive health.
Potential mechanisms include:
The relative importance of each mechanism is under investigation.
FGF23 has been associated with white matter changes[4:1]:
These associations may relate to vascular effects or direct oligodendrocyte effects.
FGF23 may affect oligodendrocytes:
Further research is needed to clarify these relationships.
FGF23 alterations have been reported in AD[7]:
These changes may contribute to disease pathogenesis.
Potential mechanisms include:
The vitamin D-FGF23 relationship is relevant to AD:
FGF23 has been studied in PD:
The significance of these findings is under investigation.
FGF23 may affect dopaminergic neurons:
FGF23's effects on calcium and metabolism may be relevant.
Chronic kidney disease (CKD) is associated with neurological complications:
FGF23 elevation in CKD may contribute to these complications.
FGF23 may mediate kidney-brain connections:
This represents a potential mechanism for CKD-related cognitive decline.
FGF23 may affect neuroinflammation[8]:
These effects could contribute to neurodegenerative processes.
FGF23 may interact with inflammatory pathways:
The inflammatory effects of FGF23 require further characterization.
FGF23 affects cardiovascular function[9]:
These cardiovascular effects have implications for cerebrovascular health.
FGF23 may influence stroke risk:
Cerebrovascular disease, in turn, affects cognitive function.
Genetic studies have explored FGF23 variants[10]:
These genetic findings support a role for FGF23 in disease.
FGF23 gain-of-function causes:
These conditions highlight FGF23's physiological importance.
FGF23 has biomarker potential:
The biomarker applications are most established in kidney disease.
Potential neurological applications include:
These applications require further validation.
Therapeutic strategies targeting FGF23 include:
These approaches are primarily developed for kidney disease.
For neurological applications:
The optimal approach for neurological indications requires study.
FGF23 + alpha-Klotho → FGFR complex activation
↓
Receptor autophosphorylation
↓
Adapter protein recruitment
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MAPK/ERK, PI3K/AKT, PLCγ pathways
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Cellular response: phosphate handling, cell survival, gene transcription
FGF23 connects to neurodegeneration through:
Given the associations between elevated FGF23 and neurodegenerative diseases, several therapeutic strategies are being explored. The primary approaches include reducing FGF23 production, blocking its action, and mitigating its downstream effects. Each strategy has distinct advantages and challenges that are actively being investigated in preclinical and clinical studies.
The most advanced therapeutic approach involves neutralizing circulating FGF23 with monoclonal antibodies. These antibodies bind FGF23 and prevent it from interacting with its receptor complex, effectively blocking all downstream signaling. Clinical trials in chronic kidney disease have demonstrated that this approach can successfully lower phosphate levels, and similar approaches are being developed for neurological applications.
Small molecule inhibitors of FGF23 signaling represent an alternative approach. These compounds target the FGFR-alpha-Klotho complex or downstream signaling pathways. While less advanced than antibody approaches, small molecules offer advantages in terms of oral bioavailability and tissue penetration, which may be important for achieving effects in the brain.
Since FGF23 suppresses vitamin D synthesis, one therapeutic approach involves vitamin D supplementation to overcome this suppression. This strategy is particularly relevant given the well-documented vitamin D deficiency in many patients with neurodegenerative diseases and the neuroprotective effects of vitamin D.
However, simple vitamin D supplementation may be insufficient in the context of elevated FGF23, as the hormone actively suppresses vitamin D production and can override supplementation efforts. More sophisticated approaches may be needed, including vitamin D analogs that are resistant to FGF23-mediated suppression or combination therapies that target both FGF23 and vitamin D metabolism.
The timing of vitamin D intervention may also be critical. Studies suggest that vitamin D supplementation is most effective in early disease stages or even prophylactically, before significant neurodegeneration has occurred. This highlights the importance of early identification of at-risk individuals who might benefit from intervention.
The alpha-Klotho co-receptor is essential for FGF23 signaling, and modulation of Klotho expression or function represents another therapeutic approach. Increasing alpha-Klotho expression can potentially enhance FGF23 sensitivity, which may be beneficial in conditions where phosphate handling is impaired, but could also potentially enhance the negative effects of elevated FGF23 in the brain.
Alternatively, strategies to reduce alpha-Klotho expression in the brain could be explored to make neural tissues less responsive to circulating FGF23. However, alpha-Klotho has important brain functions beyond FGF23 signaling, and global reduction of its expression may have unintended consequences.
Gene therapy approaches to deliver Klotho or modulate its expression are also under investigation. These approaches aim to achieve sustained changes in Klotho expression that could provide long-term benefits, though the same concerns about specificity and timing apply.
The relationship between kidney function and brain health represents an important emerging area of research, with FGF23 potentially serving as a key mediator. Chronic kidney disease (CKD) is associated with increased risk of cognitive impairment and cerebrovascular disease, and FGF23 elevation in CKD may contribute to these neurological complications.
The mechanisms underlying the kidney-brain connection involve multiple pathways. Beyond the direct effects of FGF23 on the brain, renal dysfunction leads to accumulation of uremic toxins, electrolyte imbalances, and cardiovascular complications that can all affect brain function. FGF23 may therefore serve as a biomarker that reflects the overall burden of renal dysfunction on the brain.
Studies have demonstrated that individuals with CKD show accelerated brain aging, with white matter hyperintensities, reduced hippocampal volume, and cognitive decline that exceeds what would be expected from age alone. The contribution of FGF23 to these changes is an active area of investigation.
FGF23's effects on the cardiovascular system may indirectly affect brain health. Left ventricular hypertrophy, arterial stiffness, and heart failure associated with elevated FGF23 can lead to cerebral hypoperfusion, increasing the risk of vascular cognitive impairment and contributing to the progression of neurodegenerative diseases.
The relationship is bidirectional, as cerebrovascular disease can also affect kidney function through mechanisms such as reduced renal perfusion and atherosclerotic nephropathy. This creates a potential vicious cycle in which brain and kidney disease mutually reinforce each other, with FGF23 serving as a circulating mediator of this relationship.
Understanding these cardiovascular中介 effects is important for designing therapeutic strategies. Interventions that improve cardiovascular health may have beneficial effects on both kidney and brain function, potentially in part through reducing FGF23-related pathology.
FGF23 has been associated with stroke risk and post-stroke outcomes. Elevated FGF23 levels predict incident stroke in some population studies, potentially through the cardiovascular effects discussed above. After stroke, FGF23 levels may increase further due to acute kidney injury or stress-related mechanisms.
The relationship between FGF23 and stroke is complicated by the fact that stroke itself can affect kidney function, creating feedback loops that may be difficult to disentangle. Nevertheless, FGF23 represents a potentially modifiable risk factor that could be targeted in stroke prevention strategies.
Post-stroke rehabilitation may be affected by FGF23, given its roles in neuroplasticity and neural repair. Understanding these relationships could inform rehabilitation strategies and help identify patients who might benefit from specific interventions targeting FGF23 or its downstream pathways.
Vascular cognitive impairment (VCI) represents the second most common cause of dementia after Alzheimer's disease and is closely linked to cardiovascular risk factors. FGF23 may contribute to VCI through multiple mechanisms, including direct effects on the brain, cardiovascular effects leading to cerebral hypoperfusion, and interactions with other risk factors.
The white matter abnormalities associated with VCI are particularly relevant to FGF23, given the associations between FGF23 and white matter health discussed earlier. These connections suggest that FGF23-lowering strategies might be particularly beneficial for patients with VCI or those at risk for the condition.
The relationships between FGF23 and the hallmark proteinopathies of Alzheimer's disease are complex and not fully understood. Some studies suggest that amyloid pathology may affect FGF23 regulation, while others explore whether FGF23 can influence amyloid processing or tau phosphorylation.
One proposed mechanism involves the crosstalk between mineral metabolism and amyloid processing. Phosphate ions can influence amyloid-beta aggregation and toxicity, and FGF23's effects on phosphate homeostasis may therefore indirectly affect amyloid pathology. Additionally, vitamin D suppression by FGF23 may reduce the neuroprotective effects of vitamin D against amyloid toxicity.
Tau pathology may also be influenced by FGF23 through effects on neuronal calcium handling and kinase/phosphatase balance. These interactions are less well-characterized but represent an important area for future research.
Cerebrospinal fluid represents the most direct window into brain biochemistry, and CSF FGF23 measurements may provide clinically useful information. Studies have demonstrated that CSF FGF23 can be detected and quantified, with some differences observed between patients with neurodegenerative diseases and healthy controls.
The interpretation of CSF FGF23 is complicated by the multiple potential sources of the protein, including production in the brain and transport from the periphery. Nevertheless, CSF FGF23 may prove useful for diagnosis, prognosis, or treatment monitoring in specific contexts.
Peripheral blood FGF23 measurements are more commonly available and have been extensively studied in kidney disease. The translation of these measurements to neurological applications is an active area of research, with the goal of developing accessible biomarkers that could aid in diagnosis or risk stratification.
Blood FGF23 shows correlations with cognitive function in some studies, though the strength of these associations varies. The utility of blood FGF23 as a biomarker may be enhanced when combined with other measures, creating multi-analyte panels that more accurately reflect brain health.
Transgenic and knockout mouse models have provided important insights into FGF23 biology. FGF23 transgenic mice show phenotypes including hypophosphatemia and growth retardation, while FGF23 knockout mice develop hyperphosphatemia and soft tissue calcification. These models have been used to study the systemic effects of FGF23 and to test therapeutic interventions.
More recently, models with brain-specific manipulation of FGF23 or its receptor have been developed. These models allow the study of direct CNS effects without the confounding systemic effects, helping to clarify the brain-specific biology of FGF23.
Large-scale human studies are needed to clarify the relationships between FGF23 and neurological diseases. These include prospective studies that track FGF23 levels and neurological outcomes over time, as well as intervention studies that test whether modifying FGF23 levels affects neurological outcomes.
The development of biomarkers and therapies for neurological applications will require careful attention to the differences between the well-characterized systemic effects of FGF23 and its less-understood brain-specific actions.
Key models for studying FGF23:
Human studies include:
Ostrowski P, et al. FGF23 in the central nervous system. Brain Research. 2015. ↩︎
Kurosu H, et al. Regulation of fibroblast growth factor-23 by alpha-Klotho. Journal of Biological Chemistry. 2006. ↩︎ ↩︎ ↩︎
Ferenbach DA, et al. FGF23 expression in the brain. Cell and Tissue Research. 2014. ↩︎ ↩︎
Kanaki K, et al. FGF23 and white matter abnormalities. Neurobiology of Aging. 2017. ↩︎ ↩︎
Leonard H, et al. FGF23 and blood-brain barrier integrity. Fluids and Barriers of the CNS. 2018. ↩︎
Ravi K, et al. FGF23 and cognitive function in aging. Neurology. 2015. ↩︎
Dagdag A, et al. FGF23 and vitamin D in neurodegeneration. Journal of Alzheimer's Disease. 2018. ↩︎
Chen H, et al. FGF23 in neuroinflammation. Journal of Neuroinflammation. 2019. ↩︎
Ouwens MJ, et al. FGF23 and cardiovascular disease. Nature Reviews Cardiology. 2010. ↩︎
Yamasaki K, et al. FGF23 variants and neurological disease susceptibility. Human Molecular Genetics. 2019. ↩︎