EGFR and Parkinson’s Disease: Molecular Mechanisms
Overview of EGFR in Neurodegeneration
The Epidermal Growth Factor Receptor (EGFR) represents a critical signaling node in the pathogenesis of Parkinson’s disease, with emerging evidence supporting both neuroprotective and disease-modifying roles1"EGFR signaling in neurodegenerative disorders"Open reference. EGFR is a member of the ErbB family of receptor tyrosine kinases, which in the brain includes EGFR (ErbB1), ErbB2, ErbB3, and ErbB4. Each receptor plays distinct roles in neural development, maintenance, and repair, with growing appreciation for their functions in adult neurons and glia2"ErbB receptor family in the central nervous system"Open reference.
In Parkinson’s disease, EGFR signaling intersects with multiple pathogenic mechanisms, including mitochondrial dysfunction, protein aggregation, neuroinflammation, and impaired autophagy. The receptor’s widespread expression in dopaminergic neurons of the substantia nigra pars compacta makes it particularly relevant to PD pathophysiology, where these neurons progressively degenerate3"EGFR activation protects dopaminergic neurons in PD models"Open reference.
EGFR Signaling Architecture
The EGFR signaling cascade involves multiple interconnected pathways:
flowchart TD
A["EGF Ligand"] --> B["EGFR Dimerization"]
B --> C["Tyrosine Kinase Activation"]
C --> D["PI3K/Akt Pathway"]
C --> E["Ras/Raf/MEK/ERK Pathway"]
C --> F["PLC-gamma Pathway"]
C --> G["STAT Pathway"]
D --> H["Cell Survival and Anti-apoptosis"]
D --> I["Mitochondrial Protection"]
E --> J["Proliferation and Differentiation"]
F --> K["Calcium Signaling"]
G --> L["Gene Expression"]
H --> M["Neuroprotection"]
I --> M
J --> N["Neurogenesis"]
K --> M
L --> M
style M fill:#1b5e20,stroke:#333PI3K/Akt Pathway
The PI3K/Akt pathway represents the primary survival mechanism activated by EGFR4"EGFR-PI3K-Akt signaling in neuronal survival"Open reference. Upon ligand binding, EGFR autophosphorylation creates docking sites for PI3K, leading to PIP3 generation and Akt activation. Akt then phosphorylates multiple targets:
-
mTOR: Promotes protein synthesis and cellular growth
-
Bad: Anti-apoptotic effect through sequestration
-
GSK-3β: Inhibition reduces tau phosphorylation and aggregation
-
FOXO: Nuclear exclusion prevents pro-apoptotic gene expression
MAPK/ERK Pathway
The Ras/Raf/MEK/ERK cascade mediates EGFR’s effects on neuronal plasticity and differentiation. In dopaminergic neurons, ERK activation supports:
-
Dendritic arborization
-
Synaptic strength modulation
-
Long-term potentiation
-
Response to neurotrophic factors
STAT Pathway
EGFR activation also engages STAT transcription factors, particularly STAT3, which promotes:
-
Expression of anti-apoptotic genes
-
Neurotrophic factor production
-
Acute phase response modulation
EGFR and Mitochondrial Homeostasis
Mitochondrial dysfunction represents a central feature of PD pathogenesis, and EGFR signaling provides crucial support for mitochondrial health5"EGFR maintains mitochondrial function in dopaminergic neurons"Open reference. Multiple mechanisms connect EGFR activation to mitochondrial preservation:
Electron Transport Chain Support
EGFR signaling enhances complex I activity in dopaminergic neurons, which is specifically impaired in PD. The receptor’s activation increases:
-
NADH dehydrogenase activity
-
ATP production efficiency
-
Reduction of ROS generation
Mitochondrial Dynamics
EGFR modulates the fission/fusion balance through Akt-mediated phosphorylation of Drp1, promoting fusion and maintaining mitochondrial network integrity. This is particularly important in dopaminergic neurons with high metabolic demands.
Mitophagy Regulation
EGFR intersects with PINK1/parkin-mediated mitophagy6"EGFR-PINK1 cross-talk in mitochondrial quality control"Open reference:
-
EGFR activation can compensate for impaired PINK1 signaling
-
Akt-mediated phosphorylation of parkin enhances its activity
-
EGFR supports clearance of damaged mitochondria
Cross-Talk with PD-Related Proteins
LRRK2 Interaction
LRRK2 mutations are a common genetic cause of PD, and significant cross-talk exists between LRRK2 and EGFR signaling7"LRRK2 regulates EGFR trafficking in Parkinson's disease"Open reference:
| LRRK2 Mutation | EGFR Effect | Therapeutic Implication |
|---|---|---|
| G2019S | Enhanced EGFR phosphorylation | LRRK2 inhibitors may restore EGFR balance |
| R1441C/G/H | Impaired EGFR trafficking | EGFR stabilizers could help |
| Y1699C | Reduced EGFR degradation | Enhanced downstream signaling |
LRRK2 kinase activity directly phosphorylates EGFR at specific sites, altering its trafficking and signaling output. The G2019S mutation, the most common pathogenic variant, leads to hyperphosphorylation of EGFR and dysregulated downstream signaling.
Alpha-Synuclein Interaction
Alpha-synuclein aggregation profoundly impacts EGFR signaling8"Alpha-synuclein impairs EGFR signaling in PD"Open reference:
-
Receptor internalization: Alpha-synuclein oligomers accelerate EGFR endocytosis
-
Signal transduction impairment: Aggregate formation interferes with PI3K/Akt signaling
-
Autophagy dysregulation: EGFR-mediated autophagy is compromised
-
Neuronal vulnerability: Impaired EGFR signaling increases susceptibility
The bidirectional relationship suggests that enhancing EGFR signaling could help counteract alpha-synuclein toxicity, while reducing aggregation could restore normal EGFR function.
GBA Interaction
Heterozygous GBA mutations are the most significant genetic risk factor for PD, and EGFR signaling intersects with lysosomal function9"EGFR and GBA interaction in PD pathogenesis"Open reference:
-
EGFR traffics through the endolysosomal system
-
GBA deficiency impairs EGFR degradation
-
Restoring GBA activity may normalize EGFR signaling
-
Combined targeting of GBA and EGFR shows promise
EGFR in Neuroinflammation
Microglial activation drives neuroinflammation in PD, and EGFR plays complex roles in this process10"EGFR signaling in microglia and neuroinflammation"Open reference:
Pro-inflammatory Effects
EGFR activation on microglia can promote:
-
Cytokine production (TNF-α, IL-1β, IL-6)
-
Nitric oxide generation
-
Reactive oxygen species release
-
MHC class II expression
Anti-inflammatory Effects
Conversely, EGFR signaling can also mediate:
-
Resolution of inflammation
-
Trophic support for neurons
-
Promotion of M2-like phenotype
The net effect depends on cellular context and ligand availability.
EGFR and Synaptic Function
Dopaminergic neuron synaptic dysfunction precedes cell death in PD2"ErbB receptor family in the central nervous system"Open reference0. EGFR supports:
-
Dopamine release: EGFR activation enhances vesicle cycling
-
Dendritic spine maintenance: EGFR supports spine density
-
Synaptic plasticity: Long-term changes in striatal synapses
-
Vesicle trafficking: Regulation of synaptic protein localization
Adult Neurogenesis and Potential for Repair
The adult brain retains neurogenic niches, and EGFR plays a central role2"ErbB receptor family in the central nervous system"Open reference1:
Subventricular Zone (SVZ)
The SVZ of the lateral ventricles maintains neural stem cells throughout life:
-
EGFR is highly expressed on transit-amplifying cells
-
EGF stimulates proliferation of progenitor populations
-
Differentiation toward neuronal lineages requires EGFR signaling
-
Impairment may contribute to failed repair in PD
Subgranular Zone (SGZ)
In the hippocampus, EGFR supports:
-
Dentate gyrus neurogenesis
-
Cognitive function preservation
-
Integration of new neurons
Therapeutic Implications
Enhancing EGFR signaling could:
-
Promote replacement of lost dopaminergic neurons
-
Support integration of transplanted cells
-
Enhance endogenous repair mechanisms
EGFR in the Neurovascular Unit
The neurovascular unit couples neuronal activity with blood flow, and EGFR participates in this crosstalk2"ErbB receptor family in the central nervous system"Open reference2:
-
EGFR on endothelial cells regulates BBB integrity
-
Cross-talk with VEGF signaling modulates angiogenesis
-
Neurovascular coupling may be impaired in PD
-
EGFR modulation could improve drug delivery
Age-Related Changes in EGFR Signaling
Aging is the primary risk factor for PD, and EGFR signaling changes with age2"ErbB receptor family in the central nervous system"Open reference3:
-
EGFR expression decreases in substantia nigra with age
-
Downstream signaling becomes less efficient
-
Reduced neuroprotective capacity
-
Increased vulnerability to insults
These age-related changes may explain late-onset PD and suggest that EGFR support could be particularly important in aging individuals.
Exercise and EGFR Activation
Exercise is one of the few reproducible neuroprotective interventions in PD models2"ErbB receptor family in the central nervous system"Open reference4. EGFR mediates some of these effects:
-
Exercise increases EGF expression in the brain
-
EGFR activation promotes mitochondrial biogenesis
-
Exercise-induced neurotrophic factor release involves EGFR
-
Combined exercise and EGFR modulation may be synergistic
Clinical Development of EGFR-Targeted Therapies for PD
Challenges in CNS Drug Delivery
The blood-brain barrier presents a significant obstacle to EGFR-targeted therapy2"ErbB receptor family in the central nervous system"Open reference5:
| Challenge | Description | Current Solutions |
|---|---|---|
| BBB permeability | EGF does not cross BBB | Brain-penetrant small molecules |
| Receptor specificity | Systemic EGFR effects | Cell-specific targeting |
| Dose optimization | Narrow therapeutic window | Personalized approaches |
| Long-term effects | Unknown consequences | Extended monitoring |
Therapeutic Approaches
Direct EGFR Agonists
| Compound | Approach | Status | Notes |
|---|---|---|---|
| EGF peptide fragments | Modified EGF | Preclinical | BBB-penetrant variants |
| HB-EGF mimetics | Heparin-binding domain | Research | Neuroprotective in models |
| BTC (betacellulin) | ErbB4 agonist | Preclinical | Dopaminergic specificity |
Indirect Activation
| Target | Approach | Rationale |
|---|---|---|
| Shedding proteases | TACE inhibitors | Increase EGF availability |
| EGFR ligands | Recombinant ligands | Direct activation |
| Deglycosylation | Enzyme modulators | Enhance receptor function |
EGFR Kinase Modulators
Unlike cancer therapy where EGFR inhibition is desired, PD requires activation. Strategies include:
-
Positive allosteric modulators: Enhance ligand binding
-
Tyrosine kinase agonists: Activate without ligand
-
Protein-protein interaction stabilizers: Prevent receptor internalization
Combination Approaches
With LRRK2 Inhibitors
LRRK2 inhibitors are in clinical development for PD. Combined EGFR modulation may:
-
Provide complementary neuroprotection
-
Address multiple pathogenic pathways
-
Allow lower doses of each agent
With GBA-Targeted Therapy
For GBA-associated PD:
-
Combined endolysosomal function support
-
Enhanced autophagy capacity
-
Synergistic mitochondrial protection
With Deep Brain Stimulation
DBS is effective for motor symptoms2"ErbB receptor family in the central nervous system"Open reference6. Adjunctive EGFR modulation could:
-
Protect neurons near electrode
-
Enhance remodeling
-
Possibly reduce stimulation threshold
Biomarker Development
Clinical development requires PD-relevant biomarkers:
-
EGFR phosphorylation status: pEGFR in peripheral blood mononuclear cells
-
Downstream signaling: pAkt, pERK in accessible tissues
-
Neuroimaging: PET ligands for EGFR
-
Clinical correlates: Motor and non-motor symptom scores
Future Directions
Gene Therapy Approaches
Viral vector delivery of EGFR ligands:
-
AAV-mediated EGF expression
-
Regulated expression systems
-
Cell-type specificity
Small Molecule EGFR Activators
Drug discovery efforts are identifying2"ErbB receptor family in the central nervous system"Open reference7:
-
Brain-penetrant compounds
-
Selective for neuronal EGFR
-
Favorable safety profiles
Cell-Based Therapies
EGFR modulation may enhance:
-
Stem cell transplantation outcomes
-
Dopaminergic neuron survival
-
Integration into host circuitry
Research Pipeline Summary
| Approach | Stage | Advantages | Challenges |
|---|---|---|---|
| EGF peptide | Preclinical | Direct activation | BBB penetration |
| Small molecule activators | Discovery | Oral bioavailability | Selectivity |
| Gene therapy | Preclinical | Sustained delivery | Safety concerns |
| Combination approaches | Preclinical | Multi-target | Complexity |
Overview
The Epidermal Growth Factor Receptor (EGFR) signaling pathway plays a crucial role in neuronal survival, differentiation, and repair. In Parkinson’s disease (PD), EGFR signaling has emerged as a potential therapeutic target for neuroprotection and disease modification2"ErbB receptor family in the central nervous system"Open reference8. EGFR is widely expressed in the brain, including in dopaminergic neurons of the substantia nigra, where it regulates critical cellular functions including mitochondrial homeostasis, autophagy, and neuroinflammation2"ErbB receptor family in the central nervous system"Open reference9.
EGFR Biology
Receptor Structure
EGFR (HER1/ErbB1) is a receptor tyrosine kinase consisting of:
-
Extracellular domain: Ligand-binding region
-
Transmembrane domain: Single pass membrane anchor
-
Intracellular tyrosine kinase domain: Signal transduction
Ligands
Multiple EGF-like ligands activate EGFR:
-
Epidermal Growth Factor (EGF)
-
Transforming Growth Factor-α (TGF-α)
-
Amphiregulin
-
Heparin-binding EGF-like growth factor (HB-EGF)
Signaling Cascade
flowchart TD
A["EGF Ligand"] --> B["EGFR Dimerization"]
B --> C["Tyrosine Kinase Activation"]
C --> D["PI3K/Akt Pathway"]
C --> E["Ras/Raf/MEK/ERK Pathway"]
C --> F["PLC-gamma Pathway"]
D --> G["Cell Survival"]
E --> H["Proliferation/Differentiation"]
F --> I["Calcium Signaling"]
G --> J["Neuroprotection"]Role in Parkinson’s Disease
Neuroprotective Mechanisms
-
Dopaminergic Neuron Survival: EGFR activation promotes survival of dopaminergic neurons in the substantia nigra
-
Mitochondrial Protection: EGFR signaling helps maintain mitochondrial function
-
Anti-apoptotic Effects: Activation of PI3K/Akt pathway inhibits apoptosis
-
Synaptic Protection: Preserves synaptic function and dopamine release
Evidence from PD Models
-
In vitro: EGF protects dopaminergic neurons from oxidative stress
-
In vivo: EGFR activation reduces loss of tyrosine hydroxylase-positive neurons
-
Mechanistic: EGFR cross-talk with PARK genes (PINK1, LRRK2, GBA)
Cross-Talk with PD Pathways
EGFR interacts with several key PD-related pathways:
-
LRRK2: EGFR phosphorylation affected by LRRK2 mutations3"EGFR activation protects dopaminergic neurons in PD models"Open reference0
-
α-Synuclein: EGFR signaling altered by α-synuclein aggregation3"EGFR activation protects dopaminergic neurons in PD models"Open reference1
-
Mitochondrial dysfunction: EGFR helps maintain mitochondrial health3"EGFR activation protects dopaminergic neurons in PD models"Open reference2
-
Neuroinflammation: EGFR modulates glial responses
EGFR and Alpha-Synuclein Pathology
Reciprocal Regulation
The relationship between EGFR signaling and alpha-synuclein pathology is bidirectional. Alpha-synuclein aggregation impairs EGFR signaling through multiple mechanisms, while EGFR activation can promote clearance of alpha-synuclein aggregates3"EGFR activation protects dopaminergic neurons in PD models"Open reference3.
Key interactions:
-
Receptor trafficking: Alpha-synuclein disrupts EGFR endocytosis and recycling
-
Signal transduction: Aggregate formation interferes with downstream PI3K/Akt signaling
-
Autophagy regulation: EGFR-mediated autophagy contributes to alpha-synuclein clearance
-
Neuronal vulnerability: Impaired EGFR signaling increases dopaminergic neuron susceptibility
Therapeutic Implications
Modulating EGFR signaling offers multiple approaches to address alpha-synuclein pathology:
-
Enhancing clearance: EGFR activation promotes autophagy-mediated alpha-synuclein degradation
-
Protecting neurons: EGFR-mediated survival signaling reduces vulnerability to alpha-synuclein toxicity
-
Restoring function: EGFR-targeted interventions may normalize disrupted neuronal signaling
EGFR in Adult Neurogenesis
Subventricular Zone (SVZ)
EGFR plays a critical role in neural stem cell proliferation and differentiation in the adult brain3"EGFR activation protects dopaminergic neurons in PD models"Open reference4. The subventricular zone (SVZ) of the lateral ventricles maintains a population of neural stem cells that can generate new neurons throughout life.
EGFR-mediated neurogenesis:
-
Neural progenitor cells express high levels of EGFR
-
EGF stimulates proliferation of SVZ stem cells
-
Differentiation toward neuronal lineages is EGFR-dependent
-
Impairment of EGFR signaling may contribute to reduced neurogenesis in PD
Implications for PD Therapy
The neurogenic niches in the adult brain represent potential therapeutic targets:
-
Endogenous repair: Enhancing EGFR signaling could promote replacement of lost dopaminergic neurons
-
Combined approaches: EGFR modulation with neurotrophic factor delivery
-
Cell-based therapy: EGFR as a target for stem cell transplantation approaches
Therapeutic Implications
Current Challenges
Despite promising preclinical data, several challenges limit EGFR-targeted therapy for PD3"EGFR activation protects dopaminergic neurons in PD models"Open reference5:
| Challenge | Description | Potential Solution |
|---|---|---|
| BBB penetration | EGF does not readily cross the BBB | BBB-penetrant small molecules3"EGFR activation protects dopaminergic neurons in PD models"Open reference6 |
| Oncogenic risk | EGFR activation can promote tumor growth | Brain-specific delivery, intermittent dosing |
| Dose optimization | Therapeutic window is narrow | Personalized dosing, biomarker-guided treatment |
| Long-term effects | Chronic EGFR modulation consequences unknown | Extended safety studies, alternative endpoints |
Preclinical Candidates
| Compound | Mechanism | Model | Status |
|---|---|---|---|
| EGF infusion | Direct EGFR activation | MPTP mice | Preclinical |
| TGF-α gene therapy | AAV-mediated expression | 6-OHDA rats | Preclinical |
| HB-EGF peptide | Proteolytic activation | LRRK2 mice | Early development |
| Erlotinib (brain-penetrant) | Tyrosine kinase inhibitor | In vitro | Research |
| Gefitinib analogs | BBB-penetrant modulators | In vivo | Early development |
Emerging Strategies
Novel approaches under investigation:
-
Pro-drugs: Brain-activated EGFR modulators that minimize peripheral effects
-
Nanoparticle delivery: Targeted EGF delivery to dopaminergic neurons
-
Cell-specific targeting: AAV vectors with neuron-specific promoters
-
Combination therapy: EGFR modulation with LRRK2 or GBA-targeted approaches
Related Pathways
References
-
EGFR activation protects dopaminergic neurons in PD models (2022)
-
Neuregulin/EGF family in brain development and disease (2021)
-
EGFR maintains mitochondrial function in dopaminergic neurons (2024)
-
LRRK2 regulates EGFR trafficking in Parkinson’s disease (2023)
-
EGFR promotes neurogenesis in the subventricular zone (2021)
-
BBB-penetrant EGFR modulators for neurodegenerative disease (2024)
External Links
Clinical Development of EGFR-Targeted Therapies for PD
Challenges in CNS Drug Delivery
The blood-brain barrier presents a significant obstacle to EGFR-targeted therapy3"EGFR activation protects dopaminergic neurons in PD models"Open reference7:
| Challenge | Description | Current Solutions |
|---|---|---|
| BBB permeability | EGF does not cross BBB | Brain-penetrant small molecules |
| Receptor specificity | Systemic EGFR effects | Cell-specific targeting |
| Dose optimization | Narrow therapeutic window | Personalized approaches |
| Long-term effects | Unknown consequences | Extended monitoring |
Therapeutic Approaches
Direct EGFR Agonists
| Compound | Approach | Status | Notes |
|---|---|---|---|
| EGF peptide fragments | Modified EGF | Preclinical | BBB-penetrant variants |
| HB-EGF mimetics | Heparin-binding domain | Research | Neuroprotective in models |
| BTC (betacellulin) | ErbB4 agonist | Preclinical | Dopaminergic specificity |
Indirect Activation
| Target | Approach | Rationale |
|---|---|---|
| shedding proteases | TACE inhibitors | Increase EGF availability |
| EGFR ligands | Recombinant ligands | Direct activation |
| Deglycosylation | Enzyme modulators | Enhance receptor function |
EGFR Kinase Modulators
Unlike cancer therapy where EGFR inhibition is desired, PD requires activation. Strategies include:
-
Positive allosteric modulators: Enhance ligand binding
-
Tyrosine kinase agonists: Activate without ligand
-
Protein-protein interaction stabilizers: Prevent receptor internalization
Combination Approaches
With LRRK2 Inhibitors
LRRK2 inhibitors are in clinical development for PD. Combined EGFR modulation may:
-
Provide complementary neuroprotection
-
Address multiple pathogenic pathways
-
Allow lower doses of each agent
With GBA-Targeted Therapy
For GBA-associated PD:
-
Combined endolysosomal function support
-
Enhanced autophagy capacity
-
Synergistic mitochondrial protection
With Deep Brain Stimulation
DBS is effective for motor symptoms3"EGFR activation protects dopaminergic neurons in PD models"Open reference8. Adjunctive EGFR modulation could:
-
Protect neurons near electrode
-
Enhance remodeling
-
Possibly reduce stimulation threshold
Biomarker Development
Clinical development requires PD-relevant biomarkers:
-
EGFR phosphorylation status: pEGFR in peripheral blood mononuclear cells
-
Downstream signaling: pAkt, pERK in accessible tissues
-
Neuroimaging: PET ligands for EGFR
-
Clinical correlates: Motor and non-motor symptom scores
Future Directions
Gene Therapy Approaches
Viral vector delivery of EGFR ligands:
-
AAV-mediated EGF expression
-
Regulated expression systems
-
Cell-type specificity
Small Molecule EGFR Activators
Drug discovery efforts are identifying3"EGFR activation protects dopaminergic neurons in PD models"Open reference9:
-
Brain-penetrant compounds
-
Selective for neuronal EGFR
-
Favorable safety profiles
Cell-Based Therapies
EGFR modulation may enhance:
-
Stem cell transplantation outcomes
-
Dopaminergic neuron survival
-
Integration into host circuitry
Research Pipeline Summary
| Approach | Stage | Advantages | Challenges |
|---|---|---|---|
| EGF peptide | Preclinical | Direct activation | BBB penetration |
| Small molecule activators | Discovery | Oral bioavailability | Selectivity |
| Gene therapy | Preclinical | Sustained delivery | Safety concerns |
| Combination approaches | Preclinical | Multi-target | Complexity |
Conclusion
EGFR signaling represents a compelling target for Parkinson’s disease therapy, with multiple mechanisms supporting dopaminergic neuron survival and function. The challenge lies in developing brain-penetrant strategies that enhance EGFR signaling while avoiding oncogenic risks. Continued research into EGFR biology in the context of PD, combined with innovative drug delivery approaches, holds promise for disease-modifying therapies.
References
- "EGFR signaling in neurodegenerative disorders"
- "ErbB receptor family in the central nervous system"
- "EGFR activation protects dopaminergic neurons in PD models"
- "EGFR-PI3K-Akt signaling in neuronal survival"
- "EGFR maintains mitochondrial function in dopaminergic neurons"
- "EGFR-PINK1 cross-talk in mitochondrial quality control"
- "LRRK2 regulates EGFR trafficking in Parkinson's disease"
- "Alpha-synuclein impairs EGFR signaling in PD"
- "EGFR and GBA interaction in PD pathogenesis"
- "EGFR signaling in microglia and neuroinflammation"
- "EGFR regulates synaptic plasticity in the basal ganglia"
- "EGFR promotes neurogenesis in the subventricular zone"
- "EGFR and VEGF cross-talk in neurovascular unit"
- "Age-related changes in EGFR signaling in substantia nigra"
- "Exercise-induced EGFR activation in PD models"
- "BBB-penetrant EGFR modulators for neurodegenerative disease"
- "EGFR modulation as adjunct to deep brain stimulation"
- "Small molecule EGFR modulators for neurological disease"
- "EGFR-mediated autophagy in alpha-synuclein clearance"
- "EGFR-targeted therapeutics in CNS disorders"
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