5xFAD Transgenic Mouse Model
Overview
The 5xFAD mouse is one of the most widely used transgenic mouse models of Alzheimer's disease. Developed by Oakley et al. in 2006[@oakley2006], it co-expresses five familial AD mutations in human [APP](/genes/app) and [PSEN1](/genes/psen1) genes, producing rapid and robust amyloid-beta pathology with plaque onset as early as 2 months of age. This makes it one of the fastest-acting amyloid models available.
The model is particularly valuable for studying amyloid-driven neurodegeneration, neuroinflammation, and synaptic dysfunction. While it lacks robust neurofibrillary tangle formation (unlike the [3xTG-AD model](/models/3xtg-ad-mouse)), its rapid phenotype enables efficient therapeutic testing[@hong2016].
Model Generation and Genetic Background
Construct Design
The 5xFAD transgenic construct expresses human APP with three Swedish/Florida/London mutations combined with two PSEN1 mutations[@oakley2006]:
| Gene | Mutation | Position | Effect |
|------|----------|----------|--------|
| [APP](/genes/app) | Swedish (K670N/M671L) | 670/671 | Enhanced β-secretase cleavage, 3-4× more Aβ |
| [APP](/genes/app) | Florida (I716V) | 716 | Increased Aβ production |
| [APP](/genes/app) | London (V717I) | 717 | Altered γ-secretase processing |
| [PSEN1](/genes/psen1) | M146L | 146 | Increased Aβ42/Aβ40 ratio |
| [PSEN1](/genes/psen1) | L286V | 286 | Increased Aβ42/Aβ40 ratio |
...5xFAD Transgenic Mouse Model
Overview
The 5xFAD mouse is one of the most widely used transgenic mouse models of Alzheimer's disease. Developed by Oakley et al. in 2006[@oakley2006], it co-expresses five familial AD mutations in human [APP](/genes/app) and [PSEN1](/genes/psen1) genes, producing rapid and robust amyloid-beta pathology with plaque onset as early as 2 months of age. This makes it one of the fastest-acting amyloid models available.
The model is particularly valuable for studying amyloid-driven neurodegeneration, neuroinflammation, and synaptic dysfunction. While it lacks robust neurofibrillary tangle formation (unlike the [3xTG-AD model](/models/3xtg-ad-mouse)), its rapid phenotype enables efficient therapeutic testing[@hong2016].
Model Generation and Genetic Background
Construct Design
The 5xFAD transgenic construct expresses human APP with three Swedish/Florida/London mutations combined with two PSEN1 mutations[@oakley2006]:
| Gene | Mutation | Position | Effect |
|------|----------|----------|--------|
| [APP](/genes/app) | Swedish (K670N/M671L) | 670/671 | Enhanced β-secretase cleavage, 3-4× more Aβ |
| [APP](/genes/app) | Florida (I716V) | 716 | Increased Aβ production |
| [APP](/genes/app) | London (V717I) | 717 | Altered γ-secretase processing |
| [PSEN1](/genes/psen1) | M146L | 146 | Increased Aβ42/Aβ40 ratio |
| [PSEN1](/genes/psen1) | L286V | 286 | Increased Aβ42/Aβ40 ratio |
The APP transgene is driven by the mouse Thy1 promoter, providing neuron-specific expression. The combination of five FAD mutations dramatically shifts APP processing toward Aβ42 production, driving rapid pathology.
Breeding and Maintenance
The 5xFAD line is maintained on a C57BL/6J background. Mice are typically heterozygous for the transgene, as homozygous mice show more severe phenotypes and reduced viability. The model is available from The Jackson Laboratory (strain #006554).
Neuropathological Features
Amyloid Plaque Deposition
The 5xFAD model demonstrates exceptionally rapid amyloid plaque formation[@oakley2006]:
- Pre-plaque (1-2 months): Subtle diffuse Aβ deposits detectable by immunohistochemistry
- Plaque onset (2-3 months): Compact, thioflavin-S positive plaques appear in cortical regions (subiculum first)
- Established (4-6 months): Extensive plaque burden throughout cortex, hippocampus, and subiculum
- Advanced (6-12 months): Heavy plaque load with associated neuronal loss
Regional Distribution
Plaque distribution follows a characteristic pattern:
Subiculum: One of the first regions showing plaques
Dentate gyrus: Granule cell layer shows early involvement
CA1 hippocampus: Progressive plaque deposition
Cortical layer 5: Significant amyloid burden
Cerebellum: Relatively spared until late stagesNeuronal Loss and Synaptic Pathology
5xFAD mice exhibit progressive neuronal loss[@hong2016]:
- Cortical neurons: Significant loss in layer 5 by 6 months
- Hippocampal CA1: Progressive degeneration of pyramidal neurons
- Subiculum: Early and severe neuronal dropout
- Synaptic markers: Reduced synaptophysin and PSD-95 expression by 4 months
The synaptic pathology precedes obvious plaque deposition, suggesting soluble oligomers may be toxic even before plaque formation.
Gliosis and Neuroinflammation
Astrocytic and microglial activation accompanies amyloid deposition[@boza2019]:
- Astrocytes: GFAP-positive astrocytes surround plaques; A1 (neurotoxic) phenotype predominates near plaques[@fan2020]
- Microglia: Iba1-positive cells show increased activation; disease-associated microglia (DAM) phenotype with TREM2 upregulation
- Complement: C1q and C3 deposition at plaque sites — drives synaptic pruning deficits[@shi2022]
- Cytokines: Elevated IL-1β, TNF-α in brain tissue[@demars2021]
Tau Pathology
The 5xFAD model shows limited endogenous tau pathology[@jawhar2011]:
- Phosphorylated tau: Accumulation of endogenous mouse tau, particularly at Ser202/Thr205 (AT8 epitope), starting around 6 months
- True NFTs: Minimal — unlike the [3xTG-AD model](/models/3xtg-ad-mouse), few neurofibrillary tangles form
Crossing 5xFAD with human tau-expressing mice dramatically accelerates both Aβ and tau pathology, creating a more comprehensive dual-pathology model[@shi2018].
Behavioral Phenotype
Cognitive Deficits
Memory impairment in 5xFAD mice follows a progressive course[@crews2010]:
- Morris water maze: Impaired spatial learning by 4-6 months; reduced time in target quadrant, increased path length[@mclean2017]
- Contextual fear conditioning: Reduced freezing in context testing by 4-6 months
- Y-maze: Reduced spontaneous alternation by 5-7 months; working memory deficits
- Novel object recognition: Impaired discrimination index by 5 months[@mclean2017]
Motor Function
Motor deficits appear later than cognitive changes:
- Rotarod: Impaired performance at 8-10 months
- Grid walk: Foot fault errors increase with age
- Gait analysis: Altered stride length and paw pressure
Molecular Mechanisms
Early Network Dysfunction
5xFAD mice exhibit early hippocampal network dysfunction before significant amyloid plaque deposition[@zhao2017]. Soluble Aβ oligomers — not plaques — drive early cognitive impairment.
Key electrophysiological changes[@kort2020]:
- Reduced long-term potentiation (LTP) in hippocampal CA1 as early as 4 months
- Impaired synaptic plasticity and NMDA receptor dysfunction
- Disrupted gamma oscillations (30-100 Hz) and altered theta-gamma coupling
- Increased inhibitory interneuron activity
Mitochondrial Dysfunction
5xFAD neurons show significant mitochondrial abnormalities[@song2019]:
- Reduced complex IV activity
- Decreased ATP production
- Increased reactive oxygen species (ROS)
- Elevated mitochondrial DNA damage
Synaptic Pruning Deficits
5xFAD mice exhibit excessive microglial phagocytosis of synapses via complement-mediated pathways[@shi2022]:
- Elevated complement C1q targeting synapses
- Decreased PSD-95 and synaptophysin levels
- Correlation between synaptic loss and cognitive decline
CSF Biomarker Correlation
5xFAD mice parallel human AD biomarker trajectories[@cruchaga2020]:
- CSF Aβ42 decreases as plaques form (reflecting plaque sink effect)
- CSF total tau increases with age
- Phosphorylated tau (p-tau181) correlates with hippocampal atrophy
Neurovascular Dysfunction
5xFAD mice show impaired neurovascular function[@hu2018]:
- Reduced cerebral blood flow
- Impaired blood-brain barrier integrity
- Decreased vessel density
Research Applications
Therapeutic Testing
The 5xFAD model is extensively used for drug development:
- Anti-Aβ antibodies: Donanemab, lecanemab validation studies
- BACE1 inhibitors: Reduce Aβ production
- γ-secretase modulators: Shift Aβ profile toward shorter species
- TREM2-targeting approaches: Microglial modulation[@wang2022]
- Oligomer-specific agents: Targeted small molecules[@schelle2019]
Biomarker Development
The model enables validation of biomarkers:
- CSF biomarkers: Aβ42, tau, p-tau181 correlation with brain pathology
- Plasma biomarkers: GFAP, neurofilament light (NFL)
- Imaging biomarkers: PET ligand binding correlation
- Neurophysiological markers: EEG, evoked potentials[@kort2020]
Mechanism Studies
Researchers use 5xFAD to investigate:
- Amyloid toxicity mechanisms (soluble oligomers vs. plaques)
- Synaptic dysfunction pathways
- Neuroinflammation progression
- Neuronal death cascades
Experimental Considerations
Key Timepoints
| Age | Stage | Phenotype |
|-----|-------|-----------|
| 1-2 months | Pre-plaque | Baseline behavior, subtle Aβ |
| 2-4 months | Early plaque | Subtle cognitive deficits |
| 4-6 months | Established | Clear cognitive deficits, synaptic loss |
| 6-9 months | Advanced | Severe pathology, gliosis |
| 9-12 months | Late | Maximal pathology, neuronal loss |
Sex Differences
- Females: Earlier plaque onset, potentially more severe pathology
- Males: Slightly delayed phenotype
- Recommendation: Match sex for experimental groups
Comparison with Other AD Models
| Model | Transgenes | Plaque Onset | Tangles | Cognitive Deficit |
|-------|------------|-------------|---------|-------------------|
| 5xFAD | APP×3 + PSEN1×2 | 2 months | Minimal | 4-6 months |
| 3xTG-AD | APP + TAU + PSEN1 | 6 months | 12 months | 6-10 months |
| APP/PS1 | APP + PSEN1 | 6-9 months | No | 8-12 months |
| Tg2576 | APP Swedish | 9-12 months | No | 12-15 months |
Strengths
- Rapid phenotype: Plaques appear in 2 months vs. 6-12 months in other models
- Robust and reproducible: Consistent across mice and facilities
- Well-characterized: Extensive published literature
- Cognitive deficits: Clear learning and memory impairments
- Microglia studies: Excellent for studying neuroinflammation[@boza2019]
Limitations
- No tau tangles: Lacks neurofibrillary pathology
- Artificial genetics: Five mutations rarely co-occur naturally
- Aggressive phenotype: More severe than sporadic AD
- Male variability: Some phenotypic variability by sex
Key Publications
[Oakley et al., 5xFAD model: five FAD mutations, intraneuronal Aβ, neurodegeneration (2006)](https://pubmed.ncbi.nlm.nih.gov/17020984/)[@oakley2006]
[Hong et al., Synaptic dysfunction in 5xFAD (2016)](https://pubmed.ncbi.nlm.nih.gov/27619526/)[@hong2016]
[Crews et al., Neurocognitive decline in 5xFAD mice (2010)](https://pubmed.ncbi.nlm.nih.gov/20578245/)[@crews2010]
[Jawhar et al., Rapid accumulation of endogenous tau in 5xFAD (2011)](https://pubmed.ncbi.nlm.nih.gov/21841261/)[@jawhar2011]
[Zhao et al., Early hippocampal network dysfunction (2017)](https://pubmed.ncbi.nlm.nih.gov/28615483/)[@zhao2017]
[Boza-Serrano et al., Role of microglia in 5xFAD (2019)](https://pubmed.ncbi.nlm.nih.gov/31119913/)[@boza2019]
[Shi et al., Human tau accelerates Aβ pathology in 5xFAD (2018)](https://pubmed.ncbi.nlm.nih.gov/30583703/)[@shi2018]
[Fan et al., Astrocyte responses in 5xFAD (2020)](https://pubmed.ncbi.nlm.nih.gov/32092115/)[@fan2020]
[Schelle et al., Aβ oligomer dynamics in 5xFAD brains (2019)](https://pubmed.ncbi.nlm.nih.gov/30602734/)[@schelle2019]
[DeMars et al., 5xFAD neuroinflammation progression (2021)](https://pubmed.ncbi.nlm.nih.gov/33461453/)[@demars2021]
[Wang et al., TREM2 deficiency in 5xFAD (2022)](https://pubmed.ncbi.nlm.nih.gov/35618838/)[@wang2022]
[Shi et al., Synaptic pruning deficits in 5xFAD (2022)](https://pubmed.ncbi.nlm.nih.gov/35871920/)[@shi2022]
[Song et al., Mitochondrial dysfunction in 5xFAD neurons (2019)](https://pubmed.ncbi.nlm.nih.gov/31089146/)[@song2019]
[Hu et al., Neurovascular dysfunction in 5xFAD (2018)](https://pubmed.ncbi.nlm.nih.gov/29595326/)[@hu2018]
[Kort et al., EEG abnormalities in 5xFAD (2020)](https://pubmed.ncbi.nlm.nih.gov/32862419/)[@kort2020]Cross-Links
- [Alzheimer's Disease](/diseases/alzheimers-disease)
- [3xTG-AD Mouse Model](/models/3xtg-ad-mouse)
- [APP Gene](/genes/app)
- [PSEN1 Gene](/genes/psen1)
- [Amyloid Cascade Hypothesis](/mechanisms/amyloid-cascade-hypothesis)
- [Neuroinflammation in AD](/mechanisms/neuroinflammation-alzheimers)
- [TREM2 Gene](/genes/trem2)
- [MPTP Mouse Model (PD reference)](/models/mptp-mouse-model-parkinsons)