5xFAD Transgenic Mouse Model

The 5xFAD transgenic mouse model is one of the most widely used animal models for Alzheimer's disease (AD) research. This model co-expresses five familial AD mutations—three in the [amyloid precursor protein (APP)](/genes/app) gene and two in the [presenilin 1 (PSEN1)](/genes/psen1) gene—under the neural-specific Thy1 promoter, leading to aggressive amyloid-beta (Aβ) pathology.

Genetic Background

The 5xFAD model carries the following familial AD mutations:

| Gene | Mutation | Position | Effect |
|------|----------|-----------|--------|
| [APP](/genes/app) | Swedish (K670N/M671L) | Aβ domain | Increased Aβ production |
| [APP](/genes/app) | Florida (I716V) | Aβ domain | Increased Aβ aggregation |
| [APP](/genes/app) | London (V717I) | Aβ domain | Increased Aβ aggregation |
| [PSEN1](/genes/psen1) | M146L | transmembrane | Altered γ-secretase activity |
| [PSEN1](/genes/psen1) | L286V | transmembrane | Altered γ-secretase activity |

The "5x" designation refers to the five total mutations, and "FAD" denotes familial Alzheimer's disease.

Mechanism of Pathology

Amyloid Precursor Protein Processing

The model overexpresses APP containing the Swedish, Florida, and London mutations, leading to:

The 5xFAD transgenic mouse model is one of the most widely used animal models for Alzheimer's disease (AD) research. This model co-expresses five familial AD mutations—three in the [amyloid precursor protein (APP)](/genes/app) gene and two in the [presenilin 1 (PSEN1)](/genes/psen1) gene—under the neural-specific Thy1 promoter, leading to aggressive amyloid-beta (Aβ) pathology.

Genetic Background

The 5xFAD model carries the following familial AD mutations:

| Gene | Mutation | Position | Effect |
|------|----------|-----------|--------|
| [APP](/genes/app) | Swedish (K670N/M671L) | Aβ domain | Increased Aβ production |
| [APP](/genes/app) | Florida (I716V) | Aβ domain | Increased Aβ aggregation |
| [APP](/genes/app) | London (V717I) | Aβ domain | Increased Aβ aggregation |
| [PSEN1](/genes/psen1) | M146L | transmembrane | Altered γ-secretase activity |
| [PSEN1](/genes/psen1) | L286V | transmembrane | Altered γ-secretase activity |

The "5x" designation refers to the five total mutations, and "FAD" denotes familial Alzheimer's disease.

Mechanism of Pathology

Amyloid Precursor Protein Processing

The model overexpresses APP containing the Swedish, Florida, and London mutations, leading to:

Presenilin 1 Mutations

The two PSEN1 mutations (M146L, L286V) affect γ-secretase function:

• Alter the cleavage site specificity, producing more Aβ42 relative to Aβ40
• Lead to earlier onset and more severe pathology compared to single-mutation models

Pathological Features

Amyloid Plaque Formation

• Plaques appear as early as 2 months of age in the cortex
• By 4-6 months, extensive plaque deposition in the hippocampus and subiculum
• Plaques are dense-core type, with the characteristic amyloid fibrillar structure

Neuronal Loss

• Significant loss of [subcortical cholinergic neurons](/cell-types/basal-forebrain-cholinergic-neurons) by 9 months
• Progressive neuronal atrophy in affected brain regions
• Neuronal loss precedes or coincides with plaque deposition

Neuroinflammation

• Robust microglial activation surrounding plaques
• Increased [astrocyte](/cell-types/astrocytes) reactivity (astrogliosis)
• Upregulation of inflammatory cytokines including IL-1β, TNF-α

Behavioral Deficits

• Learning and memory deficits observable by 3-4 months
• Deficits in spatial memory (Morris water maze)
• Impaired working memory and executive function
• Motor deficits in later stages

Research Applications

Therapeutic Target Validation

The 5xFAD model is extensively used for:

Mechanism Studies

Researchers use 5xFAD mice to study:

• Amyloid cascade events and downstream pathology
• Microglial biology and [neuroinflammation](/mechanisms/neuroinflammation-cross-disease) in AD
• Synaptic dysfunction and circuit-level changes
• Blood-brain barrier alterations in AD

Biomarker Development

The model enables validation of:

• PET amyloid tracers (e.g., [PiB](/therapeutics/amyloid-pet-tracers), florbetapir)
• CSF Aβ42 lowering as a pharmacodynamic marker
• Plasma biomarker candidates

Advantages and Limitations

Advantages

• Rapid pathology: Plaques appear by 2 months, much faster than other AD models
• Robust phenotype: Clear behavioral deficits and pathological changes
• Well-characterized: Extensive literature and established protocols
• Single Insertion: Single transgene insertion simplifies breeding

Limitations

• Only amyloid pathology: Lacks prominent [tau](/proteins/tau-protein) pathology
• Non-physiological overexpression: Thy1-driven overexpression doesn't reflect endogenous APP regulation
• No neuronal loss mechanism: Neuronal loss appears driven by plaque burden rather than soluble oligomers
• Limited translational relevance: Aggressive amyloid pathology may not fully reflect sporadic AD

Related Models

• [APP/PS1](/models/app-ps1-dual-transgenic-model) — Dual transgenic model with APP Swedish + PSEN1 M146L
• [3xTg-AD](/models/3xtg-ad-mouse-model) — Triple transgenic model with both amyloid and tau pathology
• [Trem2](/genes/trem2) knockout crosses — Used to study microglial contributions to amyloid clearance

References