Sélectionner une page

Single transgenic APP Mouse Models APP[V717I] mouse model 

Test the efficacy of therapies targeting AB accumulation, neuroinflammation and cognitive impairment in an early-onset amyloidosis pathology transgenic Alzheimer’s disease model

Characteristics of the transgenic APP[V717I] mouse model of Alzheimer’s disease

The single transgenic APP[V7171] mouse model represents a progressive amyloidosis mouse model suitable for studying early-stage Alzheimer’s disease therapeutics and progressive amyloid disease features. As described in the original publication (Tanghe et al.,2010), the APP[V717I] mice express human APP gene carrying the London (V717I) mutation (hence also the model being referred to as APP-London and/or APP-Ld mouse model) under the control of murine Thy1 promoter.  

Associated with familial Alzheimer’s disease, the APP[V717I] mutation is the most frequent in familial AD observed in 74 families compared to Swedish observed in 3. The V717I substitution is located downstream of the γ-secretase cleavage site and shifts APP processing toward increased production of the more aggregation-prone Aβ42 species, thereby elevating the Aβ42/Aβ40 ratio and promoting progressive amyloid deposition in brain parenchyma and vasculature.  

Belonging to the family of amyloid pathology models, the APP[V717I] model represents a highly valuable mouse model for therapeutics targeting the amyloid cascade processes as well amyloid-lowering compounds over a long duration of time. If you are searching to perform quick, proof-of-concept studies in an amyloidosis mouse model, InnoSer’s APPxPS1 mouse model may be more suitable.  

Although this model may be suitable for modulators of beginning of tau pathology, InnoSer’s combined amyloid and tau pathology mouse models offer models with robust amyloid and tau pathology phenotypes. 

Navigate to our FAQs below to learn more about the most important differences across the APP[V717I], APPxPS1 and APPxTau mouse models.  

Looking for more details about our APP[V7171] mouse model services? 

APP[V717I] mice develop progressive β-amyloid plaques at a later age (from 10 months) in cortex, hippocampus and subiculum, concomitantly with associated neuroinflammation (microgliosis, astrocytosis)

Pyroglutamate-modified Aβ42 (Aβ3(pE)-42) is detected in the insoluble brain fraction from 12 months onwards

Cognitive impairment in the Morris water maze paradigm and hippocampal LTP deficit from an age of 6 months

APP[V717I] mice show cerebral amyloid angiopathy (CAA) pathology and micro-bleedings from an age of 15-18 and 25-30 months, respectively

model overview picture of 22q11.2 deletion syndrome simple illustration of chromosome

Take advantage of InnoSer’s expertise, flexibility, and collaborative approach for your research. We support you in identifying new drug candidates, characterizing their pharmacological properties, and conducting rigorous safety and efficacy studies with state-of-the-art behavioral, bioanalytical, and histopathological readouts.

Example data featuring the APP[V717I] mouse model of Alzheimer’s disease

C'est ici que commence votre recherche sur la maladie d'Alzheimer.

Découvrez notre comparatif, élaboré par des experts, des modèles murins disponibles afin de prendre des décisions plus rapides et fondées sur des données. Consultez un exemple de calendrier d'étude, les paramètres de mesure recommandés et des exemples de données, notamment des ensembles de données de validation, pour les différents modèles murins.

Télécharger la fiche d'information sur les données d'échantillons relatifs à la SLA – Modèles murins précliniques de la SLA

Key readouts in the single transgenic APP[V717I] mouse model of Alzheimer’s disease

Biomarker analyses


Test the efficacy of your treatments
  • Quantification of soluble and insoluble A species (Aβ40, Aβ42, pyroglutamate-modified Aβ42) levels in brain/ blood/ CSF via ELISA and/or MSD
  • Plasma and CSF levels of NfL via MSD
  • EEG 

              Histopathological analysis


              Test the efficacy of your treatments 
              • Aβ plaque load (e.g., LOC, Thioflavin-S, proprietary anti-Aβ antibody)
              • Neuroinflammation and associated astrocytosis (GFAP) and microgliosis (CD45)
              • Vascular amyloid angiopathy (Aβ3(pE)-42)

                Les personnes qui travaillent sur vos recherches

                Sofie Carmans, docteure

                Sofie Carmans, docteure

                Chercheur principal en neurologie

                Thomas Vogels, docteur ès sciences

                Thomas Vogels, docteur ès sciences

                Chercheur principal en neurologie

                Foire aux questions

                At what ages are amyloid beta plaques observed in the APP[V717I] mouse model?

                In the APP[V717I] mouse model, amyloid-β (Aβ) pathology develops in a clearly age-dependent and progressive manner. Cortical levels of human-specific Aβ40 and Aβ42 (measured by ELISA in both soluble and insoluble fractions) show a gradual increase from 10 months onward, with further elevation at 12.5, until robust pathology is observed at 18 months of age.  

                Similarly, total plaque load (anti-Aβ immunostaining) and dense-core plaque development (Thioflavin S) demonstrate progressive amyloid accumulation. While early deposition can be detected from approximately 10–12.5 months, robust and extensive plaque pathology is most consistently observed at 18 months of age. In line with the pathophysiological disease progression, amyloid accumulation in APP[V717I] mice is accompanied by progressive neuroinflammation (GFAP+, CD45+).  

                Because robust plaque pathology in APP[V717I] mice is most pronounced around 18 months of age, study timelines can be relatively long.  

                For programs requiring accelerated amyloid deposition and earlier intervention windows, the APP[V717I]xPS1[A246E] mouse model may offer strategic advantages. This combined model exhibits earlier and more aggressive amyloid pathology, enabling faster go/no-go decisions, shorter study durations, and improved operational efficiency in preclinical drug development. 

                InnoSer’s team can help you select the most appropriate amyloid model based on your therapeutic modality, timeline, and translational endpoints. 

                Does the APP[V717I] London mutation mouse model display tau pathology?

                The APP[V717I] mouse model primarily models cerebral β-amyloidosis and does not develop full neurofibrillary tangle (NFT) pathology. However, at later disease stages, plaque-associated dystrophic neurites containing hyperphosphorylated murine tau are observed (Tanghe et al., 2010).  

                This absence of overt tangle pathology is consistent with other APP transgenic mouse models. Indeed, amyloid-only models robustly reproduce cerebral beta amyloidosis but do not recapitulate the full spectrum of Alzheimer’s disease encompassing tau pathology. To model both amyloid plaques and neurofibrillary tangles in vivo, the incorporation of mutant human tau is required. 

                Therefore, for programs targeting combined amyloid-and-tau disease modification, we recommend the APP[V717I]xTau[P301S] mouse model, which recapitulates both extracellular amyloid plaques and progressive tau pathology, providing a more complete Alzheimer’s disease phenotype. 

                Learn more about InnoSer’s combined amyloid and tau mouse model here.

                How does the single transgenic APP[V717I] mouse model compare to the double APP[V717I]xPS1[A246E] mouse model?

                The APP[V717I] mouse model is a well-established Alzheimer’s disease mouse model carrying the familial “London” mutation (V717I) in the human amyloid precursor protein (APP). This clinically identified early-onset familial Alzheimer’s disease mutation increases total amyloid-β (Aβ) production and shifts processing toward the aggregation-prone Aβ42 species, promoting progressive, age-dependent amyloid plaque formation. 

                In this single transgenic model, amyloid pathology develops gradually, with plaque deposition typically observed around 12–15 months of age. With aging, both Aβ40 and Aβ42 levels increase, and Aβ40 remains a major component of precipitated amyloid peptides. This slower disease kinetics makes the APP[V717I] model particularly suitable for studying age-dependent amyloid progression and long-term therapeutic interventions. 

                The double transgenic APP[V717I]xPS1[A246E] mouse model was developed as a more aggressive complement to the APP[V717I] mouse model (Dewachter et al., 2000). In line, the APP[V717I]xPS1[A246E] mouse model combines the APP[V717I] London mutation with the PS1[A246E] mutation, another clinically relevant early-onset familial Alzheimer’s disease mutation located in the transmembrane domain of presenilin-1, a core component of the γ-secretase complex. The introduction of mutant PS1 markedly enhances Aβ42 production, resulting in a dramatic increase in the Aβ42/Aβ40 ratio and significantly accelerated amyloid pathology. 

                As a consequence, robust plaque deposition is already present at 6–9 months of age in APPxPS1 mice, with plaques that are predominantly Aβ42-rich. Compared to the single APP[V717I] model, this represents a substantially shorter timeline between amyloid accumulation and overt plaque pathology. 

                In practical terms, the APP[V717I] mouse model offers a slower, age-driven amyloid phenotype, whereas the APPxPS1 model provides a more aggressive and time-efficient platform for evaluating amyloid-lowering therapies, disease-modifying strategies, and cognition-related endpoints within a defined experimental window. 

                Read more about the APP[V717I]xPS1[A246E] mouse model and its use in preclinical efficacy studies targeting Alzheimer’s disease. 

                Has disease modification been demonstrated in the APP London mutation mouse model?

                Yes, published research has shown that disease modification has been demonstrated in the APP[V717I] mouse model in preclinical studies evaluating the efficacy of BACE1 inhibitors (Jacobsen et al., 2014; Janssens et al., 2021). 

                The APP[V717I] mouse model has been widely regarded as a preferred platform for evaluating anti-BACE1 strategies. Because it expresses the human APP London mutation, the model exhibits robust and progressive increases in human Aβ42 levels in a dose-responsive manner. This provides a sensitive and translational system for quantifying reductions in both soluble and insoluble Aβ species following pharmacological intervention. 

                BACE1 is the rate-limiting enzyme responsible for the initial cleavage of APP in the amyloidogenic pathway, leading to the generation of amyloid-β (Aβ) peptides. As such, BACE1 inhibition has long been considered a rational disease-modifying strategy aimed at reducing upstream Aβ production. Although several clinical BACE1 inhibitor programs were discontinued due to safety concerns or limited cognitive benefit in symptomatic patients, the approach remains mechanistically relevant, particularly in early-intervention or prevention paradigms where reducing Aβ production may alter disease trajectory. 

                If you are advancing a BACE1 inhibitor or other Aβ-lowering therapeutic, reach out to InnoSer’s experts to design a preclinical efficacy study aligned with your development strategy. 

                Does the APP[V717I] mouse model display cognitive deficits?

                Yes, APP[V717I] mouse model mice demonstrate measurable impairments in spatial learning and memory. In the Morris Water Maze (MWM) probe test, 6-month-old transgenic animals show clear deficits compared to non-transgenic controls. Specifically, APP[V717I] mice display a reduced annulus crossing index (fewer crossings over the former platform location), decreased time spent in the target quadrant, and increased latency to reach the former platform position, indicating impaired spatial reference memory.  

                As an alternative in the APP[V717I] mouse model, synaptic and memory-related deficits can be evaluated using electrophysiological readouts using ex vivo brain slices, such as hippocampal long-term potentiation (LTP), which provide sensitive measures of synaptic plasticity that can serve as a proxy measure for memory deficits in the APP mouse model. Indeed, electrophysiological assessment in ex vivo hippocampal slices reveals LT in the CA1 region at 8 months of age. 

                However, for programs where cognitive improvement is a primary endpoint, InnoSer’s APP[V717I]xPS1[A246E] mouse model  may offer greater sensitivity, as this model demonstrates clear spatial memory deficits in the Morris water maze along with documented compound-mediated rescue effects (see also figures 1 and 2 of Easton et al., 2013). 

                Reach out to InnoSer’s study experts to discuss including cognitive readouts in your preclinical efficacy study now.

                Does the APP[V717I] mouse model show cerebral amyloid angiopathy (CAA), and why is it relevant?

                In InnoSer’s APP[V717I] mouse model, age-dependent vascular amyloid deposition consistent with cerebral amyloid angiopathy (CAA) is observed at later stages of disease progression. From approximately 15–18 months of age, amyloid deposits accumulate within cerebral vessel walls, affecting multiple vessels per coronal brain section. With advancing age, vascular amyloid pathology progresses to vessel wall damage, aneurysm formation, and microhemorrhages (around 25–30 months), recapitulating key aspects of vascular amyloidosis described in Alzheimer’s disease (See also Figure 5 of van Dorpe et al., 2000). These findings are consistent with observations reported in the original characterization of the model. 

                In parallel, APP[V717I] mice exhibit an age-dependent decrease in the CSF Aβ42/Aβ40 ratio, mirroring biomarker dynamics observed in human AD. This decline temporally coincides with extensive parenchymal and vascular amyloid deposition from approximately 15 months onward. 

                In recent years, interest in CAA has grown markedly as clinical trial outcomes have highlighted vascular amyloid as a potential driver of treatment-related adverse events, including amyloid-related imaging abnormalities (ARIA). Consequently, CAA has emerged as an important target for mechanistic studies and for the preclinical evaluation of anti-amyloid therapies, particularly immunotherapies and approaches aimed at improving vascular amyloid clearance. 

                Although the APP[V717I] (London) mouse model recapitulates key features of late-stage cerebral amyloid angiopathy, vascular amyloid deposition typically emerges from approximately 15–18 months of age. Therefore, for programs specifically investigating earlier-onset CAA, ARIA-related mechanisms, or microbleeds within a shorter experimental timeline, InnoSer’s APP[V717I]xPS1[A246E] mouse model may offer strategic advantages, as CAA develops earlier (from approximately 8 months of age).

                Reach out to our team to explore how InnoSer can support the preclinical assessment of cerebral amyloid angiopathy (CAA) and amyloid-related imaging abnormalities (ARIA).   

                Types de modèles de la maladie d'Alzheimer proposés par InnoSer

                Modèles murins transgéniques à protéine amyloïde (APP/AB)

                InnoSer propose des services de recherche préclinique utilisant plusieurs modèles transgéniques d'amyloïde différents, qui reproduisent la pathologie des plaques caractéristique de la maladie d'Alzheimer.

                Image de couverture sur la maladie d'Alzheimer, fournie par la CRO « European Neurology »

                Modèles murins transgéniques exprimant la protéine Tau

                InnoSer propose des services de recherche uniques, s'appuyant sur plusieurs modèles transgéniques de la protéine tau, qui reproduisent la pathologie des enchevêtrements neurofibrillaires de la protéine tau caractéristique de la maladie d'Alzheimer.

                CRO préclinique basée en Europe proposant des modèles murins de la maladie de Parkinson induite par le MPTP pour le développement de médicaments

                Modèles murins de formation et de propagation de la protéine tau

                InnoSer utilise un modèle d'injection d'extrait cérébral lié à la maladie d'Alzheimer, offrant ainsi des services précliniques uniques grâce à un modèle translationnel de l'amorçage et de la propagation de la pathologie tau.

                Tests neurologiques in vitro

                Évaluez vos composés candidats principaux à l'aide de les pour passer en toute confiance aux études précliniques in vivo

                Modèles murins de la maladie d'Alzheimer proposés par InnoSer

                Modèle murin transgénique PS19

                Modèle murin transgénique PS19

                Tirez parti de l'un des modèles murins les plus couramment utilisés dans la recherche préclinique pour évaluer l'efficacité de votre composé ciblant la pathologie de la protéine tau

                Modèle murin APP[V717I]

                Modèle murin APP[V717I]

                Évaluer l'efficacité de traitements ciblant l'accumulation d'AB, la neuroinflammation et les troubles cognitifs dans un modèle transgénique de la maladie d'Alzheimer présentant une pathologie d'amylose à apparition précoce
                Modèle murin Tau P301S

                Modèle murin Tau[P301S]

                Tirez parti du modèle murin Tau[P301S] exclusif d’InnoSer, caractérisé par une pathologie Tau reproductible et agressive, pour mener des études d’efficacité précliniques rapides et axées sur la prise de décision.

                Modèle murin APP[V717I] x PS1[A246E]

                Modèle murin APP[V717I] x PS1[A246E]

                Évaluer l'efficacité de traitements ciblant l'accumulation de bêta-amyloïde, la neuroinflammation et les troubles cognitifs dans un modèle transgénique APPxPS1 de la maladie d'Alzheimer à apparition précoce

                Modèle murin Tau[P301L]

                Modèle murin Tau[P301L]

                Tirer parti du modèle murin Tau[P301L] d’InnoSer, présentant une pathologie Tau progressive et bien caractérisée, pour mener des études d’efficacité précliniques axées sur les mécanismes d’action

                Modèle murin transgénique APP x PS1 ARTE10

                Modèle murin transgénique APP x PS1 ARTE10

                Faites progresser votre programme thérapeutique visant à réduire les niveaux d'amyloïde en tirant parti de la pathologie généralisée liée à la bêta-amyloïde du modèle murin ARTE10 pour mener des études précliniques d'efficacité rigoureuses.

                Modèle murin APP[V717I] x Tau[P301S], spécialistes européens en neurologie (CRO)

                Modèle murin APP[V717I] x Tau[P301S]

                Eévaluer des traitements multi-cibles chez InnoSer combinaison APPxTau  maladie d’InnoSer

                Découvrez les dernières recherches d'InnoSer

                Panels de biomarqueurs cliniquement pertinents pour des études d'efficacité exhaustives sur des modèles murins de la maladie d'Alzheimer

                Panels de biomarqueurs cliniquement pertinents pour des études d'efficacité exhaustives sur des modèles murins de la maladie d'Alzheimer

                Les modèles murins validés d'InnoSer pour la maladie d'Alzheimer (MA) intègrent des panels de biomarqueurs pertinents sur le plan translationnel — couvrant les espèces de bêta-amyloïde (Aβ), les isoformes phosphorylées de la protéine Tau, ainsi que le marqueur précoce et sensible de la neurodégénérescence que constituent les neurofilaments légers...

                Accréditation AAALAC

                InnoSer a obtenu l'accréditation AAALAC, ce qui témoigne de notre engagement en faveur d'une prise en charge et d'une utilisation responsables des animaux. AAALAC International est une organisation à but non lucratif qui promeut le traitement sans cruauté des animaux dans le domaine scientifique par le biais de programmes volontaires d'accréditation et d'évaluation. Les sites d'InnoSer aux Pays-Bas et en Belgique sont accrédités par l'AAALAC depuis 2016 et 2020, respectivement. Pour en savoir plus sur le programme d'accréditation de l'AAALAC, cliquez ici.

                Logo de l'AAALAC

                Bien-être animal

                Les « 3R » ont une incidence sur tous les domaines, depuis les changements politiques et réglementaires jusqu’au développement et à l’adoption de nouvelles technologies et approches. C’est pourquoi InnoSer s’engage en permanence à suivre ces processus. Les mesures que nous mettons en œuvre optimisent notre capacité à remplacer, réduire et perfectionner l’utilisation des animaux et facilitent notre engagement envers ces principes dans le cadre de la recherche et du développement de médicaments.