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Amyotrophic Lateral Sclerosis SOD1-G93A Transgenic ALS Mouse Model 

Develop novel targeted Amyotrophic Lateral Sclerosis (ALS) therapies by modeling early-stage symptomatic ALS using the SOD1-G93A Transgenic ALS Mouse Model

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SOD1-G93A Transgenic ALS Mouse Model 

Mutations in the superoxide dismutase 1 (SOD1) gene are associated with familial amyotrophic lateral sclerosis (ALS). SOD1 mutations are thought to result in increased oxidative stress and protein aggregation, ultimately leading to a decline in motor function. Several ALS mouse models mimic the progressive loss of motor neurons in the motor cortex, brain stem, and spinal cord. The SOD1-G93A transgenic ALS mouse model express mutant form of SOD1, representing a translationally relevant model for efficacy studies for ALS. 

In line, SOD1 mice show significant SOD1 aggregaiton, oxidative stress, motor neuron loss and significant motor impairments. This mouse model of ALS shows mild behavioral phenotypes up until 12 weeks of age, with progressive neuromuscular deficits leading to paralysis and mortality/human endpoint after 20 weeks of age. 

Looking for more details about our preclinical CRO services using the SOD1-G93A mouse model? 

✓  Early-onset of motor function impairment.

✓  Behavioural changes can be detected already at young ages in SOD1-G93A transgenic ALS mice and are progressive, making this model a valuable tool for efficacy testing of novel compounds. 

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As part of InnoSer’s neurology ALS mouse model portfolio, we also offer efficacy studies in mouse models with TDP-43 pathology, including transgenic TDP-43 mouse model. However, as each model is unique, modelling distinct pathophysiological aspects of ALS, we recommend you discuss the most appropriate model with our neurology study directors. 

InnoSer’s neurology expert team possesses relevant experience in working with multiple therapy types ranging from small molecules, peptides, enzymes, oligonucleotides, gene therapy (viral vectors – e.g.. AAVs) and immunotherapies (antibody/vaccine immunotherapies). 

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View study timelines, recommended readouts, and example data featuring behavioral across different ALS mouse models.

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SOD1-G93A Transgenic ALS Mouse Model Sample Data

SOD1-G93A Transgenic ALS Mouse Model Readouts

Principaux indicateurs comportementaux

Paramètres biologiques

Évaluez l'efficacité de vos traitements à l'aide des paramètres biologiques suivants : 
  • Sciatic nerve conduction electrophysiology study (compound muscle action potential [CMAP] and nerve conduction velocity [NCV])
  • Biomarker analysis (e.g. plasma NfL)  

    Les personnes qui travaillent sur vos recherches

    Thomas Vogels, docteur en neurologie, directeur d'étude chez InnoSer

    Thomas Vogels, docteur en sciences, In Vivo Neurologie Directeur d'étude

    Dirige une équipe d'experts scientifiques possédant une vaste expérience de nos modèles de neurologie afin de vous aider à choisir le modèle le plus adapté et vous guide dans votre conception optimale conception d’étude. Nous vous proposons la solution pour accélérerele rythme le développement de vos médicaments.

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    Foire aux questions

    What is the SOD1-G93A mouse model?

    The SOD1-G93A transgenic mouse model is one of the most widely used animal models of amyotrophic lateral sclerosis (ALS), routinely employed for preclinical disease modelling and therapeutic efficacy testing.  

    The transgenic SOD1 (superoxide dismutase 1) mice express a G93A mutant form of human SOD1. Hemizygous SOD1 mice exhibit a phenotype mimicking the disease pathology observed in patients presenting with ALS. Mice become paralyzed in one or more limbs due to loss of motor neurons in the spinal cord.  

    As a preclinical ALS CRO, InnoSer has characterized the disease progression of SOD1-G93A mice across multiple endpoints: 

    • Motor function readouts: neurological motor scoring (NeuroScore), spontaneous behavior on automatic home-cages, rotarod, and balance beam 
    • Electrophysiological readouts: nerve conduction studies including compound muscle action potential (CMAP) and nerve conduction velocity (NCV) 
    • Biomarker readouts: plasma neurofilament light chain (NfL) 

    Reach out to our team to learn more about our expertise using the SOD1-G93A mouse model for preclinical studies, including tolerability, proof-of-concept, and efficacy studies.

     

    Has disease modification been demonstrated in the SOD1-G93A mouse model?

    Yes, published research has shown that disease modification has been demonstrated in the transgenic SOD1-G93A mouse model in preclinical studies evaluating the efficacy of an antisense oligonucleotide (ASO), Tofersen targeting SOD1 (McCampbell et al., 2018) 

    The study performed by McCampbell and colleagues has demonstrated that one of the key ALS disease-mimicking symptoms in the transgenic SOD1-G93A mouse model, namely loss in compound muscle action potential (CMAP), reflecting loss of functional peripheral nerves and an increase in the plasma serum phospho-neurofilament heavy chain levels, a biomarker of neurodegeneration, was stopped by the SOD1 ASO therapy.

    In turn, this work provided the foundation for the advancement of this compound to human clinical trials and eventually its clinical indication for ALS patients with SOD1 mutation (Tofersen).

    Contact our team to determine whether Tofersen can be used as a comparator or benchmark in your SOD1-G93A preclinical study. 

    What are nerve conduction studies (NCS) and what data do they provide in the SOD1 mouse model?

    The loss of neuromuscular junction innervation and motor neuron death are one of key hallmarks of human ALS pathophysiology, which are quantitatively captured by nerve conduction studies (NCS). Importantly, in preclinical animal studies, NCS provide you with highly relevant translational data, as NCS are a standard diagnostic and disease monitoring tool in ALS patients.  

    In mice, electrophysiological recordings are performed using needle electrodes in the gastrocnemius muscle. This muscle is innervated by the sciatic nerve, which is the largest nerve of the peripheral nervous system, supplying the mouse hind limb with both motor and sensory fiber tracts. Compound muscle action potential (CMAP) measures the number and integrity of functional motor units, whereby a lower CMAP response indicates fewer functional motor units. Nerve conduction velocity (NCV) measures the speed and nerve signal propagation, serving as a proxy marker for nerve myelination. With nerve damage, white matter is lost, which means it takes longer for the stimulus to reach the connected muscle.  

    In the SOD1-G93A model, CMAP amplitude is significantly decreased compared to littermate SOD1-WT animals already at 11 weeks of age, before the onset of robust motor function deficits, confirming motor neuron degeneration and the functional decline in neuromuscular function.  

    Reach out to our team to discuss the most suitable timepoint(s) to measure NCS to assess the efficacy of your novel ALS therapeutics.

    What is the translational relevance of including plasma biomarkers such as NfL in my preclinical study package?

    Neurofilament light chain (NfL) represents a highly translationally relevant plasma biomarker of neuronal injury in many neurodegenerative diseases, including ALS.  

    Importantly, the SOD1-targeting antisense oligonucleotide (ASO) Tofersen demonstrated efficacy in reducing plasma and CSF NfL levels in both preclinical (McCampbell et al., 2018) and clinical studies (Meyer et al., 2023). Since then, many ALS clinical trials now routinely incorporate plasma and CSF NfL as a response biomarker to monitor therapeutic effects.  

    SOD1-G93A mice show elevated plasma levels of the neuronal injury biomarker (NfL) at 11 weeks of age, before the onset of robust motor function deficits, indicating the translational relevance of including this biomarker in your preclinical study designs. 

    Reach out to our team to discuss the most suitable timepoint(s) to collect plasma NfL to assess the efficacy of your novel ALS therapeutics.

    What is typical preclinical efficacy study timeline in the SOD1-G93A mouse model?

    Generally, preclinical efficacy study timelines in the SOD1-G93A mouse model depend on multiple factors, including your compound’s modality (i.e., is it a small molecule therapeutics, RNA-based therapeutics such as ASOs, siRNA and gene therapy), mechanism of action (i.e., disease-modifying or symptomatic), dosing schedules, route of administration (i.e., ICV, intrathecal, IV via tail vein or retro-orbital), as well as the choice of readouts including motor function battery tests and translational readouts such as nerve conductions studies, and plasma NfL assessments.  

    SOD1-G93A mice display motor function deficits starting at young ages (12 weeks of age) that are progressive up to 20 weeks of age, when animals start to reach paralysis and mortality/human endpoints, providing a relatively large window for testing of new therapeutics. Early motor unit dysfunction is evident as early as 11 weeks of age, before robust motor deficits are observed. As an example, for small molecule compounds, starting treatments around 6-8 weeks in the SOD1-G93A mice is typical.  

    Reach out to our team who will help you design a preclinical study package taking into account your therapeutic’s mechanism of action, experimental goals, study timelines, and budget needs.

     

    Are both male and female SOD1-G93A mice used in studies?

    Previous research has shown that male and female SOD1-G93A mice do not have the same onset of symptoms (Hatizperos et al., 2015). Therefore, while possible, including both sexes in studies involving SOD1-G93A mice increases the variability, necessitating the use of more animals to reach sufficient statistical power for the detection of treatment effects.  

    Reach out to our scientific experts who will be able to advise you on the details of your preclinical efficacy study design, including the inclusion of both male and female SOD1-G93A. 

    How does the SOD1-G93A compare to the TDP-43Q331K mouse model of ALS?

    While both SOD1-G93A and TDP43-Q331K models represent well-established preclinical models to study efficacy of novel ALS therapeutics, both differ in terms of target disease, onset, and progression of ALS pathophysiology.  

    Briefly, the SOD1-G93A mouse carries a mutation in the superoxide dismutase 1 (SOD1) gene, which accounts for ~20% of familial ALS cases (5–10% of total ALS). This model reflects SOD1 proteinopathy, with aggregation and misfolding of mutant SOD1 leading to progressive motor neuron degeneration. The TDP-43 model expresses mutant human TDP-43 (i.e., Q331K), a pathology present in ~95% of ALS and ~50% of frontotemporal dementia (FTD) cases. This makes it highly relevant not only for ALS, but also for ALS–FTD spectrum research. 

    In conclusion, if your therapy directly targets SOD1, the SOD1-G93A model is the most suitable. For therapies aiming at broader ALS mechanisms (neurodegeneration, protein aggregation, motor neuron loss, neuroinflammation), TDP-43 models are relevant to a wider patient population. 

    As a preclinical ALS CRO, InnoSer has expertise in carrying out preclinical studies in both SOD1 and mutant TDP-43 mouse models. Reach out to our team to discuss whether the SOD1-G93A or TDP-43 model is most appropriate for your compound’s mechanism of action. 

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