Benito Maffei scite author profile

Several neurodevelopmental and neuropsychiatric disorders are characterized by intermittent episodes of pathological activity. Although genetic therapies offer the ability to modulate neuronal excitability, a limiting factor is that they do not discriminate between neurons involved in circuit pathologies and “healthy” surrounding or intermingled neurons. We describe a gene therapy strategy that down-regulates the excitability of overactive neurons in closed loop, which we tested in models of epilepsy. We used an immediate early gene promoter to drive the expression of Kv1.1 potassium channels specifically in hyperactive neurons, and only for as long as they exhibit abnormal activity. Neuronal excitability was reduced by seizure-related activity, leading to a persistent antiepileptic effect without interfering with normal behaviors. Activity-dependent gene therapy is a promising on-demand cell-autonomous treatment for brain circuit disorders.

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Anti-seizure Gene Therapy for Focal Cortical Dysplasia

Barbanoj

Graham

Maffei

et al. 2023

Preprint

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Focal Cortical Dysplasias (FCDs) are a common subtype of malformation of cortical development, which frequently present with a spectrum of cognitive and behavioural abnormalities as well as pharmacoresistant epilepsy. FCD type II is typically caused by somatic mutations resulting in mTOR hyperactivity, and is the commonest pathology found in children undergoing epilepsy surgery. However, surgical resection does not always result in seizure freedom, and is often precluded by proximity to eloquent brain regions. Gene therapy is a promising potential alternative treatment and may be appropriate in cases that represent an unacceptable surgical risk. Here, we evaluated a gene therapy based on overexpression of the Kv1.1 potassium channel in a mouse model of frontal lobe FCD. An engineered potassium channel (EKC) transgene was placed under control of a human promoter that biases expression towards principal neurons (CAMK2A) and packaged in an adeno-associated viral vector (AAV9). We used an established FCD model generated by in utero electroporation of frontal lobe neural progenitors with a constitutively active human RHEB plasmid, an activator of mTOR Complex 1. First, we further characterised this by quantifying electrocorticograms and behavioural abnormalities, both in mice developing spontaneous generalised seizures and in mice only exhibiting abnormal interictal discharges. Then, using continuous video-electrocorticogram recordings from epileptic mice before and after injection of AAV9-CAMK2A-EKC in the dysplastic region, we observed a robust decrease in the frequency of seizures and in interictal activity, compared to mice injected with a control viral vector. Despite the robust anti-epileptic effect of the treatment, there was neither an improvement nor a worsening of performance in behavioural tests sensitive to frontal lobe function. AAV9-CAMK2A-EKC had no effect on interictal activity or behaviour in non-epileptic mice. AAV9-CAMK2A-EKC gene therapy is a promising therapy with translational potential to treat the epileptic phenotype of mTOR-related malformations of cortical development. Cognitive and behavioural co-morbidities may, however, resist an intervention aimed at reducing circuit excitability.

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One to Rule Them All: A Unique TAU Therapy for Neurodevelopmental Encephalopathies

Maffei

Lignani

2022

Epilepsy Curr

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Benito Maffei

On-demand cell-autonomous gene therapy for brain circuit disorders

Anti-seizure Gene Therapy for Focal Cortical Dysplasia

One to Rule Them All: A Unique TAU Therapy for Neurodevelopmental Encephalopathies

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