Relationship of electrophysiological dysfunction and clinical severity in SCN2A-related epilepsies.

Variants in the SCN2A gene cause a broad spectrum of epilepsy syndromes of variable severity including benign neonatal-infantile epilepsy (BFNIE), developmental and epileptic encephalopathies (DEE), and other neuropsychiatric disorders. Here, we studied three newly identified variants, which caused distinct phenotypes observed in nine affected individuals of three families, including BFNIE, and DEE with intractable neonatal seizures. Whole cell patch-clamp recordings of transfected tsA201 cells disclosed an increased current density and an increased subthreshold sodium inward current upon an action potential stimulus (p.(Lys908Glu)), a hyperpolarizing shift of the activation curve (p.(Val208Glu) and p.(Thr773Ile)), and an increased persistent current (p.(Thr773Ile)). To evaluate genotype-phenotype correlations, we next developed scoring systems for both the extent of the electrophysiological dysfunction and the severity of the clinical phenotype and applied those to 21 previously and newly functionally characterized SCN2A variants. All inherited variants were associated with a mild clinical phenotype and a lower electrophysiological score compared to those occurring de novo and causing severe phenotypes. Our results thus reveal a nice correlation between the extent of channel dysfunction and the clinical severity.

Contribution of early Alzheimer's disease-related pathophysiology to the development of acquired epilepsy.

Aberrant epileptic activity is detectable at early disease stages in Alzheimer's disease (AD) patients and in AD mouse models. Here, we investigated in young ArcticAß mice whether AD-like pathology renders neuronal networks more susceptible to the development of acquired epilepsy induced by unilateral intrahippocampal injection of kainic acid (IHK). In this temporal lobe epilepsy model, IHK induces a status epilepticus followed after two weeks by spontaneous recurrent seizures (SRS). ArcticAß mice exhibited more severe status epilepticus and early onset of SRS. This hyperexcitable phenotype was characterized in CA1 neurons by decreased synaptic strength, increased kainic acid-induced LTP and reduced frequency of spontaneous inhibitory currents. However, no difference in neurodegeneration, neuroinflammation, axonal reorganization or adult neurogenesis was observed in ArcticAß mice compared to wild-type littermates following IHK-induced epileptogenesis. Neuropeptide Y (NPY) expression was reduced at baseline and its IHK-induced elevation in mossy fibres and granule cells was attenuated. However, although this alteration might underlie premature seizure onset, neutralization of soluble Aß species by intracerebroventricular Aß-specific antibody application mitigated the hyperexcitable phenotype of ArcticAß mice and prevented early SRS onset. Therefore, the development of seizures at early stages of AD is mediated primarily by Aß species causing widespread changes in synaptic function.

mTORC1 and mTORC2 have largely distinct functions in Purkinje cells.

The mammalian target of rapamycin (mTOR) is a key regulator of cellular growth which associates with other proteins to form two multi-protein complexes called mTORC1 and mTORC2. Dysregulation of mTORC1 signalling in brain is implicated in neuropathological conditions such as autism spectrum or neurodegenerative disorders. Accordingly, allosteric mTOR inhibitors are currently in clinical trials for the treatment of such disorders. Here, we ablated either mTORC1 or mTORC2 conditionally in Purkinje cells of the mouse cerebellum to dissect their role in the development, function and survival of these neurons. We find that the two mouse models largely differ from each other by phenotype and cellular responses. Inactivation of mTORC2, but not of mTORC1, led to motor coordination deficits at an early age. This phenotype correlated with developmental deficits in climbing fibre elimination and impaired dendritic self-avoidance in mTORC2-deficient Purkinje cells. In contrast, inactivation of mTORC1, but not of mTORC2, affected social interest of the mice and caused a progressive loss of Purkinje cells due to apoptosis. This cell loss was paralleled by age-dependent motor deficits. Comparison of mTORC1-deficient Purkinje cells with those deficient for the mTORC1 inhibitor TSC1 revealed a striking overlap in Purkinje cell degeneration and death, which included neurofilamentopathy and reactive gliosis. Altogether, our study reveals distinct roles of mTORC1 and mTORC2 in Purkinje cells for mouse behaviour and the survival of neurons. Our study also highlights a convergence between the phenotypes of Purkinje cells lacking mTORC1 activity and those expressing constitutively active mTORC1 due to TSC1 deficiency.

A tale of two retinal domains: near-optimal sampling of achromatic contrasts in natural scenes through asymmetric photoreceptor distribution.

For efficient coding, sensory systems need to adapt to the distribution of signals to which they are exposed. In vision, natural scenes above and below the horizon differ in the distribution of chromatic and achromatic features. Consequently, many species differentially sample light in the sky and on the ground using an asymmetric retinal arrangement of short- (S, "blue") and medium- (M, "green") wavelength-sensitive photoreceptor types. Here, we show that in mice this photoreceptor arrangement provides for near-optimal sampling of natural achromatic contrasts. Two-photon population imaging of light-driven calcium signals in the synaptic terminals of cone-photoreceptors expressing a calcium biosensor revealed that S, but not M cones, preferred dark over bright stimuli, in agreement with the predominance of dark contrasts in the sky but not on the ground. Therefore, the different cone types do not only form the basis of "color vision," but in addition represent distinct (achromatic) contrast-selective channels.