Dysfunction of cortical GABAergic neurons leads to sensory hyper-reactivity in a Shank3 mouse model of ASD.

Hyper-reactivity to sensory input is a common and debilitating symptom in individuals with autism spectrum disorders (ASD), but the neural basis underlying sensory abnormality is not completely understood. Here we examined the neural representations of sensory perception in the neocortex of a Shank3B-/- mouse model of ASD. Male and female Shank3B-/- mice were more sensitive to relatively weak tactile stimulation in a vibrissa motion detection task. In vivo population calcium imaging in vibrissa primary somatosensory cortex (vS1) revealed increased spontaneous and stimulus-evoked firing in pyramidal neurons but reduced activity in interneurons. Preferential deletion of Shank3 in vS1 inhibitory interneurons led to pyramidal neuron hyperactivity and increased stimulus sensitivity in the vibrissa motion detection task. These findings provide evidence that cortical GABAergic interneuron dysfunction plays a key role in sensory hyper-reactivity in a Shank3 mouse model of ASD and identify a potential cellular target for exploring therapeutic interventions

To transduce a zebra finch: interrogating behavioral mechanisms in a model system for speech

The ability to alter neuronal gene expression, either to affect levels of endogenous molecules or to express exogenous ones, is a powerful tool for linking brain and behavior. Scientists continue to finesse genetic manipulation in mice. Yet mice do not exhibit every behavior of interest. For example, Mus musculus do not readily imitate sounds, a trait known as vocal learning and a feature of speech. In contrast, thousands of bird species exhibit this ability. The circuits and underlying molecular mechanisms appear similar between disparate avian orders and are shared with humans. An advantage of studying vocal learning birds is that the neurons dedicated to this trait are nested within the surrounding brain regions, providing anatomical targets for relating brain and behavior. In songbirds, these nuclei are known as the song control system. Molecular function can be interrogated in non-traditional model organisms by exploiting the ability of viruses to insert genetic material into neurons to drive expression of experimenter-defined genes. To date, the use of viruses in the song control system is limited. Here, we review prior successes and test additional viruses for their capacity to transduce basal ganglia song control neurons. These findings provide a roadmap for troubleshooting the use of viruses in animal champions of fascinating behaviors-nowhere better featured than at the 12th International Congress

Ephrin-B1 controls the spatial distribution of cortical pyramidal neurons by restricting their tangential migration

During development of the cerebral cortex, the various neuronal subtypes have to reach their correct final position in the post mitotic compartment where they complete their maturation and eventually establish functional networks. Precise positioning of individual neurons is acquired through tight regulation of the multiple transitions that neurons undergo on their way to the cortical plate. Neurons of the cerebral cortex are organized in layers and columns. Although several molecular mechanisms have been identified that control the final position of neurons along the radial dimension of the cortex (i.e. layer specificity), much less is known about how their final tangential, or mediolateral, distribution is controlled. However this may have a direct impact on the structural and functional organization of cortical columns, since sister neurons derived from the same progenitor display selective patterns of connectivity with each other and/or share similar functional properties. Here we studied the role of B-ephrins in the control of migration of cortical pyramidal neurons. Gain of function experiments using in utero electroporation of ephrin-B1 revealed a striking alteration of the tangential distribution of pyramidal neurons during the multipolar stage of radial migration, resulting in clustering of the pyramidal neurons in the cortical plate. Conversely, clonal analysis of migrating neurons in ephrin-B1 knockout mice showed a wider mediolateral dispersion of cortical neurons. Static and dynamic analyses of migrating neurons revealed that ephrin-B1 modulates the morphology of pyramidal neurons during their multipolar phase, thereby restricting their tangential migration at that stage. Our results demonstrate that ephrin-B1 is a specific inhibitor of non-radial migration of pyramidal neurons, thereby controlling the pattern of cortical columns. These data shed new light on this important aspect of pyramidal neuronal migration, and illustrate how alterations of patterns of migration can affect cortical column organization.Doctorat en Sciences biomédicales et pharmaceutiquesinfo:eu-repo/semantics/nonPublishe

Ephrin-B1 controls the spatial distribution of cortical pyramidal neurons by restricting their tangential migration

During development of the cerebral cortex, the various neuronal subtypes have to reach their correct final position in the post mitotic compartment where they complete their maturation and eventually establish functional networks. Precise positioning of individual neurons is acquired through tight regulation of the multiple transitions that neurons undergo on their way to the cortical plate. Neurons of the cerebral cortex are organized in layers and columns. Although several molecular mechanisms have been identified that control the final position of neurons along the radial dimension of the cortex (i.e. layer specificity), much less is known about how their final tangential, or mediolateral, distribution is controlled. However this may have a direct impact on the structural and functional organization of cortical columns, since sister neurons derived from the same progenitor display selective patterns of connectivity with each other and/or share similar functional properties. Here we studied the role of B-ephrins in the control of migration of cortical pyramidal neurons. Gain of function experiments using in utero electroporation of ephrin-B1 revealed a striking alteration of the tangential distribution of pyramidal neurons during the multipolar stage of radial migration, resulting in clustering of the pyramidal neurons in the cortical plate. Conversely, clonal analysis of migrating neurons in ephrin-B1 knockout mice showed a wider mediolateral dispersion of cortical neurons. Static and dynamic analyses of migrating neurons revealed that ephrin-B1 modulates the morphology of pyramidal neurons during their multipolar phase, thereby restricting their tangential migration at that stage. Our results demonstrate that ephrin-B1 is a specific inhibitor of non-radial migration of pyramidal neurons, thereby controlling the pattern of cortical columns. These data shed new light on this important aspect of pyramidal neuronal migration, and illustrate how alterations of patterns of migration can affect cortical column organization.Doctorat en Sciences biomédicales et pharmaceutiquesinfo:eu-repo/semantics/nonPublishe

A dual role for planar cell polarity genes in ciliated cells

International audienceIn the nervous system, cilia dysfunction perturbs the circulation of the cerebrospinal fluid, thus affecting neurogenesis and brain homeostasis. A role for planar cell polarity (PCP) signaling in the orientation of cilia (rotational polarity) and ciliogenesis is established. However, whether and how PCP regulates cilia positioning in the apical domain (translational polarity) in radial progenitors and ependymal cells remain unclear. By analysis of a large panel of mutant mice, we show that two PCP signals are operating in ciliated cells. The first signal, controlled by cadherin, EGF-like, laminin G-like, seven-pass, G-type receptor (Celsr) 2, Celsr3, Frizzled3 (Fzd3) and Van Gogh like2 (Vangl2) organizes multicilia in individual cells (single-cell polarity), whereas the second signal, governed by Celsr1, Fzd3, and Vangl2, coordinates polarity between cells in both radial progenitors and ependymal cells (tissue polarity). Loss of either of these signals is associated with specific defects in the cytoskeleton. Our data reveal unreported functions of PCP and provide an integrated view of planar polarization of the brain ciliated cells

Transcriptional mechanisms of EphA7 gene expression in the developing cerebral cortex.

The patterning of cortical areas is controlled by a combination of intrinsic factors that are expressed in the cortex and external signals such as inputs from the thalamus. EphA7 is a guidance receptor that is involved in key aspects of cortical development and is expressed in gradients within developing cortical areas. Here, we identified a regulatory element of the EphA7 promoter, named pA7, that can recapitulate salient features of the pattern of expression of EphA7, including cortical gradients. Using a pA7-Green fluorescent Protein (GFP) mouse reporter line, we isolated cortical neuron populations displaying different levels of EphA7/GFP expression. Transcriptome analysis of these populations enabled to identify many differentially expressed genes, including 26 transcription factors with putative binding sites in the pA7 element. Among these, Pbx1 was found to bind directly to the EphA7 promoter in the developing cortex. All genes validated further were confirmed to be expressed differentially in the developing cortex, similarly to EphA7. Their expression was unchanged in mutant mice defective for thalamocortical projections, indicating a transcriptional control largely intrinsic to the cortex. Our study identifies a novel repertoire of cortical neuron genes that may act upstream of, or together with EphA7, to control the patterning of cortical areas.Journal ArticleResearch Support, Non-U.S. Gov'tSCOPUS: ar.jinfo:eu-repo/semantics/publishe

Ripple-selective GABAergic projection cells in the hippocampus

Ripples are brief high-frequency electrographic events with important roles in episodic memory. However, the in vivo circuit mechanisms coordinating ripple-related activity among local and distant neuronal ensembles are not well understood. Here, we define key characteristics of a long-distance projecting GABAergic cell group in the mouse hippocampus that selectively exhibits high-frequency firing during ripples while staying largely silent during theta-associated states when most other GABAergic cells are active. The high ripple associated firing commenced before ripple onset and reached its maximum before ripple peak, with the signature theta-OFF, ripple-ON firing pattern being preserved across awake and sleep states. Controlled by septal GABAergic, cholinergic, and CA3 glutamatergic inputs, these ripple-selective cells innervate parvalbumin and cholecystokinin-expressing local interneurons while also targeting a variety of extra-hippocampal regions. These results demonstrate the existence of a hippocampal GABAergic circuit element that is uniquely positioned to coordinate ripple-related neuronal dynamics across neuronal assemblies

Nova proteins direct synaptic integration of somatostatin interneurons through activity-dependent alternative splicing

Somatostatin interneurons are the earliest born population of cortical inhibitory cells. They are crucial to support normal brain development and function; however, the mechanisms underlying their integration into nascent cortical circuitry are not well understood. In this study, we begin by demonstrating that the maturation of somatostatin interneurons in mouse somatosensory cortex is activity dependent. We then investigated the relationship between activity, alternative splicing, and synapse formation within this population. Specifically, we discovered that the Nova family of RNA-binding proteins are activity-dependent and are essential for the maturation of somatostatin interneurons, as well as their afferent and efferent connectivity. Within this population, Nova2 preferentially mediates the alternative splicing of genes required for axonal formation and synaptic function independently from its effect on gene expression. Hence, our work demonstrates that the Nova family of proteins through alternative splicing are centrally involved in coupling developmental neuronal activity to cortical circuit formation