Sachiko Mitsui

Pax6 and Engrailed 1 Regulate Two Distinct Aspects of Renshaw Cell Development

Many of the interneuron cell types present in the adult spinal cord contribute to the circuits that control locomotion and posture. Little is known, however, about the embryonic origin of these cell types or the molecular mechanisms that control their differentiation. Here we provide evidence that V1 interneurons (INs), an embryonic class of interneurons that transiently express the En1 transcription factor, differentiate as local circuit inhibitory interneurons and form synapses with motor neurons. Furthermore, we show that a subset of V1 INs differentiates as Renshaw cells, the interneuronal cell type that mediates recurrent inhibition of motor neurons. We analyze the role that two V1 IN-related transcription factor genes play in Renshaw cell development. Pax6 (paired box gene 6) is necessary for an early step in Renshaw cell development, whereas Engrailed 1 (En1), which is genetically downstream of Pax6, regulates the formation of inhibitory synapses between Renshaw cells and motor neurons. Together, these results show that Pax6 and En1 have essential roles in establishing the recurrent inhibitory circuit between motor neurons and Renshaw cells.

Two mirror-image sensory maps with domain organization in the mouse main olfactory bulb.

The glomerular sheet in the olfactory bulb (OB) provides an olfactory sensory map identifying which odorant receptors (ORs) in the nose are activated by inhaled odorants. How are the glomeruli spatially arranged in the OB? Using OCAM and neuropilin-1 (NP1) as molecular markers for target glomeruli of distinct subsets of olfactory axons, we demonstrate here that glomeruli are parceled into topographically distinct domains. Spatial arrangement of these domains suggests that each OB contains two mirror-image maps of the glomeruli. In situ hybridization shows that the glomeruli representing the same OR are symmetrically arranged; one in a domain in the lateral hemisphere and the other in a corresponding domain in the medial hemisphere of the OB. These results suggest that OB contains two symmetrical OR maps with similar domain organization.

A Novel Phenylalanine-Based Targeting Signal Directs Telencephalin to Neuronal Dendrites

Neurons sort out a variety of functional molecules to appropriate subcellular destinations. Telencephalin (TLCN; intercellular adhesion molecule-5) is a cell adhesion molecule specifically localized to somatodendritic membranes in the telencephalic neurons. Here, we established a new in vivo strategy to analyze neuronal sorting mechanisms by ectopic expression of molecules of interest in the cerebellar Purkinje cells of transgenic mice. By using this system, we identified a novel dendritic targeting determinant in the cytoplasmic tail region of TLCN. A full-length TLCN ectopically expressed in the Purkinje cells was localized exclusively to dendrites but not to axons. In contrast, a deletion of cytoplasmic C-terminal 12 amino acids (residues 901-912) or a point mutation of Phe905 to Ala abrogated the dendrite-specific targeting with appearance of the truncated and point-mutated TLCN in both axons and dendrites. Furthermore, an addition of the C-terminal 17 amino acids (residues 896-912) of TLCN to an unrelated molecule (CD8) was sufficient for its specific targeting to dendrites in several types of neurons. Because the C-terminal region of TLCN does not contain any canonical dendritic targeting sequences such as the tyrosine-based motif or the dileucine motif, this study suggests a novel mechanism of protein trafficking to the dendritic compartment of neurons.

Vitronectin Induces Phosphorylation of Ezrin/Radixin/Moesin Actin-binding Proteins through Binding to Its Novel Neuronal Receptor Telencephalin

Background: Telencephalin is an adhesion molecule specifically expressed on dendrites of telencephalic neurons. Results: Vitronectin binds telencephalin and induces phosphorylation of ezrin/radixin/moesin, accumulation of F-actin and PI(4,5)P2, and formation of phagocytic cup-like dendritic protrusions. Conclusion: Telencephalin is a novel neuronal receptor for vitronectin. Significance: This study demonstrates the functional interaction between vitronectin and telencephalin for cytoskeletal reorganization in dendritic protrusions. Vitronectin (VN) is an extracellular matrix protein abundantly present in blood and a wide variety of tissues and plays important roles in a number of biological phenomena mainly through its binding to αV integrins. However, its definite function in the brain remains largely unknown. Here we report the identification of telencephalin (TLCN/ICAM-5) as a novel VN receptor on neuronal dendrites. VN strongly binds to TLCN, a unique neuronal member of the ICAM family, which is specifically expressed on dendrites of spiny neurons in the mammalian telencephalon. VN-coated microbeads induce the formation of phagocytic cup-like plasma membrane protrusions on dendrites of cultured hippocampal neurons and trigger the activation of TLCN-dependent intracellular signaling cascade including the phosphorylation of ezrin/radixin/moesin actin-binding proteins and recruitment of F-actin and phosphatidylinositol 4,5-bisphosphate for morphological transformation of the dendritic protrusions. These results suggest that the extracellular matrix molecule VN and its neuronal receptor TLCN play a pivotal role in the phosphorylation of ezrin/radixin/moesin proteins and the formation of phagocytic cup-like structures on neuronal dendrites.

The Claustrum Coordinates Cortical Slow-Wave Activity

During sleep and awake rest, the neocortex generates large-scale slow-wave activity. Here we report that the claustrum, a poorly understood subcortical neural structure, coordinates neocortical slow-wave generation. We established a transgenic mouse line allowing genetic and electrophysiological interrogation of a subpopulation of claustral glutamatergic neurons. These claustral excitatory neurons received inputs from glutamatergic neurons in a large neocortical network. Optogenetic activation of claustral neurons in vitro induced excitatory post-synaptic responses in most neocortical neurons, but elicited action potentials primarily in inhibitory interneurons. Optogenetic activation of claustral neurons in vivo induced a Down-state featuring a prolonged silencing of neural acticity in all layers of many cortical areas, followed by a globally synchronized Down-to-Up state transition. These results demonstrate a crucial role of the claustrum in synchronizing inhibitory interneurons across the neocortex for spatiotemporal coordination of brain state. Thus, the claustrum is a major subcortical hub for the synchronization of neocortical slow-wave activity.

Vitronectin binds telencephalin and regulates dendritic spine morphogenesis

tic vesicle marker, in the axon terminal of olfactory sensory neurons (OSNs) during the period of synaptogenesis. In contrast, overexpression of PTP in OSNs rescued the phenotype of PTP morphants. Moreover, expression of dominant-negative form of PTP (PTP C1556S) in OSNs also increased VAMP2-EGFP punctate area and punctum number in the axon terminals. Electron microscopic analyses of transgenic zebrafish stably carrying OSN specific promoter-driven PTP C1556S revealed the little effect on the ultrastructure of OSN-mitral cell synapses. On the other hand, we observed a significant increase in the density of OSN-mitral cell synapses. These results suggest that PTP regulates synapse number during development of olfactory systems.