Kainate Receptor Activation Shapes Short-Term Synaptic Plasticity by Controlling Receptor Lateral Mobility at Glutamatergic Synapses.

Kainate receptors (KARs) mediate postsynaptic currents with a key impact on neuronal excitability. However, the molecular determinants controlling KAR postsynaptic localization and stabilization are poorly understood. Here, we exploit optogenetic and single-particle tracking approaches to study the role of KAR conformational states induced by glutamate binding on KAR lateral mobility at synapses. We report that following glutamate binding, KARs are readily and reversibly trapped at glutamatergic synapses through increased interaction with the ß-catenin/N-cadherin complex. We demonstrate that such activation-dependent synaptic immobilization of KARs is crucial for the modulation of short-term plasticity of glutamatergic synapses. Thus, the present study unveils the crosstalk between conformational states and lateral mobility of KARs, a mechanism regulating glutamatergic signaling, particularly in conditions of sustained synaptic activity.

Inter-Synaptic Lateral Diffusion of GABAA Receptors Shapes Inhibitory Synaptic Currents.

The lateral mobility of neurotransmitter receptors has been shown to tune synaptic signals. Here we report that GABAA receptors (GABAARs) can diffuse between adjacent dendritic GABAergic synapses in long-living desensitized states, thus laterally spreading "activation memories" between inhibitory synapses. Glutamatergic activity limits this inter-synaptic diffusion by trapping GABAARs at excitatory synapses. This novel form of activity-dependent hetero-synaptic interplay is likely to modulate dendritic synaptic signaling.

Influence of GABAAR monoliganded states on GABAergic responses.

To reach the open state, the GABA(A) receptor (GABA(A)R) is assumed to bind two agonist molecules. Although it is currently believed that GABA(A)R could also operate in the monoliganded state, the gating properties of singly bound GABA(A)R are poorly understood and their physiological role is still obscure. In the present study, we characterize for the first time the gating properties of singly bound GABA(A)Rs by using a mutagenesis approach and we propose that monoliganded GABA(A)R contribute in shaping synaptic responses. At saturating GABA concentrations, currents mediated by recombinant GABA(A)Rs with a single functional binding site display slow onset, fast deactivation kinetics, and slow rate of desensitization-resensitization. GABA(A)Rs with two binding sites activated by brief pulses of subsaturating GABA concentrations (in the range of the GABA concentration profile in the synaptic cleft) could also mediate fast deactivating currents, displaying deactivation kinetics similar to those mediated by GABA(A)Rs with a single functional binding site. Model simulations of receptors activated by realistic synaptic GABA waves revealed that a considerable proportion of GABA(A) receptors open in the monoliganded state during synaptic transmission, therefore contributing in shaping IPSCs.

TTF-1/NKX2.1 up-regulates the in vivo transcription of nestin.

TTF-1/NKX2.1, also known as T/EBP, is a homeodomain-containing gene involved in the organogenesis of the thyroid gland, lung and ventral forebrain. We have already reported that in 3T3 cells, TTF-1/NKX2.1 up-regulates the transcription of nestin, an intermediate filament protein expressed in multipotent neuroepithelial cells, by direct DNA-binding to a HRE/CRE-like site (NestBS) within a CNS-specific enhancer. Here, we demonstrate that TTF-1/NKX2.1 is co-expressed with nestin in the embryonal forebrain. We also performed a transgenic mouse embryo analysis in which NestBS was replaced by the canonical TTF-1/NKX2.1 consensus DNA-binding site (as identified in many thyroid- and lung-specific genes and very divergent from NestBS) or a random mutation. We observed beta-galactosidase expression in forebrain regions where TTF-1/NKX2.1 is expressed in wild-type embryos, and -to a minor extent- in rostralmost telencephalic regions and thalamus, whereas no beta-galactosidase expression was detected in forebrains of embryos bearing the random mutation. These data show that TTF-1/NKX2.1 regulates the transcription of the nestin gene in vivo through the NestBS site, suggesting that nestin might be at least one of the effectors of TTF-1/NKX2.1 during forebrain development. Finally, we have shown that the transactivating effect of TTF-1/NKX2.1 on the CNS-specific enhancer is unaffected by Retinoic Acid Receptor-alpha.

HMGB1, an architectural chromatin protein and extracellular signalling factor, has a spatially and temporally restricted expression pattern in mouse brain.

HMGB1 is an abundant chromatin component, so far considered ubiquitous. HMGB1 also has an extracellular signalling role: when passively released by necrotic cells, it triggers inflammation; moreover, it can be actively secreted by myeloid cells, neurons and neuronal cancer cells. We show here that HMGB1 protein is undetectable in most cells in adult mouse brain, and is present in a subset of brain cells during development, with a very complex temporal, spatial and subcellular expression pattern. HMGB1 is expressed in the cortical plate of E14.5 embryos, predominantly in the nucleus, although roughly 1% of cells show a cytoplasmic localization as well. In E16 embryos, HMGB1 is nuclearly expressed in scattered cells apparently moving from the ventricular zone to the cortical plate. HMGB1 expression is strongly down-regulated at later developmental stages; in adult mice significant expression is maintained only in areas of continuing neurogenesis. Finally, HMGB1 subcellular localization changes during retinoic acid induced differentiation of P19 neuroblastoma cells.