The cellular and subcellular distribution of four GABA(A) receptor subtypes, identified by the presence of the alpha1, alpha2, alpha3, or alpha5 subunit, was investigated immunocytochemically in dissociated cultures of hippocampal neurons. We addressed the questions whether (1) cell-type specific expression, (2) axonal/somatodendritic targeting, and (3) synaptic/extrasynaptic clustering of GABA(A) receptor subtypes was retained in vitro. For comparison, the in vivo distribution pattern was assessed in sections from adult rat brain. The differential expression of GABA(A) receptor subunits allowed to identify five morphologically distinct cell types in culture: the alpha1 subunit was observed in glutamic acid decarboxylase-positive interneurons, the alpha2 and alpha5 subunits marked pyramidal-like cells, and the alpha3 subunit labeled three additional cell types, including presumptive hilar cells. All subunits were found in the somatodendritic compartment. In addition, appropriate axonal targeting was evidenced by the intense alpha2, and sometimes alpha3 subunit labeling of axon-initial segments (AIS) of pyramidal cells and hilar cells, respectively. Accordingly, both receptor subtypes were targeted to AIS in vivo, as well. Synaptic receptors were identified by colocalization with gephyrin, a postsynaptic clustering protein, and apposition to presynaptic terminals labeled with synapsin I. In vitro and in vivo, alpha1- and alpha2-receptor subtypes formed numerous synaptic clusters, alpha3-GABA(A) receptors were located either synaptically or extrasynaptically depending on the cell type, whereas alpha5-GABA(A) receptors were extrasynaptic. We conclude that receptor targeting to broad subcellular locations does not require specific GABAergic innervation patterns, which are disturbed in vitro, but depends on protein-protein interactions in the postsynaptic cell that are both subunit- and neuron-specific.
Regulation of GABAergic synapse formation and plasticity by GSK3β-dependent phosphorylation of gephyrin
Postsynaptic scaffolding proteins ensure efficient neurotransmission by anchoring receptors and signaling molecules in synapsespecific subcellular domains. In turn, posttranslational modifications of scaffolding proteins contribute to synaptic plasticity by remodeling the postsynaptic apparatus. Though these mechanisms are operant in glutamatergic synapses, little is known about regulation of GABAergic synapses, which mediate inhibitory transmission in the CNS. Here, we focused on gephyrin, the main scaffolding protein of GABAergic synapses. We identify a unique phosphorylation site in gephyrin, Ser270, targeted by glycogen synthase kinase 3β (GSK3β) to modulate GABAergic transmission. Abolishing Ser270 phosphorylation increased the density of gephyrin clusters and the frequency of miniature GABAergic postsynaptic currents in cultured hippocampal neurons. Enhanced, phosphorylation-dependent gephyrin clustering was also induced in vitro and in vivo with lithium chloride. Lithium is a GSK3β inhibitor used therapeutically as mood-stabilizing drug, which underscores the relevance of this posttranslational modification for synaptic plasticity. Conversely, we show that gephyrin availability for postsynaptic clustering is limited by Ca 2+ -dependent gephyrin cleavage by the cysteine protease calpain-1. Together, these findings identify gephyrin as synaptogenic molecule regulating GABAergic synaptic plasticity, likely contributing to the therapeutic action of lithium.GABA A receptors | lithium chloride | postsynaptic density | PSD95 | homeostatic plasticity P lasticity of chemical synapses endows neuronal networks with the capacity to store information by adjusting their functional connectivity. Hence, understanding the molecular underpinnings of synaptic plasticity is a fundamental quest of neuroscience. These mechanisms have been characterized most extensively at glutamatergic synapses, in which a core scaffolding protein, PSD95, forms a signaling complex assembled by proteins interacting via specific PDZ domains (1). In contrast, little is known about signals regulating GABAergic synapses, despite their ubiquitous presence throughout the CNS and their key role in the control of network activity and synchronization. In particular, the postsynaptic density (PSD) of GABAergic synapses, localized primarily on neuronal somata and dendritic shafts, remains ill characterized. Gephyrin, a 93-kDa cytoplasmic polypeptide, has emerged as a multifunctional protein mediating postsynaptic aggregation of GABA A receptors (GABA A R) and glycine receptors by forming a scaffold anchored to the cytoskeleton (2-4). However, the mechanisms of gephyrin and GABA A R clustering are poorly understood, although evidence for direct interaction between gephyrin and GABA A R is slowly emerging (5, 6). Though gephyrin is a phosphoprotein (7,8), the relevance of gephyrin phosphorylation for regulating GABAergic transmission has not been addressed.In the present work, we focused on gephyrin posttranslational modification for regulating its postsyna...
Targeted deletion of the alpha1 subunit gene results in a profound loss of gamma-aminobutyric acid type A (GABA(A)) receptors in adult mouse brain but has only moderate behavioral consequences. Mutant mice exhibit several adaptations in GABA(A) receptor subunit expression, as measured by Western blotting. By using immunohistochemistry, we investigated here whether these adaptations serve to replace the missing alpha1 subunit or represent compensatory changes in neurons that normally express these subunits. We focused on cerebellum and thalamus and distinguished postsynaptic GABA(A) receptor clusters by their colocalization with gephyrin. In the molecular layer of the cerebellum, alpha1 subunit clusters colocalized with gephyrin disappeared from Purkinje cell dendrites of mutant mice, whereas alpha3 subunit/gephyrin clusters, presumably located on dendrites of Golgi interneurons, increased sevenfold, suggesting profound network reorganization in the absence of the alpha1 subunit. In thalamus, a prominent increase in alpha3 and alpha4 subunit immunoreactivity was evident, but without change in regional distribution. In the ventrobasal complex, which contains primarily postsynaptic alpha1- and extrasynaptic alpha4-GABA(A) receptors, the loss of alpha1 subunit was accompanied by disruption of gamma2 subunit and gephyrin clustering, in spite of the increased alpha4 subunit expression. However, in the reticular nucleus, which lacks alpha1-GABA(A) receptors in wild-type mice, postsynaptic alpha3/gamma2/gephyrin clusters were unaffected. These results demonstrate that adaptive responses in the brain of alpha1(0/0) mice involve reorganization of GABAergic circuits and not merely replacement of the missing alpha1 subunit by another receptor subtype. In addition, clustering of gephyrin at synaptic sites in cerebellum and thalamus appears to be dependent on expression of a GABA(A) receptor subtype localized postsynaptically.
Our previous experiments showed that infection of tobacco (Nicotiana tabacum) plants with Tobacco mosaic virus (TMV) leads to an increase in homologous recombination frequency (HRF). The progeny of infected plants also had an increased rate of rearrangements in resistance gene-like loci. Here, we report that tobacco plants infected with TMV exhibited an increase in HRF in two consecutive generations. Analysis of global genome methylation showed the hypermethylated genome in both generations of plants, whereas analysis of methylation via 5-methyl cytosine antibodies demonstrated both hypomethylation and hypermethylation. Analysis of the response of the progeny of infected plants to TMV, Pseudomonas syringae, or Phytophthora nicotianae revealed a significant delay in symptom development. Infection of these plants with TMV or P. syringae showed higher levels of induction of PATHOGENESIS-RELATED GENE1 gene expression and higher levels of callose deposition. Our experiments suggest that viral infection triggers specific changes in progeny that promote higher levels of HRF at the transgene and higher resistance to stress as compared with the progeny of unstressed plants. However, data reported in these studies do not establish evidence of a link between recombination frequency and stress resistance.
Aging is characterized by functional decline of diverse organs and an increased risk for several diseases. Therefore, a high interest exists in understanding the molecular mechanisms that stimulate aging at all levels, from cells and tissues to organs and organisms, in order to develop ways to promote healthy aging. While many molecular and biochemical mechanisms are already understood in some detail, the role of changes in epigenetic regulation has only begun to be considered in recent years. The age-dependent global reduction in heterochromatin, along with site-specific changes in the patterns of DNA methylation and modification of histones, have been observed in several aging model systems. However, understanding of the precise role of such changes requires further research. In this review, we will discuss the role of epigenetic regulation in aging and indicate future research directions that will help elucidate the mechanistic details of it.
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