The postsynaptic density (PSD) is a cellular structure specialized in receiving and transducing synaptic information. Here we describe the identification of 452 proteins isolated from biochemically purified PSD fractions of rat and mouse brains using nanoflow HPLC coupled to electrospray tandem mass spectrometry (LC-MS/MS). Fluorescence microscopy and Western blotting were used to verify that many of the novel proteins identified exhibit subcellular distributions consistent with those of PSDlocalized proteins. In addition to identifying most previously described PSD components, we also detected proteins involved in signaling to the nucleus as well as regulators of ADP-ribosylation factor signaling, ubiquitination, RNA trafficking, and protein translation. These results suggest new mechanisms by which the PSD helps regulate synaptic strength and transmission. Neurons are highly polarized cells, specializing in the reception of numerous, independent signal inputs and rapid integration of these inputs into an electrochemical response. The major sites of signal input are synapses, which are highly ordered cell junctions formed between two neurons and are typically unidirectional in fast excitatory chemical neurotransmission in the mammalian CNS. The response to neurotransmitter (NT) 1 release at the synapse is provided by a protein matrix of NT receptors and supporting proteins collectively known as the postsynaptic density (PSD) (for review, see Refs. 1-3). The PSD has several proposed functions including: signal amplification, cytoskeletal anchorage, biochemical signaling regulation, and NT receptor clustering (1, 4 -6).Changes in size and composition of the PSD correlate with changes in synaptic strength (7,8), including alterations that are stably maintained such as long-term potentiation (LTP), a physiologically relevant increase in synaptic efficacy and a model for learning and memory (9, 10). Therefore, an understanding of the protein composition of the PSD is a prerequisite for modeling the molecular interactions regulating synaptic strength.The structure of PSDs purified from rodent brains using gradient centrifugation and Triton X-100 extraction has been shown by electron microscopy (EM) to be virtually identical to the "in vivo" PSD structure (4, 11). Gel electrophoresis, enzymatic activity assays, and EM experiments have demonstrated that this procedure yields a highly pure, membranefree PSD fraction (11,12). Recent proteomic studies have investigated the composition of the PSD by SDS-PAGE or two-dimensional gel electrophoresis (2DE) coupled with MS (13-16). Li et al. (16) also performed shotgun proteomics using cysteine-containing peptides selected using ICAT techniques. However, each of these investigations identified less than one-third of previously described and biochemically confirmed PSD components, pointing to limitations in the techniques used. A recent paper by Yoshimura et al. (17) reports the identification by mass spectrometry of 492 proteins in the PSD, which suggests that the PSD is more ...
Neuronal development, plasticity and survival require activity-dependent synapse-to-nucleus signaling. Most studies implicate an activity-dependent regulation of gene expression in this phenomenon. However, little is known about other nuclear functions that are regulated by synaptic activity. Here we show that a newly identified component of rat postsynaptic densities (PSDs), AIDA-1d, can regulate global protein synthesis by altering nucleolar numbers. AIDA-1d binds to the first two postsynaptic density-95/Discs large/zona occludens-1 (PDZ) domains of the scaffolding protein PSD-95 via its C-terminal three amino acids. Stimulation of NMDA receptors (NMDARs), which are also bound to PSD-95, results in a Ca2+-independent translocation of AIDA-1d to the nucleus, where it couples to Cajal bodies and induces Cajal body-nucleolar association. Long-term neuronal stimulation results in an AIDA-1-dependent increase in nucleolar numbers and protein synthesis. We propose that AIDA-1d mediates a link between synaptic activity and control of protein biosynthetic capacity by regulating nucleolar assembly.
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