Reese
Thomas S.
Reese
Thomas S.
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PreprintInhibition of phosphatase activity facilitates the formation and maintenance of NMDA-induced calcium/calmodulin-dependent protein kinase ii clusters in hippocampal neurons( 2004-10-04) Tao-Cheng, Jung-Hwa ; Vinade, Lucia ; Winters, Christine A. ; Reese, Thomas S. ; Dosemeci, AyseThe majority of hippocampal neurons in dissociated cultures and in intact brain exhibit clustering of CaMKII into spherical structures with an average diameter of 110 nm when subjected to conditions that mimic ischemia and excitotoxicity (Tao-Cheng et al., 2001). Because clustering of CaMKII would reduce its effective concentration within the neuron, it may represent a cellular strategy to prevent excessive CaMKII-mediated phosphorylation during episodes of Ca2+ overload. Here we employ a relatively mild excitatory stimulus to promote sub-maximal clustering for the purpose of studying the conditions for the formation and disappearance of CaMKII clusters. Treatment with 30 µM NMDA for 2 min produced CaMKII clustering in ~15 percent of dissociated hippocampal neurons in culture, as observed by pre-embedding immunogold electron microscopy. These CaMKII clusters could be labeled with antibodies specific to the phospho form (Thr286) of CaMKII, suggesting that at least some of the CaMKII molecules in clusters are autophosphorylated. To test whether phosphorylation is involved in the formation and maintenance of CaMKII clusters, the phosphatase inhibitors calyculin A (5 nM) or okadaic acid (1 µM) were included in the incubation medium. With inhibitors more neurons exhibited CaMKII clusters in response to 2 min NMDA treatment. Furthermore, 5 min after the removal of NMDA and Ca2+, CaMKII clusters remained and could still be labeled with the phospho-specific antibody. In contrast, in the absence of phosphatase inhibitors, no clusters were detected 5 min after the removal of NMDA and Ca2+ from the medium. These results suggest that phosphatases type 1 and/or 2A regulate the formation and disappearance of CaMKII clusters.
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PreprintPalmitoylation regulates glutamate receptor distributions in postsynaptic densities through control of PSD95 conformation and orientation( 2016-08) Jeyifous, Okunola ; Lin, Eric I. ; Chen, Xiaobing ; Antinone, Sarah E. ; Mastro, Ryan ; Drisdel, Renaldo ; Reese, Thomas S. ; Green, William N.PSD95 and SAP97 are homologous scaffold proteins with different N-terminal domains, possessing either a palmitoylation site (PSD95) or an L27 domain (SAP97). Here, we measured PSD95 and SAP97 conformation in vitro and in postsynaptic densities (PSDs) using FRET and electron microscopy, and examined how conformation regulated interactions with AMPA-type and NMDAtype glutamate receptors (AMPARs/NMDARs). Palmitoylation of PSD95 changed its conformation from a compact to an extended configuration. PSD95 associated with AMPARs (via TARP subunits) or NMDARs (via GluN2B subunits) only in its palmitoylated and extended conformation. In contrast, SAP97 in its extended conformation associates with NMDARs but not with AMPARs. Within PSDs, PSD95 and SAP97 were largely in the extended conformation, but had different orientations. PSD95 oriented perpendicular to the PSD membrane, with its palmitoylated, N-terminal domain at the membrane. SAP97 oriented parallel to the PSD membrane, likely as a dimer through interactions of its N-terminal, L27 domain. Changing PSD95 palmitoylation in PSDs altered PSD95 and AMPAR levels but did not affect NMDAR levels. These results indicate that in PSDs, PSD95 palmitoylation, conformation and its interactions are dynamic when associated with AMPARs, and more stable when associated with NMDARs. Altogether, our results are consistent with differential regulation of PSD95 palmitoylation in PSDs resulting from the clustering of palmitoylating and depalmitoylating enzymes into AMPAR nanodomains segregated away from NMDAR nanodomains.