S-Nitrosylation and S-Palmitoylation Reciprocally Regulate Synaptic Targeting of PSD-95

SummaryPSD-95, a principal scaffolding component of the postsynaptic density, is targeted to synapses by palmitoylation, where it couples NMDA receptor stimulation to production of nitric oxide (NO) by neuronal nitric oxide synthase (nNOS). Here, we show that PSD-95 is physiologically S-nitrosylated. We identify cysteines 3 and 5, which are palmitoylated, as sites of nitrosylation, suggesting a competition between these two modifications. In support of this hypothesis, physiologically produced NO inhibits PSD-95 palmitoylation in granule cells of the cerebellum, decreasing the number of PSD-95 clusters at synaptic sites. Further, decreased palmitoylation, as seen in heterologous cells treated with 2-bromopalmitate or in ZDHHC8 knockout mice deficient in a PSD-95 palmitoyltransferase, results in increased PSD-95 nitrosylation. These data support a model in which NMDA-mediated production of NO regulates targeting of PSD-95 to synapses via mutually competitive cysteine modifications. Thus, differential modification of cysteines may represent a general paradigm in signal transduction.

► PSD-95 is S-nitrosylated at cysteines 3 and 5 ► Nitrosylation at cysteines 3 and 5 inhibits palmitoylation at these sites ► S-nitrosylation of PSD-95 inhibits synaptic clustering ► Inhibition of PSD-95 palmitoylation increases S-nitrosylation of PSD-95