Holly R. Robertson scite author profile

NMDA receptor (NMDAR)-dependent long-term potentiation (LTP) and depression (LTD) are forms of synaptic plasticity underlying learning and memory that are expressed through increases and decreases, respectively, in dendritic spine size and AMPA receptor (AMPAR) phosphorylation and postsynaptic localization. The A-kinase anchoring protein (AKAP) 79/150 signaling scaffold regulates AMPAR phosphorylation, channel activity, and endosomal trafficking associated with LTP and LTD. AKAP79/150 is targeted to dendritic spine plasma membranes by an N-terminal polybasic domain that binds phosphoinositide lipids, F-actin, and cadherin cell adhesion molecules. However, we do not understand how regulation of AKAP targeting controls AMPAR endosomal trafficking. Here we report that palmitoylation of the AKAP N-terminal polybasic domain targets it to postsynaptic lipid rafts and dendritic recycling endosomes. AKAP palmitoylation was regulated by seizure activity in vivo and LTP/LTD plasticity-inducing stimuli in cultured rat hippocampal neurons. With chemical LTP induction, we observed AKAP79 dendritic spine recruitment that required palmityolation and Rab11-regulated endosome recycling coincident with spine enlargement and AMPAR surface delivery. Importantly, a palmitoylation-deficient AKAP79 mutant impaired regulation of spine size, endosome recycling, AMPAR trafficking, and synaptic potentiation. These findings emphasize the emerging importance of palmitoylation in controlling synaptic function and reveal novel roles for the AKAP79/150 signaling complex in dendritic endosomes.

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Comparative Effectiveness of Aspirin Dosing in Cardiovascular Disease

Jones¹,

Mulder²,

Wruck³

et al. 2021

N Engl J Med

190

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BACKGROUNDThe appropriate dose of aspirin to lower the risk of death, myocardial infarction, and stroke and to minimize major bleeding in patients with established atherosclerotic cardiovascular disease is a subject of controversy. METHODSUsing an open-label, pragmatic design, we randomly assigned patients with established atherosclerotic cardiovascular disease to a strategy of 81 mg or 325 mg of aspirin per day. The primary effectiveness outcome was a composite of death from any cause, hospitalization for myocardial infarction, or hospitalization for stroke, assessed in a time-to-event analysis. The primary safety outcome was hospitalization for major bleeding, also assessed in a time-to-event analysis. RESULTSA total of 15,076 patients were followed for a median of 26.2 months (interquartile range [IQR], 19.0 to 34.9). Before randomization, 13,537 (96.0% of those with available information on previous aspirin use) were already taking aspirin, and 85.3% of these patients were previously taking 81 mg of daily aspirin. Death, hospitalization for myocardial infarction, or hospitalization for stroke occurred in 590 patients (estimated percentage, 7.28%) in the 81-mg group and 569 patients (estimated percentage, 7.51%) in the 325-mg group (hazard ratio, 1.02; 95% confidence interval [CI], 0.91 to 1.14). Hospitalization for major bleeding occurred in 53 patients (estimated percentage, 0.63%) in the 81-mg group and 44 patients (estimated percentage, 0.60%) in the 325-mg group (hazard ratio, 1.18; 95% CI, 0.79 to 1.77). Patients assigned to 325 mg had a higher incidence of dose switching than those assigned to 81 mg (41.6% vs. 7.1%) and fewer median days of exposure to the assigned dose (434 days [IQR, 139 to 737] vs. 650 days [IQR, 415 to 922]). CONCLUSIONSIn this pragmatic trial involving patients with established cardiovascular disease, there was substantial dose switching to 81 mg of daily aspirin and no significant differences in cardiovascular events or major bleeding between patients assigned to 81 mg and those assigned to 325 mg of aspirin daily. (Funded by the Patient-Centered Outcomes Research Institute; ADAPTABLE ClinicalTrials.gov number, NCT02697916.

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Regulation of Postsynaptic Structure and Function by an A-Kinase Anchoring Protein-Membrane-Associated Guanylate Kinase Scaffolding Complex

Robertson¹,

Gibson²,

Benke³

et al. 2009

Journal of Neuroscience

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CaMKII regulates the depalmitoylation and synaptic removal of the scaffold protein AKAP79/150 to mediate structural long-term depression

Woolfrey¹,

O’Leary²,

Goodell

et al. 2018

Journal of Biological Chemistry

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/CaM, a mechanism that favors phosphorylation by prolonged, weak LTD stimuli versus brief, strong LTP stimuli. Phosphorylation by CaMKII inhibited AKAP79/150 association with F-actin; it also facilitated AKAP79/150 removal from spines but was not required for it. By contrast, LTD-induced spine removal of AKAP79/150 required its depalmitoylation on two Cys residues within the N-terminal targeting domain. Notably, such LTD-induced depalmitoylation was also blocked by CaMKII inhibition. These results provide a mechanism how CaMKII can indeed mediate not only LTP but also LTD through regulated substrate selection; however, in the case of AKAP79/150, indirect CaMKII effects on palmitoylation are more important than the effects of direct phosphorylation. Additionally, our results provide the first direct evidence for a function of the well-described AKAP79/150 trafficking in regulating LTD-induced spine shrinkage. LTP7 and LTD are two opposing forms of synaptic plasticity that together are thought to underlie learning, memory, and cognition (1, 2). CaMKII and its Ca 2ϩ -independent autonomous kinase activity that is generated by Thr-286 autophosphorylation have been tightly linked to LTP for over 25 years (3-6); by contrast, an additional requirement in LTD is just emerging (7,8). LTD also requires the phosphatase calcineurin (CaN) (9, 10), and specifically a pool of CaN co-anchored with protein kinase A (PKA) at synapses by AKAP79 (in humans) or AKAP150 (the rodent homologue) (11-13). However, somewhat paradoxically, LTD stimuli ultimately trigger the synaptic removal of , suggesting the following model: LTD stimuli quickly induce CaN-dependent dephosphorylation of the AMPA-type glutamate receptor (AMPAR) subunit GluA1 at the PKA site Ser-845 to promote AMPAR internalization; subsequent CaN-dependent AKAP79/150 removal then removes AKAP-anchored PKA from synapses to prevent GluA1 Ser-845 re-phosphorylation (12,15). Here, we show that synaptic AKAP79/150 removal is also required for structural LTD (i.e. the shrinkage of dendritic spines) and that this removal requires CaMKII. Thus, our results provide a direct mechanistic explanation for the requirement of CaMKII in LTD as well as the first direct evidence for a requirement of the well-studied AKAP79/150 removal from spines in an LTD mechanism.

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