Accurate density-functional calculation of core-electron binding energies with a scaled polarized triple-zeta basis set VII. Effects of poorer geometry and poorer basis sets

It is pointed out that Ca2+-dependent modification rules for NMDA-dependent (NMDAindependent) synaptic plasticity in the striatum are similar to those in the neocortex and hippocampus (cerebellum). A unitary postsynaptic mechanism of synaptic modification is proposed. It is based on the assumption that, in diverse central nervous system structures, long-term potentiation/depression (LTP/LTD) of excitatory transmission (depression/potentiation of inhibitory transmission, LTDi/LTPi) is the result of an increasing/decreasing the number of phosphorylated AMPA and NMDA (GABAA) receptors. According to the suggested mechanism, Ca2+/calmodulin-dependent protein kinase II and protein kinase C, whose activity is positively correlated with Ca2+ enlargement, together with cAMP-dependent protein kinase A (cGMP-dependent protein kinase G, whose activity is negatively correlated with Ca2+ rise) mainly phosphorylate ionotropic striatal receptors, if NMDA channels are opened (closed). Therefore, the positive/negative posttetanic Ca2+ shift in relation to a previous Ca2+ rise must cause NMDA-dependent LTP+LTDi/LTD+LTPi or NMDA-independent LTD+LTPi/LTP+LTDi. Dopamine D1/D2 or adenosine A2A/A1 receptor activation must facilitate LTP+LTDi/LTD+LTPi due to an augmenting/lowering PKA activity. Activation of muscarinic M1/M4 receptors must enhance LTP+LTDi/LTD+LTPi as a consequence of an increase/decrease in the activity of protein kinase C/A. The proposed mechanism is in agreement with known experimental data.