Daily living often requires individuals to flexibly respond to new circumstances. There is considerable evidence that the striatum is part of a larger neural network that supports flexible adaptations. Cholinergic interneurons are situated to strongly influence striatal output patterns which may enable flexible adaptations. The present experiments investigated whether acetylcholine actions in different striatal regions support behavioral flexibility by measuring acetylcholine efflux during place reversal learning. Acetylcholine efflux selectively increased in the dorsomedial striatum, but not dorsolateral or ventromedial striatum during place reversal learning. In order to modulate the M2-class of autoreceptors, administration of oxotremorine sesquifumurate (100 nM) into the dorsomedial striatum, concomitantly impaired reversal learning and an increase in acetylcholine output. These effects were reversed by the m 2 muscarinic receptor antagonist, AF-DX-116 (20 nM). The effects of oxotremorine sesquifumurate and AF-DX-116 on acetylcholine efflux were selective to behaviorally-induced changes as neither treatment affected acetylcholine output in a resting condition. In contrast to reversal learning, acetylcholine efflux in the dorsomedial striatum did not change during place acquisition. The results reveal an essential role for cholinergic activity and define its locus of control to the dorsomedial striatum in cognitive flexibility.
Apolipoprotein E is a 299-residue
lipid carrier protein produced
in both the liver and the brain. The protein has three major isoforms
denoted apoE2, apoE3, and apoE4 which differ at positions 112 and
158 and which occur at different frequencies in the human population.
Genome-wide association studies indicate that the possession of two
apoE4 alleles is a strong genetic risk factor for late-onset Alzheimer’s
disease (LOAD). In an attempt to identify a small molecule stabilizer
of apoE4 function that may have utility as a therapy for Alzheimer’s
disease, we carried out an NMR-based fragment screen on the N-terminal
domain of apoE4 and identified a benzyl amidine based fragment binder.
In addition to NMR, binding was characterized using various other
biophysical techniques, and a crystal structure of the bound core
was obtained. Core elaboration ultimately yielded a compound that
showed activity in an IL-6 and IL-8 cytokine release assay.
Increases in blood glucose levels are an important component of the mechanisms by which epinephrine enhances memory formation. The present experiments addressed the hypothesis that a dysfunction in the blood glucose response to circulating epinephrine contributes to age-related memory impairments. Doses of epinephrine and glucagon that significantly increased blood glucose levels in young adult rats were far less effective at doing so in two-year-old rats. In young rats, epinephrine and glucose were about equally effective in enhancing memory and in prolonging post-training release of acetylcholine in the hippocampus. However, glucose was more effective than epinephrine in enhancing both memory and acetylcholine release in aged rats. These results suggest that an uncoupling between circulating epinephrine and glucose levels in old rats may lead to an age-related reduction in the provision of glucose to the brain during training. This in turn may contribute to age-related changes in memory and neural plasticity.
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