Pulsatile release of acetylcholinesterase from the substantia nigra following electrical stimulation of the striatum

Characterization of a Bioactive Peptide T14 in the Human and Rodent Substantia Nigra: Implications for Neurodegenerative Disease

The substantia nigra is generally considered to show significant cell loss not only in Parkinson's but also in Alzheimer's disease, conditions that share several neuropathological traits. An interesting feature of this nucleus is that the pars compacta dopaminergic neurons contain acetylcholinesterase (AChE). Independent of its enzymatic role, this protein is released from pars reticulata dendrites, with effects that have been observed in vitro, ex vivo and in vivo. The part of the molecule responsible for these actions has been identified as a 14-mer peptide, T14, cleaved from the AChE C-terminus and acting at an allosteric site on alpha-7 nicotinic receptors, with consequences implicated in neurodegeneration. Here, we show that free T14 is co-localized with tyrosine hydroxylase in rodent pars compacta neurons. In brains with Alzheimer's pathology, the T14 immunoreactivity in these neurons increases in density as their number decreases with the progression of the disease. To explore the functional implications of raised T14 levels in the substantia nigra, the effect of exogenous peptide on electrically evoked neuronal activation was tested in rat brain slices using optical imaging with a voltage-sensitive dye (Di-4-ANEPPS). A significant reduction in the activation response was observed; this was blocked by the cyclized variant of T14, NBP14. In contrast, no such effect of the peptide was seen in the striatum, a region lacking the T14 target, alpha-7 receptors. These findings add to the accumulating evidence that T14 is a key signaling molecule in neurodegenerative disorders and that its antagonist NBP14 has therapeutic potential.

Anatomical analysis of the neurons expressing the acetylcholinesterase gene in the rat brain, with special reference to the striatum

The localization of the neurons expressing the acetylcholinesterase gene in the rat central nervous system was studied by in situ hybridization. The striatal and nigral neurons containing acetylcholinesterase messenger RNA were especially identified. Acetylcholinesterase messenger RNA was detected in numerous areas of the central nervous system, including cholinergic areas, like striatum, nucleus basalis of Meynert, septum and diagonal band of Broca, but also non-cholinergic areas, like the cerebral cortex, the hippocampus, the cerebellum and the raphe dorsalis. In the striatum, 75% of the neurons expressing the acetylcholinesterase gene were identified as cholinergic neurons and 25% as somatostatin-producing neurons. All dopaminergic neurons of the substantia nigra pars compacta and ventral tegmental area were demonstrated to express the acetylcholinesterase gene. Our results suggest that several neuronal populations could contribute to the presence of acetylcholinesterase in the striatum: the striatal cholinergic and somatostatin-containing interneurons, the nigral dopaminergic neurons and other neurons that may be the corticostriatal, thalamostriatal and raphe-striatal neurons. This demonstrates that, especially in the striatum, acetylcholinesterase is not a specific marker of the cholinergic neurons. The diversity of the origins of striatal acetylcholinesterase suggests a multiplicity of functions for this enzyme: besides its cholinolytic actions, it may also possibly play a non-cholinolytic role in neuromodulation.

The subthalamo-nigral pathway regulates movement and concomitant acetylcholinesterase release from the substantia nigra

Within the substantia nigra acetylcholinesterase is released independently of cholinergic transmission: this release could be related to some aspects of motor control. To investigate this possibility, acetylcholinesterase release was continuously monitored in relation to specific movements evoked by central electrical stimulation. Increased intensities of stimulation of the subthalamic nucleus in awake guinea-pigs produced a behavioural response, ranging from a decrease in spontaneous movement, to chewing, to both chewing and circling movements. Enhancement of acetylcholinesterase release occurred only when large scale movements (circling as well as chewing) were evoked by subthalamic stimulation: however, a similar protocol of stimulation during ketamine-induced anaesthesia did not produce any comparable movements nor any concomitant change in the release of acetylcholinesterase. Perfusion of the glutamate agonist N-methyl-D-aspartate (NMDA) into the substantia nigra also induced an increase in release of acetylcholinesterase from the substantia nigra of conscious animals, whereas (S)-alpha-amino-3-hydroxy-5-methylisoxazole-4-proprionic acid (AMPA) did not significantly enhance acetylcholinesterase levels. It is concluded that AChE release in the substantia nigra can occur as a result of activation of glutamatergic subthalamic afferents, and that this activation may also be associated with changes in movement.

Distribution of acetylcholinesterase in the hippocampal region of the mouse: II. Subiculum and hippocampus

The distribution of acetylcholinesterase (AChE) was examined in the subiculum and hippocampus of the adult mouse (Mus musculus domesticus). A distinctly stratified AChE pattern was observed in both areas and was compared in detail with cytoarchitectural fields and layers. In the subiculum, the lateral plexiform layer was lightly stained superficially and moderately stained at depth, where it abutted the lateral, moderately stained cell layer. Medially, a moderately stained deep plexiform layer separated the darkly stained superficial plexiform layer from the equally AChE-intense cell layer. At depth, the subicular cell layer was delimited by a band of very high AChE activity. In regio superior of the hippocampus, AChE-intense bands delimited the moderately stained strata moleculare, radiatum, and oriens toward the subjacent layers. In the stratum pyramidale, precipitate insinuated between the cell bodies gave a dark appearance to the deep part of the layer. The homologous strata of regio inferior appeared darker, but the relative staining intensities corresponded largely to those in regio superior. AChE activity in the layer of mossy fibers was almost absent septally but increased gradually to very high levels temporally. The AChE staining pattern, in conjunction with cytochemical and morphological evidence, strongly suggests a division of the pyramidal cell layer of the mouse and rat into superficial and deep substrata and discourages the definition of a prosubiculum in rodents. A comparative analysis of the AChE pattern reveals that: 1) in the subiculum, differences between species are observed within a generalized pattern of medial darkly staining and lateral lightly staining portions; 2) in the hippocampus, a conservation of the AChE pattern is seen in strata associated with intrinsic hippocampal connection; while 3) numerous interspecific differences are found in the stratum moleculare.

A noncholinergic action of acetylcholinesterase (AChE) in the brain: from neuronal secretion to the generation of movement

1. In various brain regions, there is a puzzling disparity between large amounts of acetylcholinesterase and low levels of acetylcholine. One such area is the substantia nigra. Furthermore, within the substantia nigra, a soluble form of acetylcholinesterase is released from the dendrites of dopamine-containing nigrostriatal neurons, independent of cholinergic transmission. These two issues have prompted the hypothesis that acetylcholinesterase released in the substantia nigra has an unexpected noncholinergic function. 2. Electrophysiological studies demonstrate that this dendritic release is a function, not of the excitability of the cell from which the acetylcholinesterase is released, but of the inputs to it. In order to explore this phenomenon at the behavioral level, a novel system has been developed for detecting release of acetylcholinesterase "on-line." It can be seen that release of this protein within the substantia nigra can reflect, but is not causal to, movement. 3. Once released, the possible actions of acetylcholinesterase can be studied at both the cellular and the behavioral level. Independent of its catalytic site, acetylcholinesterase has a "modulatory" action on nigrostriatal neurons. The functional consequences of this modulation would be to enhance the sensitivity of the cells to synaptic inputs. 4. Many basic questions remain regarding the release and action of acetylcholinesterase within the substantia nigra and, indeed, within other areas of the brain. Nonetheless, tentative conclusions can be formulated that begin, in a new way, to provide a link between cellular mechanisms and the control of movement.

"On-line" measurement of acetylcholinesterase release from the substantia nigra of the freely-moving guinea-pig

Acetylcholinesterase is released from dopaminergic cells within the substantia nigra. The functional significance of this phenomenon has been studied in the freely-moving animal by a novel system for measuring acetylcholinesterase release from the substantia nigra "on-line" and in vivo. In the unanaesthetized guinea-pig the amount of acetylcholinesterase released was significantly greater than during anaesthesia, and release occurred in a more pulsatile manner. In addition, release of acetylcholinesterase could be evoked by either pharmacological or physiological manipulations, i.e. (1) a depolarizing concentration of potassium ions administered locally; (2) metamphetamine, administered systematically, which also resulted in increased locomotor activity; (3) drinking behaviour, elicited by presentation of a water bottle. Although all three treatments were accompanied by an increase in acetylcholinesterase release within the substantia nigra, potassium-evoked release did not cause any detectable change in behaviour. It is therefore suggested that release of the protein acetylcholinesterase within the substantia nigra is not necessarily a direct cause of locomotor activity: rather, it reflects diverse sensorimotor events.