Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.1.7 (acetylcholinesterase)
 28,390 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The cholinergic innervation of the visceral component of the nucleus of the solitary tract in the ferret was investigated by using choline acetyltransferase immunocytochemistry. The subdivisions of the ferret solitary tract nucleus as defined by Nissl architectonics were found to correspond to most of those previously assigned to the cat solitary tract nucleus. The subnuclei of the ferret solitary tract nucleus were also outlined by using immunohistochemical and histochemical methods to stain for nerve growth factor (NGF) receptor and acetylcholinesterase, respectively. In particular, the gelatinosus and interstitial subnuclei stain intensely for NGF receptor immunoreactivity and for acetylcholinesterase activity. Since abundant NGF receptor immunoreactivity is observed also in the nodose ganglion and in the solitary tract, it was assumed that the gelatinosus and the interstitial subnuclei represent the principal sites of termination of primary visceral afferents. A rich choline acetyltransferase-positive terminal axonal arborization was located in all of the subdivisions of the solitary tract nucleus but was found to be lacking in the gelatinosus and interstitial subnuclei. A small number of giant choline acetyltransferase-positive axon terminals was seen in the subnucleus gelatinosus but was assumed to be of doubtful functional significance because these terminals derive from only one or two large axons on each side of the brain. The weak cholinergic innervation of the gelatinosus and interstitial subnuclei and the stronger innervation of the other subnuclei suggest that acetylcholine has a more important role in the secondary rather than the primary processing of afferent visceral information. Because the distribution of acetylcholinesterase activity in the nucleus of the solitary tract matches that of the NGF receptor immunoreactivity rather than that of the cholinergic acetyltransferase immunoreactivity, a non-cholinergic function for acetylcholinesterase may dominate in the solitary tract nucleus of the ferret.
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PMID:Organisation of the visceral solitary tract nucleus in the ferret as defined by the distribution of choline acetyltransferase and nerve growth factor receptor immunoreactivity. 166 21

The aim of this study was to examine the development of the basalocortical pathway by using choline acetyltransferase and nerve growth factor receptor immunocytochemistry, acetylcholinesterase histochemistry and retrograde axonal transport. The observations were made in the ferret because in this species brain development occurs over a much more protracted period than in the rat. Staining for choline acetyltransferase immunoreactivity in the brain was minimal before birth. Adult levels of staining for the enzyme were not seen in cell bodies until three weeks after birth and in axons up to six weeks after birth. This, however, did not mean that presumptive cholinergic pathways are absent early in development. There was strong staining for nerve growth factor receptor in basal forebrain neurons from at least two weeks before birth. Positive staining for acetylcholinesterase was found in axons that begin to invade the cerebral cortex a week before birth. The retrograde axonal transport technique showed that the basalocortical pathway has a normal organization in the neonate. The conclusion is that cholinergic pathways form early in the prenatal period in the ferret but express their transmitter function late in postnatal development.
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PMID:Early development of the nucleus basalis-cortical projection but late expression of its cholinergic function. 168 50

Trimethyltin (TMT) is known to produce substantial damage to the hippocampal formation. It also destroys neurons within the entorhinal cortex, thereby causing degeneration of perforant path afferents that terminate in the outer molecular layer (OML) of the dentate gyrus. Surgical destruction of the entorhinal cortex also causes the perforant path to degenerate. This leads to reactive synaptogenesis (axonal sprouting) of septal afferents to the dentate gyrus. The purpose of the present study was to determine whether administration of 6 mg/kg of TMT by gavage to rats would cause axonal sprouting within the septo-dentate projection. A histochemical stain for acetylcholinesterase (AChE) was used. Compared to control subjects rats given TMT exhibited significantly denser AChE staining in the dentate OML. This is putative indication of reactive synaptogenesis within the cholinergic projection to this layer of the dentate and is somewhat surprising because other neurotoxins, such as lead and ethanol, that affect neurons within the hippocampal formation reduce the capacity for reactive synaptogenesis in response to lesions of the entorhinal cortex.
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PMID:Exposure to trimethyltin significantly enhances acetylcholinesterase staining in the rat dentate gyrus. 169 Mar 43

Morphological and functional studies have been performed on experimental vitamin E deficient rats. The predominant morphological change was axonal dystrophy and degeneration in the rostral parts of the dorsal columns, particularly in the gracile fasciculi. The dystrophic changes comprised focal axonal swellings containing accumulations of normal and abnormal organelles which included tubulovesicular structures probably derived from the smooth endoplasmic reticulum, mitochondria, dense lamellar bodies, neurofilaments, multifascicular bodies and lysosomes. Similar but lesser changes were observed in distal peripheral nerves. The appearances suggested a disturbance of axonal transport with a defect of 'turnaround' in the distal axons. Studies on the axonal transport of endogenous acetylcholinesterase showed an impairment both of fast anterograde and retrograde transport. The changes were considered to be secondary to the lack of the antioxidant effect of vitamin E as the neurological deficits could be reduced by the concomitant dietary administration of the synthetic antioxidant ethoxyquin and were markedly aggravated by the administration of polyunsaturated fatty acids. It is suggested that the neurological syndrome produced by vitamin E deficiency could be the result of damage to the function of mitochondria and other intra-axonal membranous structures which would interfer both with fast anterograde transport and 'turnaround' and lead to a distal axonal degeneration.
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PMID:Experimental vitamin E deficiency in rats. Morphological and functional evidence of abnormal axonal transport secondary to free radical damage. 171 May 28

We developed a method for detecting activity of axonal cholinesterase (CE) and carbonic anhydrase (CA)--markers for motor and sensory nerve fibers (NFs)--in the same histological section. To reach this goal, cross-sections of muscle nerves were sequentially incubated with the standard protocols for CE and CA histochemistry. A modified incubation medium was used for CA in which Co++ is replaced by Ni++. This avoids interference of the two histochemical reactions because Co++ binds unspecifically to the brown copper-ferroferricyanide complex representing CE activity, whereas Ni++ does not. Cross-sections of the trapezius muscle nerve containing efferent and afferent NFs in segregated fascicles showed that CE activity was confined to motor NFs. Axonal CA was detected solely in sensory NFs. The number of labeled motor and sensory NFs determined in serial cross-sections stained with either the new or the conventional technique was not significantly different. Morphometric analysis revealed that small unreactive NFs (diameter less than 5 microns) are afferent, medium-sized ones (5 microns less than d less than 7 microns) are unclassifiable, and large ones (d greater than 7 microns) are efferent. The heterogenous CE activity of thick (alpha) motor NFs is linked to the type of their motor units. "Fast" motor units contain CE reactive NFs; "slow" ones have CE negative neurites.
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PMID:Axon typing of rat muscle nerves using a double staining procedure for cholinesterase and carbonic anhydrase. 171 70

Adult monkey sensorimotor cortex consists of several structurally and functionally distinct areas. The developmental sequence through which the characteristic architectonic features and the borders of these areas become resolved was examined in a series of fetal, postnatal and adult monkeys by using Nissl staining, cytochrome oxidase and acetylcholinesterase histochemistry, and immunocytochemistry for GABA and the neuropeptides somatostatin, neuropeptide Y, substance P and cholecystokinin. At the youngest fetal age examined (E110), the pre- and postcentral gyri possess six clearly delineated cellular layers; populations of GABA- and neuropeptide-immunoreactive cells can be identified, but their somatic sensory cortex at E110 lacks areal cytoarchitectonic parcellation. Despite the apparent homogeneity in the cytoarchitecture of the somatic sensory cortex, incipient areal borders are revealed by staining for cytochrome oxidase and acetylcholinesterase activity, and by staining immunocytochemically for several neuropeptides. The motor cortex at E110 differs from that in adults by the presence of a prominent layer IV; a clear cytoarchitectonic border between areas 3a and 4 is detectable at E110, which is also revealed by chemoarchitectonic markers. With increasing age, the characteristic architectonic features gradually emerge and areal cytoarchitectonic borders appear, becoming adult-like by early postnatal ages. The gradual changes in cytoarchitecture are paralleled by redistributions of GABA- and neuropeptide-immunoreactive cells and fiber plexuses. The data demonstrate that the progressive refinement in cytoarchitectonic features and in the distributions of neurotransmitter- and peptide-containing cells occurs primarily during the latter third of gestation. The major changes are temporally coincident with the ingrowth of afferent axonal systems, suggesting that the establishment of connectivity may be capable of modulating finer details of structural or molecular phenotype, particularly intra-areal cytoarchitectonic features and neurotransmitter or peptide expression.
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PMID:The emergence of architectonic field structure and areal borders in developing monkey sensorimotor cortex. 171 47

A quantitative taxonomy of primate striatal neurons was elaborated on the basis of the morphology of Golgi-impregnated neurons. Dendritic arborizations were reconstructed from serial sections and digitized in three dimensions by means of a video computer system. Topological, metrical, and geometrical parameters were measured for each neuron. Groups of neurons were isolated by using uni- and multidimensional statistical tests. A neuronal species was defined as a group of neurons characterized quantitatively by a series of nonredundant parameters, differing statistically from other groups, and appearing as a separate cluster in principal component analysis. Four neuronal species were isolated: (1) the spiny neuronal species (96% of striatal neurons) characterized by spine-free proximal dendrites (up to 31 microns) and spine-laden distal dendrites, which are more numerous, shorter, and less spiny in the human than in the monkey, (2) the leptodendritic neuronal species (2%) characterized by a small number of long, thick, smooth, and sparsely ramified dendrites, (3) the spidery neuronal species (1%) characterized by very thick dendritic stems and a large number of varicose recurrent distal processes, and (4) the microneuronal species (1%) characterized by numerous short, thin, and beaded axonlike processes. All striatal neurons give off a local axonal arborization. The size and shape of cell bodies were analyzed quantitatively in Golgi material and in materials treated for Nissl-staining, immunohistochemical demonstration of parvalbumin and histochemical demonstration of acetylcholinesterase. Only three types were distinguishable: small, round cell bodies corresponding to either spiny neurons or microneurons, medium-size elongated cell bodies, which were parvalbumin-immunoreactive and corresponded to leptodendritic neurons, and large round cell bodies, which were acetylcholinesterase-positive and corresponded to spidery neurons. Thorough analysis of previously elaborated classifications revealed that spidery neurons do not exist in rats and cats and that large cholinergic neurons in these species correspond to leptodendritic neurons. From this, it can be assumed that the dendritic domain of striatal cholinergic neurons is considerably smaller in primates than in other species. Computer simulations based on both the frequency of each neuronal species and their three-dimensional dendritic morphology revealed that the striatum consists of two intertwined dendritic lattices: a fine-grain lattice (300-600 microns) formed by the dendritic arborizations of spiny, spidery, and microneurons, and a large-grain lattice (1,200 microns) formed by the dendritic arborizations of leptodendritic neurons. This suggests that cortical information can be processed in the striatum through two different systems: a fine-grain system that would conserve the precision of the cortical input, and a large-grain system that would blur it.
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PMID:Morphological taxonomy of the neurons of the primate striatum. 172 88

The morphology of the peroneus longus muscle of the Chinese quail was studied in relation to partial behavorial characteristics. On the basis of the actomyosin ATPase reaction after alkaline and acid preincubation, three fiber types are revealed. The indirect immunofluorescence, using specific antibodies against 'slow' myosin from the human vastus lateralis muscle, provokes a strong reaction on the small fiber type. The characteristics of the innervation revealed by the cholinesterase activity, concentrated in the synaptic gutters and the direct study of the nerve fibres, show focal, mono-axonal 'en plaques' endings, typical of the phasic motor system.
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PMID:[Histochemistry, immunocytochemistry, and biometry of muscle fibers and their innervation of the peroneus longus muscle]. 183 85

In patients and test animals similar changes in innervation have been revealed. Degeneration of some preterminal axons has been shown. The most manifested feature's increased ramification of distal axons. No signs of real reinnervation have been found. New collateral branches of preterminal, terminal and ++ultra-terminal axons usually have their ends at the same muscle fiber in the form of additional nervous terminals. Decreased average diameter of motor end-plates, revealed in the test animals, depends not on their degeneration, but on formation of new small motor end plates as a result of immature axonal ramification of distal axons. Acetylcholinesterase activity in the end-plates is decreased. A suggestion is made that excess of thyroid hormones in the skeletal muscle disturbs both the system of cyclic nucleotides and mechanisms of muscular contraction, connected with it and axoplasmic transport, respectively. The changes of the terminal intramuscular innervation revealed, structures of the motor end-plates with a decrease of acetylcholinesterase activity are supposed to result from disturbances of neurotrophic regulation of the muscle fibers because of the disturbances of the axoplasmic current as the excess of thyroid hormones.
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PMID:[Motor innervation of muscle fibers in thyrotoxic myopathy]. 184 24

The compound 2,5-hexanedione (HD) produces axonopathies in peripheral nerves characterized by selective accumulation of neurofilaments. Its direct actions on neurotransmitter-specific neurons in the brain are unknown. In an attempt to address this latter issue, we infused HD into the fimbria and evaluated histochemically and immunohistochemically possible structural alterations in cholinergic neurons projecting from the basal nuclear complex to the hippocampus. Putative cholinergic fibers expressing nerve growth factor receptor and acetylcholinesterase showed increases in caliber and perturbations in trajectories 2-4 days following HD treatment. Similar morphologic changes were observed in neuronal elements processed for the 68 kDa neurofilament protein. At 7 days, short collateral ramifications appeared in many cholinergic axons that were suggestive of neurite outgrowth. Correlated with these fiber alterations was a transient reduction in the number of medial septal and diagonal band somata expressing choline acetyltransferase, which returned to control levels within 6 weeks following HD treatment. These data support the view that neurofilaments play an important, perhaps cytoarchitecturally stabilizing, role in regulating axonal morphology in certain populations of cholinergic neurons.
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PMID:Cholinergic fiber perturbations and neuritic outgrowth produced by intrafimbrial infusion of the neurofilament-disrupting agent 2,5-hexanedione. 184 77


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