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Target Concepts:
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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 brain of a child with Down syndrome develops differently from a normal one, attaining a form reduced in size and altered in configuration. Directly related to the mental retardation are neuronal modifications manifest as alterations of cortical lamination, reduced dendritic ramifications, and diminished synaptic formation. However, selected cholinergic marker enzymes such as choline acetyl transferase and acetyl
cholinesterase
have shown no alterations in young children with Down syndrome. The pace of the neuronal transformations is related to stage of maturation. With early growth and development, the normal dendritic tree continuously expands. In Down syndrome, at 4 months of age, the neurons show a relatively expanded dendritic tree, but during the first year the dendrites stop growing and become atrophic relative to control neurons. Accompanying these neuronal irregularities are subtle alterations of other cell types: astrocyte, oligodendrogliocyte, microglia, and endothelial cell. In early infancy, one of the astrocytic markers, GFAP, is not altered, but there is greater expression of S-100 protein in the temporal lobe in Down syndrome. Oligodendrogliocyte dysfunction is reflected in delayed myelination in pathways of frontal and temporal lobes. Microglia appear more prominent in Down syndrome. A minority of children with Down syndrome have vascular dysplasias and focal calcification of basal ganglia. In young children, expression of beta-amyloid in Down syndrome is no different than in normal children but disappears after age two, only to reappear in adults. As some of these studies suggest, the identification of genes on
chromosome 21
and the determination of the gene product allow the production of specific antibodies and, through immunohistochemical techniques, the identification of the expression of these proteins in both normal development and Down syndrome. Specifically, the localization and appearance in development of proteins such as the beta-subunit of S-100, beta-amyloid (A4 protein), superoxide dismutase, and OK-2 are providing the means for better understanding the morphogenesis of the cellular and eventually molecular basis for the mental retardation in Down syndrome.
...
PMID:Growth and development of the brain in Down syndrome. 183 82
The trisomy-16 (TS16) mouse is considered to be a model of human trisomy 21 (Down syndrome) because of genetic homology between mouse chromosome 16 and human
chromosome 21
. We examined cholinergic function of brain and spinal cord tissue and in cultured neurons from TS16 mouse compared with that of age matched controls. Mean
acetylcholinesterase
activity in both tissue types did not differ between trisomic and control conditions. Acetylcholine (ACh) synthesis, measured as choline O-acetyltratransferase (acetyl-CoA) activity, was reduced to 67% of control in TS16 brain but not in TS16 spinal cord. Steady-state accumulation of ACh precursor, [3H]choline, was measured in primary cell cultures. Steady-state choline uptake was reduced to 35% and to 61% in neurons of TS16 brain and spinal cord, respectively, when compared with controls. Kinetics experiments in TS16 brain cells showed a 50% reduction of the maximal velocity of choline uptake when compared to controls. Further, the ACh release induced by KCl depolarization in TS16 spinal cord neurons did not differ from control neurons but was reduced in TS16 brain neurons. This effect cannot be explained solely by a reduction in ACh synthesis. The results indicate that the TS16 condition in mice significantly modified the cholinergic function in brain, and to a lesser degree in spinal cord, suggesting that the higher gene dosage inherent to the trisomic condition affects cholinergic neurons in different regions of the central nervous system in a differential fashion.
...
PMID:Regional alteration of cholinergic function in central neurons of trisomy 16 mouse fetuses, an animal model of human trisomy 21 (Down syndrome). 783 52
The phenotype of the brain in Down syndrome is different from that of a normal child both in its reduced size and altered gyral configuration. Underlying the mental retardation are neuronal abnormalities, including alterations of cortical lamination, reduced dendritic ramifications, and diminished synaptic formation. However, cholinergic enzymes such as choline acetyl transferase and acetyl
cholinesterase
have shown no abnormalities in young children with Down syndrome. The pace of dendritic maturation is altered in Down syndrome. In infancy, the normal dendritic tree continuously expands; in Down syndrome, at 4 months of age, the neurons show a relatively expanded tree, but during the first year, the dendrites stop growing and become atrophic relative to control neurons. To relate these phenotypic alterations to
chromosome 21
, we examined the gene products of several genes localized to
chromosome 21
. Identification of such genes and determination of their gene product allow the production of specific antibodies and the identification, through immunohistochemical techniques, of the expression of these proteins in both normal development and Down syndrome. Specifically, the localization and appearance during development of proteins such as S100 beta, beta A4-amyloid, superoxide dismutase, and OK-2 are providing links between genotype and phenotype. S100 beta protein is of particular interest because of its effect in vitro on neuritic outgrowth and its increased expression in the temporal lobe in Down syndrome. The brains of transgenic mice bearing multiple copies of the human S100 gene show some comparable changes to those in Down syndrome. These experimental approaches provide the means for better understanding the cellular and molecular basis for the mental retardation in Down syndrome.
...
PMID:Association of phenotypic abnormalities of Down syndrome with an imbalance of genes on chromosome 21. 831 92
Ts65Dn mice, trisomic for a portion of chromosome 16 segmentally homologous to human
chromosome 21
, are an animal model for Down's syndrome and related neurodegenerative diseases, such as dementia of the Alzheimer type. In these mice, cognitive deficits and alterations in number of basal forebrain cholinergic neurons have been described. We have measured in Ts65Dn mice the catalytic activity of the cholinergic marker, choline acetyltransferase (ChAT), as well as the activity of the acetylcholine-degrading enzyme
acetylcholinesterase
(
AChE
), in the hippocampus and in cortical targets of basal forebrain cholinergic neurons. In mice aged 10 months, ChAT activity was significantly higher in Ts65Dn mice, compared to 2N animals, in the hippocampus, olfactory bulb, olfactory cortex, pre-frontal cortex, but not in other neocortical regions. At 19 months of age, on the other hand, no differences in ChAT activity were found. Thus, alterations of ChAT activity in these forebrain areas seem to recapitulate those recently described in patients scored as cases of mild cognitive impairment or mild Alzheimer's disease. Other neurochemical markers putatively associated with the disease progression, such as those implicating astrocytic hyperactivity and overproduction of amyloid precursor protein family, were preferentially found altered in some brain regions at the oldest age examined (19 months).
...
PMID:Choline acetyltransferase activity at different ages in brain of Ts65Dn mice, an animal model for Down's syndrome and related neurodegenerative diseases. 1653 60
