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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)
A point mutation in the gene for human serum
cholinesterase
was identified that changes Asp-70 to Gly in the atypical form of serum
cholinesterase
. The mutation in nucleotide 209, which changes codon 70 from GAT to GGT, was found by sequencing a
genomic clone
and sequencing selected regions of DNA amplified by the polymerase chain reaction. The entire coding sequences for usual and atypical cholinesterases were compared, and no other consistent base differences were found. A polymorphic site near the C terminus of the coded region was detected, but neither allele at this locus segregated consistently with the atypical trait. The nucleotide-209 mutation was detected in all five atypical
cholinesterase
families examined. There was complete concordance between this mutation and serum
cholinesterase
phenotypes for all 14 heterozygous and 6 homozygous atypical subjects tested. The mutation causes the loss of a Sau3A1 restriction site; the resulting DNA fragment length polymorphism was verified by electrophoresis of 32P-labeled DNA restriction fragments from usual and atypical subjects. Dot-blot hybridization analysis with a 19-mer allele-specific probe to the DNA amplified by the polymerase chain reaction distinguished between the usual and atypical genotypes. We conclude that the Asp-70----Gly mutation (acidic to neutral amino acid substitution) accounts for reduced affinity of atypical
cholinesterase
for choline esters and that Asp-70 must be an important component of the anionic site. Heterogeneity in atypical alleles may exist, but the Asp-70 point mutation may represent an appreciable portion of the atypical gene pool.
...
PMID:Identification of the structural mutation responsible for the dibucaine-resistant (atypical) variant form of human serum cholinesterase. 291 89
Acetylcholinesterase exists predominantly as a secreted enzyme which remains cell-associated at specific extracellular locations. Its extensive structural diversity appears responsible for the unique cellular disposition of the enzyme. To examine the molecular basis of the structural divergence of
acetylcholinesterase
species, we hybridized total RNA from Torpedo californica electric organ with restriction fragments from a cDNA encoding the catalytic subunits of asymmetric species of
acetylcholinesterase
. Multiple RNA species up to 14 kilobases in length can be detected on Northern blots using a full-length cDNA for hybridization. Each of these RNA species also hybridizes with smaller restriction fragments within the open reading frame and 3'-untranslated region of the cDNA. This indicates that the entire open reading frame plus the 3'-untranslated region is contained in the large RNA species. RNase protection experiments revealed at least three points of divergence for the message species. One occurs within the COOH-terminal portion of the open reading frame at a position just 5' to the TGA stop codon. This divergence accounts for the two classes of
acetylcholinesterase
found in abundance in Torpedo. The site of splicing has been further defined by isolating a
genomic clone
containing the exon serving as the potential splice donor. We find a divergence between the cDNA and genomic DNA at the position estimated by the protection experiments. A less abundant divergence in mRNA can also be detected in the 3'-untranslated region. Another divergence occurs as a deleted sequence within the 5'-noncoding region and may be important for controlling translation efficiency. Since it is hypothesized that a single gene encodes
acetylcholinesterase
, the divergences in the very 3' region of the open reading frame and the 5'-noncoding region correspond to presumed splice junction boundaries where alternative RNA splicing occurs.
...
PMID:Multiple messenger RNA species give rise to the structural diversity in acetylcholinesterase. 319 6
This study examines the tissue specificity and the gene products arising from alternative mRNA processing of the mammalian
acetylcholinesterase
gene. By splicing either alternative exons 5 or 6 in the mouse and human genes directly to the invariant exons (exons 2, 3, and 4), we show that the
acetylcholinesterase
species expressed by transfected recombinant DNA have the properties expected for the respective enzyme forms found in tissue. Antisense mRNA derived from these cDNAs has been employed to examine differential splicing in various tissues. In most cells, the hydrophilic form of AChE encoded by the exon 4 to exon 6 splice to form the mRNA is the predominant species. However, splicing of exon 4 to exon 5, yielding a mRNA encoding the glycophospholipid-linked form of
acetylcholinesterase
, is seen primarily in erythroid and to a lesser extent in AtT-20 cells. Only small amounts of this mRNA species appear in some other cells in culture. A novel third mRNA species, which arises from an extension of exon 4 without splicing to a downstream exon, is seen in mouse erythroid but not in human erythroid cells. A cDNA encoding this species when expressed in COS cells gives rise to a unique hydrophilic, secreted form of
acetylcholinesterase
. Transfection of a human
genomic clone
into mouse erythroleukemia cells does not result in the appearance of a mRNA species with an extension of exon 4 as seen with the endogenous mouse gene. Hence, differential splicing between the mouse and human genes appears intrinsic to the coding sequence and is not dependent solely on specific factors in the mouse erythroleukemia cell.
...
PMID:Tissue-specific expression and alternative mRNA processing of the mammalian acetylcholinesterase gene. 844 45
