Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: EC:3.2.1.26 (
invertase
)
4,927
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The treatment of Caco-2 cells, a human colon adenocarcinoma cell line that closely resembles normal human small intestinal epithelial cells, with
acetaldehyde
resulted in significantly decreased activities of brush border enzymes
sucrase
, maltase, lactase, and gamma-glutamyltransferase; alkaline phosphatase activity was not affected. In the case of
sucrase
and maltase, the activities were also decreased by a combination of
acetaldehyde
and ethanol, although ethanol alone markedly increased them. The possibility that intraintestinal
acetaldehyde
, formed by intestinal microbes, might play a role in some small intestinal enzyme deficiencies observed earlier in alcoholics should therefore be considered. The mechanism by which
acetaldehyde
alters these enzyme activities remains unclear. The observation that
acetaldehyde
also disturbed cell polarization, an initial step in the process of differentiation in Caco-2 cells, indicates that
acetaldehyde
might decrease these enzyme activities by interfering with cell differentiation. Because ethanol and
acetaldehyde
metabolizing enzymes have not been previously studied from Caco-2 cells, alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) activities were also measured from these cells, and their ALDH isoenzyme pattern was characterized. Like many cancerous cell lines, Caco-2 cells were found to express no ADH. They, however, possessed ALDH activity that was comparable with normal colonic mucosal activity and also expressed the same ALDH classes (ALDHs 1 to 3) than normal human colonic mucosa.
...
PMID:Effects of acetaldehyde on brush border enzyme activities in human colon adenocarcinoma cell line Caco-2. 943 18
Studies with experimental animals indicate that
acetaldehyde
, the first metabolite of ethanol that is microbially formed in the colonic lumen, may play a role in ethanol-associated colorectal co-carcinogenesis. Although intracoIonic
acetaldehyde
concentrations are highest during the metabolism of exogenous ethanol, some individuals may also possess marked amounts of endogenous
acetaldehyde
. Since no information is available concerning the possible effects of
acetaldehyde
on human colonic epithelial cells, this study was aimed to assess whether this compound, either alone or in combination with ethanol, affects such properties of human neoplastic colonocytes that are considered relevant with regard to cancer development. Human colon adenocarcinoma cell line Caco-2 was used as a model of transformed colonocytes, and effects of
acetaldehyde
and/or ethanol on the proliferation and differentiation of these cells as well as on their adhesion to collagens I and IV, the most important extracellular matrix proteins in the colon, were studied. The results of this study show that
acetaldehyde
markedly affects the phenotype of Caco-2 cells without having direct cytotoxic effects. Like many carcinogens, it was found to have a dual effect on cell proliferation rate, acute exposure being inhibitory and chronic exposure stimulating. Acetaldehyde also considerably decreased both
sucrase
activity and nuclear content of protein kinase A catalytic subunit in Caco-2 cells, which indicate that the differentiation of the cells was disturbed. Moreover, the adhesion of Caco-2 cells to collagens I and IV was dose-dependently reduced by
acetaldehyde
treatment. All these changes, i.e. enhanced cell proliferation rate (by chronic treatment), decreased differentiation, and reduced adhesion to extracellular matrix proteins, would in vivo predict more aggressive and invasive tumour behaviour. The possibility that colonic intraluminal
acetaldehyde
, either ethanol-derived or endogenous, might enhance the development of colorectal tumours should therefore be considered.
...
PMID:Acetaldehyde alters proliferation, differentiation and adhesion properties of human colon adenocarcinoma cell line Caco-2. 985 20
The alc promoter system, derived from the filamentous fungi Aspergillus nidulans, allows chemically regulated gene expression in plants and thereby the study of gene function as well as metabolic and developmental processes. In addition to ethanol, this system can be activated by
acetaldehyde
, described as the physiological inducer in A. nidulans. Here, we show that in contrast to ethanol,
acetaldehyde
allows tissue-specific activation of the alc promoter in transgenic tobacco plants. Soil drenching with aqueous
acetaldehyde
solutions at a concentration of 0.05% (v/v) resulted in the rapid and temporary induction of the alc gene expression system exclusively in roots. In addition, the split root system allows activation to be restricted to the treated part of the root. The temporary activation of the alc system by soil drenching with
acetaldehyde
could be prolonged over several weeks by subsequent applications at intervals of 7 d. This effect was demonstrated for the root-specific induction of a yeast-derived apoplast-located
invertase
under the control of the alcohol-inducible promoter system. In leaves, which exhibit a lower responsiveness to
acetaldehyde
than roots, the alc system was induced in the directly treated tissue only. Thus,
acetaldehyde
can be used as a local inducer of the alc gene expression system in tobacco plants.
...
PMID:Local induction of the alc gene switch in transgenic tobacco plants by acetaldehyde. 1557 32
The constitutive cytosolic expression of a yeast ( Saccharomyces cerevisiae )
invertase
within potato ( Solanum tuberosum ) tubers has previously been documented to produce a dramatic metabolic phenotype in which glycolysis, respiration and amino acid synthesis are markedly enhanced at the cost of starch synthesis. These transgenic lines were further characterised by a massive cycle of sucrose degradation and resynthesis via sucrose-phosphate synthase. We have recently developed a B33 patatin driven alc gene construct allowing tight chemical control of gene expression following supply of
acetaldehyde
with minimal pleiotropic effects of the inducing agent on metabolism. This construct was used for chemical induction of the yeast
invertase
gene after 10-weeks growth to dissect the complex metabolic phenotype obtained after constitute expression. Inducible expression led to increased
invertase
activity within 24 h in well-defined areas within growing tubers. Although the sucrose levels were reduced, there was no effect on the levels of starch whilst levels of many amino acids decreased. Labelling experiments revealed that these lines exhibited increased rates of sucrose cycling, whereas rates of glycolysis and of starch synthesis were not substantially changed. From these results we conclude that sucrose cycling is stimulated in response to a short-term increase in the rate of sucrose mobilisation, providing evidence for a role of sucrose cycling as a buffering capacity that regulates the net rate of sucrose usage. In contrast, the dramatic increase in hexose-phosphate levels and the switch from starch synthesis to respiration seen on the constitutive expression of the
invertase
was not observed in the inducible lines, suggesting that this is the result of cumulative pleiotropic effects that occurred when the transgene was expressed throughout development.
...
PMID:Temporally regulated expression of a yeast invertase in potato tubers allows dissection of the complex metabolic phenotype obtained following its constitutive expression. 1560 30
A "smart" biofuel cell switchable ON and OFF upon application of several chemical signals processed by an enzyme logic network was designed. The biocomputing system performing logic operations on the input signals was composed of four enzymes: alcohol dehydrogenase (ADH), amyloglucosidase (AGS),
invertase
(
INV
) and glucose dehydrogenase (GDH). These enzymes were activated by different combinations of chemical input signals: NADH,
acetaldehyde
, maltose and sucrose. The sequence of biochemical reactions catalyzed by the enzymes models a logic network composed of concatenated AND/OR gates. Upon application of specific "successful" patterns of the chemical input signals, the cascade of biochemical reactions resulted in the formation of gluconic acid, thus producing acidic pH in the solution. This resulted in the activation of a pH-sensitive redox-polymer-modified cathode in the biofuel cell, thus, switching ON the entire cell and dramatically increasing its power output. Application of another chemical signal (urea in the presence of urease) resulted in the return to the initial neutral pH value, when the O(2)-reducing cathode and the entire cell are in the mute state. The reversible activation-inactivation of the biofuel cell was controlled by the enzymatic reactions logically processing a number of chemical input signals applied in different combinations. The studied biofuel cell exemplifies a new kind of bioelectronic device where the bioelectronic function is controlled by a biocomputing system. Such devices will provide a new dimension in bioelectronics and biocomputing benefiting from the integration of both concepts.
...
PMID:Biofuel cell controlled by enzyme logic network--approaching physiologically regulated devices. 1935 82
