Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
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 terms competition and competitive were in use for appropriate types of interaction in human and animal behaviour from the seventeenth century. In the nineteenth and early twentieth centuries they reached more technical uses in biology, especially in darwinian studies; and in chemistry in describing competing reactions, surface phenomena and the influence of substituent groupings in reactant molecules. Use of competitive and non-competitive to describe enzyme inhibitors had a specific beginning when J. B. S. Haldane (following premonitory work of others) applied the terms in 1927 and 1930 to types of inhibition already differentiated by Michaelis and co-workers. The theoretical background in kinetics and stereochemistry so acquired gave a firmness to the application of the terms in biochemistry. The first examples concerned glycosidases, especially beta-D-fructofuranosidase or
invertase
, and interactions of carbon monoxide and oxygen at
iron
-porphyrin systems. They were thus of interest in toxicology and in enzyme and carrier studies. The sphere of application of the biochemically-defined terms expanded greatly when, following investigation of sulphonamide action, it was realized that concepts of enzyme inhibition by structurally related compounds offered a route to understanding the action of existing medicaments and to the production of new ones. Ideas and terminology based on competitive and non-competitive enzyme inhibition and receptor occupancy have subsequently been applied in many ways. Examples include application to the analysis of feedback inhibition and other processes of metabolic control; to receptor relationships among neurotransmitters and medicaments; and to understanding interactions at sensory receptors.
...
PMID:The origin and use of the terms competitive and non-competitive in interactions among chemical substances in biological systems. 303 Jul 38
We studied the activity and kinetic parameters of microvillous enzymes in intestinal villous cells and the concentration of the secretory component (SC) of p-immunoglobulin A in subcellular fractions of crypt cells in 35-day-old rats made
iron
deficient from birth and in controls. The aim of the study is to investigate the biochemical basis for the decreased activity of brush-border disaccharidases observed in growing animals with chronic iron deficiency. In rats made
iron
deficient, the specific (per unit protein) and the total (per total intestinal length) activities of
sucrase
, lactase, maltase, aminopeptidase, and diamine oxidase were decreased from -17 to -66% compared with the activities measured in the controls. The lower activity of
sucrase
in the brush-border membrane of the
iron
-deficient rats was associated with much slower enzyme synthesis rate than in control animals. Km of
sucrase
was identical in both
iron
-deficient rats and controls, but the maximum velocity of enzyme reaction was reduced proportionally to the enzymatic activity, indicating a lesser amount of enzyme rather than an inactivation. Electron microscopy of epithelial villous cells from
iron
-deficient rats revealed a marked rarefaction of secretory granules (transport vesicles) without apparent change in the morphology of the brush-border membrane or of cellular organelles. In villus and crypt cells isolated from the jejunum of
iron
-deficient rats, SC concentration was reduced to a level about half that of the controls. When SC concentration was measured in subcellular fractions of crypt cells, SC content in each fraction was two to three times lower in
iron
-deprived rats than in controls without evidence of accumulation of the protein at a given subcellular level.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Alteration of intracellular synthesis of surface membrane glycoproteins in small intestine of iron-deficient rats. 378 40
Parenchymal cells isolated from rat liver are capable of taking up free hemoglobin. Uptake was saturable with a concentration for half-maximal velocity of 1.35 mg/ml (1.99 X 10(-5) M) hemoglobin. At a concentration of 0.088 mg/ml, the endocytic index for hemoglobin uptake was 4.5 microliters/h per mg of cell protein. This may be compared with the rate of fluid pinocytosis by these cells of 0.025 microliter/h per mg of cell protein (determined with yeast
invertase
as the marker). Free beta globin chains were also taken up with an endocytic index of 26.7 microliters/h per mg of cell protein at a beta chain concentration of 0.075 mg/ml. Hemoglobin inhibited the uptake of labeled beta globin. Hemoglobin-haptoglobin complex at a concentration of 0.12 mg/ml (as hemoglobin) was cleared at a rate of 0.89 microliter/h per mg cell protein and its uptake was also inhibited by free hemoglobin. We conclude that haptoglobin serves to conserve the
iron
of hemoglobin by preventing its renal clearance and not by promoting its hepatic uptake.
...
PMID:Uptake of free hemoglobin by rat liver parenchymal cells. 648 98
The weanling process is characterized by the transition from a liquid diet poor in
iron
(rat milk) to a solid diet high in
iron
(chow pellets). To examine the effects of
iron
content of the weanling diet on terminal maturation of rat small intestine, suckling pups, nursed by
iron
-sufficient mothers, were weaned by day 16 onto a solid basal diet that was either deficient [low-
iron
diet (LID): 0.5 mg
iron
/100 g solid] or high [high-
iron
diet (HID) controls: 30 mg
iron
/100 g solid] in
iron
. The animals were studied during or at the end of the 4th postnatal wk. By day 17 rats weaned onto the LID exhibited an initial rise in jejunal
sucrase
activity as did their controls, but the activity plateau of the enzyme was reduced to a level 60% of the controls. On day 28
iron
-deprived rats were anemic and showed significant decreases (P less than 0.01 compared with HID rats) in the activity of jejunal
sucrase
(-57%), neutral lactase (-83%), and maltase (-46%), whereas villus height, crypt depth, mucosal mass parameters, ileal acid beta-galactosidase activity, mucosal protein, and DNA synthesis rates were equivalent in LID and HID groups. The concentration of the secretory component, a glycoprotein synthesized by the intestinal crypt cell, was markedly depressed (P less than 0.01 vs. controls) in the jejunum (-54%) and ileum (-79%) of
iron
-deprived rats. When D-[1-14C]glucosamine was injected intraperitoneally, incorporation of the label into jejunal and ileal brush-border proteins was two to three times lower for
iron
-deficient rats than for controls.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Role of dietary iron in maturation of rat small intestine at weaning. 674 22
Newborn rats born to
iron
deficient mothers (IDM) were found to have significantly lower hemoglobin,
sucrase
, lactase and maltase levels compared to control newborn rats. Rats born to IDM and nursed by IDM, when sacrificed at 21 days of age, had statistically significantly lower hemoglobin, serum
iron
,
sucrase
, lactase and maltase levels compared to control rats. Rats born to IDM, but nursed by
iron
sufficient mothers (ISM) and sacrificed at 21 days of age, had hemoglobin, serum
iron
and
sucrase
levels compared to control rats whereas lactase and maltase were not corrected by 21 days of nursing by ISM. Rats burn to IDM and nursed by either IDM or ISM for 21 days were given intramuscular
iron
dextran and placed on
iron
sufficient diet (ISD) for 7 days. These animals experienced correction of the hemoglobin, serum
iron
,
sucrase
and maltase levels compared to control rats, whereas intestinal lactase was not corrected by 7 days of ISD and intramuscular
iron
. Rats born to ISM, nursed by IDM and sacrificed on day 21 had significantly lower hemoglobin, serum
iron
and intestinal lactase levels compared to control rats. Rats both to ISM and nursed by IDM were given intramuscular
iron
dextran on day 21 and placed on an ISD from day 21-28. These animals had a return in hemoglobin, serum
iron
,
sucrase
and maltase levels comparable to control rats. Rats born to and nursed by ISM and maintained on an
iron
deficient diet from day 21-84 had significantly lower hemoglobin, serum
iron
,
sucrase
, lactase and maltase levels compared to control rats. Rats born to and nursed by ISM, maintained on
iron
deficient diet from day 21-84, and then given intramuscular
iron
dextran on day 84 and maintained on an ISD until day 92, experienced correction of the hemoglobin, serum
iron
and lactase levels compared to control rats. Intramuscular
iron
and 7 days of ISD did not correct the
sucrase
and maltase levels in these rats. Lactose tolerance tests in
iron
deficient rats showed flat curves compared to controls. After
iron
treatment, lactose tolerance curves returned to control values. Iron deficiency in rats in utero, during the nursing and postweaning period causes, in addition to anemia, a reduction in jejunal disaccharidase activity because of an alteration in the enzymes of the brush border membrane. Varying degrees of reduction and response of certain disaccharidases to
iron
treatment are dependent on the time of
iron
deprivation in relationship to the intra-uterine and postnatal development of the digestive and absorptive functions in the small intestine. Alterations in the levels of disaccharidases demonstrated in this paper represents another aspect of the spectrum of biochemical effects of iron deficiency.
...
PMID:Disaccharidase levels in iron deficient rats at birth and during the nursing and postweaning periods: response to iron treatment. 707 2
Duodenal mucosa showed normal morphology, interepithelial lymphocytes, alkaline phosphatase, and
sucrase
in a girl with growth retardation and iron deficiency, but normal absorption of lactose and xylose after two years of abnormal stools. Mucosal lactase was low. Fourteen months later mucosal damage consistent with coeliac disease was evident, and gluten intolerance was subsequently confirmed by gluten challenge. It is probable that, in some children, the mucosal lesion occurs very gradually, so that at an early stage with normal morphology, suppression of lactase activity and possibly interference with
iron
absorption may be the only abnormalities.
...
PMID:Early or pre-coeliac mucosa: development of gluten enteropathy. 746 78
Recent studies have indicated that lactoferrin may act as a cell mitogen. The effect of human and bovine lactoferrins on the proliferation and differentiation of a human intestinal epithelial cell line (Caco-2) was investigated and compared with that of human transferrin. Caco-2 cells were cultured in serum-free media supplemented with both
iron
-unsaturated and -saturated forms of the
iron
-binding proteins. Cell proliferation and differentiation were evaluated by examining growth curves and measuring
sucrase
and alkaline phosphatase activities of brush border membrane fractions, respectively. The
iron
-binding status of lactoferrins and transferrin affected the proliferation of Caco-2 cells. The
iron
-saturated forms of human (S-hLf), bovine (S-bLf) lactoferrins and human transferrin (S-hTf) enhanced cell proliferation, while
iron
-unsaturated forms (U-hLf, U-bLf, and U-hTf) suppressed it.
Iron
-binding status also determined the effect of lactoferrin and transferrin on cellular differentiation, but this effect differed for different brush border enzymes. S-hTf enhanced
sucrase
activity more than S-hLF or S-bLf. Both U-hLf and U-bLf markedly suppressed
sucrase
activity. U-hTf suppressed alkaline phosphatase activity appreciably, while the other
iron
-binding proteins showed no significant effect on it. Lactoferrin and transferrin may modulate the proliferation and differentiation of intestinal epithelial cells, but their efficacy depends on their saturation with
iron
.
...
PMID:Iron saturation alters the effect of lactoferrin on the proliferation and differentiation of human enterocytes (Caco-2 cells). 766 12
Transcription of the three unlinked, homologous STA1-3 glucoamylase-encoding genes, involved in starch degradation by Saccharomyces cerevisiae, was previously shown to be down-regulated by the presence of STA10, acting via three upstream repression sequence regions that were identified in the STA2 promoter. Here we report the cloning and characterization of a putative transcriptional activator gene, MSS10 (multicopy suppressor of STA10), which, when present in multiple copies, overcomes STA10 repression. Deletion of MSS10, located on chromosome XV, resulted in media-specific extinction of glucoamylase synthesis. The nucleotide sequence of MSS10 is identical to three other genes from S. cerevisiae identified as: FUP1, a gene that enhances
iron
-limited growth; PHD2, a gene identified for its ability to induce pseudohyphal growth in diploid cells grown on nitrogen-limited media; and MSN1, a gene encoding a transcriptional activator involved in
invertase
regulation.
...
PMID:A multicopy suppressor gene, MSS10, restores STA2 expression in Saccharomyces cerevisiae strains containing the STA10 repressor gene. 866 91
The intestinal mucosa is characterized by cell proliferation, commitment, differentiation, digestion and absorption. These processes occur at specified locations along the crypt to villus axis. A technique is reported for the isolation of cells along this axis which allows the study of any one of these processes in an enriched population of cells. As an example, the uptake of transferrin-bound
iron
by enterocytes was studied. Rats were fed diets normal, high (30% carbonyl
iron
) or low in
iron
for 12 days. Cells from either the duodenum or ileum were isolated by incubating in a Ca(2+)-, Mg2+-free, cation chelating solution for varying periods. The incorporation of thymidine into DNA was measured in these cells as a marker of the crypt region, while alkaline phosphatase and
sucrase
activities marked mature enterocytes. The in vivo uptake of transferrin-bound 59Fe was measured in cells isolated either 2 or 4 h after intravenous injection. This procedure resulted in the isolation of 10 fractions of viable cells. Earlier fractions were enriched at least 10-fold in villus cells and the last fractions in crypt cells. Cells in intermediate fractions were at various stages of development. Uptake of transferrin-bound
iron
into enterocytes was highest with feeding an
iron
-loaded diet compared with control or
iron
-deficient diets. However, with all diets uptake was highest in crypt cells and this fell at the crypt-villus junction to be only 25%, as high at the villus tip as the crypt. A technique for the reproducible isolation of viable enterocytes along a crypt-villus axis is described. Transferrin receptor activity changes with maturation of the enterocyte.
...
PMID:Characterization of isolated duodenal epithelial cells along a crypt-villus axis in rats fed diets with different iron content. 950 94
The aim of the present study was to investigate whether the brush border membrane ferric reductase activity of Caco-2 cells is modulated during cell differentiation. The ferric reductase activity was determined in whole cells and isolated microvillous membranes at different stages of cell differentiation by measuring the amount of Fe3+ reduced during the incubation time. Our results indicated that the ferric reductase activity decreased in fastly growing cells and reactivated in postconfluent cells in contrast to the alkaline phosphatase and
sucrase
activities which were progressively expressed during differentiation as conventional indicators of cell maturity. The lowest ferric reductase activity was found in cells at the log phase of proliferation, while freshly seeded or highly differentiated cells had significantly higher enzyme activities. Cells grown under serum-free conditions had similar ferric
iron
reduction rates as cells propagated under standard conditions. Reagents or hormones affecting cell metabolism through different pathways had no significant effect on this transplasma membrane redox system.
...
PMID:The plasma membrane Fe(3+)-reductase activity of Caco-2 cells is modulated during differentiation. 986 49
1
2
3
Next >>
