EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Epidermal Langerhans cells resemble macrophages/monocytes in several remarkable ways: both bear surface receptors for the Fc portion of immunoglobulin molecules and for the C3b complement component. They take up, process and present antigen to reactive lymphocytes in an extremely effective fashion. They display on their cell surfaces the alloantigenic determinants encoded by genes of the I region of the major histocompatibility complex. Using ATPase activity, Langerhans cell surface densities are abnormal in 3 cutaneous sites which exhibit unique immunologic properties: markedly reduced numbers in hamster cheek pouch; reduced numbers and uneven distributions in murine tail skin; no Langerhans cells occur within corneal epithelium. As a functional expression of the absence of Langerhans cells from murine corneas, allografts prepared from corneal epithelium fail to sensitize recipients to Ia antigens encoded by I region genes of the donor. Corneal grafts disparate from their hosts at only I region loci are accepted for at least 45 days. The absence of Langerhans cells from cornea may account in part for its property as an immunologically privileged tissue. Subthreshold numbers of Langerhans cells in cheek pouch epithelium may contribute significantly to the observations that the hamster cheek pouch is an immunologically privileged site. We infer that skin deficient in Langerhans cells may be consequently deficient in alloantigenicity. Equally important, Langerhans cell-poor skin may be lacking in certain essential functions relating to the induction and expression of immune reactivity.
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PMID:Unusual numbers and distribution of Langerhans cells in skin with unique immunologic properties. 699 73

In experiments carried out in rabbit eyes, UV rays of 254 or 312 nm wavelength damaged the anterior eye segment, whereas those of 365 nm wavelength did not. Two min irradiation with 254 nm UV rays led to a decrease of catalase activity in the corneal epithelium. After 5 min irradiation the catalase activity in the epithelium was not detectable at all. Catalase activity was also diminished in the corneal endothelium and lens epithelium. In this stage the changes were accompanied by decreased activities of Na(+)--K(+)-dependent adenosine triphosphatase, gamma-glutamyl transpeptidase and increased activities of lysosomal enzymes in the corneal and lens epithelium as well as in the corneal endothelium. The transparency of the cornea and lens was decreased. Plasmin activity appeared in the tear fluid. The irradiation with UV rays of 312 nm caused similar disturbances, however, a longer exposure was necessary. In contrast, irradiation with UV rays of 365 nm did not produce any changes. The described corneal disturbances were prevented by dropping of catalase solution on the eye surface during the irradiation or shortly after it. However, after a protracted irradiation aprotinin had to be added to catalase to achieve the healing. The decrease of catalase activity and its prevention by a local application of catalase suggests a key role of oxyradicals in the damage of the eye by UV rays.
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PMID:The damaging effect of UV rays (with the wavelength shorter than 320 nm) on the rabbit anterior eye segment. I. Early changes and their prevention by catalase-aprotinin application. 753 31

Mannitol was introduced into the media of bovine corneal endothelial cells grown in culture. This was accomplished in order to compare its influence on Na,K-ATPase activity with that of high levels of glucose that inhibit the enzyme. The study was conducted with the intent of showing possible adverse osmolar effects on enzyme activity. Mannitol was found to inhibit NA,K-ATPase when compared with mannitol-free medium (11 U vs. 202 U). However, this inhibition was significantly greater than that produced by high levels of glucose. When mannitol was introduced directly into the assay for the plasma membrane-extracted enzyme, the inhibition was as severe (14 U) as for that placed in the culture medium. By way of comparison, glucose introduced into the enzyme assay caused no significant inhibition (189 U). The mannitol concentration used was 20 mM and in the media there was an osmotic pressure of 347 mOsmol/kg. The high glucose concentration was 25 mM and the osmotic pressure in the media was 341 mOsmol/kg. These osmotic pressures were compared with that of the control medium (with 5 mM glucose), which generated a pressure of 308 mOsmol/kg. None of these values were judged sufficiently high to rupture cell plasma membranes or alter cell morphology as seen by vital staining and phase contrast microscopy. In addition, it was found that mannitol had no effect on cellular DNA, whereas a previous study showed that high glucose caused an increased unwinding of duplex DNA. This study suggests that mannitol inhibits endothelial cell Na,K-ATPase by a different mechanism than that of glucose. It further points out that osmotic effects may not be involved with either mechanism.
Cornea 1995 May
PMID:Effects of mannitol on cultured corneal endothelial cell Na,K-ATPase activity. 760 Aug 14

Rabbit cornea (control or infected with herpes virus) was studied at different time periods after the infection. The change of both ultrastructure and topochemistry of lactate dehydrogenase, adenosine triphosphatase, 5'-nucleotidase is found. The alteration of phosphohydrolase ultracytochemistry is probably due to the enzyme mechanisms which are responsible for reproduction of the herpes simplex virus. Further study of herpetic keratitis enzymology will allow better understanding of the pathogenesis and improve the treatment of herpetic keratitis.
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PMID:[Ultrastructural and ultracytochemical analysis of herpes infected cornea]. 798 38

An investigation was made on the possible effects of high levels (450 mg/dl) of glucose on the activities of Na,K-ATPase [E.C. (Enzyme Commission) 3.6.1.37] and Mg-ATPase (E.C. 3.6.1.4) in plasma membrane preparations of bovine corneal endothelial cells grown in tissue culture. The activities of these enzymes were compared with the activities of the same enzymes from cells grown in low or "fasting" levels (90 mg/dl) of glucose. All activities were assayed from cells that were secondary cultures (15-25 days after trypsinization). The results indicated a 76% decrease in activity for Na,K-ATPase (0.04 units in high glucose vs. 0.17 units in low glucose). The activity for Mg-ATPase also decreased by 33% (0.24 units in high glucose vs. 0.36 units in low glucose). A t-test for significance indicated that the loss of activity in both enzymes was highly significant (p < 0.001) in the high glucose media. Assays for ATPase activity of plasma membranes were also made directly in high glucose after removal of the membranes from cells grown in low-glucose media. However, those membrane ATPases showed no significant decrease in activity. Tests for DNA damage of cells grown in the presence of high levels of glucose indicated a 15.5% change (decrease) in the amount of double-stranded DNA remaining after alkali treatment. This change was highly significant also (p < 0.001). These data suggest that the diabetic state may negatively affect membrane-bound ATPases of the corneal endothelium and further point to the possibility of an altered synthetic rate of ATPase polypeptides as a result of DNA damage.
Cornea 1993 Jul
PMID:Alteration of ATPase activity and duplex DNA in corneal cells grown in high glucose media. 839 96

In summary, this review has provided information concerning the application of histochemical and cytochemical procedures used to detail the normal versus pathological cornea and ocular surface. Specifically, histochemical analysis has been used to study protein and peptide degradation in cornea, to analyze stromal non-collagenous and collagenous fibers and associated extracellular matrix. Cytochemistry of the ocular surface has been used to detail the morphology of corneal and conjunctival mucin. Use of small cationic probes as well as lectin-gold binding was advantageous to quantitatively demonstrate that ocular mucin contains sialylated residues and that the number of these residues significantly changes (increases) with age. These data are important in that the degree of sialylation has been shown to correlate with the ability of bacterial organisms to adhere to and infect the immature in contrast to the mature corneal surface. The use of lectin analysis of diseased ocular tissue also has shown that there are specific alterations in glycoconjugates which occur in the diseased versus normal human cornea. Wound healing in cornea is an important problem which has been studied at length using combined histochemical and biochemical approaches. Results support the hypothesis that apical cell surfaces of the leading edge of a migrating sheet differ from those of the normal epithelium. During wound healing, alpha 6 integrin expression by corneal epithelial cells has been demonstrated, but another protein, syndecan was only seen in non-migrating epithelium which had restratified. The association of immunoglobulins with the ocular surface epithelium of the cornea, their change with age and kinetics of appearance also has been demonstrated using a cytochemical approach. Histochemical procedures have been used to localize Class I and Class II molecules in cornea and conjunctiva. Class II antigen expression has been shown to be absent on corneal endothelium, but it can be induced by treatment with IFN-gamma. These data are of importance in corneal pathology such as that resulting in rejection of corneal transplants. Langerhans cells (Class II, Ia positive) also are not found in normal central cornea. They are localized in the peripheral cornea and are stained histochemically by ADPase, ATPase and by specific anti-Ia and other antisera. Increased numbers of LC have been demonstrated in cornea following various stimuli and in diseases of the cornea including both bacterial and viral induced keratitis.
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PMID:Corneal and ocular surface histochemistry. 845 77

Aldose reductase is a rate limiting enzyme in the polyol pathway associated with the conversion of glucose to sorbitol. The enzyme is located in the eye (cornea, retina, lens), kidney, myelin sheath, and also in other tissues less involved in diabetic complications. Experiments in diabetic animals have implicated sorbitol accumulation in the lens to the development of cataracts. The use of inhibitors of aldose reductase in animal studies has demonstrated that diabetic complications such as cataracts, nephropathy, and slowing of nerve conduction can be ameliorated. While an osmotic effect can explain the physical changes in the lens leading to cataract formation, the effect of sorbitol accumulation in other tissues and the resulting diabetic complications has been linked to the depletion of myoinositol content resulting in a derangement of sodium-potassium adenosine triphosphatase activity. Since glucose and other hexoses are poor substrates for aldose reductase, it is only in hyperglycemia when the enzyme hexokinase is saturated that aldose reductase is activated, leading to accumulation of sorbitol. The kinetics of inhibition of aldose reductase by a variety of inhibitors has been delineated. The dose required varies from inhibitor to inhibitor and is consistent with their inhibition constants. Toxicity is a consideration in the use of some of the inhibitors, as was demonstrated with sorbinil which caused hypersensitivity reactions in 10 percent of patients. Other inhibitors such as tolerant have shown efficacy and are under clinical investigation. Interpretation of results obtained with aldose reductase inhibitor therapy in human subjects suggest that these inhibitors are effective at early stages of diabetic complications.
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PMID:Aldose reductase and its inhibition in the control of diabetic complications. 845 42

The effect of melittin on electrophysiological parameters of the bullfrog cornea was studied using an in vitro preparation. Epithelial cells of corneas were impaled with microelectrodes. Experiments were done under short-circuit current (Isc) conditions. Melittin was added in concentrations of 10(-5)M to the stromal or 10(-6)M to the tear solution. The effects of melittin were as follows: (i) stromal side, a decrease in Isc; an increase in the apical membrane fractional resistance, fRo; no change in the transepithelial conductance, gt; and a depolarization of the intracellular potential, Vo; (ii) tear side, an initial (first 10 min) increase and then a decrease in Isc; a decrease in fRo; an initial (first 10 min) increase with subsequent small decrease in gt; and a depolarization of Vo. Changes in tear Na+, but not in tear K+, with melittin present in tear solution, induced changes in some electrical parameters. The effects on the tear side may be explained by opening of nonspecific channels in the apical membrane with some specificity for Na+ channel. The subsequent effects on the tear and the effects on the stromal side may be explained by an inhibition of the primary transport system, that is, of the Na+/K+ -ATPase pump located in the basolateral membrane. In these experiments, there was no evidence of opening of channels in the basolateral membrane.
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PMID:Effect of melittin on electrophysiological parameters in the frog cornea epithelium. 859 29

Extensive work with melittin has shown that the venom has multiple effects, probably, as a result of its interaction with negatively changed phospholipids. It inhibits well known transport pumps such as the Na(+)-K(+)-ATPase and the H(+)-K(+)-ATPase. Melittin increases the permeability of cell membranes to ions, particularly Na+ and indirectly Ca2+, because of the Na(+)-Ca(2+)-exchange. This effect results in marked morphological and functional changes, particularly in excitable tissues such as cardiac myocytes. In some other tissues, e.g., cornea, not only Na+ but Cl- permeability is also increased by melittin. Similar effects to melittin on H(+)-K(+)-ATPase have been found with the synthetic amphipathic polypeptide Trp-3.
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PMID:Effect of melittin on ion transport across cell membranes. 1007 85

Effect of Hirudo therapy on the activities of transport adenosine triphosphatases (ATPases) of the retina and pigmented epithelium (PE) is studied in normal and albino rabbits whose eyes were exposed to potent illumination (100,000 Lux at the level of the cornea for 90 min). The exposure decreased the activities of ATPase, which did not recover in any of animal groups. Hirudo therapy immediately after illumination increased the enzymes activity in pigmented animals in comparison with intact control: by 20% in the retina and by 23% in PE; Mg-ATPase activity increased by 23% in the retina and decreased by 10% in PE. In subsequent 24 h, ATPase activities decreased, but in comparison with exposed retina the activity of Na,K-ATPase in the retina was 70% increased and in PE 78% increased; the activities of Mg-ATPase were increased by 33 and 8%, respectively. Complete recovery of ATPase activities was attained in 8 days. In albino animals, ATPase activities did not recover completely, but they were notably higher than in intact controls. Hirudo therapy before illumination had a marked protective effect.
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PMID:[The effect of Hirudo therapy on a change in the activity of retinal transport adenosinetriphosphatases in the rabbit with photic eye damage]. 1043 50

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