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Query: EC:2.4.99.7 (
sialyltransferase
)
1,534
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Chloride channels were previously purified from bovine kidney cortex membranes using a drug affinity column. Reconstitution of the purified proteins into artificial liposomes and planar bilayers yielded chloride channels. A 64 x 10(3) M(r) protein, p64, identified as a component of this chloride channel, was used to generate antibodies which depleted solubilized kidney membranes of all chloride channel activity. This antibody has now been used to identify a clone, H2B, from a kidney cDNA library. Antibodies, affinity-purified against the fusion protein of H2B, from a kidney cDNA library. Antibodies, affinity-purified against the fusion protein of H2B, also depleted solubilized kidney cortex from all chloride channel activity. The predicted amino acid sequence of p64 shows that it contains two and possibly four putative transmembrane domains and potential phosphorylation sites by protein kinases A and C. There was no significant homology to other protein (or DNA) sequences in the data base including other anion channels or the
cystic fibrosis transmembrane conductance regulator
. The protein is expressed in all cells tested and probably represents the chloride channel of intracellular organelles. Cystic fibrosis (CF) is associated with a defect in a cyclic-AMP-activated chloride channel in secretory epithelia which leads to decreased fluid secretion. In addition, many mucus glycoproteins show decreased sialylation but increased sulfation. We have recently shown that the pH of intracellular organelles is more alkaline in CF cells, an abnormality that is due to defective chloride conductance in the vesicle membranes. We postulate that the defect in the intracellular chloride channel, and hence the alkalization, could explain the glycosylation abnormalities since the pH optimum of Golgi
sialyltransferase
is acid while that of focusyl- and sulfotransferases is alkaline. Defects in sialyation of glycolipids might also generate receptors for Pseudomonas, which is known to colonize the respiratory tract of CF patients.
...
PMID:Chloride channels of intracellular organelles and their potential role in cystic fibrosis. 133 94
Work addressing whether
cystic fibrosis transmembrane conductance regulator
(
CFTR
) plays a role in regulating organelle pH has remained inconclusive. We engineered a pH-sensitive excitation ratiometric green fluorescent protein (pHERP) and targeted it to the Golgi with
sialyltransferase
(ST). As determined by ratiometric imaging of cells expressing ST-pHERP, Golgi pH (pH(G)) of HeLa cells was 6.4, while pH(G) of mutant (DeltaF508) and wild-type
CFTR
-expressing (WT-CFTR) respiratory epithelia were 6.7-7.0. Comparison of genetically matched DeltaF508 and WT-
CFTR
cells showed that the absence of
CFTR
statistically increased Golgi acidity by 0.2 pH units, though this small difference was unlikely to be physiologically important. Golgi pH was maintained by a H(+) vacuolar (V)-ATPase countered by a H(+) leak, which was unaffected by
CFTR
. To estimate Golgi proton permeability (P(H(+))), we modeled transient changes in pH(G) induced by inhibiting the V-ATPase and by acidifying the cytosol. This analysis required knowing Golgi buffer capacity, which was pH dependent. Our in vivo estimate is that Golgi P(H(+)) = 7.5 x 10(-4) cm/s when pH(G) = 6.5, and surprisingly, P(H(+)) decreased as pH(G) decreased.
...
PMID:Proton leak and CFTR in regulation of Golgi pH in respiratory epithelial cells. 1150 68
This paper reviews experiments from this lab that have tested the hypothesis that pH of the Golgi (pH(G)) of cystic fibrosis (CF) airway epithelial cells is alkaline compared to normal, that this altered pH affects
sialyltransferase
and other Golgi enzymes controlling biochemical composition of the plasma membrane and that altered surface biochemistry increases bacterial binding. We generated a plasmid encoding a modified green fluorescence protein-
sialyltransferase
(GFP-ST) chimera protein that was pH-sensitive and localized to the Golgi when transfected into HeLa cells and also CF and normal or
cystic fibrosis transmembrane conductance regulator
- (CFTR)-corrected airway epithelial cells. Digital imaging microscopy of these Golgi-localized probes showed that there was no correlation between pH(G) (6.4-7.0) and the presence of CFTR, whether cells were in HCO(3)(-)/CO(2)-containing or in HCO(3)(-)/CO(2)-free solutions. Activation of CFTR by raising cell [cAMP] had no effect on pH(G). Thus, CFTR seemed not to be involved in controlling pH(G). Experiments on HeLa cells using an avidin-
sialyltransferase
chimera in combination with a pH-sensitive fluorescent biotin indicated that even in cells that do not express CFTR, Cl(-) and K(+) conductances of the Golgi and other organelle membranes were large and that pH(G) was controlled solely by the H(+) v-ATPase countered by a H(+) leak. A mathematical model was applied to these and other published data to calculate passive H(+) permeability (P(H+)) of the Golgi, endoplasmic reticulum, trans-Golgi network, recycling endosomes and secrety granules from a variety of cells. An organelle's acidity was inversely correlated to its calculated P(H+). We conclude that the CFTR plays a minor role in organelle pH regulation because other (Cl(-) and K(+)) channels are present in sufficient numbers to shunt voltages generated during H(+) pumping. Acidity of the Golgi (and perhaps other organelles) appears to be determined by the activity of H(+) pumps countered by H(+) leaks.
...
PMID:Cystic fibrosis transmembrane conductance regulator and H+ permeability in regulation of Golgi pH. 1187 64
