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Query: EC:2.4.99.6 (
sialyltransferase
)
1,546
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The cation-independent mannose 6-phosphate receptor (MPRCI) functions in the packaging of both newly made and extracellular lysosomal enzymes into lysosomes. The subcellular location of MPRCI reflects these two functions; receptor is found in the Golgi complex, in endosomes, and on the cell surface. To learn about the intracellular pathway followed by surface receptor and to study the relationship between the receptor pools, we examined the entry of the surface MPRCI into Golgi compartments that contain
sialyltransferase
. Sialic acid was removed from surface-labeled K562 cultured human
erythroleukemia
cells by neuraminidase treatment. When the cells were returned to culture at 37 degrees C, surface MPRCI was resialylated by the cells with a half-time of 1-2 h. Resialylation was inhibited by reduced temperature, a treatment that allows surface molecules to reach endosomes but blocks further transport. These results indicate that surface MPRCI is transported to the
sialyltransferase
compartment in the Golgi complex. After culture at 37 degrees C, a small fraction (10-20%) of the resialylated receptor was found on the cell surface. Because a similar fraction of the total receptor pool is found on the cell surface, it is likely that cell surface MPRCI mixes with the cellular pool after resialylation. These data also support the idea that extracellular and newly made lysosomal enzymes are transported to lysosomes through a common compartment.
...
PMID:Transport of surface mannose 6-phosphate receptor to the Golgi complex in cultured human cells. 254 Feb
The intracellular movement of cell surface transferrin receptor (TfR) after internalization was studied in K562 cultured human
erythroleukemia
cells. The sialic acid residues of the TfR glycoprotein were used to monitor transport to the Golgi complex, the site of sialyltransferases. Surface-labeled cells were treated with neuraminidase, and readdition of sialic acid residues, monitored by isoelectric focusing of immunoprecipitated TfR, was used to assess the movement of receptor to
sialyltransferase
-containing compartments. Asialo-TfR was resialylated by the cells with a half-time of 2-3 h. Resialylation occurred in an intracellular organelle, since it was inhibited by treatments that allow internalization of surface components but block transfer out of the endosomal compartment. Moreover, roughly half of the resialylated molecules were cleaved when cells were retreated with neuraminidase after culturing, indicating that this fraction of the molecules had returned to the cell surface. These results suggest that TfR is transported from the cell surface to the Golgi complex, the intracellular site of sialyltransferases, and then returns to the cell surface. This pathway, which has not been previously described for a cell surface receptor, may be different from the route followed by TfR in iron uptake, since reported rates of transferrin uptake and release are significantly more rapid than the resialylation of asialo-TfR.
...
PMID:Intracellular movement of cell surface receptors after endocytosis: resialylation of asialo-transferrin receptor in human erythroleukemia cells. 298 85
The recycling of cellular glycoproteins to the site of Golgi mannosidase I, an enzyme of asparagine-linked oligosaccharide synthesis, was studied in K562 human
erythroleukemia
cells. Cells were metabolically labeled in the presence of deoxymannojirimycin, a reversible inhibitor of Golgi mannosidase I. This generates glycoproteins with immature oligosaccharides in their normal locations. Transport to the mannosidase I compartment was then assessed by testing for the conversion of oligosaccharides into mature forms during reculture without deoxymannojirimycin. Transferrin receptor (TfR) was acted on by mannosidase I during reculture, suggesting that it returned to the region of the Golgi complex where this enzyme resides. The slow rate of this transport (t1/2 greater than 6 h) implies that it is probably different than TfR movement during transferrin internalization (t1/2 = 10-20 min) and TfR transport to the
sialyltransferase
compartment in the Golgi complex (t1/2 = 2-3 h) (Snider, M. D., and O. C. Rogers, 1985, J. Cell Biol., 100:826-834). The total cell glycoprotein pool was also transported to the mannosidase I compartment with a half-time of 4 h. Because this transport is 5-10 times faster than the rate of de novo glycoprotein synthesis in these cells, it is likely that most of the glycoprotein traffic through the Golgi complex is composed of recycling molecules.
...
PMID:Membrane traffic in animal cells: cellular glycoproteins return to the site of Golgi mannosidase I. 301 99
Recent reports have suggested that the majority of the molecular traffic through the Golgi apparatus is comprised of recycling, rather than newly synthesized, molecules. To evaluate the importance of this recycling pathway in greater detail, we examined the internalization and recycling of cell surface glycoproteins on EL-4 cells, a murine T-cell lymphoma, using sialic acids as covalent markers. Sialic acids were removed from the surface of living cells by exhaustive treatment with Vibrio cholerae sialidase at 4 degrees C and shown to be derived primarily from glycoproteins (93%), with only a small amount from glycolipids (7%). Cells were recultured at 37 degrees C over time and monitored for the resialylation of the cell surface using a sensitive high pressure liquid chromatography adaptation of the thiobarbituric acid assay for sialic acids. The return of sialic acid to the cell surface was found to be contingent upon de novo protein synthesis indicating that the bulk of plasma membrane sialoglycoconjugates do not recycle to an endogenous
sialyltransferase
-containing compartment for oligosaccharide reprocessing. Identical results were found for K562 cells, a human
erythroleukemia
cell line. The movement of specific glycoproteins was followed using the enzyme rat liver alpha 2-6Gal beta 1-4GlcNAc
sialyltransferase
together with CMP-[3H]NeuAc as an impermeant probe of the cell surface. Surface sialoglycoproteins were internalized slowly, a process unaffected by cycloheximide treatment. Only a few of these internalized glycoproteins were found to return to a trans-Golgi compartment followed by recycling to the cell surface. Taken together, these data indicate that the majority of replacement of sialic acids on the cell surface is due to de novo synthesis of glycoproteins and that only a small number of glycoproteins recycle through a trans-Golgi compartment.
...
PMID:Intracellular trafficking of cell surface sialoglycoconjugates. 318 95
We have previously shown that erythroid differentiation of Friend murine leukemia cells by dimethylsulfoxide results in a decrease in sialic acid content and net negative surface charge. The mechanism responsible for the decrease in sialic acid content was examined by measuring the synthesis of sialic acid from N-acetylmannosamine and its catabolic removal from sialoconjugates during the maturation process. A decrease in the incorporation of N-[3H]acetylmannosamine into sialoglycoconjugates occurred as early as 12 h after exposure to dimethylsulfoxide. Radioactivity incorporated into sialoglycoconjugates was relatively stable in untreated and dimethyl-sulfoxide-treated cells, implying that catabolic removal of sialic acid residues was not a factor in the decreased surface sialic acid content of differentiated
erythroleukemia
cells. In addition, no difference existed between control and treated cells in
sialyltransferase
activity. Significant decreases occurred, however, in the incorporation of radioactivity from N-[3H]acetylmannosamine into N-acetylneuraminic acid, CMP-N-acetylneuraminic acid and a material tentatively identified as N-acetylmannosamine-6-phosphate, 48 h after the addition of dimethylsulfoxide. The decrease in sialic acid biosynthesis in differentiated
erythroleukemia
cells was reflected by an 83% decrease in the amount of radioactively-labeled sialic acid released by neuraminidase treatment of cells exposed to dimethylsulfoxide. These findings are consistent with a cellular aging phenomenon triggered by the polar solvent-induced differentiation of the leukemic cells into more mature forms.
...
PMID:Synthesis of sialoglycoconjugates during dimethylsulfoxide-induced erythrodifferentiation of friend leukemia cells. 705 15
In this paper we report that 3'-azido-3'-deoxythymidine (AZT) treatment of human
erythroleukemia
(K562) cells greatly alters the pattern of protein glycans and significantly modifies beta,(1 --> 4)galactosyltransferase, beta-galactosidase, and alpha,(2 --> 8)
sialyltransferase
activities. In particular, AZT-treated K562 cells exhibited a decreased incorporation of sialic acid (86% of control) into protein glycans, being the reduced alpha,(2 --> 6) incorporation almost of the same magnitude with respect to that of alpha,(2 --> 3) (93 and 90% of control, respectively). Moreover, the drug exposure of cells induced a decrease of both mannose terminally linked and galactose linked as beta,(1 --> 4) (90 and 92% of control, respectively) and a significant increase of galactose beta,(1 --> 3) (112% of control). In addition, beta,(1 --> 4)galactosyltransferase and beta-galactosidase activities were found enhanced in K562-treated cells (30 and 12%, respectively), while alpha,(2-8 )
sialyltransferase
activity decreased (75% of control). Sialyltransferase activities of other types i.e. 30, 60, 3 N, 6 N, did not show any appreciable differences irrespective of AZT-treatment. Besides previous studies which report that AZT exposure of K562 cells, indirectly prevents nucleotide-sugar import into the Golgi complex, with consequent inhibition of glycosylation, our observations show for the first time that AZT affects several enzymatic activities involved in specific glycosylation reactions leading, in turn, to protein glycans alteration.
...
PMID:Protein glycans alteration and a different distribution of some enzymatic activities involved in the glycan processing are found in AZT-treated K562 cells. 1457 75
