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Query: EC:3.5.1.52 (
PNGase F
)
1,527
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Two variant sublines of murine L1210 leukemia cells (L1210A and L1210JF) overexpress the cell surface
folate receptor
(FR). The membrane bound FR in L1210A cells exhibited significantly (up to 17-fold) greater relative affinities for (6S)-N5-methyltetrahydrofolate, (6S)-N5-formyltetrahydrofolate and methotrexate compared to the FR in L1210JF cells. Furthermore, receptor-mediated transport of [3H]-(6S)-N5-methyltetrahydrofolate was much more efficient in L1210A cells compared to L1210JF cells. When solubilized with Triton X-100, the ligand binding characteristics of FR from both sublines resembled those of the receptor associated with L1210 JF cell membranes. N-terminal amino acid sequence analysis as well as RT-PCR analysis of the entire coding region revealed a single species of FR in both cells, identical to murine FR-alpha. The FR in L1210JF cells was sensitive to phosphatidylinositol specific phospholipase C (PI-PLC) indicating the presence of a glycosyl-phosphatidylinositol (GPI) membrane anchor while the FR in L1210A cells was resistant to PI-PLC; however, the FR in L1210A cells was released from plasma membranes by nitrous acid, as expected for GPI and its PI-PLC resistant structural variants. Treatment of L1210A cell membranes with mild base rendered the protein PI-PLC sensitive as expected for GPI anchors acylated in the inositol ring and also decreased the affinities of the membrane associated FR for reduced folates. When the cDNA for murine FR-alpha was expressed in parental L1210 cells the protein was PI-PLC resistant but was sensitive to PI-PLC when the cDNA was expressed in human 293 fibroblasts. In L1210JF, L1210A, and parental L1210 cells, several cell surface proteins, including FR, incorporated [3H]ethanolamine, a component of the GPI membrane anchor; however, the labeled proteins were released by PI-PLC only in L1210JF cells. The above results preclude any peculiarity of the FR polypeptide in either L1210 subline as the basis for the observed differences in PI-PLC sensitivity and membrane-associated functions of FR. Partial deglycosylation of membrane associated FR from either cell with
N-glycanase
did not influence its ligand binding characteristics. The results of this study lead to the hypothesis that variant GPI structures may modulate the function of a protein by influencing its conformation/topography in the membrane. Such effects may be identified by their disappearance/reduction upon detergent solubilization or mild base treatment of the membrane.
...
PMID:Variant GPI structure in relation to membrane-associated functions of a murine folate receptor. 897 5
Variable amounts of soluble forms of a variety of glycosyl-phosphatidylinositol (GPI)-anchored proteins occur extracellularly, but the molecular mechanisms governing their release are not entirely clear. When the GPI-anchored
folate receptor
(FR) type beta was expressed transiently in human 293 fibroblasts, there was a roughly equal distribution of [3H]folic acid binding protein between the cell surface and the medium after 24 h over a wide range of expression levels of FR-beta. The difference in apparent molecular masses between the soluble FR-beta and the PI-PLC-treated membrane protein indicated that the former was not released from the membrane by the action of phospholipase. Brefeldin A inhibited the release of soluble FR-beta from both the transfected 293 cells and stable recombinant CHO (CHO-FR-beta) cells while pre-existing levels of cell surface FR were unaltered suggesting the absence of a precursor-product relationship between the membrane-associated FR-beta and the soluble protein in the medium. [35S]Cysteine pulse-chase analysis was consistent with this finding. Interchanging of carboxyl-terminal peptides between FR-beta and FR-alpha revealed that the nature of the processed signal for GPI modification was responsible for the quantitative membrane anchoring of FR-alpha and the production of soluble FR-beta. When total cell lysates were analyzed by Western blot, a diffuse band of apparent 41 kDa and three additional sharp bands of apparent 35, 33, and 29.3 kDa were seen. The 41 kDa band was identified as the PI-PLC sensitive cell surface receptor. Several mutant constructs of FR-beta, in which the carboxyl-terminal signal for GPI modification was either disrupted or deleted only gave the three lower bands. The three sharp bands from the wild-type and the mutant forms of FR-beta were identified as nonglycosylated (29.3 kDa) or glycosylated polypeptides in which the carboxyl-terminal peptide was at least partially proteolyzed without GPI modification. All of the mutations in the GPI signal resulted in the recovery of [3H]folic acid binding protein in the media which, similar to the wild-type FR recovered from the media, were converted to the 29.3 kDa band by
N-glycanase
. The results from this study indicate that a carboxyl-terminal peptide in FR-beta is efficiently proteolyzed intracellularly by a pathway that is independent of GPI signal recognition resulting in proper protein folding and secretion. Such carboxyl-terminal sequences could represent a simple adaptation for proteins whose physiologic functions reside both at the cell surface and in extracellular fluids, allowing their selective and tissue-specific release.
...
PMID:Proteolysis of the carboxyl-terminal GPI signal independent of GPI modification as a mechanism for selective protein secretion. 939 77
In a previous study with inhibitors of N-glycosylation, it was proposed that core glycosylation of the
folate receptor
(FR) is required for the proper folding of the protein [Luhrs (1991) Blood 77, 1171-1180]. The human FR isoforms type alpha and type beta have three and two candidate sites for N-glycosylation respectively, only one of which is conserved. The significance of N-glycosylation at each of these loci in the expression and function of FR was examined by eliminating the sites both individually and in combination by introducing Asn-->Gln substitutions. Translation experiments in vitro showed that the mutations did not alter the synthetic rates of the polypeptides. The recombinant proteins were expressed in human 293 fibroblasts. Treatment with
N-glycanase
and analysis by Western blotting of the wild-type and mutant proteins revealed that all of the candidate sites in both FR-alpha and FR-beta are glycosylated. When all of the N-glycosylation sites were abolished, 2% and 8% of FR-alpha and FR-beta respectively were expressed on the cell surface compared with the corresponding wild-type proteins; the residual FR polypeptides in the cell lysates were unable to bind [3H]folic acid. In both the proteins, the inclusion of each additional N-glycosylation site partly contributed to restoration of cell surface [3H]folic acid binding and receptor-mediated folate transport. Further, in FR-beta the introduction of an additional unnatural site of N-glycosylation resulted in the enhancement of the expression of the cell surface receptor compared with the wild-type protein. The results indicate that the total mass of N-glycosylation, not a specific locus of the modification, is critical for the efficient folding and optimal expression of functional FR-alpha and FR-beta.
...
PMID:Expression levels of functional folate receptors alpha and beta are related to the number of N-glycosylated sites. 958 53
