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Calcified Tissue International

Erschienen in:

01.01.2005

Effects of Tunicamycin, Mannosamine, and Other Inhibitors of Glycoprotein Processing on Skeletal Alkaline Phosphatase in Human Osteoblast-Like Cells

verfasst von: J.R. Farley, P. Magnusson

Erschienen in: Calcified Tissue International | Ausgabe 1/2005

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Abstract

Skeletal alkaline phosphatase (sALP) is a glycoprotein—~20% carbohydrate by weight, with five presumptive sites for N-linked glycosylation, as well as a carboxy-terminal site for attachment of the glycolipid structure (glycosylphosphatidylinositol, GPI), which anchors sALP to the outer surface of osteoblasts. The current studies were intended to characterize the effects of inhibiting glycosylation and glycosyl-processing on the synthesis, plasma membrane attachment, cellular–extracellular distribution, and reaction kinetics of sALP in human osteosarcoma (SaOS-2) cells. sALP synthesis, glycosylation, and GPI-anchor attachment were assessed as total protein synthesis/immunospecific sALP synthesis, sialic acid content (i.e., wheat germ agglutinin precipitation), and insolubility (i.e., temperature-dependent phase-separation), respectively. sALP reaction kinetics were characterized by analysis of dose-dependent initial velocity data, with a phosphoryl substrate. The results of these studies revealed that the inhibition of either N-linked glycosylation or oligosaccharide synthesis for GPI-anchor addition could affect the synthesis and the distribution of sALP, but not the kinetics of the phosphatase reaction. Tunicamycin—which blocks N-linked glycosylation by inhibiting core oligosaccharide synthesis—decreased cell layer protein and the total amount of sALP in the cells, while increasing the relative level of sALP in the cell-conditioned culture medium (CM, i.e., the amount of sALP released). These effects were attributed to dose- and time-dependent decreases in sALP synthesis and N-linked glycosylation, and an increase in apoptotic cell death (P < 0.001 for each). In contrast to the effects of tunicamycin on N-linked glycosylation, the effects of mannosamine, which inhibits GPI-anchor glycosylation/formation, included (1) an increase in cell layer protein; (2) decreases in sALP specific activity, in the cells and in the CM; and (3) increases in the percentages of both anchorless and wheat germ agglutinin (WGA)-soluble sALP in the medium, but not in the cells (P < 0.005 for each). These effects of mannosamine were, presumably, a consequence of inhibiting the insertion/attachment of sALP to the outside of the plasma membrane surface. Neither mannosammine nor tunicamycin had any effect on the reaction kinetics of sALP or on the apparent affinity (the value of K_M) for the phosphoryl substrate.

The distributions of these circulating sALP isoforms (designated B/I, B1, and B2), which can be separated by use of HPLC [45], vary with age and with changes in skeletal metabolism [45–48]. With respect to glycosylation, the B2 isoform has more sialic acid than either B1 or B/I [22], suggesting that the distribution of the sALP isoforms (i.e., B/I, B1, and B2) may be determined at the level of sialic acid addition to and/or removal from the terminal position(s) of the branched-chain polysaccharides.

Although we cannot dismiss the possibility that the inhibition of N-linked glycosylation decreased the level of sALP by decreasing stability; previous studies of tunicamycin effects on GPI-anchored proteins [28] do not support that conclusion. It is also possible that some aspect of N-linked glycosylation is essential for the proper folding of nascent sALP, such that an inhibition of glycosylation would inhibit sALP activity, but not sALP protein synthesis. Although our immunochemical data indicate that tunicamycin decreased sALP synthesis, we do not know to what extent the ALP-specific polyclonal antibodies were glycosyl epitope-specific.

In the absence of tunicamycin, the N-linked glycosylation of sALP proceeds with the addition of a core polysaccharide unit (i.e., glucose₃- mannose₉-N-acetyl-glucosamine₂)Please verify format to substrate asparagine residues on newly formed sALP, and this would (usually) be followed by the sequential removal of the three glucose residues and one of the nine mannose residues, reflecting the activities of glucosidases I and II and α-mannosidase I, respectively [25]. Further processing, by α-rnannosidase I, would generate the branched-chain mannose-5 N-acetyl-glucosamine-2, structures that serve as the (most common) substrates for the synthesis of more complex N-linked oligosaccharides.

The effects of 1,10-phenanthroline, which had been reported to inhibit GPI-specific glycan synthesis [33], could be abrogated by co-incubation with equimolar Zn, suggesting that the observed effects were actually due to phenanthroline inhibition of sALP activity, by chelating the essential Zn.

Although knockout studies, using mice lacking the PIG-A gene, have shown that GPI anchor formation is essential for fetal development, the specific functions of GPI anchors have not been determined, and, in fact, a variety of functions have been suggested, including increased lateral mobility (i.e., in the plasma membrane); mediation of release or secretion by lipase activity; targeting to apical surfaces; and the regulation of endocytosis/protein turnover, including potocytosis [25].

Our initial efforts to identify (and quantify) the effects of inhibitors of glycosyl processing on sALP molecular weight (i.e., by separation on nondenaturing 3% to 15% gradient polyacrylamide gel electrophoresis) revealed heterogeneity. Although tunicamycin, mannosamine, bromoconduritol, and castanospermine each reduced the average molecular weight of sALP, the enzyme activity was distributed over a range of molecular weight (data not shown). Additional studies, using site-directed mutagenic techniques to replace the amino acid sites for oligosaccharide additions may be required to assess the specific roles of the carbohydrates on sALP, and the actual sizes of each.

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Titel: Effects of Tunicamycin, Mannosamine, and Other Inhibitors of Glycoprotein Processing on Skeletal Alkaline Phosphatase in Human Osteoblast-Like Cells
verfasst von: J.R. Farley
P. Magnusson
Publikationsdatum: 01.01.2005
Verlag: Springer-Verlag
Erschienen in: Calcified Tissue International / Ausgabe 1/2005
Print ISSN: 0171-967X
Elektronische ISSN: 1432-0827
DOI: https://doi.org/10.1007/s00223-004-0023-2

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