Glycosylation in type I collagen occurs as O-linked galactosyl-
(G-) lesser and glucosylgalactosyl-hydroxylysine (GG-Hyl); however,
its biological significance is still not well understood. To investigate
the function of this modification in bone, we have generated preosteoblast
MC3T3-E1 (MC)-derived clones, short hairpin (Sh) clones, in which Glt25d1 gene expression was stably suppressed. In Sh clones,
the GLT25D1 protein levels were markedly diminished in comparison
to controls (MC and those transfected with the empty vector). In Sh
collagen, levels of both G- and GG-Hyl were significantly diminished
with a concomitant increase in the level of free-Hyl. In addition,
the level of immature divalent cross-links significantly diminished
while the level of the mature trivalent cross-link increased. As determined
by mass spectrometric analysis, seven glycosylation sites were identified
in type I collagen and the most predominant site was at the helical
cross-linking site, α1–87. At all of the glycosylation
sites, the relative levels of G- and GG-Hyl were markedly diminished,
i.e., by ∼50–75%, in Sh collagen, and at five of these
sites, the level of Lys hydroxylation was significantly increased.
The collagen fibrils in Sh clones were larger, and mineralization
was impaired. These results indicate that GLT25D1 catalyzes galactosylation
of Hyl throughout the type I collagen molecule and that this modification
may regulate maturation of collagen cross-linking, fibrillogenesis,
and mineralization.