Contiguous hydroxyproline residues direct hydroxyproline arabinosylation in Nicotiana tabacum.

Hydroxyproline (Hyp) O-glycosylation characterizes the hydroxyproline-rich glycoprotein (HRGP) superfamily of the plant extracellular matrix. Hyp glycosylation occurs in two modes: Arabinosylation adds short oligoarabinosides (Hyp-arabinosides) while galactosylation leads to the addition of larger arabinogalactan polysaccharides (Hyp-polysaccharides). We hypothesize that sequence-dependent glycosylation of small peptide motifs results in glycomodules. These small functional units in combination with other repetitive peptide modules define the properties of HRGPs. The Hyp contiguity hypothesis predicts arabinosylation of contiguous Hyp residues and galactosylation of clustered noncontiguous Hyp residues. To determine the minimum level of Hyp contiguity that directs arabinosylation, we designed a series of synthetic genes encoding repetitive (Ser-Pro(2))(n), (Ser-Pro(3))(n), and (Ser-Pro(4))(n). A signal sequence targeted these endogenous substrates to the endoplasmic reticulum/Golgi for post-translational proline hydroxylation and glycosylation in transformed Nicotiana tabacum cells. The fusion glycoproteins also contained green fluorescence protein, facilitating their detection and isolation. The (Ser-Pro(2))(n) and (Ser-Hyp(4))(n) fusion glycoproteins yielded Hyp-arabinosides but no Hyp-polysaccharide. The motif (Ser-Pro(3))(n) was incompletely hydroxylated, yielding mixed contiguous/noncontiguous Hyp and a corresponding mixture of Hyp-arabinosides and Hyp-polysaccharides. These results plus circular dichroic spectra of the glycosylated and deglycosylated (Ser-Pro(2))(n), (Ser-Pro(3))(n), and (Ser-Pro(4))(n) modules corroborate the Hyp contiguity hypothesis and indicate that Hyp O-glycosylation is indeed sequence-driven.