TY - JOUR
T1 - Complex formation regulates the glycosylation of the reversibly glycosylated polypeptide
AU - De Pino, Verónica
AU - Borán, Mariela
AU - Norambuena, Lorena
AU - González, Mariela
AU - Reyes, Francisca
AU - Orellana, Ariel
AU - Moreno, Silvia
N1 - Funding Information:
Acknowledgments We thank Susana RaVo and Marta L. Bravo for excellent technical assistance. The Andes-Antorchas Foundations (grant C-13680/3), by the Secyt (grant PICT 01-06986), by the CONICET (grant PIP 6076), by the Fondecyt (grant 1030551) and MNPCB (P02-009-F) supported this work. S.M. is Career Investigator of the CONICET and V.D.P. was supported by CONICET fellowships, Argentina.
PY - 2007/7
Y1 - 2007/7
N2 - Reversible glycosylated polypeptides (RGPs) are highly conserved plant-specific proteins, which can perform self-glycosylation. These proteins have been shown essential in plants yet its precise function remains unknown. In order to understand the function of this self-glycosylating polypeptide, it is important to establish what factors are involved in the regulation of the RGP activity. Here we show that incubation at high ionic strength produced a high self-glycosylation level and a high glycosylation reversibility of RGP from Solanum tuberosum L. In contrast, incubation at low ionic strength led to a low level of glycosylation and a low glycosylation reversibility of RGP. The incubation at low ionic strength favored the formation of high molecular weight RGP-containing forms, whereas incubation at high ionic strength produced active RGP with a molecular weight similar to the one expected for the monomer. Our data also showed that glycosylation of RGP, in its monomeric form, was highly reversible, whereas, a low reversibility of the protein glycosylation was observed when RGP was part of high molecular weight structures. In addition, glycosylation of RGP increased the occurrence of non-monomeric RGP-containing forms, suggesting that glycosylation may favor multimer formation. Finally, our results indicated that RGP from Arabidopsis thaliana and Pisum sativum are associated to golgi membranes, as part of protein complexes. A model for the regulation of the RGP activity and its binding to golgi membranes based on the glycosylation of the protein is proposed where the sugars linked to oligomeric form of RGP in the golgi may be transferred to acceptors involved in polysaccharide biosynthesis.
AB - Reversible glycosylated polypeptides (RGPs) are highly conserved plant-specific proteins, which can perform self-glycosylation. These proteins have been shown essential in plants yet its precise function remains unknown. In order to understand the function of this self-glycosylating polypeptide, it is important to establish what factors are involved in the regulation of the RGP activity. Here we show that incubation at high ionic strength produced a high self-glycosylation level and a high glycosylation reversibility of RGP from Solanum tuberosum L. In contrast, incubation at low ionic strength led to a low level of glycosylation and a low glycosylation reversibility of RGP. The incubation at low ionic strength favored the formation of high molecular weight RGP-containing forms, whereas incubation at high ionic strength produced active RGP with a molecular weight similar to the one expected for the monomer. Our data also showed that glycosylation of RGP, in its monomeric form, was highly reversible, whereas, a low reversibility of the protein glycosylation was observed when RGP was part of high molecular weight structures. In addition, glycosylation of RGP increased the occurrence of non-monomeric RGP-containing forms, suggesting that glycosylation may favor multimer formation. Finally, our results indicated that RGP from Arabidopsis thaliana and Pisum sativum are associated to golgi membranes, as part of protein complexes. A model for the regulation of the RGP activity and its binding to golgi membranes based on the glycosylation of the protein is proposed where the sugars linked to oligomeric form of RGP in the golgi may be transferred to acceptors involved in polysaccharide biosynthesis.
KW - Golgi
KW - Plant polysaccharides
KW - Reversibly glycosylated polypeptide
KW - Self-glycosylation
KW - Xyloglucan
UR - http://www.scopus.com/inward/record.url?scp=34250015859&partnerID=8YFLogxK
U2 - 10.1007/s00425-007-0485-3
DO - 10.1007/s00425-007-0485-3
M3 - Article
C2 - 17333254
AN - SCOPUS:34250015859
SN - 0032-0935
VL - 226
SP - 335
EP - 345
JO - Planta
JF - Planta
IS - 2
ER -