Isolation of a Brassica napus L. cDNA encoding a putative high-mobility-group HMG I/Y protein.

A cDNA encoding a high-mobility-group protein has been isolated from a microspore-specific library of Brassica napus. The 930 bp cDNA contains a 612 bp open reading frame encoding a protein of 203 amino acids residues exhibiting significant homology to HMG-I/Y protein from Arabidopsis thaliana (62%). The predicted protein contains four copies of the 'AT-hook' motif which is involved in binding A/T-rich DNA. Southern blotting indicates that the HMG-I/Y gene is a single-copy gene in B. napus. Transcription of the HMG-I/Y gene was detected in all tissues examined, with the highest expression in pollen-derived embryos. In situ localization studies of flower organs indicate the transcript to be preferentially located in petals and sepals. Subcellular localization analysis performed during pollen development showed that the transcript of the HMG-I/Y gene is predominantly associated with polysomes.

Role of N-glycosylation of 66 and 69 kDa glycoproteins in wall formation during pollen tube growth in vitro.

Two abundant cell wall glycoproteins (66 and 69 kDa) accumulate during growth in pollen tubes of tobacco. Glycosylation of the proteins was experimentally modified by application of the specific inhibitors tunicamycin and castanospermine to in vitro cultured pollen. Newly synthesized proteins were labeled with a 14C-amino acid mixture supplied to the medium. Modified glycoproteins were extracted from pollen tubes and isolated cell walls, and separated by 1-D and 2-D electrophoresis. The size of the molecules was reduced by tunicamycin and increased by castanospermine, effects which were measurable from the beginning of cultivation. The modification of the glycan moiety did not affect deposition of the proteins in the wall. Cultivation in the continuous presence of either inhibitor led to reduced callose deposition in the secondary cell wall and to inhibition of pollen tube growth. The results suggest that the two proteins play a role in the formation of the callose wall, and that this function depends on proper glycosylation of the molecules. As a consequence, the glycoproteins are essential for growth of the pollen tube.