Sorting of proteins to vacuoles in plant cells

for correspondence

Desiccation and osmotic stress increase the abundance of mRNA of the tonoplast aquaporin BobTIP26-1 in cauliflower cells.

Changes in vacuolar structure and the expression at the RNA level of a tonoplast aquaporin (BobTIP26-1) were examined in cauliflower (Brassicaoleracea L. var. botrytis) under water-stress conditions. Gradual drying out of slices of cauliflower floret tissue caused its collapse, with a shrinkage in tissue and cell volumes and an apparent vesiculation of the central vacuole, whereas osmotic stress resulted in plasmolysis with a collapse of the cytoplasm and the central vacuole within. Osmotic stress caused a rapid and substantial increase in BobTIP26 mRNA in slices of floret tissue. Exposure of tissue slices to a regime of desiccation showed a slower but equally large rise in BobTIP26 mRNA followed by a rapid decline upon rehydration. In situ hybridization showed that BobTIP26-2 mRNA is expressed most highly in meristematic and expanding cells of the cauliflower florets and that desiccation strongly increased the expression in those cells and in differentiated cells near the xylem vessels. These data indicate that under water-deficit conditions, expression of the tonoplast aquaporin gene in cauliflower is subject to a precise regulation that can be correlated with important cytological changes in the cells

Proteins of ribosome-bearing and free-membrane domains in Bacillus subtilis

In lysates of Bacillus subtilis a free-membrane fraction without ribosomes can be separated from the denser membrane-ribosome complexes. As determined by one-dimensional sodium dodecyl sulfate gel electrophoresis, these two fractions differ markedly in protein composition; at least six major bands (molecular weights, 130,000, 92,000, 68,000, 64,000, 45,000, and 31,000) are essentially unique to the complexed-membrane fraction (CM proteins), and two are unique to the free-membrane fraction. After growth was slowed, the proportion of the free-membrane fraction increased, but the composition of this fraction was the same, whereas after puromycin treatment, which abruptly increased the proportion of the free-membrane fraction, this fraction contained CM proteins. Thus, it appears that the two fractions recovered from growing cells represent topographically and functionally distinct domains. In addition, the effect of growth rate suggests that formation of the complexed domain is regulated at least roughly in parallel with the formation of ribosomes. The separation of these membrane fractions should facilitate the study of protein secretion, membrane topography, and morphogenesis in bacteria.</jats:p

Localization and quantitation of proteins characteristic of the complexed membrane of Bacillus subtilis

We prepared antibodies to four proteins (molecular weights, 68,000, 64,000, 45,000, and 31,000) that are characteristic of the complexed (ribosome-bearing) fraction of the membrane of Bacillus subtilis and found that these proteins are immunologically distinct. Quantitation by immunoprecipitation confirmed that the ribosome-free membrane fraction contains much lower concentrations of these four proteins than the complexed-membrane fraction. The 64-kilodalton protein appeared to be attached more loosely than the other proteins, since it was more readily extracted from the membrane. In addition, this protein was also present in the cytosol in an even greater amount than in the membrane. The 68-, 64-, and 31-kilodalton proteins are present in cells in stoichiometrically equivalent amounts.</jats:p