Showing papers by "Klaus Palme published in 2000"

Localization of AtROP4 and AtROP6 and interaction with the guanine nucleotide dissociation inhibitor AtRhoGDI1 from Arabidopsis.

Abstract: The small GTPases of the Rho family play a key role in actin cytoskeletal organization. In plants, a novel Rho subfamily, called ROP (Rho of plants), has been found. In Arabidopsis, 12 ROP GTPases have been identified which differ mainly at their C-termini. To test the localization of two members of this subfamily (AtROP4 and AtROP6), we have generated translational fusions with the green fluorescent protein (GFP). Microscopic analysis of transiently transfected BY2 cells revealed a predominant localization of AtROP4 in the perinuclear region, while AtROP6 was localized almost exclusively to the plasma membrane. Swapping of the AtROP4 and AtROP6 C-termini produced a change in localization. As RhoGDIs are known to bind to the C-terminus of GTPases of the Rho family, we searched for ArabidopsisRhoGDI genes. We identified the AtRhoGDI1gene and mapped it to chromosome 3. AtRhoGDI1 encodes a 22.5 kDa protein which contains highly conserved amino acids in the isoprene binding pocket and exhibits 29% to 37% similarity to known mammalian RhoGDI homologues. The AtRhoGDI1 gene was expressed in all tissues studied. Using the yeast two-hybrid system, we showed specific interaction of AtRhoGDI1 with both AtROP4 and AtROP6 as well as with their GTP-locked mutants, but not with a GTPase of the RAB family. Recombinant GST-AtRhoGDI1 could bind GFP-AtROP4 from transgenic tobacco BY2 cell extracts, confirming the interaction observed with the two-hybrid system.

Developmental regulation of the maize Zm-p60.1 gene encoding a β-glucosidase located to plastids

Abstract: A beta-glucosidase that cleaves the biologically inactive hormone conjugates cytokinin-O- and kinetin-N3-glucosides is encoded by the maize Zm-p60.1 gene. The expression of the Zm-p60.1 gene was analyzed by Northern blot analysis and in-situ hybridization. It was found that the expression levels of the Zm-p60.1-specific mRNA changed after pollination of carpellate inflorescences. The Zm-p60.1 cDNA was expressed in E. coli and antibodies were raised against this protein. An antibody was used to determine the tissue-specific localization of this protein. By in situ immunolocalization experiments, this protein was found to be located in cell layers below the epidermis and around the vascular bundles of the coleoptile. In the primary leaf, the Zm-p60.1 protein was detected in cells of the outermost cell layer and around the vascular tissue. In floral tissue, Zm-p60.1 was present in the glumes, the carpels and in the outer cell layer of the style. In coleoptiles, as determined by immuno-electronmicroscopy, the Zmp60.1 protein was located exclusively in the plastids.

The DNA-binding activity of Gal4 is inhibited by methylation of the Gal4 binding site in plant chromatin

Abstract: Derivatives of the Saccharomyces cerevisiae transcription factor Gal4 which act as effective transcription activators in yeast, Drosophila, mammalian cells and plant protoplasts are shown to direct expression from a GUS reporter construct when expressed in transgenic tobacco. However, in comparison to 35S-GUS controls, Gal4-mediated expression of the reporter gene was relatively weak and extremely variable. GUS expression was lost as plants matured and it was almost undetectable in most of their progeny. Gal4-mediated gene expression could be restored by treating tissues with 5-aza-cytidine, implicating cytosine methylation in the loss of Gal4-mediated expression. Restoration of reporter expression was not accompanied by an increase in steady-state levels of the activator transcript. We propose that the DNA-binding activity of Gal4 is sensitive to methylation of its binding site in plant chromatin. The Gal4-DNA co-crystal predicts that 5-methylcytosine at either of the outer two positions of the binding site will effectively prevent Gal4 binding. We show that these positions become extensively methylated in transgenic plants and that methylation of Gal4-binding sites interferes with Gal4 binding in vitro. These observations suggest that the Gal4 DNA-binding domain is intrinsically sensitive to cytosine methylation and that, despite the success of Gal4-based expression systems in yeast and Drosophila, Gal4 is not ideal for use in plant gene expression technology.