GFP accumulation controlled by an auxin-responsive promoter as a non-destructive assay to monitor early auxin response

We have constructed transgenic Arabidopsis lines that contain a gene for green fluorescent protein (GFP) under the control of auxin-responsive domains A and B of the promoter from the pea PS-IAA4/5 gene. The chimeric transgene was named BA-mgfp5-ER. GFP was detected after the application of indole-3-acetic acid at concentrations as low as 100 nM in epidermal cells in the root elongation zone. The induction of the reporter gene was highly specific to auxin and was correlated with the auxin-induced change in epidermal cell shape. No GFP accumulation was observed in the lateral root meristem that was formed as a result of exogenous auxin application. These results suggest that auxin signals were transmitted through several distinct pathways depending on the cell type. The intensity of the GFP signal was strong enough to be observed through the plastic lid of the culture dish using a dissecting microscope, thereby enabling GFP expression to be monitored in an aseptic environment. Thus, the BA-mgfp5-ER transgenic plant can be a powerful tool for screening mutants that are defective in auxin signaling and the expression of early auxin-response genes.     

Phenotypic instability of transgenic tobacco plants and their progenies expressing Arabidopsis thafiana small GTP-binding protein genes

Chimeric genes consisting of the cauliflower mosaic virus 35S promoter, a CDNA encoding a small GTP-binding protein from Arabidopsis thaliana (ara-2 or ara-4) and the terminator of the nopaline synthase gene were cloned into a binary vector. Tobacco leaf tissues were transformed with this plasmid via Agrobacterium-mediated transformation. Transgenic plants possessing either ara-2 or ara-4 occasionally showed morphological abnormalities in leaves and other organs. However, such alterations were not always associated with co-transferred characters, such as kanamycin tolerance, and they arose in no more than 10% of the transgenic plants. Such phenomena were also observed in the progenies of the primary transgenic plants. Despite such unusual inheritance of the phenotypic abnormalities, GTP-binding activity of the inserted ara gene products was detected in all plants tested.     

Histochemical Localization of a Chimeric Gene (rolC-GUS) Expression in Zygotic Embryos of Transgenic Tobacco Plants

Histochemical localization of the expression pattern of a chimericgene (rolC-GUS) in zygotic embryo development in tobacco plantswas analysed. The results indicate that strong expression waslocalized mainly in the vascular cylinders of the cotyledonsand central axis of the hypocotyl. Quantitative analysis indicatedan increase of gene expression in embryos up to 20 d after pollination(DAP), but decreased at 30 DAP. Continuous increase of GUS activitywas recorded up to 12 d after imbibition (DAI) in germinatingseeds. The xylem cells were visualized following phloem differentiationin the cotyledons at 3 DAI.Copyright 1994, 1999 Academic Press Tobacco (Nicotiana tabacum cv. Samsun), transgenic plants, rolC promoter-GUS chimeric gene, germinating seeds, transition region, zygotic embryos     

The biological roles of small GTPases and interacting proteins in plants

Extensive studies on the molecular mechanisms of vesicular trafficking have revealed that molecules involved in this cellular function are remarkably well conserved from yeast to higher plants. However, it is not clear at all how a variety of organisms maintain the individual divergent systems using the common machinery of vesicular traffic. We have been attempting to understand the roles and regulatory mechanisms of vesicular traffic in plants through the study of Rab/Ypt GTPases. Ara proteins are Rab/Ypt homologues ofArabidopsis, which are implicated in the regulation of vesicular traffic. Their biochemical properties are similar to those of the Rab/Ypt proteins from animal and yeast cells. The overexpression ofARA2 orARA4 causes pleiotropic morphological abnormalities in the transgenic tobacco plants. The GTPase cycle of Ara proteins has to be strictly controlled for their proper functions. We have identified two classes of regulator molecules of Ara2 and Ara4. One is the GTPase activating protein (GAP), and the other is the GDP dissociation inhibitor (GDI). GAP has been identified as an activity accelerating the hydrolysis of GTP by Ara2 or Ara4. GDI (AtGDI1) has been isolated as a molecule interacting with Ara4 using a novel method for detecting interactions between foreign molecules in yeast. Further studies on the interacting molecules should unveil the regulatory system of and signal transduction pathway via Ara proteins. The extended abstract of a paper presented at the 13th International Symposium in Conjugation with Award of the Internation Prize for Biology “Frontier of Plant Biology”     

The Rheb family of GTP-binding proteins

Rheb proteins represent a novel and unique family of the Ras superfamily GTP-binding proteins that is conserved from yeast to human. Biochemical studies establish that they bind and hydrolyze GTP. Molecular modeling studies reveal a few structural differences between Rheb and Ras, which may suggest that residues involved in biochemical activities differ between the two G-proteins. The function of Rheb has been studied in a number of organisms that point to the involvement of Rheb in cell growth and cell cycle progression. In addition, studies in fungi suggest that Rheb is involved in arginine uptake. Further studies in Drosophila and mammalian cells have shown that the effects of Rheb on growth and cell cycle progression are mediated by the effect on the insulin/TOR/S6K signaling pathway. These studies have also shown that a complex consisting of the tuberous sclerosis gene products, Tsc1/Tsc2, serves as a GTPase activating protein (GAP) for Rheb, implying Rheb's role in this genetic disorder. Finally, Rheb proteins have been shown to be farnesylated and small molecule inhibitors of protein farnesyltransferase can block the ability of Rheb to activate the TOR/S6K signaling.     

Phenotypic instability of transgenic tobacco plants and their progenies expressing Arabidopsis thafiana small GTP-binding protein genes

Chimeric genes consisting of the cauliflower mosaic virus 35S promoter, a CDNA encoding a small GTP-binding protein from Arabidopsis thaliana (ara-2 or ara-4) and the terminator of the nopaline synthase gene were cloned into a binary vector. Tobacco leaf tissues were transformed with this plasmid via Agrobacterium-mediated transformation. Transgenic plants possessing either ara-2 or ara-4 occasionally showed morphological abnormalities in leaves and other organs. However, such alterations were not always associated with co-transferred characters, such as kanamycin tolerance, and they arose in no more than 10% of the transgenic plants. Such phenomena were also observed in the progenies of the primary transgenic plants. Despite such unusual inheritance of the phenotypic abnormalities, GTP-binding activity of the inserted ara gene products was detected in all plants tested.     

The Tsc/Rheb signaling pathway controls basic amino acid uptake via the Cat1 permease in fission yeast

The Tsc/Rheb signaling pathway plays critical roles in the control of growth and cell cycle. Studies in fission yeast have also implicated its importance in the regulation of amino acid uptake. Disruption of tsc2 ⁺, one of the tsc ⁺ genes, has been shown to result in decreased arginine uptake and resistance to canavanine. A similar effect is also seen with other basic amino acids. We have identified a permease responsible for the uptake of basic amino acids by genetic complementation and disruption. SPAC869.11 (termed Cat1 for cationic amino acid transporter) contains 12 predicted transmembrane domains and its overexpression in wild type fission yeast leads to the increased uptake of basic amino acids and sensitivity to canavanine. Disruption of cat1 ⁺ in the Δtsc2 background interfered with the suppression of the canavanine-resistant phenotype of Δtsc2 mutants by a dominant negative Rheb. In Δtsc2 mutant strains, the amount of Cat1 was not altered, but instead was mislocalized. This mislocalization was suppressed by the expression of dominant negative Rheb. In addition, we found that the loss of the E3 ubiquitin ligase, Pub1, also restores proper localization. These results provide a crucial link between Tsc/Rheb signaling and the regulation of the basic amino acid permease in fission yeast.