The LEA proteins and trehalose loving couple: a step forward in anhydrobiotic engineering

Arf family GTP-binding proteins function in the regulation of membrane-trafficking events and in the maintenance of organelle structure. They act at membrane surfaces to modify lipid composition and to recruit coat proteins for the generation of transport vesicles. Arfs associate with membranes through insertion of an N-terminal myristoyl moiety in conjunction with an adjacent amphipathic alpha-helix, which embeds in the lipid bilayer when Arf1 is GTP-bound. In this issue of the Biochemical Journal, Lundmark et al. report that myristoylated Arfs in the presence of GTP bind to and cause tubulation of liposomes, and that GTP exchange on to Arfs is more efficient in the presence of liposomes of smaller diameter (increased curvature). These findings suggest that Arf protein activation and membrane interaction may initiate membrane curvature that will be enhanced further by coat proteins during vesicle formation.     

Pools of water in anhydrobiotic organisms: A thermally stimulated depolarization current study

The ability to survive the removal of water in anhydrous biosystems is especially remarkable as a departure from the manifold structural and functional dependences on the presence of H₂O molecules. Identifiable pools of water present in dry soybean axes were investigated by means of the thermally stimulated depolarization current method. Samples were examined in the temperature range 100-340 K and over water contents (h, in gram H₂O per gram sample dry weight) ranging from h = 0.05 to 0.30 g/g. Three water-dependent relaxation mechanisms were detected; one attributed to dipolar reorientation of H₂O molecules hydrogen-bonded to other water molecules, one to reorientation of CH₂OH groups, and one to a glass transition in sugar-water domains. These glassy domains can protect intracellular components against destruction in the dehydrated state. Interestingly, protecting glassy domains were not found in dehydration intolerant seeds, supporting the hypothesis that the ability to withstand dehydration is associated with intracellular glass formation. A model for the state of cell water at interfaces is proposed.     

An abundant LEA protein in the anhydrobiotic midge,PvLEA4, acts as a molecular shield by limiting growth of aggregating protein particles

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Transfection and expression of plasmid DNA in plant cells by an arginine-rich intracellular delivery peptide without protoplast preparation

The delivery and expression of exogenous genes in plant cells have been of particular interest for plant research and biotechnology. Here, we present results demonstrating a simple DNA transfection system in plants. Short arginine-rich intracellular delivery peptide, a protein transduction domain, was capable of delivering plasmid DNA into living plant cells non-covalently. This peptide-mediated DNA delivery conferred several advantages, such as nuclear targeting, non-toxic effect, and ease of preparation without protoplast formulation. Thus, this novel technology shall provide a powerful tool to investigate gene function in vivo, and lay the foundation for the production of transgenic plants in future.     

Expression of plant group 2 and group 3 lea genes in Saccharomyces cerevisiae revealed functional divergence among LEA proteins

To study functions of late embryogenesis abundant (LEA) proteins, which accumulate in plant cells under water deficit conditions, in vivo functional analyses were carried out using a yeast (Saccharomyces cerevisiae) heterologous expression system. Two lea genes, tomato le4 (group 2) and barley HVA1 (group 3), were expressed under the GAL1 promoter, and the gene products were detected using specific antisera. The growth of the transformants was scored and compared with a control strain to analyze the effect of these proteins on yeast cells under stress conditions. The yeast cells expressing HVA1 showed shorter lag period when transferred to a medium containing 1.2 M NaCl as compared to a control strain, while the cells expressing le4 did not show improved growth. Attenuated growth inhibition in a medium containing 1.2 M KCl was observed in the yeast cells expressing le4 and HVA1. No obvious growth improvement was observed in a high sorbitol medium in the cells expressing either le4 or HVA1. Increased freezing tolerance was observed in both lea-expressing cells, while no effect on heat tolerance was observed. These results support the hypothesis that different LEA proteins play a distinctive role in the protection against cellular dehydration.     

Regulated expression of plant tRNA genes by the prokaryotic tet and lac repressors

The prokaryotic tet operator (tetO) sequence was inserted at positions upstream and downstream of sequences encoding the Arabidopsis thaliana tRNA _AUC ^Lys or tRNA _AUC ^Trp suppressor tRNAs, and tRNA expression in carrot protoplasts was measured by translational suppression of a nonsense codon in a luciferase reporter gene. Regulation of tRNA expression by the tetracycline repressor (tetR) occurred from genes with the tetO inserted at position –1 (for the tRNA _AUC ^Trp gene), or at positions –2, –6 and –10 (for the tRNA _AUC ^Lys gene), and repression reached 90%. The inducer tetracycline (Tc) restored tRNA expression. Similarly, carrot protoplasts transfected with human tRNA _AUC ^Ser genes containing the lac operator (lacO) in their 5-flanking sequence with or without the lac repressor (lacI) gene, conditionally expressed tRNAs which suppressed the luciferase reporter. Up to 30-fold repression occured by the lactose repressor when lacO was located at position –1 of the tRNA _AUC ^Ser coding sequence. In the presence of the inducer isopropyl--thiogalactoside (IPTG), repression was relieved. These results demonstrate that sequences flanking tRNA genes can strongly influence tRNA expression in plants, and in a conditional fashion when bound by inducible proteins.     

Optimizing the expression of chimeric genes in plant cells

Summary The Serratia marcescens chiA gene encodes a secreted chitinase activity which contributes to the fungal growth inhibition exhibited by this bacterium. The coding region from the chiA gene was fused to the promoter and 3 polyadenylation region of the Agrobacterium nopaline synthase gene. Site-directed mutagenesis of specific nucleotides surrounding the initiating AUG of the coding sequence of this chimeric gene resulted in up to an eight-fold increase in the amount of chitinase protein detected in transformed plant tissue. Analysis of the chiA mRNA indicated that these nucleotides also affected mRNA levels. At least 50% of the chitinase protein produced in transformed tobacco cells was the same molecular weight as the S. marcescen secreted protein.     

Dehydration-specific induction of hydrophilic protein genes in the anhydrobiotic nematode Aphelenchus avenae

Some organisms can survive exposure to extreme desiccation by entering a state of suspended animation known as anhydrobiosis. The free-living nematode Aphelenchus avenae can be induced to enter the anhydrobiotic state by exposure to a moderate reduction in relative humidity. During this preconditioning period, the nematode accumulates large amounts of the disaccharide trehalose, which is thought to be necessary, but not sufficient, for successful anhydrobiosis. To identify other adaptations that are required for anhydrobiosis, we developed a novel SL1-based mRNA differential display technique to clone genes that are upregulated by dehydration in A. avenae. Three such genes, Aav-lea-1, Aav-ahn-1, and Aav-glx-1, encode, respectively, a late embryogenesis abundant (LEA) group 3 protein, a novel protein that we named anhydrin, and the antioxidant enzyme glutaredoxin. Strikingly, the predicted LEA and anhydrin proteins are highly hydrophilic and lack significant secondary structure in the hydrated state. The dehydration-induced upregulation of Aav-lea-1 and Aav-ahn-1 was confirmed by Northern hybridization and quantitative PCR experiments. Both genes were also upregulated by an osmotic upshift, but not by cold, heat, or oxidative stress. Experiments to investigate the relationship between mRNA levels and protein expression for these genes are in progress. LEA proteins occur commonly in plants, accumulating during seed maturation and desiccation stress; the presence of a gene encoding an LEA protein in an anhydrobiotic nematode suggests that some mechanisms of coping with water loss are conserved between plants and animals.     

Language: Life without numbers

If your language did not have words for numbers, would you be able to think about numeric quantities? An Amazonian culture where number words are limited to one, two and many has provided new insights to the interaction between thought and language.     

Changes in surface features during desiccation of the anhydrobiotic plant parasitic nematode Ditylenchus dipsaci

The anhydrobiotic nematode Ditylenchus dipsaci is a fast-dehydration strategist, itself generating the slow rate of water loss necessary for survival. A permeability slump occurs during the initial phases of desiccation. This may be produced by changes in the nematode's cuticle. Two scanning electron microscopic techniques were used to follow changes in surface structures during desiccation. Freeze substitution and critical-point drying produced artifacts that obscured changes produced by the desiccation of the nematode. Low-temperature field emission scanning electron microscopy (FESEM) was successful in following changes that reflected those observed by light microscopy (LM). Significant changes in diameter, the lateral alae, and the cuticular annulations were demonstrated using this technique. Two types of annulations were observed: the major annulations, which extended to meet the margins of the lateral alae, and the minor annulations, which did not. With desiccation the prominence of the annulations increased, their spacing decreased, and the minor annulations extended closer to the margins of the lateral alae. These observations are consistent with the permeability slump resulting from a decrease in the width of the annulation groove and an increase in its depth. However, this requires confirmation using techniques that can follow annulation changes in individual nematodes.     

Transition from natively unfolded to folded state induced by desiccation in an anhydrobiotic nematode protein

Late embryogenesis abundant (LEA) proteins are associated with desiccation tolerance in resurrection plants and in plant seeds, and the recent discovery of a dehydration-induced Group 3 LEA-like gene in the nematode Aphelenchus avenae suggests a similar association in anhydrobiotic animals. Despite their importance, little is known about the structure of Group 3 LEA proteins, although computer modeling and secondary structure algorithms predict a largely alpha-helical monomer that forms coiled coil oligomers. We have therefore investigated the structure of the nematode protein, AavLEA1, in the first such analysis of a well characterized Group 3 LEA-like protein. Immunoblotting and subunit cross-linking experiments demonstrate limited oligomerization of AavLEA1, but analytical ultracentrifugation and gel filtration show that the vast majority of the protein is monomeric. Moreover, CD, fluorescence emission, and Fourier transform-infrared spectroscopy indicate an unstructured conformation for the nematode protein. Therefore, in solution, no evidence was found to support structure predictions; instead, AavLEA1 seems to be natively unfolded with a high degree of hydration and low compactness. Such proteins can, however, be induced to fold into more rigid structures by partner molecules or by altered physiological conditions. Because AavLEA1 is associated with desiccation stress, its Fourier transform-infrared spectrum in the dehydrated state was examined. A dramatic but reversible increase in alpha-helix and, possibly, coiled coil formation was observed on drying, indicating that computer predictions of secondary structure may be correct for the solid state. This unusual finding offers the possibility that structural shifts in Group 3 LEA proteins occur on dehydration, perhaps consistent with their role in anhydrobiosis.