Alberto Martinez

Creation of ecdysone receptor chimeras in plants for controlled regulation of gene expression.

Abstract Transformation with a chimeric receptor containing the glucocorticoid transactivation and DNA-binding domains fused to an ecdysteroid receptor ligand-binding domain permits ecdysone agonist-inducible gene expression in monocotyledonous plant cells. The inducible system is based on the specific activation of a chimeric receptor containing the ligand-binding domain of the Heliothis virescens ecdysteroid receptor and the inducer RH5992 (a 20-hydroxyecdysone agonist). RH5992 is an non-steroidal agrochemical with a high specificity for lepidopteran ecdysone receptors. Addition of RH5992 to transformed cells results in high levels of inducible expression in a ligand-specific manner, particularly when the effector receptor is coupled to the strong transactivator VP16. A chimeric construct containing the Drosophila ecdysone ligand-binding domain failed to activate reporter gene activity with RH5992, while activation was observed in the presence of muristeroneA. The system described provides the basis for an inducible gene expression system that is compatible with agricultural use.

Chemical-inducible gene expression systems for plants—a review†

Chemical-inducible expression systems, or ‘gene switches’, provide an opportunity for the temporal, spatial and quantitative control of genetically engineered traits. This review describes molecular and chemical aspects of several gene switches which have appeared in the literature and a novel unpublished system. Molecular components from plant, bacterial, fungal, insect and mammalian sources have all been utilised to develop gene switches. A brief description of the underlying principle of each approach and some detail of how they perform in transgenic plants is given. Although gene switch systems have utility for fundamental and applied research, particular reference is given to those systems with potential for application in agriculture.

Genetic evidence that the higher plant Rab-D1 and Rab-D2 GTPases exhibit distinct but overlapping interactions in the early secretory pathway

GTPases of the Rab1 subclass are essential for membrane traffic between the endoplasmic reticulum (ER) and Golgi complex in animals, fungi and plants. Rab1-related proteins in higher plants are unusual because sequence comparisons divide them into two putative subclasses, Rab-D1 and Rab-D2, that are conserved in monocots and dicots. We tested the hypothesis that the Rab-D1 and Rab-D2 proteins of Arabidopsis represent functionally distinct groups. RAB-D1 and RAB-D2a each targeted fluorescent proteins to the same punctate structures associated with the Golgi stacks and trans-Golgi-network. Dominant-inhibitory N121I mutants of each protein inhibited traffic of diverse cargo proteins at the ER but they appeared to act via distinct biochemical pathways as biosynthetic traffic in cells expressing either of the N121I mutants could be restored by coexpressing the wild-type form of the same subclass but not the other subclass. The same interaction was observed in transgenic seedlings expressing RAB-D1 [N121I]. Insertional mutants confirmed that the three Arabidopsis Rab-D2 genes were extensively redundant and collectively performed an essential function that could not be provided by RAB-D1, which was non-essential. However, plants lacking RAB-D1, RAB-D2b and RAB-D2c were short and bushy with low fertility, indicating that the Rab-D1 and Rab-D2 subclasses have overlapping functions.

Transcriptional activation of the cloned Heliothis virescens (Lepidoptera) ecdysone receptor (HvEcR) by MuristeroneA

Ecdysteroids play an important role during insect development. We report here the isolation and characterisation of an Ecdysone receptor (EcR) homologue from Heliothis virescens (HvEcR) and present evidence supporting the HvEcR active role as an active component of the native insect receptor. Alignment of the deduced amino acid sequence of HvEcR with those of EcRs from other species confirmed its membership of this family and showed that it is closely related to the B1 isoform of Drosophila melanogaster. Northern blot analysis showed that two transcripts (6.0 and 6.5 kb) were recognised by a probe spanning the DNA and ligand binding domains of the HvEcR. Genomic Southern blots showed that the HvEcR is encoded by a single copy gene. Two lines of evidence towards the functional activity of the HvEcR are presented. In vitro transcribed and translated HvEcR showed specific binding to hsp27 and pall response elements in the presence of CfUSP. Stable expression of HvEcR in 293 cells induced reporter gene activity in the presence of muristeroneA in a dose dependant manner while dexamethasone failed to activate.

PAH-Domain-Specific Interactions of the Arabidopsis Transcription Coregulator SIN3-LIKE1 (SNL1) with Telomere-Binding Protein 1 and ALWAYS EARLY2 Myb-DNA Binding Factors

The eukaryotic SIN3 protein is the central component of the evolutionarily conserved multisubunit SIN3 complex that has roles in regulating gene expression and genome stability. Here we characterise the structure of the SIN3 protein in higher plants through the analysis of SNL1 (SIN3-LIKE1), SNL2, SNL3, SNL4, SNL5 and SNL6, a family of six SIN3 homologues in Arabidopsis thaliana. In an Arabidopsis-protoplast beta-glucuronidase reporter gene assay, as well as in a heterologous yeast repression assay, full-length SNL1 was shown to repress transcription in a histone-deacetylase-dependent manner, demonstrating the conserved nature of SIN3 function. Yeast two-hybrid screening identified a number of DNA binding proteins each containing a single Myb domain that included the Arabidopsis ALWAYS EARLY proteins AtALY2 and AtALY3, and two telomere binding proteins AtTBP1 and AtTRP2/TRFL1 as SNL1 partners, suggesting potential functions for SNL1 in development and telomere maintenance. The interaction with telomere-binding protein 1 was found to be mediated through the well-defined paired amphipathic helix domain PAH2. In contrast, the AtALY2 interaction was mediated through the PAH3 domain of SNL1, which is structurally distinct from PAH1 and PAH2, suggesting that evolution of this domain to a more novel structural motif has occurred. These findings support a diverse role of SNL1 in the regulation of transcription and genome stability.

Glucocorticoid-inducible gene expression vectors for use in Drosophila melanogaster Schneider 2 cells

Inducible, vector‐based, expression systems that allow fine control of transgene expression are gaining more and more use in fundamental research as well as in therapeutic applications. In an effort to develop a tightly regulated heterologous expression system for Drosophila Schneider 2 cells, three different inducible reporter constructs were compared. These comprised six copies of the glucocorticoid response element fused to one of three distinct types of Drosophila gene promoters: (1) a TATA‐box containing, (2) a TATA‐less and (3) a bidirectional core sequence. These were fused to a luciferase reporter gene. The promoter constructs displayed different basal as well as agonist‐induced activities. The implications of the observations made are discussed in the context of promoter properties and of induction of genes that may be studied in Drosophila.