Nuclear localization of the Hermes transposase depends on basic amino acid residues at the N-terminus of the protein

For the Hermes transposable element to be mobilized in its eukaryotic host, the transposase, encoded by the element, must make contact with its DNA. After synthesis in the cytoplasm, the transposase has to be actively imported into the nucleus because its size of 70.1 kDa prevents passive diffusion through the nuclear pore. Studies in vitro using transient expression of a Hermes-EGFP fusion protein in Drosophila melanogaster Schneider 2 cells showed the transposase was located predominantly in the nucleus. In silico sequence analysis, however, did not reveal any nuclear localization signal (NLS). To identify the sequence(s) responsible for localization of Hermes transposase in the nucleus, truncated or mutated forms of the transposase were examined for their influence on sub-cellular localization of marker proteins fused to the transposase. Using the same expression system and a GFP-GUS fusion double marker, residues 1-110 were recognized as sufficient, and residues 1-32 as necessary, for nuclear localization. Amino acid K25 greatly facilitated nuclear localization, indicating that at least this basic amino acid plays a significant role in this process. This sequence overlaps the proposed DNA binding region of the Hermes transposase and is not necessarily conserved in all members of the hAT transposable element family.     

Chrysanthemum: advances in tissue culture, cryopreservation, postharvest technology, genetics and transgenic biotechnology

Members of the Chrysanthemum-complex include important floricultural (cut-flower) and ornamental (pot and garden) crops, as well as plants of culinary, medicinal and (ethno)pharmacological interest. The last 35 years have seen a tremendous emphasis on their in vitro tissue culture and micropropagation, while the latter 10–15 years has seen a surge in transformation experiments, all aimed at ameliorating aesthetic and growth characteristics of the plants. This review highlights all available literature that exists on ornamental Chrysanthemum in vitro cell, tissue and organ culture, micropropagation and transformation.     

Foot-and-mouth disease virus VP1 protein fused with cholera toxin B subunit expressed in Chlamydomonas reinhardtii chloroplast

A Chlamydomonas reinhardtii chloroplast expression vector, pACTBVP1, containing the fusion of the foot and mouth disease virus (FMDV) VP1 gene and the cholera toxin B subunit (CTB) gene was constructed and transfered to the chloroplast genome of C. reinhardtii by the biolistic method. The transformants were identified by PCR, Southern blot, Western blot and ELISA assays after selection on resistant medium and incubation in the dark. The CTBVP1 fusion protein was expressed in C. reinhardtii chloroplast and accounted for up to 3% of the total soluble protein. The fusion protein also retained both GM1-ganglioside binding affinity and antigenicity of the FMDV VP1 and CTB proteins. These experimental results support the possibility of using transgenic chloroplasts of green alga as a mucosal vaccine source.     

Rare instances of Cre-mediated deletion product maintained in transgenic wheat

Previously, we described a Cre-lox based strategy to convert a complex multi-copy integration pattern to a single-copy transgene (Srivastava et al., 1999). When a lox-containing transgenic line of wheat was crossed with a cre-expressing line, extra copies of the transgene were deleted by site-specific recombination. This process included the removal of a lox-flanked selection marker gene, bar. Three out of six F₁ plants were chimeric for the resolved and the complex loci because both completely resolved and incompletely resolved patterns were found in the F₂ population. From one F₁ plant, 4 out of 20 F₂ progeny showed not only incomplete resolution of the complex integration pattern, but also the presence of a circular loxP-bar-nos3 fragment, which we refer to as the bar circle. This bar circle was detected in subsequent generations, and was associated with the presence of both the lox transgene and the cre locus. We hypothesize that the cre gene in these bar circle plants must have undergone a genetic or epigenetic change that altered the spatial and/or temporal pattern of cre expression. Late expression might excise the DNA incompletely, and late in development. What is surprising is that the DNA is not degraded, but remains in the cells as an extra-chromosomal circular molecule.     

Transgene integration,organization and interaction in plants

It has been appreciated for many years that the structure of a transgene locus can have a major influence on the level and stability of transgene expression. Until recently, however, it has been common practice to discard plant lines with poor or unstable expression levels in favor of those with practical uses. In the last few years, an increasing number of experiments have been carried out with the primary aim of characterizing transgene loci and studying the fundamental links between locus structure and expression. Cereals have been at the forefront of this research because molecular, genetic and cytogenetic analysis can be carried out in parallel to examine transgene loci in detail. This review discusses what is known about the structure and organization of transgene loci in cereals, both at the molecular and cytogenetic levels. In the latter case, important links are beginning to be revealed between higher order locus organization, nuclear architecture, chromatin structure and transgene expression.     

Expression of Barstar as a selectable marker in yeast mitochondria

We describe a new and potentially universal selection system for mitochondrial transformation based on bacterial genes, and demonstrate its feasibility in Saccharomyces cerevisiae. We first found that cytoplasmically synthesized Barnase, an RNase, interferes with mitochondrial gene expression when targeted to the organelle, without causing lethality when expressed at appropriate levels. Next, we synthesized a gene that uses the yeast mitochondrial genetic code to direct the synthesis of the specific Barnase inhibitor Barstar, and demonstrated that expression of this gene, BARSTM, integrated in mtDNA protects respiratory function from imported barnase. Finally, we showed that screening for resistance to mitochondrially targeted barnase can be used to identify rare mitochondrial transformants that had incorporated BARSTM in their mitochondrial DNA. The possibility of employing this strategy in other organisms is discussed.Communicated by R. G. Herrmann     

An improved protocol for<Emphasis Type="Italic"> Agrobacterium</Emphasis>-mediated transformation of<Emphasis Type="Italic"> Antirrhinum majus</Emphasis> L.

Efficient Agrobacterium -mediated transformation of Antirrhinum majus L. was achieved via indirect shoot organogenesis from hypocotyl explants of seedlings. Stable transformants were obtained by inoculating explants with A. tumefaciens strain GV2260 harboring the binary vector pBIGFP121, which contains the neomycin phosphotransferase gene (NPT II) as a selectable marker and the gene for the Green Fluorescent Protein (GFP) as a visual marker. Putative transformants were identified by selection for kanamycin resistance and by examining the shoots using fluorescence microscopy. PCR and Southern analyses confirmed integration of the GFP gene into the genomes of the transformants. The transformants had a morphologically normal phenotype. The transgene was shown to be inherited in a Mendelian manner. This improved method requires only a small number of seeds for explant preparation, and three changes of medium; the overall transformation efficiency achieved, based on the recovery of transformed plants after 4–5 months of culture, reached 8–9%. This success rate makes the protocol very useful for producing transgenic A. majus plants.Communicated by G. Jürgens     

Electroporation of embryogenic protoplasts of sweet orange (<Emphasis Type="Italic">Citrus sinensis</Emphasis> (L.) Osbeck) and regeneration of transformed plants

Summary Electroporation conditions were optimized for the transfection of protoplasts isolated from an embryogenic cell line of sweet organe [Citrus sinensis (L.) Osbeck ev. Hamlin]. Electric field strength (375–450 V cm⁻¹) vector DNA concentration (100 μgml⁻¹), carrier DNA concentration (100 μgml⁻¹), electroporation buffer (pH 8), and preelectroporation heat shock of protoplasts (5 min at 45°C) were optimized. The plasmid vector pBI221 containing the β-glucuronidase (GUS) coding sequence under the control of the CaMV 35S promoter was used and GUS activity was measured 24h after electroporation. All variables significantly affected transfection efficiency and when optimal conditions for each were combined. GUS activity was 7714 pmol 4-methylumbelliferone (MU) mg⁻¹ (protein) min⁻¹. Protoplasts were then electroporated in the presence of green fluorescent protein (GFP) expression vectors pARS101 or pARS108. Green fluorescent embryos were selected, plants regenerated, and integration of the transgene was confirmed by Southern blot analysis. Both plasmids were constructed using EGFP, a GFP variant 35 times brighter than wtGFP, having a single, red-shifted excitation peak, and optimized for human codon-usage. pARS101 was constructed by placing EGFP under the control of a 35S–35S promoter containing 33 bp of the untranslated leader sequence from alfalfa mosaic virus. pARS108 was constructed similarly except sequences were added for transport and retention of EGFP in the lumen of the endoplasmic reticulum. Mention of a trademark, warranty, proprietary product, or vendor does not constitute a guarantee by the US Department of Agriculture and does not imply its approval to the exclusion of other products or veudors that may also be suitable.     

T-DNA recombination and replication in maize cells

T-DNA recombination and replication was analyzed in 'black mexican sweet' (BMS) cells transformed with T-DNAs containing the replication system from wheat dwarf virus (WDV). Upon recombination between the T-DNA ends, a promoterless marker gene (gusA) was activated. Activation of the recombination marker gene was delayed and increased exponentially over time, suggesting that recombination and amplification of the T-DNA occurred in maize cells. Mutant versions of the viral initiator gene (rep), known to be defective in the replication function, failed to generate recoverable recombinant T-DNA molecules. Circularization of T-DNA by the FLP/FRT site-specific recombination system and/or homologous recombination was not necessary to recover circular T-DNAs. However, replicating T-DNAs appeared to be suitable substrates for site-specific and homologous recombination. Among 33 T-DNA border junctions sequenced, only one pair of identical junction sites was found implying that the population of circular T-DNAs was highly heterogenous. Since no circular T-DNA molecules were detected in treatments without rep, it suggested that T-DNA recombination was linked to replication and might have been stimulated by this process. The border junctions observed in recombinant T-DNA molecules were indicative of illegitimate recombination and were similar to left-border recombination of T-DNA into the genome after Agro-mediated plant transformation. However, recombination between T-DNA molecules differed from T-DNA/genomic DNA junction sites in that few intact right borders were observed. The replicating T-DNA molecules did not enhance genomic random integration of T-DNA in the experimental configuration used for this study.