Processing, targeting, and antifungal activity of stinging nettle agglutinin in transgenic tobacco.

The gene encoding the precursor to stinging nettle (Urtica dioica L. ) isolectin I was introduced into tobacco (Nicotiana tabacum). In transgenic plants this precursor was processed to mature-sized lectin. The mature isolectin is deposited intracellularly, most likely in the vacuoles. A gene construct lacking the C-terminal 25 amino acids was also introduced in tobacco to study the role of the C terminus in subcellular trafficking. In tobacco plants that expressed this construct, the mutant precursor was correctly processed and the mature isolectin was targeted to the intercellular space. These results indicate the presence of a C-terminal signal for intracellular retention of stinging nettle lectin and most likely for sorting of the lectin to the vacuoles. In addition, correct processing of this lectin did not depend on vacuolar deposition. Isolectin I purified from tobacco displayed identical biological activities as isolectin I isolated from stinging nettle. In vitro antifungal assays on germinated spores of the fungi Botrytis cinerea, Trichoderma viride, and Colletotrichum lindemuthianum revealed that growth inhibition by stinging nettle isolectin I occurs at a specific phase of fungal growth and is temporal, suggesting that the fungi had an adaptation mechanism.

Characterization of Urtica dioica agglutinin isolectins and the encoding gene family.

Urtica dioica agglutinin (UDA) has previously been found in roots and rhizomes of stinging nettles as a mixture of UDA-isolectins. Protein and cDNA sequencing have shown that mature UDA is composed of two hevein domains and is processed from a precursor protein. The precursor contains a signal peptide, two in-tandem hevein domains, a hinge region and a carboxyl-terminal chitinase domain. Genomic fragments encoding precursors for UDA-isolectins have been amplified by five independent polymerase chain reactions on genomic DNA from stinging nettle ecotype Weerselo. One amplified gene was completely sequenced. As compared to the published cDNA sequence, the genomic sequence contains, besides two basepair substitutions, two introns located at the same positions as in other plant chitinases. By partial sequence analysis of 40 amplified genes, 16 different genes were identified which encode seven putative UDA-isolectins. The deduced amino acid sequences share 78.9-98.9% identity. In extracts of roots and rhizomes of stinging nettle ecotype Weerselo six out of these seven isolectins were detected by mass spectrometry. One of them is an acidic form, which has not been identified before. Our results demonstrate that UDA is encoded by a large gene family.

Non-recombinant background in gene targeting: illegitimate recombination between a hpt gene and a defective 5' deleted nptII gene can restore a Kmr phenotype in tobacco.

Previously we have demonstrated gene targeting in plants after Agrobacterium-mediated transformation. In these initial experiments a transgenic tobacco line 104 containing a T-DNA insertion with a defective neomycin phosphotransferase (nptII) gene was transformed with a repair construct containing an otherwise defective nptII gene. Homologous recombination between the chromosomally located target and the incoming complementary defective nptII construct generated an intact nptII gene and led to a kanamycin-resistant (Kmr) phenotype. The gene targeting frequency was 1 x 10(-5). In order to compare direct gene transfer and Agrobacterium-mediated transformation with respect to gene targeting we transformed the same transgenic tobacco line 104 via electroporation. A total of 1.35 x 10(8) protoplasts were transformed with the repair construct. Out of nearly 221,000 transformed cells 477 Kmr calli were selected. Screening the Kmr calli via PCR for recombination events revealed that in none of these calli gene targeting had occurred. To establish the origin of the high number of Kmr calli in which gene targeting had not occurred we analysed plants regenerated from 24 Kmr calli via PCR and sequence analysis. This revealed that in 21 out of 24 plants analysed the 5'-deleted nptII gene was fused to the hygromycin phosphotransferase (hpt) gene that was also present on the repair construct. Sequence analysis of 7 hpt/nptII gene fusions showed that they all contained a continuous open reading frame. The absence of significant homology at the fusion site indicated that fusion occurred via a process of illegitimate recombination. Therefore, illegitimate recombination between an introduced defective gene and another gene present on the repair construct or the chromosome has to be taken into account as a standard byproduct in gene targeting experiments.

Mechanisms of intermolecular homologous recombination in plants as studied with single- and double-stranded DNA molecules.

To elucidate the mechanism for intermolecular homologous recombination in plants we cotransformed Nicotiana tabacum cv Petit Havana SR1 protoplasts with constructs carrying different defective derivatives of the NPTII gene. The resulting kanamycin resistant clones were screened for possible recombination products by PCR, which proved to be a valuable technique for this analysis. Our results show that the double-stranded circular DNA molecules used in this study recombine predominantly via a pathway consistent with the single-strand annealing (SSA) model as proposed for extrachromosomal recombination in mammalian cells. In the remaining cases recombination occurred via a single reciprocal recombination, gene conversion and possibly double reciprocal recombination. Since single-stranded DNA is considered to be an important intermediate in homologous recombination we also established the recombination ability of single-stranded DNA in intermolecular recombination. We found that single-stranded DNA enters in recombination processes more efficiently than the corresponding double-stranded DNA. This was also reflected in the recombination mechanisms that generated the functional NPTII gene. Recombination between a single-stranded DNA and the complementing DNA duplex occurred at similar rates via a single reciprocal recombination and the SSA pathway.

A quick method to estimate the T-DNA copy number in transgenic plants at an early stage after transformation, using inverse PCR.

Agrobacterium-mediated transformation of plants is known to result in transgenic plants with a variable number of integrated T-DNA copies. Our aim was to obtain transgenic tobacco plants containing one integrated T-DNA copy per genome. Therefore, a quick method was developed to estimate the T-DNA copy number of young transgenic plantlets within 10 weeks after transformation. Inverse polymerase chain reaction (IPCR) was used to amplify junction fragments, i.e. plant genomic DNA sequences flanking the known T-DNA sequences.

Extrachromosomal homologous recombination and gene targeting in plant cells after Agrobacterium mediated transformation.

We determined whether T-DNA molecules introduced into plant cells using Agrobacterium are suitable substrates for homologous recombination. For the detection of such recombination events different mutant versions of a NPTII construct were used. In a first set of experiments protoplasts of Nicotiana tabacum SR1 were cocultivated with two Agrobacterium tumefaciens strains. Each strain contained a different T-DNA, one carrying a 5' deleted NPTII gene and the other a NPTII gene with a 3' deletion. A restored NPTII gene was found in 1-4% of the protoplasts that had been cotransformed with both T-DNAs. Restoration of the NPTII gene could only be the consequence of homologous recombination between the two different T-DNAs in the plant cell, since the possibility of recombination in Agrobacterium was excluded in control experiments. In subsequent experiments was investigated the potential use of Agrobacterium for gene targeting in plants. A transgenic tobacco line with a T-DNA insertion carrying a defective NPTII gene with a 3' deletion was transformed via Agrobacterium with a T-DNA containing a defective NPTII repair gene. Several kanamycin resistant plant lines were obtained with an intact NPTII gene integrated in their genome. In one of these lines the defective NPTII gene at the target locus had been properly restored. Our results show that in plants recombination can occur between a chromosomal locus and a homologous T-DNA introduced via A. tumefaciens. This opens the possibility of using the Agrobacterium transformation system for site directed mutagenesis of the plant genome.