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.
Manganese serves an important function in Lactobacillus plantarum in protection against oxidative stress and this bacterium can accumulate Mn 2+ up to millimolar levels intracellularly.Although the physiological role of Mn 2+ and the uptake of this metal ion have been well documented, the only uptake system described so far for this bacterium is the Mn 2+ -and Cd 2+-specific P-type ATPase (MntA). Recently, the genome of L. plantarum WCFS1 has been sequenced allowing in silico detection of genes potentially encoding Mn 2+ transport systems, using established microbial Mn 2+ transporters as the query sequence. This genome analysis revealed that L. plantarum WCFS1 encodes, besides the previously described mntA gene, an ABC transport system (mtsCBA) and three genes encoding Nramp transporters (mntH1, mntH2 and mntH3).
Agrobacterium tumefaciens is known to transfer part of its tumor-inducing (Ti) plasmid to the filamentous fungus Aspergillus awamori by illegitimate recombination with the fungal genome. Here, we show that when this Ti DNA shares homology with the A. awamori genome, integration can also occur by homologous recombination. On the basis of this finding, we have developed an efficient method for constructing recombinant mold strains free from bacterial DNA by A. tumefaciens-mediated transformation. Multiple copies of a gene can be integrated rapidly at a predetermined locus in the genome, yielding transformants free of bacterial antibiotic resistance genes or other foreign DNA. Recombinant A. awamori strains were constructed containing up to nine copies of a Fusarium solani pisi cutinase expression cassette integrated in tandem at the pyrG locus. This allowed us to study how mRNA and protein levels are affected by gene copy number, without the influence of chromosomal environmental effects. Cutinase mRNA and protein were maximal with four gene copies, indicating a limitation at the transcriptional level. This transformation system will potentially stimulate market acceptance of derived products by avoiding introduction of bacterial and other foreign DNA into the fungi.
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.
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.
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