A new strategy for generating geminivirus resistant plants using a DNA betasatellite/split barnase construct.

The betasatellite DNA associated with cotton leaf curl disease contains a single ORF, ßC1, which is a pathogenicity determinant. Deletion of the ßC1 ORF showed that it was not required for betasatellite replication in the presence of Tomato leaf curl virus-Australia (TLCV-Au). A series of betasatellite/split mutant barnase gene constructs, in which a direct repeat of the Bacillus amyloliquefaciens barnase gene flanked the betasatellite, were shown to replicate in tobacco in the presence of TLCV-Au. A betasatellite/split intact barnase gene construct, with the optimal direct repeat unit of the barnase gene, was introduced into Nicotiana tabacum plants. Approximately one third of the transgenic lines containing the betasatellite/split barnase gene constructs were shown to be completely resistant to the TLCV-Au infection. The betasatellite/split intact barnase gene cassette ensures that there is no expression of the barnase in the absence of TLCV-Au, but upon infection of the cell with the virus, release of the betasatellite/split barnase cassette as a replicating molecule resulting in the reconstitution and expression of an active barnase gene and the destruction of the infected cell. This system offers the potential to provide resistance in a variety of plant species against geminiviruses that support the replication of betasatellite.

Tomato leaf curl virus satellite DNA as a gene silencing vector activated by helper virus infection.

Tomato leaf curl virus (TLCV) satellite DNA (sat-DNA) constructs containing functional segments of the cauliflower mosaic virus (CaMV) 35S promoter, replicate in tobacco in the presence of helper TLCV and silence GUS activity in transgenic tobacco plants containing a CaMV 35S-GUS expression cassette. We have analysed these plants for evidence of the hallmarks of silencing. The GUS transcript was not detectable in the leaves of GUS-silenced tobacco plants. These plants contained siRNAs of approximately 23 nt in length homologous to both the 35S promoter region and the GUS ORF. The absence of GUS expression and the existence of siRNAs in transgenic plants show that the silencing induced by TLCV sat-DNA is due to RNA silencing. To test the utility of this silencing system, a 341 nucleotide promoter sequence of the petunia chalcone synthase A (ChsA) was inserted into the sat-DNA and inoculated into petunia plants, together with the helper TLCV, and found to markedly reduce pigmentation of flowers and the level of ChsA transcript. This DNA-based silencing system has the potential to introduce epigenetic traits via short DNA inserts to a variety of plants that are hosts to different geminiviruses supporting the sat-DNA.