Development of a molecular marker specific to a novel CMS line in radish (Raphanus sativus L.).

In this study, we have investigated the cytoplasmic male sterility (CMS) of a novel male sterile radish line, designated NWB CMS. The NWB CMS was crossed with 16 fertile breeding lines, and all the progenies were completely male sterile. The degree of male sterility exhibited by NWB CMS is more than Ogura CMS from the Cruciferae family. The NWB CMS was found to induce 100% male sterility when crossed with all the tested breeding lines, whereas the Ogura CMS did not induce male sterility with any of the breeding lines. PCR analysis revealed that the molecular factor that influenced Ogura CMS, the orf138 gene, was absent in the NWB CMS line, and that the orf138 gene was not also expressed in this CMS line. In order to identify the cytoplasmic factors that confer male sterility in the NWB CMS line, we carried out RFLP analyses with 32 mitochondrial genes, all of which were used as probes. Fourteen genes exhibited polymorphisms between the NWB CMS line and other radish cultivars. Based on these RFLP data, intergenic primers were developed in order to amplify the intergenic regions between the polymorphic genes. Among these, a primer pair at the 3' region of the atp6 gene (5'-cgcttggactatgctatgtatga-3') and the 5' region of the nad3 gene (5'-tcatagagaaatccaatcgtcaa-3') produced a 2 kbp DNA fragment as a result of PCR. This DNA fragment was found to be specific to NWB CMS and was not present in other CMS types. It appears that this fragment could be used as a DNA marker to select NWB CMS line in a radish-breeding program.

Transgenic watermelon rootstock resistant to CGMMV (cucumber green mottle mosaic virus) infection.

In watermelon, grafting of seedlings to rootstocks is necessary because watermelon roots are less viable than the rootstock. Moreover, commercially important watermelon varieties require disease-resistant rootstocks to reduce total watermelon yield losses due to infection with viruses such as cucumber green mottle mosaic virus (CGMMV). Therefore, we undertook to develop a CGMMV-resistant watermelon rootstock using a cDNA encoding the CGMMV coat protein gene (CGMMV-CP), and successfully transformed a watermelon rootstock named 'gongdae'. The transformation rate was as low as 0.1-0.3%, depending on the transformation method used (ordinary co-culture vs injection, respectively). However, watermelon transformation was reproducibly and reliably achieved using these two methods. Southern blot analysis confirmed that the CGMMV-CP gene was inserted into different locations in the genome either singly or multiple copies. Resistance testing against CGMMV showed that 10 plants among 140 T1 plants were resistant to CGMMV infection. This is the first report of the development by genetic engineering of watermelons resistant to CGMMV infection.

PPI1: a novel pathogen-induced basic region-leucine zipper (bZIP) transcription factor from pepper.

We have isolated a full-length cDNA, PPI1 (pepper-PMMV interaction 1), encoding a novel basic region-leucine zipper (bZIP) DNA-binding protein, from expressed sequence tags differentially expressed in Capsicum chinense P1257284 infected with Pepper mild mottle virus (PMMV). PPI1 encodes a predicted protein of 170 amino acids and contains a putative DNA-binding domain that shares significant amino acid identity with ACGT-binding domains of members of the bZIP DNA-binding protein family. PPI1 was localized in the nucleus and had transcriptional activation activity in yeast. Transcripts of the PPI1 gene were preferentially induced during an incompatible interaction by inoculation with PMMV, Pseudomonas syringae pv. syringae 61, and Xanthomonas campestris pv. vesicatoria race 3. However, the PPII gene was not induced by abiotic stressors that activate the plant defense-signaling pathway. Our data provide the first evidence that a bZIP transcription factor is preferentially induced by pathogen attack, suggesting that PPI1 may play a specific functional role in the regulation of expression of plant defense-related genes.