The suppression of plant defence reactions plays a crucial role in causing plant diseases. In this report, we show that inducible plant defences are repressed during the development of Cercospora leaf spot disease. In the early phase of infection of sugar beet (Beta vulgaris L.) leaves with the phytopathogenic fungus Cercospora beticola , a reduction in the expression of the phenylalanine ammonia lyase (BvPAL) and cinnamic acid 4-hydroxylase (BvC4H) genes was observed. BvPAL reduction was found at the transcript and enzyme activity levels. In order to analyse the signal transduction process responsible for suppression, the BvPAL promoter was isolated. An abbreviated 5'- and 3'- deletion series of the promoter was effected using transient biolistic assays, which showed that the activity of a truncated promoter from positions -34 to +246, relative to the transcriptional starting site, retains approximately 30 of the activity of the full-length promoter. The region within the BvPAL promoter required for the reduction in transcription was identified as being positions -34 to +45, with respect to the start of the transcription. This region is equivalent to the core promoter, characterised by the TATA-box, an initiator (Inr) and an unknown downstream element in the region between +7 and +45. These data indicate that (1) plant defence responses are repressed during the development of Cercospora leaf spot disease and (2) the PAL core promoter is involved in the detection of the repression signal.
Protoplasts have been isolated from leaves of shoot cultures of six dihaploid clones of Solanum tuberosum L. (2n = 2x = 24). In the KM medium (Kao and Michayluk 1975), sustained cell divisions were obtained in up to 50% of the plated protoplasts of four clones, whereas only a few divisions occurred in the other two clones. The first mitosis appeared 2–8 days after plating, dependent on the clones. In the clones showing sustained cell divisions, a protoplast titre of about 5 × 103 per ml turned out to be optimal. The culture conditions for protoplasts of one of the poorly growing clones, clone H2 140, have been improved using modified KM media, plating at a concentration of as high as 5 × 104 cells per ml, and subsequent diluting at intervals 5 days. The dilutions were carried out with media containing 0.25% agar. Up to 60% of the plated protoplasts underwent divisions within 10 days under these conditions. After about 15 days, the regenerants were transferred onto media inducing organogenesis. Shoots and roots were formed on modified media MS (Murashige and Skoog 1962) and B5 (Gamborg et al. 1968). Plants have been regenerated in four of the investigated clones. Countings of chromosomes revealed a satisfactory stability of the karyotype in shoot culture and protoplast regeneration.
Cercospora leaf spot disease, caused by the fungus Cercospora beticola, is the most destructive foliar disease of sugar beet (Beta vulgaris) worldwide. Despite the great agronomical importance of this disease, little is known about its underlying molecular processes. Technical resources are scarce for analyzing this important crop species. We developed a sugar beet microarray with 44,000 oligonucleotides that represent 17,277 cDNAs. During the four stages of C. beticola-B. vulgaris interactions, we profiled the transcriptional responses of three genotypes: susceptible, polygenic partial resistance, and monogenic resistant. Similar genes were induced in all three genotypes during infection but with striking differences in timing. The monogenic resistant genotype displayed strong defense responses at 1 day postinoculation (dpi). The other genotypes displayed defense responses in a later phase (15 dpi) of the infection cycle. The partially resistant genotype displayed a strong defense response in the late phase of the infection cycle. Furthermore, the partially resistant genotype expressed pathogen-related transcripts that the susceptible genotype lacked. These results indicate that resistance was achieved by the ability to mount an early defense response, and partial resistance was determined by additional defense and signaling transcripts that allowed effective defense in the late phase of the infection cycle.
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