Pathogen-induced production of the antifungal AFP protein from Aspergillus giganteus confers resistance to the blast fungus Magnaporthe grisea in transgenic rice

Rice blast, caused by Magnaporthe grisea, is the most important fungal disease of cultivated rice worldwide. We have developed a strategy for creating disease resistance to M. grisea whereby pathogen-induced expression of the afp (antifungal protein) gene from Aspergillus giganteus occurs in transgenic rice plants. Here, we evaluated the activity of the promoters from three maize pathogenesis-related (PR) genes, ZmPR4, mpi, and PRms, in transgenic rice. Chimeric gene fusions were prepared between the maize promoters and the beta-glucuronidase reporter gene (gus A). Histochemical assays of GUS activity in transgenic rice revealed that the ZmPR4 promoter is strongly induced in response to fungal infection, treatment with fungal elicitors, and mechanical wounding. The ZmPR4 promoter is not active in the seed endosperm. The mpi promoter also proved responsiveness to fungal infection and wounding but not to treatment with elicitors. In contrast, no activity of the PRms promoter in leaves of transgenic rice was observed. Transgenic plants expressing the afp gene under the control of the ZmPR4 promoter were generated. Transformants showed resistance to M. grisea at various levels. Our results suggest that pathogen-inducible expression of the afp gene in rice plants may be a practical way for protection against the blast fungus. Most agricultural crop species suffer from a vast array of fungal diseases that cause severe yield losses all over the world. Rice blast, caused by the fungus Magnaporthe grisea (Herbert) Barr (anamorph Pyricularia grisea), is the most devastating disease of cultivated rice (Oryza sativa L.), due to its     

In vitro binding of the tomato bZIP transcriptional activator VSF-1 to a regulatory element that controls xylem-specific gene expression

The bean grp1.8 gene is specifically expressed in vascular tissue. Monomers and multimers of a 28 bp regulatory element of the grp1.8 promoter ( vs-1 ) specifically activated both the −82 CaMV 35S and the −76/ grp1.8 minimal promoters in vascular tissue of transgenic tobacco plants. vs-1 partially overlaps with a negative regulatory element in the grp1.8 promoter that is necessary for restriction of gene expression to vascular tissue. Nuclear extracts from tobacco and tomato cells contain a factor that binds to vs-1 in vitro . To study the molecular basis of xylem-specific expression mediated by the vs-1 promoter element, a gene was isolated from tomato encoding a protein that binds to vs-1 in vitro . This protein, designated VSF-1, contains a bZIP motif close to the C-terminus. Mutated vs-1 elements were no longer bound by VSF-1 and also failed to activate the minimal −82 CaMV 35S promoter in vivo . Transient expression of VSF-1 in protoplasts stimulated vs-1 dependent activation of the −76/ grp1.8 minimal promoter. Binding studies and use of a polyclonal antiserum against VSF-1 provided further evidence that vs-1 is a potential in vivo target site, as VSF-1 was a part of the observed complex formed between vs-1 and nuclear protein extract. vs-1 does not contain the 5'-ACGT-3' core sequence that is part of known plant bZIP protein binding sites or another palindromic sequence. Based on the unusual binding specificity and a characteristic amino acid sequence in the bZIP domain we propose that VSF-1 and the partially homologous PosF21, a bZIP protein from Arabidopsis , belong to a new family of plant bZIP proteins.     

Site-directed mutagenesis of the organ-specific element in the soybean leghemoglobin Ibc3 gene promoter

The expression of a soybean leghemoglobin 5' Ibc 3–GUS-3' nos chimeric gene was analyzed in Lotus corniculatus after site-specific mutagenesis of the nodulin consensus sequences, AAAGAT and CTCTT, present in the organ-specific element (OSE) (−139 to −102). Full-length promoters (−1956,+46) carrying clustered point mutations in the CTCTT sequence or in both the AAAGAT and the CTCTT sequences were inactive. Point mutations in the AAAGAT sequence had only minor effects on the expression level. Substitution of the ATTG sequence between the AAAGAT and the CTCTT sequences in the OSE reduced the activity in nodules to 10%. This, together with the conservation of the ATTGT sequence in the same position of leg-hemoglobin genes from other legumes, indicates that these sequences, in addition to the nodulin consensus sequences of the OSE, are important for high-level nodule-specific expression. Substitution of the CTCTT sequences outside the OSE (−44,−40 and −79,−75) results in promoter activities of approximately 50%.