Inhibition of fungal disease development in plants by engineering controlled cell death

We have tested a new strategy for engineering fungal disease resistance in crops which is based on inhibition of fungal growth and reproduction by controlled generation of necrotic lesions at infection sites, analogous to the naturally occurring hypersensitive cell death. The approach relies on the...

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Bibliographic Details
Published in:Bio/Technology 1995-10, Vol.13 (10), p.1085-1089
Main Authors: Strittmatter, Günter, Janssens, Jan, Opsomer, Chris, Botterman, Johan
Format: Article
Language:English
Subjects:
adn recombinado
adn recombine
Agriculture
bacillus
Bioinformatics
Biological and medical sciences
Biomedical and Life Sciences
Biomedical Engineering/Biotechnology
Biomedicine
Biotechnology
disease resistance
enzyme inhibitors
esporulacion
ethylene
etileno
Fundamental and applied biological sciences. Psychology
gene
gene transfer
genes
Genetic engineering
Genetic technics
genetic transformation
genetica
genetics
genetique
inhibicion
inhibidores de enzimas
inhibiteur d' enzyme
inhibition
Life Sciences
Methods. Procedures. Technologies
necrose
necrosis
pathogenese
pathogenesis
patogenesis
Phytophthora infestans
plantas transgenicas
plante transgenique
proteinas
proteine
proteins
recombinant dna
resistance aux maladies
resistencia a la enfermedad
ribonucleasas
ribonuclease
ribonucleases
solanum
Solanum tuberosum
sporulation
transferencia de genes
transfert de gene
transformacion genetica
transformation genetique
Transgenic animals and transgenic plants
Transgenic plants
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Summary:We have tested a new strategy for engineering fungal disease resistance in crops which is based on inhibition of fungal growth and reproduction by controlled generation of necrotic lesions at infection sites, analogous to the naturally occurring hypersensitive cell death. The approach relies on the use of two chimeric genes. On the one hand, a promoter fragment of the potato prp1-1 gene which mediates rapid and localized transcriptional activation selectively in response to pathogen attack is used to drive the expression of the bacterial ribonuclease, barnase. On the other hand, transgenic plants express barstar, a specific inhibitor of barnase, to minimize the detrimental effects of potential background barnase synthesis in non-infected tissue. Sporulation of the late-blight fungus Phytophthora infestans was considerably reduced on leaves from transgenic potato lines harboring this two-component system. Treatment of leaves from such plants with ethylene, a chemical stimulus of prp1-1 promoter activity, resulted in rapid tissue destruction, indirectly indicating the inducibility and action of barnase. Furthermore, the reduction of fungal sporulation cosegregated with the transgenes in an F1 population.
ISSN:0733-222X
2331-3684
1546-1696
DOI:10.1038/nbt1095-1085