Botrytis blight (gray mold), caused by Botrytis cinerea, is one of the most widely distributed diseases of ornamental plants. In geranium plants, gray mold is responsible for important losses in production. The mold Aspergillus giganteus is known to produce and secrete a basic low-molecular-weight protein, the antifungal protein (AFP). Here, the antifungal properties of the Aspergillus AFP against various B. cinerea isolates obtained from naturally infected geranium plants were investigated. AFP strongly inhibited mycelial growth as well as conidial germination of B. cinerea. Microscopic observations of fungal cultures treated with AFP revealed reduced hyphal elongation and swollen hyphal tips. Washout experiments in which B. cinerea was incubated with AFP for different periods of time and then washed away revealed a fungicidal activity of AFP. Application of AFP on geranium plants protected leaves against Botrytis infection. Cecropin A also was active against this pathogen. An additive effect against the fungus was observed when AFP was combined with cecropin A. These results are discussed in relation to the potential of the afp gene to enhance crop protection against B. cinerea diseases.
Passage of cucumber necrosis virus (CNV) containing defective interfering (DI) RNAs through cucumber plants decreased the accumulation of DI RNAs to undetectable levels. Subsequent passages in two Nicotiana species (Nicotiana benthamiana or N. clevelandii) resulted in the appearance of DI RNA species that were larger than the DI RNAs observed during exclusive serial passages of CNV through the Nicotiana species. Sequence analysis of cloned cDNAs corresponding to the two DI RNA populations indicated that the smaller CNV-DI RNAs contained the four conserved regions (I through IV) of the genome typical of tombusvirus DI RNAs, whereas the larger DI RNAs were of similar organization but had a direct repeat of the middle portion of the molecule. This result suggests that the host has an influence on the type of DI RNA that accumulates during consecutive high multiplicity of infection passages. A comparative analysis of deletions targeting the individual conserved regions in both CNV and tomato bushy stunt virus (TBSV) DI RNAs revealed that only region III was completely dispensable for accumulation of either DI RNA species. More refined deletion analyses in regions I and II indicated that smaller segments of 75 and 35 nucleotides (nt), respectively, could be deleted without abolishing infectivity. The dispensable sequences in region II of both TBSV and CNV DI RNAs mapped to the top portion of a putative stem-loop structure. These studies indicate that both essential and nonessential sequences are conserved in DI RNAs. The essential sequences in regions I, II, and IV likely contain important cis-acting elements, whereas nonessential regions such as region III may play secondary roles such as optimally spacing cis-acting elements or maintaining the DI RNA at an overall size that is stable.
Nicotiana benthamiana plants transformed with the coat protein gene of tomato bushy stunt virus (TBSV) failed to elicit effective virus resistance when inoculated with wildtype virus. Subsequently, R1 and R2 progeny from 13 transgenic lines were inoculated with a TBSV mutant containing a defective coat protein gene. Mild symptoms typical of those elicited in nontransformed plants infected with the TBSV mutant initially appeared. However, within 2 to 4 weeks, up to 20% of the transgenic plants sporadically began to develop the lethal syndrome characteristic of wild-type virus infections. RNA hybridization and immunoblot analyses of these plants and nontransformed N. benthamiana inoculated with virus from the transgenic lines indicated that wild-type virus had been regenerated by a double recombination event between the defective virus and the coat protein transgene. Similar results were obtained with a TBSV deletion mutant containing a nucleotide sequence marker, and with a chimeric cucumber necrosis virus (CNV) containing the defective TBSV coat protein gene. In both cases, purified virions contained wild-type TBSV RNA or CNV chimeric RNA derived by recombination with the transgenic coat protein mRNA. These results thus demonstrate that recombinant tombus-viruses can arise frequently from viral genes expressed in transgenic plants.
Despite the fact that around 200 cry genes from Bacillus thuringiensis have already been cloned, only a few Cry proteins are toxic towards a given pest. A crucial step in the mode of action of Cry proteins is binding to specific sites in the midgut of susceptible insects. Binding studies in insects that have developed crossresistance discourage the combined use of Cry proteins sharing the same binding site. If resistance management strategies are to be implemented, the arsenal of Cry proteins suitable to control a given pest may be not so vast as it might seem at first. The present study evaluates the potential of B. thuringiensis for the control of a new pest, the geranium bronze (Cacyreus marshalli Butler), a butterfly that is threatening the popularity of geraniums in Spain. Eleven of the most common Cry proteins from the three lepidopteran-active Cry families (Cry1, Cry2, and Cry9) were tested against the geranium bronze for their toxicity and binding site relationships. Using 125 I-labeled Cry1A proteins we found that, of the seven most active Cry proteins, six competed for binding to the same site. For the long-term control of the geranium bronze with B. thuringiensis-based insecticides it would be advisable to combine any of the Cry proteins sharing the binding site (preferably Cry1Ab, since it is the most toxic) with those not competing for the same site. Cry1Ba would be the best choice of these proteins, since it is significantly more toxic than the others not binding to the common site.
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