Differentially expressed cDNAs in Alternaria alternata treated with 2-propenyl isothiocyanate

The molecular mechanism of the fungal tolerance phenotype to fungicides is not completely understood. This knowledge would allow for the development of environmentally friendly strategies for the control of fungal infection. With the goal of determining genes induced by 2p-ITC, a forward suppressive subtractive hybridization was performed using cDNAs from ITC-treated Alternaria alternata as a “tester” and from untreated fungus as a “driver.” Using this approach, a library containing 102 ESTs was generated that resulted in 50 sequences after sequence assembly (17 contigs and 33 singletons). Blastx analysis revealed that 38% and 40% of the sequences showed significant similarity with known and hypothetical proteins, respectively, whereas 18% were not similar to known genes. These last sequences could represent novel genes that play an unknown role in the molecular responses of fungi during adaptation to 2p-ITC. Clones similar to opsins, ABC transporters, calmodulin, ATPases and SNOG proteins were identified. Using real-time RT-PCR analysis, significant inductions of an ABC transporter and a Ca⁺⁺ ATPase during 2p-ITC treatment were discovered. These results suggest that the fungal resistance phenotype to 2p-ITC involves calcium ions and 2p-ITC efflux via an ABC transporter.     

Changes in Phenolic Acid Content During Alternaria alternata Infection in Tomato Fruit

Phenolic acids are components of the plant defence system; however few studies had been done with fruits. The objective of this experiment was to elucidate the changes in phenolic acid content in tomato fruits in response to pathogenic attack. Tomato fruit ‘Pinto’ was inoculated with spores of Alternaria alternata and stored for 10 days at 25°C and 90–92% of relative humidity. Sampling of epicarp and mesocarp tissues of control and infected tomato fruits were done every 2 days. Phenolic acids were extracted from each tissue and identified by HPLC coupled to a mass spectrometer. Quantification was done based in standard curves. In vitro evaluation of the phenolic acid effect either one‐by‐one and in a mixture of phenolic acids (MPA) over A. alternata spore germination was done with 25, 50, 100, 200 and 500 mm . It was found caffeic, chlorogenic and vanillic acids in both epicarp and mesocarp tomato tissues before the beginning of the experiment. Infected tomato fruits showed significantly higher concentrations of vanillic acid in the epicarp, only. Chlorogenic acid and the MPA inhibit spore germination by 30%, whereas caffeic acid and vanillic acid inhibit 16% at 500 mm . It was concluded that chlorogenic, vanillic and caffeic acids are phytoanticipins in tomato fruit. The concentration of vanillic acid also increases in tomato fruit epicarp as part of the defence system during a pathogenic attack.     

Induction of Enzymes and Phenolic Compounds Related to the Natural Defence Response of Netted Melon Fruit by a Bio-elicitor

Fungal disease in netted melon fruit is an important factor affecting their postharvest quality and therefore an important cause of large economic losses around the world. Among the alternatives to control fungal diseases, the induction of the natural defence response (NDR) in fruits is promising. The objective of this study was to induce the NDR in netted melon treated with a bio-elicitor formulated from Fusarium oxysporum growth in a potato dextrose agar enriched with netted melon skin. Netted melon fruits (cv 'Primo') were not treated (C), untreated and inoculated with F. oxysporum (IN), treated with a bio-elicitor (FES), or treated with the bio-elicitor and inoculated (FES + IN). After treatments, fruits were stored for 8 days at 20°C with 90–92% relative humidity. Melon was sampled every 2 days at 20°C to evaluate the development of Fusarium rot symptoms as disease index percentage (DI), changes in phenolic compounds, changes in phenylalanine ammonia-lyase (PAL) activity, chitinase activity (ChA) and β-1,3-glucanase activity (GA). It was found that DI in netted melon fruit was significantly reduced in the FES + IN as compared with the IN treatment. FES + IN and FES treatments showed the highest increase of phenolic acids. Higher levels of PAL activity were observed in the treatments IN, FES, and FES + IN with respect to C, after 4 days of storage. A large increase in ChA activity was observed in the treatments IN, FES and FES + IN after 6 days of storage. No differences in GA activity were found among FES, FES + IN and C treatments throughout storage. IN treatment showed the highest increase in GA activity after 4 days of storage. It is concluded that the bio-elicitor activates the NDR as measured by the increase in phenolic acids synthesis, PAL and ChA enzymes activity, in a similar way as the infection by the living pathogen.     

Utilization of Caffeic Acid Phenethyl Ester to Control Alternaria alternata Rot in Tomato (Lycopersicon esculentum Mill.) Fruit

Chemical fungicides that are related with resistant strains develop negative effects on human health and environment. Propolis is a resinous substance collected by bees with positive effects on human health and inhibitory activity against Alternaria alternata. Caffeic acid phenethyl ester (CAPE) is a component of the propolis. The objective of this experiment was to test the effect of CAPE on fungi infecting tomato fruit using as a model the pathosystem A. alternata‐tomato. CAPE was chemically synthesized in our laboratory and analysed with nuclear magnetic resonance spectroscopy. Different concentrations (0, 16, 32, 48, 64, 80, 90 and 100 μm ) of CAPE were tested on A. alternata growing in vitro. For the in vivo experiment, red ripe tomato fruit was inoculated with A. alternata and untreated or treated with 1, 50 and 100 μm of CAPE. After that, the fruit was stored at 25°C for up to 20 days. Colony size (CS) was recorded in vitro. In tomato fruits, the severity of infection (SI), respiration rate (RR), ethylene production (EP), pH, total soluble solids (TSS), weight loss (WL) and titratable acidity (TA) were evaluated during the storage time. CAPE melting point and spectral data probed to be the right molecule. In vitro, 64 and 100 μm of CAPE reduced CS by 30%. In vivo, 50 and 100 μm of CAPE reduced SI higher than the fungicide Captan^® with no effects on RR, EP, WL, pH, TSS and TA. It was concluded that CAPE controls A. alternata infection better than a commercial fungicide without negative effects on tomato fruit ripening and fruit quality.