Filippo De Curtis

Resistance of Postharvest Biocontrol Yeasts to Oxidative Stress: A Possible New Mechanism of Action

ABSTRACT We detected the generation of the reactive oxygen species (ROS) superoxide anion ( O.(-) (2)) and hydrogen peroxide (H(2)O(2)) in apple wounds 2 immediately after wounding, and assessed the relationships between (i) timely colonization of apple wounds by biocontrol yeasts, (ii) resistance of these microorganisms to oxidative stress caused by ROS, and (iii) their antagonism against postharvest wound pathogens. We analyzed a model system consisting of two yeasts with higher (Cryptococcus laurentii LS-28) or lower (Rhodotorula glutinis LS-11) antagonistic activity against the postharvest pathogens Botrytis cinerea and Penicillium expansum. LS-28 exhibited faster and greater colonization of wounds than LS-11. In contrast to LS-28, the number of LS-11 cells dropped 1 and 2 h after application, and then increased only later. In vitro, LS-28 was more resistant to ROS-generated oxidative stress. The combined application of biocontrol yeasts and ROS-deactivating enzymes in apple wounds prevented the decrease in number of LS-11 cells mentioned above, and enhanced colonization and antagonistic activity of both biocontrol yeasts against B. cinerea and P. expansum. Polar lipids of LS-11 contained the more unsaturated and oxidizable alpha-linolenic acid, which was absent in LS-28. Resistance to oxidative stress could be a key mechanism of biocontrol yeasts antagonism against postharvest wound pathogens.

Activity of the Yeasts Cryptococcus laurentii and Rhodotorula glutinis Against Post-harvest Rots on Different Fruits

More than 200 yeasts were selectively isolated from microbial populations on the surface of different fruits. Fifty of these isolates were tested against blue mould ( Penicillium expansum ) on wounded apples. Isolates LS-11 of Rhodotorula glutinis and LS-28 of Cryptococcus laurentii were the most effective antagonists. They were further evaluated at 20IC on different fruits (apples, pears, strawberries, kiwi fruits and table grapes) against several of the main post-harvest pathogens ( Botrytis cinerea, Penicillium expansum, Rhizopus stolonifer and Aspergillus niger ) and at 4IC on apples inoculated with P. expansum . At 20IC the antagonists significantly reduced rot incidence and showed a wide range of activity on different hostpathogen combinations; isolate LS-28 exhibited a higher and more stable activity than LS-11. Both yeasts were also effective against P. expansum in cold storage conditions. Populations of the two yeasts were assessed on wounded and unwounded surfaces of apples kept at both 20 and 4...

Effect of the Biocontrol Yeast Rhodotorula glutinis Strain LS11 on Patulin Accumulation in Stored Apples.

ABSTRACT Contamination of apples (Malus domestica) and derived juices with fungicide residues and patulin produced by Penicillium expansum are major issues of food safety. Biocontrol agents represent an alternative or supplement to chemicals for disease control. Our data show that these microbes could also contribute to actively decreasing patulin accumulation in apples. Three biocontrol agents, Rhodotorula glutinis LS11, Cryptococcus laurentii LS28, and Aureobasidium pullulans LS30, were examined for their in vitro growth in the presence of patulin and for their capability to decrease mycotoxin recovery from the medium. Strain LS11 yielded the highest growth rates and the greatest decrease of toxin recoveries. Further, it caused the appearance of two major spots on thin-layer chromatography (TLC) plates, suggesting possible metabolization of the mycotoxin. In vivo, i.e., in the low percentage of LS11-pretreated apples infected by P. expansum, patulin accumulation was significantly lower than in nontreated infected fruits. Yeast cells survived and increased in infected apples and, in a model system emulating decaying apple, resulted in accelerated breakdown of patulin and the production of the same TLC spots as those detected in vitro. These data suggest that biocontrol yeast cells surviving in decaying apples could metabolize patulin and/or negatively affect its accumulation or synthesis. To our knowledge, this is the first report describing the effect of a biocontrol agent on patulin accumulation in vivo.

Integrated control of apple postharvest pathogens and survival of biocontrol yeasts in semi-commercial conditions

The biocontrol yeast isolates Rhodotorula glutinis LS11, Cryptococcus laurentii LS28 and Aureobasidium pullulans LS30 were tested against Botrytis cinerea and Penicillium expansum on apples artificially inoculated and stored at 3 and 20 °C. Isolates LS28 and LS30 were most effective, consistently resulting in high reductions of fungal decay, while isolate LS11 was effective only on apples stored at 3 °C. The yeasts showed good in vitro resistance to dicarboximides and copper fungicides, while they were inhibited by triazoles. Isolate LS11, in contrast to LS28 and LS30, was also inhibited by benzimidazoles. The yeasts were tested on naturally-infected apples in semi-commercial conditions for 2 years. They were applied twice: soon after harvesting and 20 days later, at the beginning of the cold storage. The antagonists significantly reduced fungal decay when combined with a low dosage of benomyl showing an activity comparable to that exerted by the fungicide alone at full dosage. Periodical monitoring of the epiphytic biocontrol yeast populations in both the field and cold room showed a good rate of survival of the antagonists on the skin of treated apples. Specific fingerprints relying on amplified restriction length polymorphism (AFLP) were used to integrate the morphology-based monitoring of the yeasts.

Rapid Assessment of Gray Mold (Botrytis cinerea) Infection in Grapes with a Biosensor System

Botrytis cinerea is the causative agent of gray mold disease, which causes considerable economic losses to winemakers. The extent of gray mold infection of winegrapes is commonly visually estimated, a method that is prone to assessor bias. Here, we used rapid and simple enzyme-based screening consisting of carbon-electrode, screen-printed amperometric biosensors to estimate gluconic acid and glycerol concentration in winegrapes infected with different degrees of B. cinerea. The lower limits of quantification of the screen-printed amperometric biosensors were 3 mg/L for gluconic acid (corresponding to an infection rate of less than 1%) and 35 mg/L for glycerol; the response times with a flow rate of 0.5 mL/min were in a range of 0.5 to 2 min in the linear ranges of the two assays. This study demonstrates the efficacy of amperometric biosensors for rapid analysis of gluconic acid and glycerol in grapes. The measurements confirmed that concentrations of both compounds are highly correlated with the rate of B. cinerea infection (R2 = 0.98). Thus, the biosensor developed to measure gluconic acid in grapes (or must) was more precise and gave a faster response than methods that currently exist for determining the rate of B. cinerea infection of grape berries.