Activity of Metarhizium brunneum and Beauveria bassiana against early developmental stages of the false codling moth Thaumatotibia leucotreta.

This study evaluated the efficacy of two entomopathogenic Hypocrealean fungi, Metarhizium brunneum (laboratory isolate) and Beauveria bassiana (the commercial product Botanigard), for preventative control of the false codling moth, Thaumatotibia leucotreta. The mortality of eggs and first instar larvae was studied in three different assays. First, fungal virulence was examined under optimal laboratory conditions (25 °C, 85% RH) by placing T. leucotreta eggs on conidia-impregnated filter paper. One-day-old eggs and first instar larvae were susceptible to both fungi. In contrast, 5-day-old eggs (advanced embryo development) were susceptible to M. brunneum, but not to B. bassiana. The activity of both fungi against eggs was assessed under two humidity regimes: 85% RH-optimal for fungal germination, and 60% RH-the average humidity in the laboratory. Pieces of parchment paper serving as oviposition surfaces were treated with each of the fungi and introduced to gravid females at different time points after inoculation (0, 2, 7 and 14 days). Although the tested fungal species differed in their virulence to T. leucotreta eggs, both reduced hatching rate under both humidity regimes to 8.3-58.3%, compared to 71.7-83.3% in the control treatments. To evaluate reduction of T. leucotreta infestation of fruit, 'Ori' citrus fruit (easy peeler Citrus sinensis) were treated with each of the fungi. Eggs were placed on the fruit peels and the fruit were maintained under room conditions (25 °C, 60% RH). Between 41.7% and 54.1% of fruit in control groups were infested by the T. leucotreta larvae. Treatments with either of the fungi resulted in about 16% infestation of the fruit with larvae, a marked (3.3-fold) reduction.

Single Cell Encapsulation via Pickering Emulsion for Biopesticide Applications.

A new approach for single cell microencapsulation in an oil-in-water (o/w) Pickering emulsion is presented. The water/paraffin emulsions were stabilized by amine-functionalized silica nanoparticles. The droplet size of the emulsions was highly tunable, and ranged from 1 to 30 µm in diameter. The controllable droplet size along with the high colloidal stability of the Pickering emulsionswas harnessed to obtain single cell microencapsulation. Successful encapsulation of the conidia entomopathogenic fungus Metarhizium brunneum by the studied Pickering emulsions was confirmed via confocal laser scanning microscopy. The resulting systems were implemented to develop a novel biopesticide formulation for arthropod pest control. The conidia incorporated in the emulsions were applied to Ricinus communis leaves by spray assay. After drying of the emulsion, a silica-based honeycomb-like structure with an ordered hierarchical porosity is formed. This structure preserves the individual cell encapsulation. The successful single cell encapsulation has led to a high distribution of conidia cells on the leaves. The Pickering emulsion-based formulation exhibited significantly higher pest control activity against Spodoptera littoralis larvae compared to the control systems, thus making it a promising, cost-effective, innovative approach for tackling the pest control challenge.

Development of synchronized, autonomous, and self-regulated oscillations in transpiration rate of a whole tomato plant under water stress.

Plants respond to many environmental changes by rapidly adjusting their hydraulic conductivity and transpiration rate, thereby optimizing water-use efficiency and preventing damage due to low water potential. A multiple-load-cell apparatus, time-series analysis of the measured data, and residual low-pass filtering methods were used to monitor continuously and analyse transpiration of potted tomato plants (Solanum lycopersicum cv. Ailsa Craig) grown in a temperature-controlled greenhouse during well-irrigated and drought periods. A time derivative of the filtered residual time series yielded oscillatory behaviour of the whole plant's transpiration (WPT) rate. A subsequent cross-correlation analysis between the WPT oscillatory pattern and wet-wick evaporation rates (vertical cotton fabric, 0.14 m(2) partly submerged in water in a container placed on an adjacent load cell) revealed that autonomous oscillations in WPT rate develop under a continuous increase in water stress, whereas these oscillations correspond with the fluctuations in evaporation rate when water is fully available. The relative amplitude of these autonomous oscillations increased with water stress as transpiration rate decreased. These results support the recent finding that an increase in xylem tension triggers hydraulic signals that spread instantaneously via the plant vascular system and control leaf conductance. The regulatory role of synchronized oscillations in WPT rate in eliminating critical xylem tension points and preventing embolism is discussed.