Responses of diamondback moth to diverse entomopathogenic fungi collected from non-agricultural habitats - Effects of dose, temperature and starvation.

We evaluated the virulence of Beauveria bassiana and Metarhizium isolates from soil collected across different vegetation types in Queensland, against chlorantraniliprole-resistant and insecticide-susceptible diamondback moth (DBM) larvae. Host insecticide resistance status had no effect on susceptibility to the pathogens when conidia were topically applied to larvae in the laboratory, and one B. bassiana isolate was significantly more virulent to larvae than the others (seven days after inoculation). The influence of temperature (15, 20, 25 or 30 °C): (i) at the point of host inoculation with conidia and (ii) when the pathogens had already initiated infection and were proliferating in the host haemocoel, was determined experimentally for its influence on virulence, disease progression, and sporulation. Temperature at inoculation had a greater effect on host insect mortality than it did when the fungus was already proliferating in the host haemocoel. The rearing temperature of hosts prior to inoculation had a greater effect on host susceptibility to disease than starvation of the larvae at the time of inoculation. Our results also show that each fungal isolate has its own temperature relations and that these can vary considerably across isolates, and at different points in the pathogen life cycle (germination and cuticular penetration versus growth in the host haemocoel). Temperature also had an idiosyncratic effect, across isolates and across the variables typically used to assess the potential of fungal entomopathogens as biological control agents (time to death, mortality and sporulation rates). This study demonstrates that in addition to pathogenicity and virulence, the temperature relationships of each fungal isolate when infecting insects needs to be taken into account if we are to understand their ecology and use them effectively in pest management.

Arsenic and its compounds in mushrooms: A review.

The purpose of this article is to review the detail concentration of arsenic in some species of mushrooms as well as organic and inorganic forms of arsenic in the substrates where wild and cultivated edible mushrooms grow. We also briefly review the molecular forms of arsenic in mushrooms. There is still a lack of experimental data from the environment for a variety of species from different habitats and for different levels of geogenic arsenic in soil. This information will be useful for mushrooms consumers, nutritionists, and food regulatory agencies by describing ways to minimize arsenic content in edible mushrooms and arsenic intake from mushroom meals.