Safe Use of Replicating Bacteria in Biological Control

Naturally occurring entomopathogenic bacteria provide an important resource for pest control. Greatest benefit will be obtained from the application of replicating bacteria which can establish in the host's environment and provide long term control. Bacteria developed for pest control are required to be safety tested and registered, yet bacteria are frequently introduced into the environment to enhance plant growth or aid soil processes without regulation. Why then, is the use of insect pathogenic bacteria treated differently? Augmentation of bacteria already present in the environment is unlikely to have any unwanted side effects as application is only changing the spatial and temporal distribution of the microbe and will have little long term effect on the total population. Users of the bacteria, however, will be exposed to the bacterium at a level higher than experienced naturally and potential adverse effects of this interaction should be addressed through Tier 1 safety testing. Non-target organisms should also be tested. If new organisms (exotic strains or modified bacteria) are to be introduced to the environment, their potential effects on the environment should be considered. The question of horizontal gene flow from applied bacteria also needs to be addressed. A better understanding of microbial ecology and Systems for tracking new strains and genes are essential to develop appropriate assessment procedures to ensure the safe utilisation of bacteria in biological control

Desempenho de Trichogramma pratissolii Querino & Zucchi (Hymenoptera, Trichogrammatidae) em ovos de Anagasta kuehniella (Zeller) (Lepidoptera, Pyralidae) sob efeito de Bacillus thuringiensis Berliner

Visando estudar o efeito da bactéria entomopatogênica Bacillus thuringiensis (Bt) sobre fêmeas adultas de Trichogramma pratissolii e sua progênie, este trabalho foi realizado com diferentes isolados de Bt e Bt kurstaki misturados ao alimento fornecido para o parasitóide antes de parasitar ovos de Anagasta kuehniella. Para tanto, suspensões de seis isolados de Bt E-3, E-10, E-15, E-16, E-19, E-20 e o Bt kurstaki foram misturados em gotícula de mel (1:1), como fonte de alimento e mel puro como testemunha, e, em seguida, foram oferecidos simultaneamente cartelas com ovos do hospedeiro para o parasitismo. Foram utilizadas 20 repetições por tratamento. O experimento foi mantido em câmara climatizada a 25 ? 1masculineC, UR 70 ? 10% e fotofase de 14h. Foram avaliados os parasitismos diários, totais e acumulados; sobrevivência; emergência e razão sexual da progênie. Os tratamentos não afetaram o parasitismo, razão sexual e a longevidade, porém em alguns tratamentos (E-3, E-10, E-16 e E-20) foi observado efeito indireto sobre a emergência da progênie, o que implicaria a necessidade de mais liberações massais do parasitóide para alcançar os resultados esperados. Por outro lado, a aceleração do parasitismo verificada em todos os tratamentos sugere que adultos de T. pratissolii, quando submetidos à pressão de algum fator externo tendem a parasitar o mais rápido possível para assegurar a sobrevivência da progênie. Portanto, a combinação Bt + T. pratissolii pode favorecer a atuação do parasitóide em campo, principalmente em casos em que é necessária uma rápida redução dos níveis populacionais da praga

Impacts of transgenic plants and microorganisms on soil biota

Little is known about the impacts of transgenic plants and microorganisms on soil biota and processes despite the large number of field releases of transgenic crops Recent work has shown that transgenic plants can cause changes in the soil biota (both invertebrates and microorganisms) associated with these plants Often the changes are transient but their impact on the soil ecosystem remains unknown Horizontal gene transfer from genetically modified (GM) bacteria to indigenous soil bacteria has been demonstrated but movement of genes from transgenic plants if it occurs at all has not yet been detected in natural systems Soil invertebrates appear to play an important role in horizontal gene transfer between bacteria in soil</jats:p

New records of entomophthoran fungi from insects in Australia

Five species of entomophthoran fungi (Zygomycetes: Entomophthoraceae) are described from Australian insect populations for the first time. Two species, Entomophthora muscae and Erynia bullata, were found attacking Diptera; one species, Neozygites parvispora, was found attacking thrips; and two others, Entomophaga aulicae and Erynia gammae (recombined from Tarichium) were found on Lepidoptera