Effects of sublethal doses of crop protection agents on honey bee (Apis mellifera) global colony vitality and its potential link with aberrant foraging activity.

Honey bees (Apis mellifera) are the most economically valuable pollinators of fruit crops worldwide. Taking into account bees' contributions to other flowering agricultural crops, about one-third of our total diet comes directly or indirectly from bee-pollinated plants. However, in recent years there increasingly have been worrisome alarm sounds on serious bee mortalities and mysterious disappearance of bees from beehives. Among several environmental factors (e.g. climate and bee pathogens), stress factors arising from agricultural practices can potentially play a role in bee losses. Detailed knowledge on the effects of plant protection products is essential to improve usage with minimal risks. In order to identify potential medium- and long-term effects, we followed up various sublethal contaminated hives during the prolongation of the fruit-growing season. More specifically, a large-scale experiment was conducted in which at four distinct locations (in the Limburg region of Belgium) four different bee colonies (representing three different contaminations -imidacloprid, fenoxycarb, indoxacarb- and a non-contaminated control hive) were thoroughly monitored every 2-7 days. Our observations point towards decays of overall colony vitality for several hives a couple of weeks after treatment, as indicated by a set of carefully assessed parameters including the total amount of active and dead bees, total surface of capped brood and overall colony weight. These outcomes could be linked to subtle differences in foraging activity between distinct hives. The implications of these results are discussed in terms of potential short-term and long-term consequences of disturbed foraging ability triggered by exaggerated exposure to sublethal doses of crop protection chemicals, and its potential impact on colony health.

Amfor expression in the honeybee brain: a trigger mechanism for nurse-forager transition.

The honeybee's colony fitness relies on an optimized age-dependent division of labor. Transition from nursing activities to foraging activities is associated with an increase in the expression of the Amfor gene. Ben-Shahar et al. [Ben-Shahar, Y., Robichon, A., Sokolowski, M.B., Robinson, G.E., 2002. Influence of gene action across different time scales on behavior. Science 296, 741-744] showed that the Amfor transcripts and their gene products are involved in regulating the transition from one task to the next. In this study, we investigated the trajectory of the expression of this gene in the brain over time. The expression pattern could contribute to our understanding of the involvement of Amfor in the transition process. Is there a gradual increase in transcript or a peak in expression triggering a downstream path of multiple differential gene expression? Hereto, bees were sampled from colonies containing marked 1-day-old bees every 2 or 3 days around the expected time of transition from nurse to forager, from day 13 to 25. To quantify Amfor transcript in the brain, we developed a real-time RT-PCR assay, based on Taqman technology, using fluorescent probes. Results revealed a trigger mechanism rather than a continued elevation of Amfor expression. The appearance of an Amfor expression peak suggests that under normal physiological conditions foraging behavior is, at least in part, due to a trigger-effect of Amfor.

Failure of the ammonia oxidation process in two pharmaceutical wastewater treatment plants is linked to shifts in the bacterial communities.

AIMS: To investigate whether two different wastewater treatment plants (WWTPs) -- treating the same pharmaceutical influent -- select for a different bacterial and/or ammonia oxidizing bacterial (AOB) community. METHODS AND RESULTS: Molecular fingerprinting demonstrated that each WWTP had its own total bacterial and AOB community structure, but Nitrosomonas eutropha and N. europea were dominant in both WWTP A and B. The DNA and RNA analysis of the AOB communities revealed different patterns; so the most abundant species may not necessarily be the most active ones. Nitritation failures, monitored by chemical parameter analysis, were reflected as AOB community shifts and visualized by denaturing gradient gel electrophoresis (DGGE)-based moving window analysis. CONCLUSIONS: This research demonstrated the link between functional performance (nitritation parameters) and the presence and activity of a specific microbial ecology (AOB). Clustering and moving window analysis based on DGGE showed to be valuable to monitor community shifts in both WWTPs. SIGNIFICANCE AND IMPACT OF THE STUDY: This study of specific community shifts together with functional parameter analysis has potential as a tool for relating functional instability (such as operational failures) to specific-bacterial community shifts.