Listening for faint rustling noises made by tasty beetles on a quiet day is simple for bats hunting with their exquisitely sensitive hearing. So try imagining what it must be like trying to locate rustling treats just metres from a roaring highway. It would seem to be almost impossible to pick out a centipede's footsteps as a juggernaut hurtles past; or is it? How animals that locate their prey by sound alone cope in our increasingly noisy world puzzles Björn Siemers from the Max Planck Institute for Ornithology in Germany. Siemers explains that no one had ever measured whether bats that hunt by listening for rustling insects are affected by man-made noise. However, this is a question that Siemers is frequently asked by urban planners keen to minimise our impact on local wildlife populations. Curious to know how sharp-eared bats react to loud background noise, Siemers and his colleagues Andrea Schaub and Joachim Ostwald monitored foraging bats' responses to rustling mealworms in noisy environments and publish their results on 19th September 2008 in The Journal of Experimental Biology on http://jeb.biologists.org.

Researchers led by Dr Robin Allaby of the University of Warwick's plant research arm Warwick HRI have found evidence that genetics supports the idea that the emergence of agriculture in prehistory took much longer than originally thought.

Three RND efflux systems had been identified in H pylori, namely hefABC, hefDEF, and hefGHI, each of which consisted of a translocase, an accessory protein. But the contribution of efflux proteins to antibiotic resistance is not well established. 27 putative translocases also had been identified in the H pylori 26695 genome, but only four putative H pylori OEPs or TolC homologs were identified. While they could not quantitate the operons expression levels of the efflux systems in multidrug resistance strains of H pylori.