First molecular detection of Mycobacterium bovis in environmental samples from a French region with endemic bovine tuberculosis.

AIMS: The aim of the study was to determine the prevalence of Mycobacterium bovis (the causative agent of bovine tuberculosis, bTB) in environmental matrices within a French region (Côte d'Or) affected by this zoonotic disease. METHODS AND RESULTS: We report here the development and the use of molecular detection assays based on qPCR (double fluorescent dye-labelled probe) to monitor the occurrence of Mycobacterium tuberculosis complex (MTBC) or Myco. bovis in environmental samples collected in pastures where infected cattle and wildlife had been reported. Three qPCR assays targeting members of the MTBC (IS1561' and Rv3866 loci) or Myco. bovis (RD4 locus) were developed or refined from existing assays. These tools were validated using Myco. bovis spiked soil, water and faeces samples. Environmental samples were detected positive for the presence of MTBC strains and Myco. bovis in the environment of bTB-infected farms in the Côte d'Or region. CONCLUSIONS: The development of molecular assays permitted testing of several types of environmental samples including spring water, sediment samples and soils from badger setts entrance located in the vicinity of these farms, which were repeatedly contaminated with Myco. bovis (up to 8·7 × 10(3) gene copies per gram of badger sett soil). For the first time, direct spoligotyping of soil DNA enabled identification of Myco. bovis genotypes from environmental matrices. SIGNIFICANCE AND IMPACT OF THE STUDY: All together, these results suggest that Myco. bovis occurs at low levels in environmental matrices in Côte d'Or within the bTB-infected area. Drinking contaminated water or inhaling contaminated bioaerosols might explain cattle infection in some cases.

Understanding the formation of new clusters of alkali and alkaline Earth metals: a new synthetic approach, single-crystal structures, and theoretical calculations.

A new synthetic approach, reacting alkaline earth metal iodides with butyllithium, lithium hydroxide, and/or lithium butoxide under salt elimination, is presented, giving access to some interesting clusters of calcium, strontium, and barium, partially in combination with lithium. The so far largest calcium cluster Li[[Ca(7)(mu(3)-OH)(8)I(6)(thf)(12)](2)(mu(2)-I)].3THF, 4, and the new strontium compound [Sr(3)I(3)(OH)(2)(thf)(9)]I, 5, are shown to feature common building blocks of OH-capped M(3) triangles. On the basis of mainly electrostatic interactions, these clusters are not volatile. By introducing LiO(t)Bu, the two clusters [IM(O(t)Bu)(4)[Li(thf)](4)(OH)] (6, M = Sr; 7, M = Ba) are prepared, 7 exhibiting volatility as an important physical property, which makes it a potential precursor for chemical vapor deposition. The structural relationship between 4, 5, 6, and 7 and their respective starting materials is shown, and possible reaction mechanisms are proposed. Exhibiting surprising and new structural motifs, the bonding modes of these clusters are investigated by the electron localization function as well as by ab initio calculations.