SUMMARYThe endocannabinoid system plays a central role in retrograde synaptic communication, and controls both glutamatergic and c-aminobutyric acid (GABA)ergic transmission via type 1 cannabinoid (CB1) receptor. Both in sclerotic human hippocampi and in the chronic phase of pilocarpineinduced epilepsy in mice with sclerosis, CB1-receptor-positive interneuron somata were preserved both in the dentate gyrus and in the CA1 area, and the density of CB1-immunostained fibers increased considerably in the dentate molecular layer. This suggests that, although CB1 receptors are known to be reduced in density on glutamatergic axons, the CB1-receptor-expressing GABAergic axons sprout, or there is an increase of CB1-receptor levels on these fibers. The changes of CB1 immunostaining in association with the GABAergic inhibitory system appear to correlate with the severity of pyramidal cell loss in the CA1 subfield. These results confirm the involvement of the endocannabinoid system associated with GABAergic transmission in human temporal lobe epilepsy (TLE), as well as in the chronic phase of the pilocarpine model in mice. Pharmacotherapy aimed at the modulation of endocannabinoidmediated retrograde synaptic signaling should take into account the opposite change in CB1-receptor expression observed on glutamatergic versus GABAergic axon terminals.
The molecular mechanisms of resistance to fluoroquinolones, tetracyclines, an aminocyclitol, macrolides, a lincosamide, a phenicol, and pleuromutilins were investigated in Mycoplasma bovis. For the identification of mutations responsible for the high MICs of certain antibiotics, whole-genome sequencing of 35 M. bovis field isolates and 36 laboratory-derived antibiotic-resistant mutants was performed. In vitro resistant mutants were selected by serial passages of M. bovis in broth medium containing subinhibitory concentrations of the antibiotics. Mutations associated with high fluoroquinolones MICs were found at positions 244 to 260 and at positions 232 to 250 (according to Escherichia coli numbering) of the quinolone resistance-determining regions of the gyrA and parC genes, respectively. Alterations related to elevated tetracycline MICs were described at positions 962 to 967, 1058, 1195, 1196, and 1199 of genes encoding the 16S rRNA and forming the primary tetracycline binding site. Single transversion at position 1192 of the rrs1 gene resulted in a spectinomycin MIC of 256 g/ml. Mutations responsible for high macrolide, lincomycin, florfenicol, and pleuromutilin antibiotic MICs were identified in genes encoding 23S rRNA. Understanding antibiotic resistance mechanisms is an important tool for future developments of genetic-based diagnostic assays for the rapid detection of resistant M. bovis strains. KEYWORDS antibiotic resistance, cattle, Mycoplasma bovisA ntibiotics are among the most important therapeutic tools in the veterinary and human medicine, but their use is limited since resistance tends to evolve in pathogenic bacteria. The microorganisms are exposed to selective pressure by the use of antimicrobials in medicine and agriculture, favoring the development, survival, and spread of resistant clones (1).Mycoplasma spp. are members of the class Mollicutes and comprise the simplest life form that can replicate independently from the host (2). Mycoplasma spp. have no cell wall and they have a limited number of metabolic pathways. The greatly reduced genome size and coding capacity of Mycoplasma spp. makes them a good model for genetic studies. Mycoplasma spp. are fast-evolving bacteria with several human and animal pathogens; however, their importance is often underestimated (2). Mycoplasma bovis is a major cause of calf pneumonia, mastitis and arthritis, and it is responsible for significant economic losses (3). Adequate housing and appropriate antibiotic treatment
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