03518naa a2200337 a 450000100080000000500110000800800410001902200140006002400340007410000210010824501910012926000090032052024870032965000290281665300250284565300080287065300140287865300200289265300240291270000200293670000230295670000190297970000160299870000200301470000200303470000190305470000190307370000160309270000290310877300430313719916752017-06-19       2014    bl uuuu     u00u1 u    #d  a1471-21647 a10.1186/1471-2164-15-5352DOI1 aZULETA, L. F. G.  aThe complete genome of Burkholderia phenoliruptrix strain BR3459a, a symbiont of Mimosa flocculosabhighlighting the coexistence of symbiotic and pathogenic genes.h[electronic resource]  c2014  aBACKGROUND: Burkholderia species play an important ecological role related to xenobiosis, the promotion of plant growth, the biocontrol of agricultural diseases, and symbiotic and non-symbiotic biological nitrogen fixation. Here, we highlight our study as providing the first complete genome of a symbiotic strain of B. phenoliruptrix, BR3459a (=CLA1), which was originally isolated in Brazil from nodules of Mimosa flocculosa and is effective in fixing nitrogen in association with this leguminous species. RESULTS: Genomic comparisons with other pathogenic and non-pathogenic Burkholderia strains grouped B. phenoliruptrix BR3459a with plant-associated beneficial and environmental species, although it shares a high percentage of its gene repertoire with species of the B. cepacia complex (Bcc) and "pseudomallei" group. The genomic analyses showed that the bce genes involved in exopolysaccharide production are clustered together in the same genomic region, constituting part of the Group III cluster of non-pathogenic bacteria. Regarding environmental stresses, we highlight genes that might be relevant in responses to osmotic, heat, cold and general stresses. Furthermore, a number of particularly interesting genes involved in the machinery of the T1SS, T2SS, T3SS, T4ASS and T6SS secretion systems were identified. The xenobiotic properties of strain BR3459a were also investigated, and some enzymes involved in the degradation of styrene, nitrotoluene, dioxin, chlorocyclohexane, chlorobenzene and caprolactam were identified. The genomic analyses also revealed a large number of antibiotic-related genes, the most important of which were correlated with streptomycin and novobiocin. The symbiotic plasmid showed high sequence identity with the symbiotic plasmid of B. phymatum. Additionally, comparative analysis of 545 housekeeping genes among pathogenic and non-pathogenic Burkholderia species strongly supports the definition of a new genus for the second branch, which would include BR3459a. CONCLUSIONS: The analyses of B. phenoliruptrix BR3459a showed key property of fixing nitrogen that together with genes for high tolerance to environmental stresses might explain a successful strategy of symbiosis in the tropics. The strain also harbours interesting sets of genes with biotechnological potential. However, the resemblance of certain genes to those of pathogenic Burkholderia raise concerns about large-scale applications in agriculture or for bioremediation.  aFixação de Nitrogênio  aComparative genomics  aFBN  aGenômica  aNitrogen fixing  aPathogenic Bacteria1 aCUNHA, C. de O.1 aCARVALHO, F. M. de1 aCIAPINA, L. P.1 aSOUZA, R. C1 aMERCANTE, F. M.1 aFARIA, S. M. de1 aBALDANI, J. I.1 aSTRALIOTTO, R.1 aHUNGRIA, M.1 aVASCONCELOS, A. T. R. de  tBMC Genomicsgv.15, p. 535, Jun. 2014.