RESUMO
The alarming rise in hard-to-treat bacterial infections is of great concern to human health. Thus, the identification of molecular mechanisms that enable the survival and growth of pathogens is of utmost urgency for the development of more efficient antimicrobial therapies. In challenging environments, such as presence of antibiotics, or during host infection, metabolic adjustments are essential for microorganism survival and competitiveness. Toxin-antitoxin systems (TASs) consisting of a toxin with metabolic modulating activity and a cognate antitoxin that antagonizes that toxin are important elements in the arsenal of bacterial stress defense. However, the exact physiological function of TA systems is highly debatable and with the exception of stabilization of mobile genetic elements and phage inhibition, other proposed biological functions lack a broad consensus. This review aims at gaining new insights into the physiological effects of TASs in bacteria and exploring the experimental shortcomings that lead to discrepant results in TAS research. Distinct control mechanisms ensure that only subsets of cells within isogenic cultures transiently develop moderate levels of toxin activity. As a result, TASs cause phenotypic growth heterogeneity rather than cell stasis in the entire population. It is this feature that allows bacteria to thrive in diverse environments through the creation of subpopulations with different metabolic rates and stress tolerance programs.
RESUMO
Os sistemas toxina-antitoxinas (TA) compreendem um conjunto de genes que são amplamente difundidos em procariotos. No cromossomo, os sistemas podem estar envolvidos na indução de morte celular em resposta a condições estressantes, indução de persistência, formação de biofilme, colonização de novos nichos, manutenção da mobilidade bacteriana e virulência de bactérias patogênicas. Em E. coli K12, 36 sistemas TA foram descritos, dos quais o do tipo II é o mais abundante e estudado. Dentre as oito toxinas pesquisadas nesse trabalho, o gene da toxina HipA está presente em 76 das 100 cepas de ExPEC estudadas. Apesar da abundância de hipA em ExPEC e em diversos genomas bacterianos, a participação dos sistemas hipA/B na indução da persistência ainda não é clara. Portanto, o sistema hipA/B de duas cepas ExPEC isoladas de infecção sanguínea foi deletado, e estas foram avaliadas quando a indução da persistência bacteriana na presença de antibióticos, formação de biofilme, resistência ao soro e sobrevivência em macrófagos. O sistema TA hipA/B não influenciou no fenótipo de resistência ao soro humano e na sobrevivência intracelular em macrófagos, no entanto, participou da indução da persistência por ciprofloxacino em um isolado (EC182); e da formação de biofilme em superfície de vidro do isolado (EC273)
Toxin-antitoxin (TA) systems comprise a set of genes that are widespread in prokaryotes. On the chromosome, the systems may be involved in the induction of cell death in response to stressful conditions, persistence induction, biofilm formation, colonization of new niches, maintenance of bacterial mobility and virulence. In E. coli K12, 36 TA systems have been described, of which type II is the most abundant. Among the eight toxins searched in this work, hipA is present in 76 bacteria of the 100 ExPEC strains studied. Despite the abundance of hipA in ExPEC and in several bacterial genomes, the participation of hipA/B modules in the persistence is still unclear. Therefore, hipA/B system of two ExPEC strains isolated from blood infection was deleted and consequently evaluated in bacterial persistence induced by antibiotics, serum resistance and macrophage survival. Despite the fact that, the TA hipA/B system did not influence the phenotype of resistance to human serum and intracellular survival in macrophages. Herein, we described that hipA/B was important for persistence induction in one isolate (EC182); and may participate in the biofilm formation on the glass surface in the other studied strain (EC273)
Assuntos
Sistemas Toxina-Antitoxina , Biofilmes , Escherichia coli Extraintestinal Patogênica/classificação , Antibacterianos/efeitos adversosRESUMO
INTRODUCTION: This study assessed the cleaning, shaping, and disinfection abilities of 2 instrumentation systems in molar root canals using a novel correlative analytical approach. METHODS: The root canals from extracted mandibular and maxillary molars with apical periodontitis were pair matched according to anatomic similarities as determined by micro-computed tomographic analysis and prepared with either XP-endo Shaper (FKG Dentaire, La Chaux-de-Fonds, Switzerland) (n = 16) or Reciproc Blue (VDW, Munich, Germany) (n = 16) instruments and 2.5% sodium hypochlorite irrigation. Pre- and postpreparation micro-computed tomographic scans were used to identify and calculate the unprepared surface areas (shaping), which were histobacteriologically evaluated for the presence of residual bacteria (disinfection) and pulp tissue remnants (cleaning) in each canal third. RESULTS: Unprepared canal surface areas for XP-endo Shaper and Reciproc Blue in the full canal length were approximately 26% and 19% (P < .05), respectively (30% and 23% in the apical part of the canal, P > .05). Preparation with Reciproc Blue resulted in 37.5% canals free of bacteria in all sections examined and 56% in the apical sections only. XP-endo Shaper resulted in 44% canals free of bacteria in all sections, and 56% in the apical part of the canal only. Pulp tissue remnants were not observed in 31% (all canal sections) and 50% (apical canal sections) of specimens from both instrument systems. No significant differences were observed between instruments when comparing the amount of pulp tissue remnants and the number of cases negative for bacteria and tissue remnants (P > .05). CONCLUSIONS: Although the Reciproc Blue instrument had superior shaping ability in comparison with XP-endo Shaper, both systems performed similarly in cleaning and disinfecting root canals. Irregular canals and difficult-to-reach areas were not thoroughly cleaned and disinfected by any of the tested systems.
Assuntos
Periodontite Periapical , Preparo de Canal Radicular , Cavidade Pulpar , Humanos , Dente Molar , Microtomografia por Raio-XRESUMO
Bordetella pertussis is the causative agent of pertussis, aka whooping cough. Although generally considered an extracellular pathogen, this bacterium has been found inside respiratory epithelial cells, which might represent a survival strategy inside the host. Relatively little is known, however, about the mechanism of internalization and the fate of B. pertussis inside the epithelia. We show here that B. pertussis is able to enter those cells by a mechanism dependent on microtubule assembly, lipid raft integrity, and the activation of a tyrosine-kinase-mediated signaling. Once inside the cell, a significant proportion of the intracellular bacteria evade phagolysosomal fusion and remain viable in nonacidic lysosome-associated membrane-protein-1-negative compartments. In addition, intracellular B. pertussis was found able to repopulate the extracellular environment after complete elimination of the extracellular bacteria with polymyxin B. Taken together, these data suggest that B. pertussis is able to survive within respiratory epithelial cells and by this means potentially contribute to host immune system evasion.