Efecto de la temperatura en el subproteoma de membrana externa de Escherichia coli

[es]En sus habitas naturales, los microorganismos están en un estado constante de adaptación a cambios tanto bióticos como abióticos. Ante situaciones de estré s, como por ejemplo cambios en nutriente s, temperatura o de osmolar idad , la s estrategias de supervivencia o adapta ción se puede n manifestar como cambios fenotípicos y genotípicos . En este estudio se analizaron algunos mecanismos de cambio asociados a la supervivencia y la composición proteica de membrana en Escherichia coli (bact eria mesófila), al ser expuesta a condiciones de ayuno y a temperaturas subó ptimas (4 y 20ºC). Al realizar un análisis comparativ o del subproteoma de membrana entre estas dos temperaturas, se observó que ante la ausencia de nutrientes, E. coli respondía de forma diferen te en la expresió n de proteí nas as ociadas a estructura (lipoproteínas), conservación de la energía y transporte, con un aumento en el nú mero de proteí nas expresadas a 20 o C. Se observó, además, una importante diferencia en la supervivencia a estas dos temperaturas, donde el número de células en el estado viable no cultivable (VNC) representaron un porcentaje importante a 20ºC

Early response to nanoparticles in the Arabidopsis transcriptome compromises plant defence and root-hair development through salicylic acid signalling

Background: The impact of nano-scaled materials on photosynthetic organisms needs to be evaluated. Plants represent the largest interface between the environment and biosphere, so understanding how nanoparticles affect them is especially relevant for environmental assessments. Nanotoxicology studies in plants allude to quantum size effects and other properties specific of the nano-stage to explain increased toxicity respect to bulk compounds. However, gene expression profiles after exposure to nanoparticles and other sources of environmental stress have not been compared and the impact on plant defence has not been analysed. Results: Arabidopsis plants were exposed to TiO2-nanoparticles, Ag-nanoparticles, and multi-walled carbon nanotubes as well as different sources of biotic (microbial pathogens) or abiotic (saline, drought, or wounding) stresses. Changes in gene expression profiles and plant phenotypic responses were evaluated. Transcriptome analysis shows similarity of expression patterns for all plants exposed to nanoparticles and a low impact on gene expression compared to other stress inducers. Nanoparticle exposure repressed transcriptional responses to microbial pathogens, resulting in increased bacterial colonization during an experimental infection. Inhibition of root hair development and transcriptional patterns characteristic of phosphate starvation response were also observed. The exogenous addition of salicylic acid prevented some nano-specific transcriptional and phenotypic effects, including the reduction in root hair formation and the colonization of distal leaves by bacteria. Conclusions: This study integrates the effect of nanoparticles on gene expression with plant responses to major sources of environmental stress and paves the way to remediate the impact of these potentially damaging compounds through hormonal priming.