Capacidad de bacterias halófilas para capturar sodio in Vitro y su posible aplicación en bioremediación en suelos salinos-sódicos
Ability of Halophile Bacteria to Capturesodium and Its Possible Application in Bioremediation of Saline-Sodic Soil
Ability of Halophile Bacteria to Capturesodium and Its Possible Application in Bioremediation of Saline-Sodic Soil
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Las prácticas agrícolas inadecuadas han sido la causa del aumento de los suelos salinos–sódicos en todo el planeta. Su recuperación se ha hecho principalmente cambiando el sodio por otro catión, generalmente calcio, remediando en forma mecánica y usando plantas halotolerantes. Aunque estas prácticas controlan en alguna medida el problema, no se ha podido hacer una recuperación efectiva en estos suelos. Este trabajo presenta como alternativa, el uso de bioremediación con bacterias halófilas. El objetivo de la investigación fue evaluar la capacidad de cinco especies de bacterias halófilas para capturar iones sodio in vitro y diseñar una propuesta para su posible aplicación en bioremediación de suelos sódicos y salinos. La captura del sodio se demostró comparando la concentración inicial de la solución de sodio sin inocular y la concentración de la misma con la bacteria inoculada a través de la técnica de espectroscopia de absorción atómica.Las bacterias que demostraron la capacidad de captura de sodio in vitro fueron: Vibrio alginolyticus, Vibrio metschnikovii, Flavimonas oryzihabitans y Agrobacterium tumefasciens. Serratia marcescens no demostró captura. La comprobación de la captura de sodio permitió hacer dos propuestas: diseñar un bioreactor con un consorcio microbiano que incluya las bacterias que capturaron sodio en el experimento y bacterias autóctonas presentes en los suelos salinos y sódicos; utilizar ingeniería genética para implantar el gen de bomba de sodio de la especie con mejor captura, en especies nativas existentes en este tipo de suelos. The inadequate agricultural practices have been the cause of the increase of saline-sodic soils in the entire planet. Its recovery has been done mainly changing sodium by another cation, generally calcium, remedying in mechanical form and using halotolerant plants. Although these practices control the problem to a certain extent, it has not been able to make an effective recovery in these soils. This work displays as an alternative, the use of bioremediation with halophiles bacteria. The objective of the investigation was to evaluate the capacity of five species of halophiles to capture in vitro sodium ions and to design a proposal for its possible application in bioremediation of sodic and saline soils. The capture of sodium was demonstrated by comparing the initial concentration of the sodium solution without inoculating and the concentration of the same one with the bacterium inoculated through the technique of spectroscopy of atomic absorption.The bacteria that demonstrated the capacity to capture sodium in vitro were: Vibrio alginolyticus, Vibrio metschnikovii, Flavimonas oryzihabitans and Agrobacterium tumefasciens. Serratia marcescens did not demonstrate capture. The verification of the sodium capture allowed as to make two proposals: to design a bioreactor with a microbial partnership that includes the bacteria that captured sodium in the experiment and native bacteria in saline and sodic soils and to use genetic engineering to implant the gene of sodium bomb of the species with better capture in existing indigenous flora in this type of grounds.
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