Influence of nutrients addition and bioaugmentation on the hydrocarbon biodegradation of a chronically contaminated Antarctic soil.

Complexity involved in the transport of soils and the restrictive legislation for the area makes on-site bioremediation the strategy of choice to reduce hydrocarbons contamination in Antarctica. The effect of biostimulation (with N and P) and bioaugmentation (with two bacterial consortia and a mix of bacterial strains) was analysed by using microcosms set up on metal trays containing 2.5 kg of contaminated soil from Marambio Station. At the end of the assay (45 days), all biostimulated systems showed significant increases in total heterotrophic aerobic and hydrocarbon-degrading bacterial counts. However, no differences were detected between bioaugmented and nonbioaugmented systems, except for J13 system which seemed to exert a negative effect on the natural bacterial flora. Hydrocarbons removal efficiencies agreed with changes in bacterial counts reaching 86 and 81% in M10 (bioaugmented) and CC (biostimulated only) systems. Results confirmed the feasibility of the application of bioremediation strategies to reduce hydrocarbon contamination in Antarctic soils and showed that, when soils are chronically contaminated, biostimulation is the best option. Bioaugmentation with hydrocarbon-degrading bacteria at numbers comparable to the total heterotrophic aerobic counts showed by the natural microflora did not improve the process and showed that they would turn the procedure unnecessarily more complex.

Extracellular proteases from the Antarctic marine pseudoalteromonas sp. P96-47 strain.

The extracellular protease-production capacity of 33 bacterial isolates taken from marine biotopes in King George Island, Antarctica, was evaluated in liquid cultures. The P96-47 isolate was selected due to its high production capacity and was identified as Pseudoalteromonas sp. The optimal growth temperature was 20 degrees C and the optimal for protease production was 15 degrees C. Proteases were purified from culture supernatants, developing a multiple-band profile in zymograms. They were classified as neutral metalloproteases and worked optimally at 45 degrees C with an Eact of 47 kJ/mol. Their stability was higher at neutral pH, retaining more than 80% of activity at pH 6-10 after 3 h incubation at 4 degrees C. After 90 min incubation at 40 and 50 degrees C, the percentages of residual activities were 78% and 44%. These results contribute to the basic knowledge of Antarctic marine proteases and also help evaluate the probable industrial applications of P96-47 proteases.

Extracellular proteases from the Antarctic marine Pseudoalteromonas sp. P96-47 strain / Proteasas extracelulares de la cepa marina antártica Pseudoalteromonas sp. P96-47

The extracellular protease-production capacity of 33 bacterial isolates taken from marine biotopes in King George Island, Antarctica, was evaluated in liquid cultures. The P96-47 isolate was selected due to its high production capacity and was identified as Pseudoalteromonas sp. The optimal growth temperature was 20 °C and the optimal for protease production was 15 °C. Proteases were purified from culture supernatants, developing a multiple-band profile in zymograms. They were classified as neutral metalloproteases and worked optimally at 45 °C with an Eact of 47 kJ/ mol. Their stability was higher at neutral pH, retaining more than 80% of activity at pH 6-10 after 3 h incubation at 4 °C. After 90 min incubation at 40 and 50 °C, the percentages of residual activities were 78% and 44%. These results contribute to the basic knowledge of Antarctic marine proteases and also help evaluate the probable industrial applications of P96-47 proteases.

La capacidad productora de proteasas extracelulares de 33 aislamientos bacterianos tomados de biotopos marinos en la Isla Rey Jorge, Antártida, fue evaluada en cultivo líquido. El aislamiento P96-47 fue seleccionado debido a su alta capacidad productora y fue identificado como Pseudoalteromonas sp. La temperatura óptima de crecimiento fue de 20 °C y la de producción de 15 °C. Las proteasas fueron purificadas a partir del sobrenadante de cultivo, y en los zimogramas desarrollaron un perfil de múltiples bandas. Estas proteasas fueron clasificadas como metaloproteasas neutras y se observó que trabajan óptimamente a 45 °C, con una Eact de 47 kJ/ mol. Su estabilidad fue superior a pH neutro y retuvieron más del 80% de su actividad a pH 6-10 después de 3 h de incubación a 4 °C. Luego de 90 min de incubación a 40 y 50 °C, las actividades residuales fueron 78% y 44%, respectivamente. Los resultados que se presentan en este trabajo contribuyen al conocimiento básico de las proteasas marinas antárticas y también a evaluar las probables aplicaciones industriales de las proteasas de P96-47.

Factors influencing protease production by two Antarctic strains of Stenotrophomonas maltophilia.

The influence of culture medium buffer capacity, the supplementation of culture medium with L-ala and the requirement of calcium for exoprotease production by Antarctic psychrotrophic Stenotrophomonas maltophilia strains ANT-1-1 and ANT-7-1 were examined. When increasing concentrations of calcium chloride (0 to 0.3 g l-1) were added to culture media, maximum protease production yields increased 70-75% (ANT-1-1) and 50% (ANT-7-1), while biomass levels showed little difference. Calcium was also necessary for optimal activity of proteases. L-ala had no effect on protease production. The reduction in buffer capacity, with the consequent change in external pH, had a positive effect, enhancing protease yields. Secretion of proteases into the medium started at the beginning of the stationary phase, corresponding with a rise in pH values up to pH 8.7 and was maximal at 36 h of culture. These results indicate that the regulation of calcium concentration and buffer capacity and also pH monitoring are factors to be considered when the design of an industrial culture medium and the optimisation of protease production processes using these Antarctic strains are concerned.

Factors influencing protease production by two Antarctic strains of Stenotrophomonas maltophilia

The influence of culture medium buffer capacity, the supplementation of culture medium with L-ala and the requirement of calcium for exoprotease production by Antarctic psychrotrophic Stenotrophomonas maltophilia strains ANT-1-1 and ANT-7-1 were examined. When increasing concentrations of calcium chloride (0 to 0.3 g l-1) were added to culture media, maximum protease production yields increased 70-75 (ANT-1-1) and 50 (ANT-7-1), while biomass levels showed little difference. Calcium was also necessary for optimal activity of proteases. L-ala had no effect on protease production. The reduction in buffer capacity, with the consequent change in external pH, had a positive effect, enhancing protease yields. Secretion of proteases into the medium started at the beginning of the stationary phase, corresponding with a rise in pH values up to pH 8.7 and was maximal at 36 h of culture. These results indicate that the regulation of calcium concentration and buffer capacity and also pH monitoring are factors to be considered when the design of an industrial culture medium and the optimisation of protease production processes using these Antarctic strains are concerned.

Factors influencing protease production by two Antarctic strains of Stenotrophomonas maltophilia

The influence of culture medium buffer capacity, the supplementation of culture medium with L-ala and the requirement of calcium for exoprotease production by Antarctic psychrotrophic Stenotrophomonas maltophilia strains ANT-1-1 and ANT-7-1 were examined. When increasing concentrations of calcium chloride (0 to 0.3 g l-1) were added to culture media, maximum protease production yields increased 70-75 (ANT-1-1) and 50 (ANT-7-1), while biomass levels showed little difference. Calcium was also necessary for optimal activity of proteases. L-ala had no effect on protease production. The reduction in buffer capacity, with the consequent change in external pH, had a positive effect, enhancing protease yields. Secretion of proteases into the medium started at the beginning of the stationary phase, corresponding with a rise in pH values up to pH 8.7 and was maximal at 36 h of culture. These results indicate that the regulation of calcium concentration and buffer capacity and also pH monitoring are factors to be considered when the design of an industrial culture medium and the optimisation of protease production processes using these Antarctic strains are concerned.(AU)

Factors influencing protease production by two Antarctic strains of Stenotrophomonas maltophilia.

The influence of culture medium buffer capacity, the supplementation of culture medium with L-ala and the requirement of calcium for exoprotease production by Antarctic psychrotrophic Stenotrophomonas maltophilia strains ANT-1-1 and ANT-7-1 were examined. When increasing concentrations of calcium chloride (0 to 0.3 g l-1) were added to culture media, maximum protease production yields increased 70-75

(ANT-1-1) and 50

(ANT-7-1), while biomass levels showed little difference. Calcium was also necessary for optimal activity of proteases. L-ala had no effect on protease production. The reduction in buffer capacity, with the consequent change in external pH, had a positive effect, enhancing protease yields. Secretion of proteases into the medium started at the beginning of the stationary phase, corresponding with a rise in pH values up to pH 8.7 and was maximal at 36 h of culture. These results indicate that the regulation of calcium concentration and buffer capacity and also pH monitoring are factors to be considered when the design of an industrial culture medium and the optimisation of protease production processes using these Antarctic strains are concerned.